Thesis for the degree of doctor of philosophy On Aging and the Role of Ubp3 in Heterochromatic Gene Silencing and Protein Quality Control David Öling Department of Chemistry and Molecular Biology Cover picture: an old ubp3∆ mutant cell displaying protein aggregates in green (Ssa2-GFP), bud scars in red (WGA) and the nucleus in blue (DAPI). The image is presented as a maximum intensity projection of several Z-stack widefield fluorescence images. Pictures taken and edited by: David Öling ISBN: 978-91-628-132-9 http://hdl.handle.net/2077/36643 © David Öling All rights reserved. No part of this publication may be reproduced or transmitted, in any form or by any means, without written permission. Printed by: Ale Tryckteam, Bohus, Sweden 2014. To Family and Friends Abstract Aging is characterized by a build-up of damage in organisms ranging from protists to multi- cellular species. This damage adversely affects core components such as DNA and proteins which are necessary to sustain life. Remarkably, as an old yeast cell divides, its daughter cell is fully rejuvenated suggesting that age-related damage can be asymmetrically inherited and/or completely ameliorated. This thesis approaches the central question of how cells combat such damage to allow longevity. Specific interest was directed towards the deubiquitinating enzyme Ubp3 which had already been shown to be tightly linked to regulation of transcription and proteome surveillance, both of which are essential in cells adaptation to stress. In this thesis, I show that cells lacking Ubp3 are short-lived despite displaying decreased unequal recombination at rDNA and increased silencing at all three heterochromatic regions in S. cerevisiae subjected to transcriptional silencing. These findings are at odds with existing aging-models in yeast, highlighting that increased silencing at rDNA is associated with long lifespan. Instead, our data suggest that premature aging in cells devoid of UBP3 is caused by a pathway other than rDNA recombination/silencing. Indeed, I found that Ubp3 has an important dual role in protein quality control by saving or destroying aberrant protein species depending on the stage at which the damaged protein is committed for proteasomal destruction. Furthermore, in virgin and young cells lacking UBP3, aggregated proteins accumulated prematurely at a juxta- nuclear position whereas wild-type cells showed no indication of protein damage. In middle- aged and older cells in the same mutant, more aggregates accumulated at a peripheral location. This accumulation of peripheral aggregates correlated, in time, with a decline in mutant cell survival. Similar to Ubp3, the well-characterized silencing-factor Sir2 is known to regulate other aging- processes unlinked to silencing. We show that Sir2-deficient cells display increased daughter cell inheritance of stress and age-induced misfolded proteins deposited in aggregates and inclusion bodies. This asymmetric inheritance has been argued to take place in a passive manner due to slow and random diffusion of aggregates. We present evidence that this is not a plausible scenario. The control of damage inheritance is more likely mediated by Sir2- dependent regulation of the chaperonin CCT which is required for folding actin and feeding the polarisome with properly folded substrates. We discuss data underlying these conflicting models and seek to understand which model best explains how damage asymmetry is achieved. Keywords: Aging, protein damage, segregation, transcriptional silencing, rDNA, UBP3, SIR2, protein aggregates Abbreviations ATP Adenosine triphosphate CPY Carboxy peptidase Y CVT Cytoplasm to vacuole targeting DNA Deoxyribonucleic acid DSB Double strand break DUB Deubiquitinating enzyme eccDNA Extra chromosomal circular DNA E-Pro EXP-promoter ER Endoplasmatic reticulum ERAD Endoplasmatic reticulum associated degradation ERC Extra chromosomal circle ERQC Endoplasmatic reticulum quality control GFP Green fluorescent protein Hsp Heat shock protein IPOD Insoluble protein deposit JUNQ Juxta nuclear quality control compartment MAT Mating type MTC Mitochondrial translation control NPC Nuclear pore complex ORC Origin recognition complex PQC Protein quality control rDNA Ribosomal DNA RENT Regulator of nucleolar silencing and telophase exit RFB Replication fork block RLS Replicative lifespan RNA Ribonucleic acid RNAPI Ribonucleic acid polymerase I RNAPII Ribonucleic acid polymerase II RNAPIII Ribonucleic acid polymerase III ROS Reactive oxygen species SGA Synthetic genetic array TF Transcription factor TFIID Transcription factor II D TFIIE Transcription factor II E TFIIH Transcription factor II H TOR Target of rapamycin ts Temperature sensitive Ub Ubiquitin UPS Ubiquitin proteasome system Index 1. Introduction ......................................................................................................................................... 1 1.1 Background .................................................................................................................................... 1 1.2 Theories of aging ............................................................................................................................ 1 1.3 Yeast as a model system for studying aging .................................................................................. 4 2. Aging factors and their inheritance ..................................................................................................... 6 2.1 Malfunctioning mitochondria ......................................................................................................... 6 2.2 Vacuolar acidity ............................................................................................................................. 8 2.3 ERCs and transcriptional control .................................................................................................... 9 2.3.1 Chromatin organization .......................................................................................................... 9 2.3.2 Mating type loci .................................................................................................................... 10 2.3.3 Telomeres ............................................................................................................................. 11 2.3.4 rDNA .................................................................................................................................... 12 2.3.5 Segregation of ERCs ............................................................................................................ 13 2.4 Damaged proteins and protein quality control ............................................................................. 14 2.4.1 Protein misfolding and aggregation ...................................................................................... 14 2.4.2 Chaperones and disaggregation ............................................................................................ 17 2.4.3 The ubiquitin proteasome system ......................................................................................... 18 2.4.3.1 Ubiquitination ............................................................................................................ 20 2.4.3.2 Deubiquitination ........................................................................................................ 22 2.4.4 Spatial quality control .......................................................................................................... 24 2.4.4.1 Q-bodies/stress-foci/peripheral aggregates ................................................................ 25 2.4.4.2 JUNQ and IPOD ........................................................................................................ 25 2.4.4.3 Other quality control compartments .......................................................................... 28 2.4.5 Segregation of aggregates .................................................................................................... 29 3. Aim, results and discussion ............................................................................................................... 32 3.1 Role of Ubp3 in genomic silencing .............................................................................................. 32 3.2 Role of Ubp3 in protein quality control and aging ....................................................................... 36 3.3 Asymmetric inheritance of damaged proteins .............................................................................. 41 4. Concluding remarks .......................................................................................................................... 44 5. Acknowledgments ............................................................................................................................. 48 6. References ......................................................................................................................................... 50 Papers included in this thesis: I. Öling D, Masoom R, Kvint K (2014) Loss of Ubp3 increases Silencing, decreases Unequal Recombination in rDNA, and shortens the Replicative Lifespan in Saccharomyces cerevisiae. Molecular biology of the cell.25:1916- 1924 II. Öling D, Eisele F, Kvint K, Nyström T (2014) Opposing roles of Ubp3- dependent deubiquitination regulate replicative lifespan and heat resistance. The EMBO journal 33: 747-761 III. Liu B, Larsson L, Caballero A, Hao X, Öling D, Grantham J, Nyström T (2010) The polarisome is required for segregation and retrograde transport of protein aggregates. Cell 140: 257-267 IV. Liu B, Larsson L, Franssens V, Hao X, Hill SM, Andersson V, Höglund D, Song J, Yang X, Öling D, Grantham J, Winderickx J, Nystrom T (2011) Segregation of protein aggregates involves actin and the polarity machinery. Cell 147: 959-961 Other publications: V. Caballero A, Ugidos A, Liu B, Öling D, Kvint K, Hao X, Mignat C, Nachin L, Molin M, Nyström T (2011) Absence of mitochondrial translation control proteins extends lifespan by activating sirtuin-dependent silencing. Molecular Cell 42: 390-400 1 1. Introduction 1.1 Background A consequence of modern medicine is that the quality and length of life has improved. One result of this is that there is a shift in the number of aged individuals in our population. A positive trend indeed, but this benefit comes with a cost as the primary source for many illnesses and diseases is old age. It is therefore of importance to understand the underlying mechanisms of aging in general, and age-related disorders in particular so that we can enjoy a full and healthy life. 1.2 Theories of aging Aging is often defined as an organism's time-dependent loss of tissue and cellular function accompanied with decreased fertility and increased mortality (Kirkwood & Austad, 2000). However, there are organisms that do not follow the conventional pattern of changes in mortality and fertility usually accompanied by old age. One example is the mute swan (Cygnus olor) that shows, contrary to humans, an increase in fertility and near constant mortality rate during its lifespan (Jones et al, 2014). Such examples aside, there are several theories describing the aging process, none of which are mutually exclusive and should be viewed as complementary. However, most theories adopt well to the declaration by Dobzhansky, that "nothing in biology makes sense except in the light of evolution" (Ayala, 1977). Weismann's theory of programmed death was one of the first aging hypotheses based on Darwinian evolutionary theory (Weismann, 1882). The 2 concept of programmed death implies that natural selection inheritably programs death to occur in order to limit the lifespan of an individual. As a consequence, old and new generations will not compete for the same resources and this will benefit the whole population (not only the individual). Other similar and more contemporary "evolvability" theories of aging have been proposed, highlighting that a programmed death aids a population by allocating resources to the younger members (Goldsmith, 2008; Skulachev, 2011). However, it should be noted that Weismann later discarded his theory in favor for the "germ-plasm" theory stating that the immortal "germ-line" transfers the hereditary material whereas the soma (somatoplasm) "ages" (Weismann, 1891). In this theory, aging of the soma occurs due to resource allocation to the maintenance of the germ- line. Starting around 1950, the classical theories of aging arose as a response to the theory of "programmed death". The forerunners were Haldane, Medawar and Williams. Haldane studied the prevalence of Huntington's disease and was stunned by its frequency found in the English population. He suggested that the high frequency of this dominant, deadly neurological disease was due to the late onset of symptoms and that it therefore escaped natural selection. Medawar elaborated this idea in the theory of "mutation accumulation" (Medawar, 1952). As the name implies, it stipulates that detrimental mutations accumulate with old age. According to this theory, these mutations would not be under pressure of natural selection as it is rare to find old individuals in "the wild" due to predation and disease. Indeed, in 1966, Hamilton presented mathematical evidence coined "Hamilton's forces of natural selection" that supported the idea that natural selection declined with age (Hamilton, 1966). Williams formed the first theory, coined antagonistic pleitropy, that implied certain "aging genes" (Williams, 1957). The name suggests that certain genes are beneficial early in life but at post-reproductive age, they may become 3 detrimental. Later, in 1977, Kirkwood presented a theory that was less based in population genetics than previous ideas. His idea of aging sought answers in the physiology of the body and reproduction. The theory, coined the "disposable soma" envisions the body as disposable and the germ-line as non-disposable (Kirkwood, 1977). According to this theory, the maintenance of cellular (soma) damage competes for energy with the reproductive system (germ-line). A prediction of this theory is that the soma will gradually deteriorate as energy is allocated from the soma to keep the germ-line intact. The classical theories of aging has generated three major predictions. First, it is not likely that specific genes have been selected to promote aging. Second, aging is not programmed but rather a consequence of the accumulated somatic damage generated due to limited investments in maintenance and repair. Finally, there are genes whose actions may be adverse at old age (Kirkwood & Austad, 2000; Williams, 1957). These genes may simply have escaped natural selection (Huntington's disease), or they are pleiotropic in the sense that the organism enjoys positive effects of the allele at a young age but adverse effects at older age. More evidence and clear cut examples in support of the latter scenario is still pending. However, the target of rapamycin (TOR) drives growth and protein synthesis whereas its inhibition promotes aging. It has been suggested that these features make the TOR-encoding genes fall in to the category of antagonistic pleitropy (Blagosklonny, 2010). In this context it is interesting to note that most pathways regulating longevity are in some manner accompanied by an increased stress tolerance. 4 1.3 Yeast as a model system for studying aging Research in mammalian cell systems is ideal to gather experimental evidence and draw conclusions relevant for humans. However, there is one big problem; their long lifespans. Rats and mice live 3-5 years and primates up to 40 years (Steinkraus et al, 2008). Nevertheless, research done in rodents has contributed greatly to our understanding of aging pathways. At the cellular level, human or mouse fibroblasts have traditionally been the preferred cell model as they have a limited proliferative capacity before they reach senescence - the Hayflick limit (Hayflick, 1965). Invertebrate organisms have proven to be invaluable for aging- research because of their short lifespans and that they are easily manipulated genetically and environmentally. The most common invertebrate model systems are fruit flies (Drosophila melanogaster), worms (Caenorhabditis elegans) and yeast (Saccharomyces cerevisiae) with lifespans ranging from months to weeks, down to days. Yeast, in fact, may serve as a unicellular model to study both antagonistic pleiotropy and the disposable soma theory of aging since, like old animals, old yeast cells are rare in a population. Yeast provides an exceptional model system when studying aging in general and cellular segregation in particular. Yeast divide asymmetrically by budding, leaving the larger mother with a bud scar (Seichertova et al, 1975) and a larger cell volume (Hartwell & Unger, 1977). Utilizing these characteristics of yeast, Robert Mortimer was the first to perform a replicative lifespan (RLS) analysis already in the late 1950s (Mortimer & Johnston, 1959). He did not, however, attempt to link replicative aging in yeast to higher multi-cellular organisms. Is it feasible to utilize a single cell yeast species such as Saccharomyces cerevisiae to predict cellular mechanisms in multi-cellular 5 organisms? Yes, one hypothesis proposes that yeast can be used to predict replicative aging for mitotic or stem cell populations in complex organisms (Longo et al, 2012). Yeast has also been used extensively to study chronological aging which is thought to share features with non-dividing or post-mitotic mammalian cells (Longo et al, 2012). In addition, many pathways known to regulate aging such as calorie restriction is conserved in yeast, worms, flies and many more organisms (Masoro, 2005). Yeast has also been utilized to study SGS1, the yeast homologue of the human WRN gene which is implicated in Werner’s syndrome, a rare genetic disorder characterized by premature aging in young adults (Yamagata et al, 1998). Another well characterized and conserved gerontogene is the silent information regulator SIR2, which together with ribosomal DNA (rDNA) was recently confirmed to be a major determinant of RLS (Kwan et al, 2013). This protein deacetylase is implicated in various aging pathways, a number of which are discussed in the subsequent chapters. 6 2. Aging factors and their inheritance A yeast mother cell produces a finite number of daughter cells before it reaches a state of senescence. Remarkably, each daughter cell has a full replicative potential and may divide 20-30 times even when generated from an old mother cell. This implies that there are one or more senescence factors that are retained in the mother cell (Egilmez & Jazwinski, 1989; Henderson & Gottschling, 2008). There are at least four criteria that need to be met in order to classify as an "aging factor". First, the senescence factor should be more abundant in old cells. Second, introducing such factors in young cells should accelerate their aging. Third, reducing the progressive accumulation of a putative senescence factor should extend the lifespan. Last, the senescence factor should be retained in the mother cell during cytokinesis (Henderson & Gottschling, 2008). The last criteria of asymmetric segregation of aging factors may be viewed as the mother's sacrifice so that her progeny can start out in life free of damage. In yeast, at least four such factors have been characterized: malfunctioning mitochondria, vacuolar acidity, extrachromosomal ribosomal DNA circles (ERCs) and damaged proteins. The latter two are given special emphasis in this thesis. 2.1 Malfunctioning mitochondria Damaged or faulty mitochondria is one putative senescence factor that accumulate with replicative age in yeast cells (Erjavec et al, 2013; Higuchi et al, 2013; Klinger et al, 2010; Scheckhuber et al, 2007; Veatch et al, 2009). It has been shown that mutations that reduce age-related mitochondrial fragmentation and dysfunction can extend the RLS of mother cells (Scheckhuber et al, 2007). Interestingly, mitochondria are segregated asymmetrically, with the healthier 7 mitochondria being primarily inherited by the daughter cell (Klinger et al, 2010; McFaline-Figueroa et al, 2011). Such a filtering process is intriguing and calls for a short summary of how mitochondria are currently thought to be inherited. Several reports suggest that mitochondria are transferred to the daughter cell via actin cables and the myosin V-type protein Myo2 (Vevea et al, 2014). Myo2 moves towards the daughter cell by its own motor-force, but against the actin cable flow. This is because actin monomers are inserted at the polarisome, a site at the tip of the daughter cell, which causes a flow backwards to the mother cell. This implies that factors entering the bud need, by necessity, to move faster than the backward cable flow. Evidently, cells utilize this feature to transport reduced and healthy mitochondria (to the daughter) which move faster against the flow than oxidized and malfunctioning mitochondria (Higuchi et al, 2013). Furthermore, manipulation of the cable counter-flow by mutations in the MYO1 gene (reduced flow) resulted in more faulty mitochondria reaching the daughter cell whereas a TPM2 mutation (enhanced flow) resulted in increased inheritance of healthy mitochondria. Importantly, increasing the inheritance of healthy mitochondria by enhancing the flow, prolonged the lifespan. Segregation of mitochondria is also regulated by Sir2. This protein deacetylase is implicated in actin cable abundance and cytoskeletal functions - a process which is further addressed in paper III. Removal of SIR2 decreases the flow of actin cables and retrograde movement of mitochondria thereby allowing defect mitochondria to enter the daughter cell. Over-expression of SIR2, on the other hand, had the opposite effect on cable flow and mitochondrial inheritance (Higuchi et al, 2013). Intriguingly, deletion of SOV1, a member of the yeast mitochondrial translation module (MTC), increases Sir2 activity (Paper V). It has been speculated that such boost in activity, similar to Sir2 over-expression, provides an assurance mechanism whereby daughters receive the best 8 mitochondria as the mother cell ages and mitochondrial quality decline (Nystrom & Liu, 2014). 2.2 Vacuolar acidity The sequence of events that occur during yeast aging is a topic of intensive research and has recently been traced back to an early functional decline of the vacuole. Gottschling and colleagues observed that mitochondrial inner- membrane potential was reduced by this functional decline manifested as an increase in vacuolar pH of the mother cell (Hughes & Gottschling, 2012). The mitochondrial membrane potential itself leads to further age associated problems such as genomic maintenance and loss of heterozygosity (Veatch et al, 2009). Vacuoles, like mitochondria, are transferred to the daughter as Myo2-cargo transported on actin cables (Hill et al, 1996). Intriguingly, the vacuole found in a mother cell displays erroneous pH control whereas the vacuole in a daughter cell regains its acidic pH (Hughes & Gottschling, 2012). This type of segregation control differs from the filtering of functional/dysfunctional mitochondria as it is the daughter specific environment that is important for a fully functional vacuole (Hughes & Gottschling, 2012). The link between vacuole function and mitochondrial deficiency was proposed to be due to the reduced storage capacity for neutral amino acids which require proper acidification of the vacuole (Hughes & Gottschling, 2012). The authors speculated that, since mitochondria catabolize neutral amino acids, the excess of leaked amino acids in the cytoplasm could potentially interfere with proton-dependent mitochondrial carrier processes with subsequent failure to maintain the membrane potential. It is still obscure why vacuolar pH control initially fails and how daughter cells rejuvenate this control. 9 2.3 ERCs and transcriptional control Another example of aging factors are ERCs (Sinclair & Guarente, 1997). In S. cerevisiae, rDNA consists of 100 to 200 tandem repeats (Fig. 1) and the ERCs may be formed by excision from these repeats. Subsequently, they can replicate via an autonomously replicating sequence (rARS) embedded in the sequence (Fig. 1). Formation of ERCs is tightly linked to transcriptional silencing and recombination frequency at the rDNA loci and has been observed to dramatically influence cellular aging (Sinclair & Guarente, 1997). In effect, silencing may be described as regions of poorly transcribed chromatin. In Saccharomyces cerevisiae, in addition to rDNA, silenced chromatin is found at the sub-telomeric regions and at the HMR and HML - cryptic mating type loci (Aparicio et al, 1991; Rusche et al, 2003). The Sir-complex establishes, maintains and spreads silent chromatin across these heterochromatin domains (Strahl-Bolsinger et al, 1997). In order to understand how ERCs are linked to silencing, it is important to understand the fundamental organization and structure of chromatin and rDNA. 2.3.1 Chromatin organization DNA does not exist as a "naked" linear double-stranded helix but is instead organized in a complex of proteins and DNA which may be visualized as beads on a string. Each "bead" on the string represents a functional unit called a nucleosome. In yeast, this protein complex is represented by two copies each of the four core histones: H2A, H2B, H3 and H4 around which the DNA is wrapped. This compaction of DNA is called chromatin and is the constituent of chromosomes. The condensation enables the DNA to fit inside the nucleus, provides strengthening during mitosis and prevents DNA damage. 10 Furthermore, the condensation of chromatin is highly influential on transcription as it may facilitate or hinder access to genes by RNA polymerase and transcription factors. A region where chromatin is condensed is called heterochromatin. In contrast, a region where DNA is less condensed is called euchromatin. In order for genes to be accessed and transcription initiated, the chromatin needs to be "opened", or remodeled. The chromatin environment is determined by the joint actions of DNA methylation, ATP driven remodeling, incorporation of a histone variant (H2A.Z) and post transcriptional modifications (e.g. methylation, acetylation, phosphorylation and ubiquitination of histones) (Chen & Dent, 2014). Consequently, such modifications change the binding-affinity between histones and DNA (loosened/tightened) but can also promote recruitment of transcription factors. Thus, repositioning, modification or expelling of histones/nucleosomes is key in transcriptional, replicational and recombinatorial regulation (Rando & Winston, 2012). 2.3.2 Mating type loci Yeast has the ability to switch sex (mating type) depending on what allele (MATa or MATα) is present at the MAT locus. This is possible because yeast has additional silent copies of each allele: HMR (hidden mating type right) and HML (hidden mating type left). The mechanism for establishing silent mating type at the HML/HMR loci relies on the Sir-complex which is recruited to flanking domains called E and I silencers. The silencer domains contain unique binding sites for DNA-binding proteins (Rap1 and Abf1) and origin recognition complex (ORC). Together these factors recruit the Sir-multi-protein-complex consisting of Sir1, Sir2, Sir3 and Sir4 (Ghidelli et al, 2001; Moretti et al, 1994). Subsequent to Sir-complex recruitment, Sir2 deacetylates a H3 and H4 tail residing on an adjacent nucleosome. The Sir-complex (except Sir1) then 11 proceeds to spread in between silencer domains to establish silent chromatin (Wierman & Smith, 2013). 2.3.3 Telomeres Telomeric silencing is regulated by Sir2 and Sir4 in complex. This complex is recruited via Rap1 associated with certain terminal telomeric sequences. Bound Sir2/Sir4 pursues with histone deacetylation together with Sir3 at subtelomeric regions (Hecht et al, 1996; Hoppe et al, 2002; Tanny & Moazed, 2001). The H4 tail lysine K16 is particularly important since it has a dual role in silencing. Acetylated H4K16 recruits Sir2/Sir4 and repels Sir3, whereas deacetylation of H4K16 mediated by Sir2 promotes binding of the Sir-holocomplex (Sir2/3/4) (Oppikofer et al, 2011). This implies that acetylation/deacetylation of H4K16 mediates sequential binding of Sir-proteins to establish silent chromatin. In higher eukaryotes it is well established that telomere length plays a key role in cellular senescence (Harley, 1991). Dividing cells not expressing telomerase, an enzyme able to "repair" shortened telomeres, will eventually reach a critical telomere length which is linked to the Hayflick limit. Consequently, cells reach senescence, or occasionally, restore length via a recombination event (Draskovic & Londono Vallejo, 2013). In yeast (S. cerevisiae) telomerase is constitutively expressed resulting in perpetual maintenance of telomere length in both mother and daughter cells (D'Mello & Jazwinski, 1991). However, mutations causing shortening of telomeres, do shorten RLS (Lundblad & Szostak, 1989). 12 2.3.4 rDNA The mechanism of silencing at rDNA is different from that of telomeres and MAT since the deacetylase Sir2 is the only Sir-protein occupying this region. Instead, the scaffold for Sir2 recruitment constitutes the nucleolar protein Net1 and the phosphatase Cdc14, the so called RENT complex (Regulator of Nucleolar Silencing and Telophase exit) (Huang & Moazed, 2003). RENT localizes to two distinct regions in the rDNA locus (Fig. 1). First, RENT may be recruited near the 35S promoter. Divergently, RENT is also recruited to a place in the intragenic spacer region 1 (IGS1) where it mediates silencing of the RNAPII-dependent promoter E-pro. The recruitment of RENT to IGS1 is facilitated by Fob1 binding to the replication fork block (RFB, Fig. 1). In this process, Fob1 acts synergistically with a cohibin complex (Lrs4 and Csm1) to suppress rDNA recombination between rDNA repeats (Huang et al, 2006). Figure 1. Schematic representation of chromosome XII and the rDNA repeats. Each repeat encodes a RNAPI-dependent 35S precursor rRNA and a 5S RNAPIII transcribed 5S rRNA. Each unit also contains two intragenic spacer regions (IGS1, 2). Other significant sites are the RFB , the autonomously replicating sequence-rARS and the bidirectional, RNAPII- dependent E-pro. 13 Maintenance of silencing of the highly repetitive rDNA is crucial for cell viability. Fob1 is primarily known for blocking replication at RFB in rDNA (Brewer & Fangman, 1988). Consequently, binding of Fob1 may cause double strand breaks (DSBs) of the DNA at stalled replication forks, which in turn could lead to unequal sister chromatid recombination. This mechanism is an important control mechanism for regulating rDNA copy number and variation. In agreement with this, in a fob1∆ mutant, unequal sister chromatid recombination is reduced and rDNA copy number is stabilized (Kobayashi et al, 1998). Another layer of rDNA copy number control is provided by Sir2 that silences an RNAPII-dependent promoter (E-Pro) at rDNA (Fig. 1). The transcriptional activity at E-Pro is thought to dissociate cohesin complexes responsible for binding sister chromatids together (Kobayashi & Ganley, 2005). Subsequently, a broken sister chromatid-end may recombine unequally during DSB repair thereby regulating copy number change, loss of genetic material, and ERC formation (Huang & Moazed, 2006; Kobayashi & Ganley, 2005). Consistent with this, a sir2∆ mutation prevents cohesin association thereby promoting unequal recombination and increased rDNA copy number. Taken together, Sir2 and Fob1 are key regulators of transcriptional silencing, recombination frequency, and stability at rDNA. These processes are further addressed in paper I. 2.3.5 Segregation of ERCs ERCs accumulate in aging cells and are distributed asymmetrically in a mother- cell biased manner (Sinclair & Guarente, 1997). One reason for this bias is that ERCs do not contain a centromeric sequence which is a prerequisite for equal distribution between mother and daughter cell (Murray & Szostak, 1983). Recently, two mechanisms further explaining this distribution have been 14 proposed: the tethering model and the diffusion model. The tethering model is explained by the attachment of ERCs to nuclear pore complexes (NPCs) which are themselves retained in the mother via a septin-dependent diffusion barrier (Shcheprova et al, 2008). The diffusion model, on the other hand, is founded on data showing that the NPCs are not blocked from moving into the daughter nucleus. Instead, the mother-biased segregation of ERCs is achieved by the geometry of the bud neck together with the short time of mitosis (Gehlen et al, 2011) which, would not allow diffusion of ERCs into daughters. To this end, it is noteworthy that the latter model does not exclude the possibility that ERCs are attached to NPCs. 2.4 Damaged proteins and protein quality control Damaged and aggregated proteins have recently emerged as bona fide aging factors in yeast and the levels of these factors increase in aging mother cells (Aguilaniu et al, 2003; Erjavec et al, 2007; Hill et al, 2014). To understand how protein aggregates might lead to aging it is important to highlight the protein quality control (PQC) system aimed at avoiding the occurrence of such protein damage. 2.4.1 Protein misfolding and aggregation PQC is a complex surveillance system evolved to combat proteomic aberrancies. Protein damage may be induced by exogenous or endogenous errors and stress causing misfolding. For instance, protein misfolding can occur as proteins are de novo synthesized, or more rarely, due to mutations. Misfolded or aberrant proteins are either refolded by molecular chaperones or cleared by proteolytic 15 degradation. Either way, these actions prevent proteins from aggregating. Understanding protein aggregation and its underlying mechanism is medically important since certain neurodegenerative diseases are associated with this feature. Aggregation of a protein may occur when it is in an intermediate or misfolded state where it exposes hydrophobic residues. These residues are normally buried when the protein is in its native conformation. However, if exposed, they trigger aggregation (Hartl & Hayer-Hartl, 2009). Another cause of aggregate formation is mutations causing a protein to consistently misfold. Neurodegenerative diseases such as Huntington's, Parkinson's and Alzheimer's are represented by this type of inherent misfolding and subsequent aggregation (Chiti & Dobson, 2006; Powers et al, 2009; Ross & Poirier, 2004). Other, more frequent occurring aggregating scenarios include mis-incorporation of amino acids during translation or faulty assembly of protein complexes (Drummond & Wilke, 2008). Aggregation is also induced by environmental stressors such as heat and oxidative stress. Heat stress tends to cause widespread but reversible misfolding of proteins whereas oxidative stress is associated with both reversible and irreversible protein modifications (Parsell et al, 1994). Reactive oxygen species (ROS), may also induce widespread protein damage and misfolding by replacement of certain native side-chains of amino acids by carbonyl groups (Stadtman & Levine, 2000). These protein-modifications can lead to cross- linking with other proteins and subsequent aggregation. Protein aggregation also occurs during aging. This is presumably a slower process than, for example heat shock, and the cause and effect of such aggregation is a topic of intensive research. It has been shown that oxidatively damaged and aggregated carbonylated proteins accumulate in cytoplasmic foci as a yeast cell age (Erjavec et al, 2007). We found support for a general and gradual decline in protein quality control as we observed a correlation with 16 certain types of cytoplasmic aggregates with replicative age (Paper II). These findings indicate that aged cells are less able to remove aberrant proteins and sequester them into specific inclusion bodies. Similarly, it has been suggested that such general decline in PQC is one reason for the late age onset of the aforementioned neuro-degenerative diseases (Tyedmers et al, 2010). The term "protein aggregate" is a convenient terminology used to envision a state of accumulated misfolded proteins but perhaps too generic to describe the true nature of the complex conformation of misfolded proteins found in these structures. This complexity is exemplified by the observation that the same protein can yield different aggregate morphology depending on the type of denaturing agent used to induce misfolding (Wang et al, 2010). Nevertheless, aggregates may simplistically be divided into amorphous or amyloid-like. These both aggregate classes contain -sheets to a varying degree and organization (Alberti et al, 2010). Most amorphous aggregates are extremely diverse in their structure, but it has been suggested that they consist of misfolded and aggregated proteins that are quite similar to their native conformation in solution (Qin et al, 2007). Amyloid fibrils, on the other hand, are represented by a higher amount of -sheet content which form a densely packed core made up of a continuous sheet of -strands arranged perpendicularly to the fibrillar axis (Kirschner et al, 1986). Amyloids grow at the fibrillar ends by incorporation of polypeptides with a similar primary sequence resulting in a homogenous aggregate composition. Moreover, the amyloid-like aggregates are considered as less soluble than amorphous aggregates based on their resilience to chemical perturbations that affect protein structure. The formation of this class of aggregates may be preceded by a form of prefibrillar aggregates which is highly reactive and toxic to the organism (Glabe, 2008). These prefibrillar aggregates as well as amyloid fibrils are associated with age-induced maladies such as Alzheimer's, Huntington's and Parkinson's disease. Whether age-induced 17 aggregates of non-disease proteins are amorphous or amyloid-like, or perhaps a mixture of both, is still an unresolved issue. 2.4.2 Chaperones and disaggregation The first and most effective means for the cell to maintain proteostasis is to prevent proteins from misfolding. Molecular chaperones belong to a family of multi-domain proteins governing a wide array of tasks such as: protein folding, refolding/unfolding and protein remodeling. Chaperones in yeast are to a large extent represented by heat shock proteins (Hsp) including small Hsps, Hsp40s and Hsp70s. The core components of this machinery are the Hsp60s and Hsp70s which prevent the accumulation of misfolded proteins via ATP-dependent refolding (Hartl & Hayer-Hartl, 2009). Misfolded proteins which fail to refold to its native state are degraded by proteasomes or transported to vacuoles for degradation by acidic hydrolases (Goldberg, 2003; Kirkin et al, 2009). Failure in handling of corrupt proteins by any of these components results in protein aggregation. Disaggregation or resolution of a protein aggregate requires a fine- tuned co-operation between several types of chaperones. Aggregate resolution by the oligomeric ring-forming AAA+ ATPase Hsp104 was first demonstrated in yeast (Parsell et al, 1994). However, Hsp104 alone has little effect on aggregate resolution but together with the Hsp40s and Hsp70s e.g. Ydj1 and Ssa1 respectively, it achieves its full potential as a disaggregase (Glover & Lindquist, 1998). The same is true for the Hsp40s and Hsp70s alone as they also show limited disaggregation capacity without each other. This chaperone system works mechanistically by an initial binding of the Hsp70s together with J-proteins. The binding of these components is 18 assumed to prevent access of proteases to the aggregated protein (Zietkiewicz et al, 2004). The Hsp70-protein complex is then believed to present and mediate transfer of the complex to Hsp104 via its M-domain (Haslberger et al, 2007). Subsequently, Hsp104 is proposed to execute an ATP-dependent threading action leading to extraction of a misfolded protein from the aggregate (Lum et al, 2004). However, another model has also been proposed where Hsp104 acts as a molecular crowbar where an ATP-dependent conformational change in Hsp104 rips the aggregate open leading to disaggregation (Glover & Lindquist, 1998). Disaggregation is crucial for both proteasomal degradation or chaperone mediated refolding 2.4.3 The ubiquitin proteasome system The ubiquitin proteasome system (UPS) is the principal pathway for degrading aberrant proteins in eukaryotic cells (Hershko et al, 2000). The degradation of a protein is specific and is conferred by the ubiquitin system, whereas the proteasome itself serves as a non-specific protease. The ubiquitination of a protein is governed by an enzymatic cascade tagging the protein with ubiquitin (Ub) which then serves as a signal for destruction by the proteasome. The degradation of most proteins is dependent on ATP-fueled proteases which was first described in the late 1970s (Etlinger & Goldberg, 1977). Prior to degradation, proteins are unfolded and prepared by AAA-ATPase complexes of homo- or heterohexameric ring structures for transport to the inner proteolytic compartment of the proteasome (Sauer & Baker, 2011). Degradation-products are by necessity transported inside the proteasome since the active sites are localized there (Lupas et al, 1997). The proteasome localizes to both the nucleus and cytoplasm (Tanaka, 2009). 19 The components of this degradation-complex consists of a cylinder- shaped proteolytic core, the 20S particle which is bound at one or both ends by the 19S regulatory particle (Lupas et al, 1993) (Fig. 2). These two subcomplexes together constitute the 26S proteasome (Fig. 2). The AAA-ATPase part of the 26S proteasome is represented by the subunits Rpt1-Rpt6 forming a heterohexamer which is proposed to have non-redundant functions (Bar-Nun & Glickman, 2012; Wollenberg & Swaffield, 2001). Other constituents of the 26S proteasome are the 13 Rpn-proteins which are not part of the ATPase family. The structure of the full 26S proteasome has remained elusive until recently when electron microscopy imaging shed a new light on the proteasomal composition (Lander et al, 2012; Lasker et al, 2012). The proteasome cannot degrade aggregated proteins in vitro (Gregori et al, 1995). Furthermore, it has been shown that aggregates reduce proteasomal activity in vivo (Andersson et al, 2013; Bence et al, 2001; Verhoef et al, 2002). In addition, data also suggest that genetically manipulating proteasome levels can influence yeast replicative lifespan as boosting proteasome levels increased the lifespan whereas reducing proteasome levels shortened the lifespan (Kruegel et al, 2011). Kruegel and colleagues also observed a correlation with proteasome levels and aggregate management in young cells. Interestingly, a recent study found that over-expressing the yeast metacaspase Mca1, counter-acted accumulation of unfolded proteins/aggregates and prolonged lifespan. The lifespan extension was shown to be dependent on both Hsp104 and normal proteasome levels indicating that protein aggregates/inclusions are true aging factors in the yeast model system (Hill et al, 2014). 20 Figure 2. Schematic representation of the proteasomal subunits. The 19S can bind to one or both ends of the 20S subunit. Together they constitute the full, 2.5 MDa protease complex which is the 26S proteasome. 2.4.3.1 Ubiquitination Ubiquitin is a small, ubiquitously expressed and highly conserved protein throughout the eukaryotic kingdom (Hershko & Ciechanover, 1998). Ubiquitin conjugated to a target protein can direct the substrate to a specific cellular location, trafficking route, modify the activity, recruit binding partners or present it to the 26S proteasome for destruction (Komander & Rape, 2012). Ubiquitination has also been shown to direct proteins to specific protein quality control compartments (Kaganovich et al, 2008). The ubiquitination of a protein requires three enzymes: E1 - the ubiquitin activating enzyme; E2 - the ubiquitin conjugating enzyme and E3 - the ubiquitin ligase (Pickart & Eddins, 2004). Efficient proteasomal targeting and degradation sometimes also requires a fourth, additional conjugation factor - E4, which facilitates multi-ubiquitination (Koegl et al, 1999). An additional level of regulation involves the usage of lysine residues on ubiquitin where the most common ones are K48 or K63 linkage-specific ubiquitination. A Ub-chain on K48 is sufficient to target a protein to the proteasome whereas a K63 chain has been associated with targeting membrane proteins for vacuolar degradation (Galan & Haguenauer- Tsapis, 1997; Springael et al, 1999). Moreover, these linkages of Ub may be branched differently although the function of these branches is still elusive. 21 The ubiquitination process is initiated by Ub-activation (E1) which is ATP-dependent (Fig. 3-1). The reaction involves the C-terminal domain of Ub (Gly76) attached via a thioester bond to a cysteine residue in the active center of the E1 (Sun et al, 2006). Next, in an intermediate step the activated Ub is transferred by the E1 to a ubiquitin- conjugating enzyme (E2) (Fig. 3-2). This step also requires the C-terminal domain of Ub (Gly76) which is attached to a cysteine residue of the E2 with a thioester bond. The last step is the transfer of Ub to the substrate mediated by an E3 enzyme (Fig. 3-3). The substrate protein itself is bound to the specific E3 as well as the Ub-charged E2. The substrate- ubiquitination can take place in two fashions: Ub may be transferred directly from the E2 to the substrate protein (RING E3); or from E2 to E3 and then subsequently from E3 to the substrate protein (HECT E3) (Hochstrasser, 2006). Subsequent rounds of ubiquitination may be facilitated by an E4 elongation factor (Fig. 3-4). Figure 3. Ubiquitination. 1) ATP-dependent activation of Ub carried out by an E1. 2) Ub is transferred via an E2 Ub-carrier protein. 3) If the E3 is a RING domain ligase, the E2-Ub complex binds to the E3 carrying the substrate protein and transfers the activated Ub directly to the subsrate. If the E3 is a HECT domain ligase, Ub is transferred from the E2-Ub complex to an E3 and then to the substrate. 4) Polyubiquitin chain-elongation may be facilitated by E4 ligases. 22 Only one ubiquitin activating enzymes (E1) exist in yeast (Uba1) whereas E2s are more numerous (eleven enzymes) and most abundant is the E3 family where 42 ligases have been fully characterized so far (Lee et al, 2008) (database updated 2014). Ubiquitin ligases confer specificity to the ubiquitin proteasome system. Some ligases like Ubr1, Hul5 and Ltn1 act in the cytoplasm to clear aberrant proteins whereas others, Hrd1 and Doa10 act proximally to the ER to clear membrane proteins or substrates targeted for secretion (Theodoraki et al, 2012; Vembar & Brodsky, 2008). In addition, San1 a ligase acting as a nuclear PQC component has been reported to mediate destruction of misfolded proteins that are translocated to the nucleus (Gardner et al, 2005; Heck et al, 2010; Prasad et al, 2010). There is considerable redundancy in the PQC network of ligases although it has been shown specifically that Ubr1 promotes clearance of protein aggregates, particularly when the autophagic system is deactivated (Theodoraki et al, 2012). 2.4.3.2 Deubiquitination Ubiquitin is long-lived and recycled which may seem surprising due to its attachment to substrates destined for degradation (Swaminathan et al, 1999). This is due to the action of deubiquitinating enzymes which cleave ubiquitin- protein bonds between Gly76 on ubiquitin and a Lys residue of the substrate protein or preceding ubiquitin. Deubiquitinating enzymes (DUBs) fall into a large family of cysteine proteases with four main subfamilies in yeast: the larger UBP family with 16 genes (ubiquitin-specific proteases) and the smaller Otu, Uch, and JAMM families containing one to two genes each. The Ubp enzymes vary in size, homology and structural complexity except for the conserved core catalytic domain which enables them to cleave ubiquitin from a wide range of substrates. 23 There are many major ubiquitin-controlled pathways in the cell such as cell-cycle control, DNA repair and vesicle trafficking (Kim et al, 2003). DUBs provide an extra layer of regulation by modifying the ubiquitin status of proteins involved in these pathways. DUBs act by executing various different actions. First, DUBs have the ability to process ubiquitin precursors. This biosynthetic processing is important because three of the four ubiquitin encoding genes UBI1 - UBI4 are translated as N-terminal fusions to ribosomal proteins (Finley et al, 1989). Ubiquitin is also translated as multiple linear Ub-fusions (UBI4). DUBs are responsible for the processing of these fusions to release and unblock the C-termini of ubiquitin (Fig. 4-1). Second, DUBs may edit a non- degradative Ub-signal by trimming the Ub-chain length (Fig. 4-2). This processing of the Ub-chain gives rise to a type of regulation where the Ub- linkage may be changed and thereby alter the fate of the ubiquitinated protein. Another process carried out by DUBs is to detach protein-ubiquitin chains for substrates committed for proteasomal degradation (Fig. 4-3). Targets bound for proteasomal degradation may not enter correctly if the ubiquitin chain is still attached. Moreover, degradation of ubiquitin itself is energetically unfavorable. Last, DUBs can determine the fate of a protein by removing mono/poly-Ub chains. Moreover, these unattached Ub-chains are disassembled by DUBs which is important for the recycling of Ub (Fig. 4-3 and 4-4). This process prohibits abnormal accumulation of Ub-chains which have been shown to interfere with proteasomal degradation (Amerik et al, 1997). 24 Figure 4. DUB functions. 1) DUBs cleave Ub-ribosomal hybrid fusions or polyubiquitin to generate free Ub. 2) A non-degradative Ub-chain may be edited by DUBs to change the Ub- signal. 3) Proteasomal degradation is associated with recycling of Ub which ensures homeostasis of the Ub-pool. 4) The reversal of ubiquitination determines the stability/fate of a protein. Moreover, DUBs disassemble Ub-chains to generate free Ub. 2.4.4 Spatial quality control Chaperones have also been shown to be paramount for the spatial sequestration of misfolded proteins and aggregates into distinct "compartments". Several quality control compartments have been defined in yeast and organization of aggregates into these compartments depends on the type of protein species that was initially misfolded as well as protein damaging agent used. Spatial quality control and its terminology is a young field and these following sections aim at summarizing what is currently known about various aggregates and their compartmentalization. 25 2.4.4.1 Q-bodies/stress-foci/peripheral aggregates An early stress responsive sequestration of ER-associated aggregates has recently been observed and was coined "Q-bodies" (Escusa-Toret et al, 2013). These Q-bodies form puncta that move and coalesce into larger structures which are speculated to be a transient stage prior to formation of other types of aggregates (Fig. 5) (Escusa-Toret et al, 2013). Similar to Q-bodies, there are reports that describe other transient aggregates such as "stress foci" and "peripheral aggregates" (Specht et al, 2011; Spokoini et al, 2012). These three "types" of small aggregates share many characteristics and may turn out to be the same. For example, all of them form upon heat-stress, associate with Hsp104 and are precursors for larger inclusion-body formation. Q-bodies, apparently also require ATP, sHSPs like Hsp42 and the cortical ER for maturation or formation (Sontag et al, 2014). Similarly, Hsp42 and the actin cytoskeleton are required for formation of peripheral aggregates (Specht et al, 2011). A recent study utilized the disease-associated protein Htt103Q which also form small Hsp104-associated foci similar to stress foci/Q-bodies/peripheral aggregates (Song et al, 2014). Intriguingly, the study found that Hsp42 is required for heat- induced Hsp104-associated foci but not for Htt103Q foci suggesting that the routes employed for foci formation are not identical (Song et al, 2014). We are only beginning to understand these PQC pathways and further experiments should provide insight into the requirements for these aggregation pathways. 2.4.4.2 JUNQ and IPOD Soluble but misfolded proteins appear to accumulate in a juxta nuclear quality control compartment coined JUNQ - where proteasomes are concentrated (Fig. 5) (Kaganovich et al, 2008). Another compartment called IPOD, insoluble 26 protein deposit, sequesters less soluble proteins and is localized to the periphery of the cell in the proximity to the vacuole (Fig. 5) (Spokoini et al, 2012). These two compartments vary in what cellular components they require for formation and resolution. Figure 5. Model for management of misfolded proteins. Non-native proteins which are not refolded by chaperones are ubiquitinated and directed to proteasomes for destruction in the JUNQ compartment. Simultaneously (or prior to), misfolded proteins localize to cytosolic stress foci/Q-bodies/peripheral aggregates. These smaller aggregates are either cleared or may coalesce to larger inclusion bodies like JUNQ or IPOD. Proteins destined to JUNQ co-localizes frequently with chaperones from the Hsp70 family, but less frequently with Hsp104 suggesting a more prominent role for Hsp70s in JUNQ management (paper II) (Malinovska et al, 2012; Weisberg et al, 2012). The formation of JUNQ requires the action of the ubiquitin conjugating enzymes Ubc4/Ubc5 (Kaganovich et al, 2008). The functional role of the JUNQ compartment has been suggested to be a storage depot for misfolded proteins keeping them in a folding-competent state for either refolding or destruction by the proteasome. 27 Proteins compartmentalized in the IPOD are represented by terminally misfolded proteins and amyloid-forming species such as prions or polyglutamine expanded Huntingtin. Factors co-localizing with the IPOD are Hsp104 and the autophagy marker Atg8 (Kaganovich et al, 2008). Autophagy is the vacuolar-dependent degradation of cellular material ranging from organelles and even protein aggregates (Lamark & Johansen, 2012). This process is usually mediated by a membrane-enclosed vesicle (autophagosome), which subsequently fuses with the vacuole (Reggiori & Klionsky, 2013). However, the precise role for Atg8 and autophagy in managing IPOD is still obscure. Hsp104 on the other hand, has been shown to be required for the maturation of smaller aggregates into both JUNQ and IPOD (Spokoini et al, 2012). On a functional level, the IPOD is thought of as a compartment that provides suppression of cytotoxicity caused by aggregation-prone proteins (Kaganovich et al, 2008). In support of this notion, a toxic misfolded protein generated from a point mutation - SOD1G93A, accumulates in JUNQ, but directing it away from JUNQ to IPOD reduces the harmful effects on human cell viability (Weisberg et al, 2012). The toxicity of the Sod1-mutant was speculated to be due to sequestration of Hsp70s which thereby prevented the delivery of misfolded proteins to proteasomes (Weisberg et al, 2012). Other quality control factors that regulate aggregate sorting during stress are the Hook family proteins Btn2 and Cur1. They physically interact with chaperones to provide a sorting pathway for misfolded proteins in the cytosol. It has been suggested that Btn2 together with Hsp42 promotes the accumulation of non-amyloid proteins to IPOD (Malinovska et al, 2012). In the same study, the authors also showed that Btn2 bound to the Hsp40 chaperone Sis1 promotes targeting of misfolded proteins to JUNQ. This duality in protein sorting is achieved via Cur1 which governs the sorting of Sis1 to the nucleus. Thus, 28 cytosolic concentration of chaperones determine the sorting of misfolded proteins. 2.4.4.3 Other quality control compartments The earliest defined mammalian quality control compartment is ERQC - ER- derived quality control compartment, which is localized near the centriole and acts as a deposition-site for misfolded ER-derived secretory proteins (Kamhi- Nesher et al, 2001). The subsequent degradation of these proteins by the proteasome is called ERAD (ER-associated degradation). In yeast, prior to ERAD, proteins accumulate in a membrane bound deposition site termed ERAC (ER-associated compartment) (Huyer et al, 2004). Proteins can also be cleared from the ER by an autophagy pathway. Mammalian cells and yeast show many similarities in spatial quality control as they both display JUNQ and IPOD-like compartments (Kaganovich et al, 2008). However, the utilization of cell components varies between the species. One striking example is the mammalian aggresome which share some features with the yeast IPOD. The mammalian aggresome is located at the microtubuli organizing centre and is encompassed by a vimentin cage as opposed to the yeast IPOD (Johnston et al, 1998). Targeting of proteins to the aggresome is directed by ubiquitin (in most cases), histone deacetylase 6 and dynein coupled with microtubuli (Kawaguchi et al, 2003). Furthermore, the aggresome has also been implicated in terminal sequestration of misfolded proteins, protein folding, clearance and aggregate retention (Sontag et al, 2014). Recent data also suggest that the mammalian JUNQ is surrounded by a vimentin cage, a finding which sheds new light on the definitions of PQC-compartments as well as serving as an example of how the same compartments may utilize different factors in different cell types (Ogrodnik et al, 2014). 29 2.4.5 Segregation of aggregates Mother-cell biased segregation of damaged and aggregated proteins employ several cellular components so that the daughter cell may enjoy a damage free proteome. The disaggregase Hsp104 and Sir2 are required for this asymmetric segregation as well as components regulating the actin cytoskeleton (paper III and IV) (Erjavec et al, 2007; Song et al, 2014; Tessarz et al, 2009). Aggregates containing Hsp104 may be tethered to the actin cytoskeleton and thereby retained in the mother during budding (Fig. 6). A role for Sir2 in segregation appears to involve folding of actin mediated by the chaperonin CCT. The importance of the cytoskeletal network in aggregate segregation is evident also by the requirement of the polarisome, the formin Bni1, the myosin motor protein Myo2 and the actin organization protein calmodulin - Cmd1 (paper III and IV) (Song et al, 2014). By utilizing tropomyosin and formin-dependent actin nucleation at the polarisome, daughter cells can also clear themselves of aggregates by a retrograde flow back into the mother cell (paper III). An alternative idea is that aggregates are segregated due to slow diffusion rather than actin-dependent retention in the mother cell (Zhou et al, 2011). The models explaining how aggregate asymmetry is achieved is further addressed in the discussion of paper III and IV Segregation of aggregates and sequestration of proteins to quality control compartments are tightly linked. A yeast study showed that deleting Hsp104, or inhibiting its disaggregase activity, traps aggregates in small "stress foci" and a large portion of these aggregates were passed on to the daughter cell (Spokoini et al, 2012). However, if aggregates are allowed to mature into either JUNQ or IPOD, they are retained in the mother cell (Spokoini et al, 2012). Using VHL, a model misfolding and aggregating protein, it was suggested that JUNQ is attached to the nuclear surface whereas the IPOD is attached to the 30 vacuole (Kaganovich et al, 2008; Spokoini et al, 2012). The authors concluded that the confinement of aggregates to the surface of organelles exclude them from transfer into the daughter cell. The formation and segregation of peripheral aggregates both require the actin cytoskeleton highlighting the importance of this system in asymmetrical inheritance. Interestingly, the disease protein Htt103Q which does not form either IPOD or JUNQ but rather smaller disperse aggregates reminiscent of Q-bodies, stress-foci and peripheral aggregates, also display polarity-dependent retention in the mother cell (paper IV). This evidence further strengthens the observation that smaller Hsp104-dependent aggregates as well as inclusion bodies are subjected to segregation quality control (Fig. 6) (Song et al, 2014). 31 Figure 6. Model depicting segregation of protein aggregates. Various factors establish asymmetric segregation of protein aggregates in yeast. The polarisome, the actin cytoskeleton and Hsp104 are required for the retention of aggregates in the mother cell. In addition, mother-biased segregation is also mediated via sequestration of aggregates into JUNQ and IPOD. These compartments are themselves subjected to mother biased segregation due to their attachment to the nucleus and vacuole respectively. 32 3. Aim, results and discussion The aim of this thesis was to elucidate the role of the deubiquitinating enzyme Ubp3 in aging. Specifically, I focused on heterochromatic silencing and protein quality control since Ubp3 had previously been identified as being linked to these processes. 3.1 Role of Ubp3 in genomic silencing Ubp3 is a deubiquitinating enzyme with a human orthologue in Usp10. UBP3 encodes a 101,9 kDa DUB which together with its cofactor Bre5, is involved in a number of cellular processes, some of which regulate transcription (non- transcription-related processes targeted by Ubp3 are discussed in paper II). For example, it has been shown that Ubp3 positively activates osmoresponsive genes and is required for proper induction of PHO5 (Kvint et al, 2008; Sole et al, 2011). In addition, Ubp3 interacts physically with key factors of the transcription machinery such as TFIID, TATA-binding protein (Tbp1) and RNAPII (Auty et al, 2004; Chew et al, 2010; Kvint et al, 2008). Moreover, the stability/function of both Tbp1 and RNAPII are regulated by Ubp3 (Chew et al, 2010; Kvint et al, 2008). Interestingly, loss of Ubp3 results in increased silencing at both mating-type loci and telomeres (Moazed & Johnson, 1996). Also, the authors found evidence for a physical interaction between Sir4 and Ubp3 suggesting that Ubp3 inhibits silencing via Sir4 or the Sir-complex (Moazed & Johnson, 1996). However, precisely how this works is not known. In an attempt to understand how Ubp3 affects transcription in heterochromatic regions we discovered that, in addition to mating-type loci and telomeres, Ubp3 also acts as an anti-silencing factor at rDNA. There are many factors implicated in silencing but an exact explanation of the mechanism of 33 how RNAPII-dependent transcription is obstructed is still pending. One hypothesis is that the dense structure of heterochromatin prevents accessibility of the transcription machinery. However, one study presented data showing that general transcription factors (TF) such as TBP and RNAPII assembled at HMR without subsequent initiation (Sekinger & Gross, 2001). In addition, the same group found that TFIIH and a serine5-phosphorylated RNAPII could be detected at silent promoters strongly suggesting that Sir-mediated silencing suppresses transcription at a later step (Gao & Gross, 2008). However, conflicting data from another group suggested that neither TFIIB, TFIIE nor RNAPII were localized at silenced promoters but instead, an activator (Ppr1) was present (Chen & Widom, 2005). Our data supports those of Gross and colleagues as we observed that increased silencing by loss of UBP3 correlated with lower levels of RNAPII at all silent loci in yeast suggesting that RNAPII is indeed active in wild-type cells in these regions (paper I). In addition, in ubp3∆ mutants, relative Net1/RENT-occupancy at rDNA and Sir2/3 at MAT-loci respectively, is generally higher, suggesting that silent chromatin is not fully saturated with silencing factors in wild-type cells. Taken together, RNAPII seems to be present and active in heterochromatic regions in wild-type cells and this presence is dependent on Ubp3. However, the precise mechanism how Ubp3 alters silencing is still pending. In this context, it should be addressed whether congregation of silencing factors (i.e. denseness of chromatin), presence of general TFs or recruitment/modification of RNAPII is altered in Ubp3-deficient cells. It should also be noted that relative levels of H4K16ac/H4K16 and Sir2 occupancy differ between the three heterochromatic regions in ubp3∆ mutants (paper I). Thus, distinct mechanisms may operate to silence DNA at different regions. Silencing and transcriptional regulation at the rDNA loci is intimately linked with replicative aging. One such link is ERCs which, when 34 they were first discovered, were believed to prevent cell division by titrating important factors for DNA replication and maintenance (Kaeberlein et al, 1999; Kwan et al, 2013). However, new data puts ERC formation secondary to rDNA stability as an aging factor as limited RLS has been observed regardless of the absolute number of ERCs (Ganley et al, 2009; Kwan et al, 2013). Ganley and colleagues presented evidence that a strain with reduced replication activity and low ERC-levels had a reduced lifespan due to compromised rDNA stability. No explanation for this instability was presented but the authors speculated that that non-functional DNA repair proteins are retained in the mother cell leading to accumulation of mother-specific rDNA damage. It was speculated that one possible outcome of this rDNA damage could be manifested as poor ribosome quality (Ganley et al, 2009). The RNAPII and Sir2-dependent regulation of E-pro (driving expression of non-coding transcripts) is an integral part of the rDNA theory of aging as activity of this promoter directly affects stability at the rDNA via displacement of cohesin (Kobayashi, 2011). In support of this model, it was recently shown that Sir2's effect on lifespan is predominantly mediated by its action at the rDNA E-pro and it was suggested that the resulting rDNA instability is causative for aging rather than being a byproduct of it (Saka et al, 2013). We found that a ubp3∆ mutant, which has increased silencing (i.e. down- regulates E-pro activity) at rDNA, has a reduced RLS (paper I). In addition, cells lacking Ubp3 have very little unequal recombination at rDNA suggesting that rDNA instability is not a prerequisite for aging (in ubp3∆ mutants). However, SIR2 is epistatic to UBP3 with regard to unequal recombination at rDNA, whereas loss of Sir2 requires Ubp3 for full de-repression of a URA3 allele at rDNA (paper I). These findings suggest that recombination is not directly proportional to levels of transcriptional activity at rDNA, as was previously proposed by Kobayashi and colleagues (Kobayashi & Ganley, 2005). 35 However, it is possible that Sir2 may have additional roles in inhibiting recombination that is partly independent of its role in silencing, but this has to be further studied. We found evidence that the role of Ubp3 in aging may be unlinked to silencing/unequal rDNA recombination by combining mutations of UBP3 with mutations in SIR2 and FOB1. Deletion of FOB1 somewhat suppressed the short lifespan of a ubp3∆ mutant, indicating that Fob1 either reduces recombination further, resulting in lifespan extension, or that Fob1 affects RLS extension via another pathway than rDNA recombination. Deleting SIR2 in a ubp3∆ mutant reduced lifespan to that of a sir2∆ single mutant, suggesting that a short lifespan correlates with a high recombination frequency. Deletion of UBP3 in the sir2∆ fob1∆ (same as wild-type lifespan) shortened the lifespan to that of a ubp3∆ single mutant, again suggesting a role for Ubp3 in RLS that is independent of silencing or unequal recombination in rDNA (Öling and Kvint, unpublished data). Similarly, the lifespan of sir2∆ fob1∆ double mutant calls for extra attention since deleting FOB1 does not fully suppress the short lifespan of a sir2∆ mutant while fully suppressing ERC accumulation (Kaeberlein et al, 1999). These data, suggests that both Sir2 and Ubp3 are implicated in other functions related to aging that are distinct from transcription control at rDNA. For instance, proper clearance of protein aggregates have been shown in a number of studies to be associated with premature aging (Erjavec et al, 2007; Heeren et al, 2004; Hill et al, 2014; Kruegel et al, 2011). Such roles for both Ubp3 and Sir2 are discussed further in paper II, III and IV. 36 3.2 Role of Ubp3 in protein quality control and aging As described above, Ubp3 is involved in transcriptional regulation and silencing but there is also mounting evidence that this DUB is important for PQC. For example, nutrient signaling and protein quality control is mediated in part by Ubp3-dependent degradation of mature 60S ribosomes (ribophagy) during nitrogen starvation (Kraft et al, 2008). The E3 ligase Ltn1 was recently proposed to act as an antagonizer of Ubp3 in this process (Ossareh-Nazari et al, 2014). Furthermore, Ubp3 has been shown to regulate Ras/PKA signaling by interacting with Ira2 and regulating its activity, and level of ubiquitination (Li & Wang, 2013). These findings suggest that Ubp3 is controlling both the quantity and quality of diverse proteins. Many additional processes are regulated by Ubp3 and its co-factor Bre5 during non-starvation conditions. Ubp3 regulates the degradation of Sec23, a component of the ER-Golgi transport related COPII vesicle (Cohen et al, 2003). It was later shown that the specific Sec23 degradation is regulated also by the AAA-ATPase Cdc48 and Rsp5, a ubiquitin ligase (Ossareh-Nazari et al, 2010). Ubp3 also reverses the ubiquitination of Atg19, a CVT pathway (cytoplasm to vacuole trafficking) receptor protein implicated in the vacuolar delivery of two enzymes, aminopeptidase I and alfa-mannosidase (Baxter et al, 2005). Two other seemingly unrelated processes regulated by Ubp3 include the microtubuli-system (Stu1) and DNA repair (Rad4) (Brew & Huffaker, 2002; Mao & Smerdon, 2010). The latter study showed that Ubp3 interacts physically with the 26S proteasome to facilitate destruction of Rad4. These studies point to a dual role for Ubp3 where it facilitates destruction of some proteins whereas it rescues others. This duality is addressed in paper II. To answer why cells lacking Ubp3 are short-lived even though they show increased silencing and decreased rDNA recombination, we hypothesized 37 that this might be linked to a role of Ubp3 in PQC. Craig and colleagues isolated Ubp3 as a high copy suppressor of a temperature sensitive strain deleted for the two major cytoplasmic yeast chaperones SSA1/SSA2 (Baxter & Craig, 1998). The authors proposed a model where Ubp3 over-production rescued the double mutant by reversing ubiquitination of temporarily misfolded proteins, thereby preventing proteasomal degradation and allowing some residual activity of these proteins. However, no experimental evidence for this idea was provided. The chaperones Ssa1/Ssa2 belong to a subfamily of yeast Hsp70s which also include Ssa3 and Ssa4. SSA1 and SSA2 display roughly 98% sequence homology and are functionally redundant in many cellular processes whereas SSA3 and SSA4 are less (~80%) similar to SSA1 or SSA2. There is little data on Ssa3 function and only slightly more on Ssa4. Though, one study showed that a ssa1∆ ssa2∆ mutant is synthetically dead if SSA4 also is deleted (Werner-Washburne et al, 1987). The same study also showed that deletion of SSA1/SSA2 induced expression of SSA4. Therefore, we speculated that the Ubp3-dependent suppression was achieved by up-regulating SSA4 or possibly SSA3. However, this was not the case (paper II). We next asked whether elevated Ubp3 levels provided enhanced folding capacity in the ssa1∆ ssa2∆ strain. Utilizing a luciferase refolding assay we observed no enhanced refolding activity by Ubp3 over-expression. Instead, we speculated that the suppression may be mediated by enhanced clearance of already misfolded and aggregated proteins. To address this question we used the well-characterized protein aggregate-reporter Hsp104-GFP, which is intimately connected with protein quality control and aggregate clearance (Glover & Lindquist, 1998). Hsp104 is dependent on Ssa1 or Ssa2 to find aggregates and over-production of Ubp3 did not suppress such requirement, suggesting that Ubp3-dependent suppression is mediated independently of Hsp104 (Winkler et al, 2012). 38 In the model proposed by Craig and colleagues, the loss of Ssa1/Ssa2-dependent folding activity is argued to be particularly detrimental at elevated temperatures as many proteins with residual activity are degraded rather than refolded (Baxter & Craig, 1998). Ubp3, in this model, removes ubiquitin-tags from the partly active proteins, rescues them from proteasomal degradation, and thereby allows better growth at high temperatures. We found experimental support for this model: first, we observed a Ubp3-dosage dependent suppression of Ssa1/Ssa2-deficiency where the highest levels of Ubp3 correlated with growth even at 37°C. Second, the misfolded model protein ΔssCPY* was stabilized by Ubp3-dependent deubiquitination in the absence of SSA1/SSA2. Last, we genetically altered proteasome levels by deleting RPN4 (lower levels) and UBR2 (higher levels) and crossed these mutants with a ssa1∆ ssa2∆ strain. In line with the proposed model, lowering proteasome levels in the ssa1∆ ssa2∆ allowed for better growth at high temperatures, whereas boosting proteasome levels (ubr2∆) was detrimental for viability. Intriguingly, over producing Ubp3 in ssa1∆ ssa2∆ ubr2∆ restored viability (paper II). Next, we also investigated whether the same mechanism held true for cells experiencing another kind of stress - aging. Loss of Ubp3 resulted in a shorter lifespan as did loss of SSA1/SSA2. However, over-expression of Ubp3 rescued the short lifespan of ssa1∆ ssa2∆. In contrast to heat tolerance, this suppression was dependent on normal proteasome levels as seen by deleting RPN4 in the Hsp70-deficient strain. In line with this, we also found that enhancing proteasome levels by deleting UBR2 in a ubp3∆ mutant restored the lifespan back to wild-type levels (unpublished data). One interpretation of such results is that inefficient deubiquitination by Ubp3 can partially be overcome by boosting the end point of this pathway - proteasomal destruction. These observations point to an "aging related role" for Ubp3 mediating proteasomal destruction of proteins. Thus, we conclude that the Craig model explains the role 39 of Ubp3 in certain genetic and environmental contexts such as heat stress and Hsp70 deficiency, but fails to explain the role of Ubp3 in old cells. Enhancing proteasome capacity extends lifespan and this extension has been suggested to be associated with reduced accumulation of aggregates (Kruegel et al, 2011). Similarly, aging is associated with a progressive decline in 26S proteasome activity, which could potentially redistribute misfolded proteins to specific protein aggregate compartments (Andersson et al, 2013; Kaganovich et al, 2008; Kruegel et al, 2011). Moreover, it was recently shown that the meta- caspase Mca1 acts as lifespan extending gene and that the extension required both Hsp104-dependent disaggregase activity and fully functional proteasomes which links this lifespan control to the removal of damaged and aggregated proteins (Hill et al, 2014). To this end, we sought to investigate a possible link between Ubp3, aggregate compartmentalization, and aging. To detect such a link we utilized the mother enrichment strain (Lindstrom & Gottschling, 2009) modified to C-terminally tag GFP on the endogenous Ssa2. Using this construct, we observed a premature JUNQ accumulation associated with loss of UBP3 as compared to wild-type cells. In addition, formation of peripheral aggregates was drastically accelerated in the same mutant. We suggest that this phenotype is associated with the reduced capacity of ubp3∆ mutant cells to properly deubiquitinate proteasome substrates and allow entry to the 26S proteasome. It is possible that inefficient proteasome destruction of aberrant proteins could "overwhelm" the JUNQ compartment resulting in subsequent redistribution of aberrant proteins to peripheral sites in aging cells. Consistent with this, reducing proteasome levels by RPN4 deletion displayed a similar phenotype as the ubp3∆ mutant (unpublished data). As the accumulation of peripheral aggregates coincides with accelerated aging in the absence of UBP3, it is tempting to speculate that these specific aggregates are indeed true aging factors. 40 Ubp3 can both stabilize and destabilize proteins according to our data. Rad4 has previously been shown to require Ubp3 for proper degradation (Mao & Smerdon, 2010). In contrast, Rpb1 is stabilized by Ubp3 (Kvint et al, 2008). These findings, together with data from this study on Ubc9ts and ΔssCPY* raises the question of how a DUB mechanistically can execute these two diametrically different actions on proteins. We envision deubiquitination to act at different stages towards destruction of proteins and that the timing determines the outcome. This notion is supported by the finding that ΔssCPY* was deubiquitinated and stabilized by Ubp3 over-production. This is consistent with deubiquitination occurring at a stage prior to proteasomal "commitment". In contrast, Ubp3-assisted proteasomal destruction of a substrate would not be detectable in a strain over-producing Ubp3 as this would rapidly degrade the substrate and escape analysis. However, loss of UBP3, we speculated, would result in increased ubiquitination and stabilization of such a substrate. Consistent with this, Ubc9ts exemplified this latter scenario (paper II). In conclusion, the data presented for ΔssCPY* and Ubc9ts are consistent with a scenario where Ubp3-dependent deubiquitination occurs at different stages toward commitment to proteasomal degradation (Fig. 7). 41 Figure 7. Schematic drawing of Ubp3-dependent deubiquitination. The salvage pathway (top half) depicts how a protein is rescued from destruction. The degradation pathway (lower part) depicts how a protein is committed to the proteasome for degradation. 3.3 Asymmetric inheritance of damaged proteins Sir2 has been implicated as a regulator of aging and age-related maladies in a wide variety of organisms including yeast, worms, flies, fish and mammals (Galan & Haguenauer-Tsapis, 1997; Lindstrom & Gottschling, 2009; Masoro, 2005; Springael et al, 1999). As discussed previously, the yeast Sir2 accomplishes this regulation, in part, by histone-deacetylation resulting in increased silencing and decreased formation of ERCs (Kaeberlein et al, 1999). Just like ERCs, damaged and aggregated proteins accumulate in mother cells and are subjected to a mother-cell biased segregation (Aguilaniu et al, 2003; Erjavec et al, 2007). This damage asymmetry is dependent on Hsp104 and Sir2 where the latter is linked to actin cable-dependent processes and the polarisome (paper III). The role of actin cables in damage retention has been suggested to be the result of the association of aggregates (including prions) to the actin 42 cytoskeleton thereby preventing their free diffusion into the daughter cell (Chernova et al, 2011; Tessarz et al, 2009). Sir2 deficiency reduces actin cable abundance and the velocity of retrograde actin flow from the polarisome (Erjavec & Nystrom, 2007; Higuchi et al, 2013). Apparently, in strains devoid of HSP104, specialized "compartments" such as IPOD and JUNQ are not properly maturing and aggregates are "trapped" in stress foci (Spokoini et al, 2012). These smaller foci are increasingly inherited by the daughter cell as opposed to IPOD and JUNQ which are sequestered by the mother cell. In addition, other small, stress foci-like aggregates such as those formed by Htt103Q are also asymmetrically inherited as shown in paper IV. Taken together, these findings strongly suggest a model where asymmetric segregation of damaged proteins is dependent on various factors such as a functional actin cytoskeleton, as well as tethering of aggregates to organelles. This model was challenged by Li and colleagues which suggested that asymmetric inheritance is a purely passive process due to the geometry of yeast cells and a slow random diffusion of aggregates (Zhou et al, 2011). This model views aggregate inheritance as regulated by the size of the bud neck and how long this channel is open for diffusion of aggregates. However, in this study, some aggregates appeared stationary whereas others where more mobile (Zhou et al, 2011). This diversity in aggregate population may not best be modeled by employing an average diffusion coefficient. In fact, this model was challenged in the Spokoini study due to the observation that the larger of these aggregates were IPOD or JUNQ inclusions. By definition, these aggregates cannot diffuse freely as they are attached to the vacuole and nuclear membrane respectively (Spokoini et al, 2012). A recent study tested whether the passive diffusion model or the factor-dependent tethering model was more relevant to explain how asymmetrical inheritance of aggregates is achieved (Song et al, 2014). The 43 authors argued that increasing the time for completing cytokinesis would enhance aggregate inheritance of such aggregates moved by passive diffusion. However, this was not the case. Furthermore, mutants with increased daughter cell inheritance of aggregates did not show a larger bud-neck diameter, longer generation time or increased number of aggregates. If aggregates are segregated by random diffusion, these traits would be expected by mutants displaying increased inheritance. However, neither the sir2∆ mutant nor any of the other identified mutants displayed any of the aforementioned traits. Importantly, this study identified additional factors as essential for establishing damage asymmetry. These factors include the actin-associated proteins Cmd1 and Myo2 as well as ER- Golgi transport components. Moreover, both Huntingtin 103Q and heat-induced, Hsp104-associated stress-foci were found to co-localize with Cmd1- and Myo2-enriched structures and super-resolution 3-D microscopy showed that these aggregates co-localize with the actin cytoskeleton. 44 4. Concluding remarks Faulty mitochondria, defective vacuoles, ERCs and/or rDNA instability, and damaged proteins all seem to be factors present in old yeast cells. The crucial question is: are the same factors dysfunctional in aged metazoans (animals) and can we transfer the lessons learned from yeast to therapeutically combat age- related disorders? Accumulating evidence suggest that we can answer cautiously with a "yes" to both parts of this question. For example, enrichment of dysfunctional mitochondria are causative for aging also in metazoans (Bratic & Larsson, 2013). One reason for this dysfunctionality in mice are mutations of the maternally originated mtDNA which, when transferred to the progeny, cause clonal expansion of these errors during development (Ross et al, 2013). Another mechanism, as described earlier, is dysfunctional mitochondria preceded by a collapse in vacuolar pH-control (Hughes & Gottschling, 2012). Whatever the cause for unhealthy mitochondria, keeping these organelles in good shape appears pivotal for a full lifespan. Lysosomes, similar to yeast vacuoles, are indispensable for autophagy and inhibiting this machinery triggers cellular degeneration (Rubinsztein et al, 2011). Importantly, reduced autophagic capacity is often accompanied by aging and such cellular degeneration. Therefore, targeting macro-autophagy seems like an interesting possibility for age-related therapeutic purposes. Unlike ERCs in yeast, extra chromosomal circular DNA (eccDNA) in metazoans do not seem to be causative for aging but elevated levels of eccDNA have been observed in patients suffering from Werner's syndrome (described earlier) (Kunisada et al, 1985). However, the sirtuins, which are known to regulate ERC formation and rDNA stability, may still be targeted therapeutically as the mammalian sirtuins have been shown to play a key role in age-related diseases (Guarente, 2013). The fourth, and perhaps most intensely 45 studied aging factor in this thesis is damaged proteins and there is an increasing body of evidence suggesting that aberrant and aggregated protein-species affect also the rate of metazoan aging as well as trigger age-related neurological disease (Taylor & Dillin, 2011). For example, in Caenorohabditis elegans, protein-amyloids have been chemically targeted and this resulted in an extended lifespan suggesting that such targeting may prove useful for therapeutic purposes (Alavez et al, 2011). Transcription control at the rDNA loci, which links aging to both rDNA instability and ERC formation, is influenced by UBP3 in a manner that suggests that deletion of this gene should display an extended lifespan. However, we did not observe such extension of RLS, instead defects in PQC and proteasomal degradation with subsequent accumulation of aberrant proteins seems a more likely explanation to cause premature aging in the absence of UBP3. However, our data does not exclude the possibility that transcriptional regulation by Ubp3 is causing premature aging related to alterations of the proteome. Ubp3 was shown to divergently determine the fate of two model proteins but we know little of the native substrates regulated by Ubp3. It would therefore be interesting to compare the proteome of old and young cells in both a wild-type and ubp3∆ mutant. This is particularly interesting in light of the finding that levels of certain chaperones, such as Hsp70, decline with age in rats (Heydari et al, 1993). Whether or not UBP3 (or USP10 in mammals) is a good target for therapeutic purposes related to age-related disorders is too early to predict and more research on this subject is needed. To this end, it is interesting to note that USP10 is required for efficient p53 activation in response to DNA damage and it suppresses tumor cell growth in RCC cells (Yuan et al, 2010). Moreover, several studies demonstrate that over-expression of UBP3 is able to suppress the toxicity mediated by aggregation of the Parkinson's-related protein alfa-synuclein (Cooper et al, 2006; Tenreiro et al, 2014). The suppression of this 46 toxicity was suggested to be due to an Ubp3-dependent increase of forward ER- Golgi trafficking mediated via Sec23 stabilization and subsequent promotion of vesicle exit from the ER. Recent insight of intracellular PQC-pathways has triggered my curiosity for the Hsp70-specific biochemical interaction enabling either Ssa1 or Ssa2 to present a substrate to Hsp104 for disaggregation. Further research should benefit from utilizing the ssa1∆ ssa2∆ mutant to create a cellular context where Hsp104 is largely absent from aggregates. In this environment it should be possible to screen for other factors that are important for Hsp104 in aggregate recognition. Initially, a plasmid collection containing sequences encoding the various domains of the Ssa-proteins should be generated to further study the Hsp70-Hsp104 interaction. These plasmids could also be utilized to study the effect of PQC in aging where Hsp104 is either present or absent from age- induced aggregates. The Hsp70-Hsp104 system is particularly interesting since it has been suggested to be required for formation of smaller aggregates such as stress foci, Q-bodies and peripheral aggregates. In addition, these aggregates have been speculated to be a transient stage to other types of larger aggregates/inclusion bodies (i.e. IPOD and JUNQ) (Escusa-Toret et al, 2013; Song et al, 2014; Spokoini et al, 2012). The smaller aggregates seemingly differ slightly in their nature. For example, Ubc9ts which is has been shown to form Q- bodies, move in an actin-independent (but energy-dependent) manner whereas peripheral aggregates and Htt103Q associate with actin cables (Escusa-Toret et al, 2013; Song et al, 2014; Specht et al, 2011). This discrepancy is interesting and may suggest that different proteins are directed to different spatial locations. However, another explanation is that different experimental protocols yield different results. This is exemplified by the fact that Htt103Q forms aggregates upon production whereas Ubc9ts misfold by elevated temperature, a procedure known to disrupt actin cables. In addition, some protocols utilize proteasome 47 inhibitors whereas others do not. This is important, especially as the JUNQ compartment readily forms upon inhibition of proteasomes (Kaganovich et al, 2008). Data from our group, and others, add to the complexity of this machinery since it implicates Ssa1 or Ssa2 as paramount for Hsp104 to find aggregates and perform any disaggregating activity (paper II) (Winkler et al, 2012). Yet, large IPOD like inclusions (GFP-Ubc9ts) are frequently observed in the absence of these major Hsp70s (Escusa-Toret et al, 2013), indicating that at least IPOD can form regardless of Hsp70s and presumably also Hsp104. In addition, we also observed that ΔssCPY*-GFP localizes to both IPOD and JUNQ in the absence of SSA1/SSA2 (unpublished data). However, we do not yet know if Hsp104 is present in these inclusions in this genetic context. It should also be noted that SSA4 is highly induced in the absence of SSA1 and SSA2 which may aid a small fraction of Hsp104 to localize to (or form) IPOD. A further characterization of all these aggregate-types should benefit future research in the PQC-field. PQC also encompasses asymmetrical segregation of protein aggregates. This phenomenon is analogous to the separation of germ-cell and somatic cell types in higher organisms (Guarente, 2010). Recently, it was shown that oxidatively damaged proteins segregate asymmetrically during cytokinesis of various types of stem-cells (Bufalino et al, 2013). Interestingly, these stem- cells employ different bias on the segregation of damaged components. Specifically, the cell-line that was on the receiving end of damaged proteins had in-fact always a shorter lifespan. Similar to yeast, this segregation was dependent on various factors (Ogrodnik et al, 2014). Finally, a deeper understanding of the underlying mechanisms of PQC will certainly help our understanding of why some proteins associated with neurological disorders and aging cause cytotoxicity, and how these may be therapeutically targeted. 48 5. Acknowledgments I'm grateful to my supervisors Thomas and Kristian for making my doctoral training balanced, educating, and above all, fun! Thank you for the excellent scientific input but also for the less scientific input on where to drink craft beer and what golf clubs to swing. On that note, I would also like to thank KK for another shared journey: the one of lowering our golf-HCPs! I would also like to acknowledge a number of people that mattered when I worked with this thesis. Special thanks to: Karin, for your love and patience during these years. My family: Elisabet, Crister, Martin, Nina, Elsie and Sofia for taking an interest in my work, but more importantly, for always finding time for support. My extended family through Karin: Maggan, Janne, Sofia, Martin, Rasmus and Frida for making me feel at home "down here". Thanks to past and present members (and hang-arounds) of the T.N lab. Anne for teaching me how to replica-plate and meaningful discussions about how not to starve and what legendary pants to wear etc. Sandra, Sarah, Ninja-Lisa, Stephanie and Rebecca for interesting or un-interesting discussions during experiments, travels, lunch and so on... Frederik and Anja for scientific input and always having time for a helping hand. Frederike for passionate food discussions. Ken lycka till med svenskan, du kommer trivas i Sverige. Veronica for a "fragrance-free" lab and cup-cakes. Katarina as-well, for cup-cakes (stop slacking and bring more). Mikael for guiding me through my first stumbling steps in science. Antonio, likewise, and also for hospitality, teaching me about mutantes and taking an interest in my work long after departing from the lab. Malin for hyping me up based on one lab-report but more so for your warm 49 personality. Bertil, I know you are making Paris a gayer place but you are also missed here! Laurence for an awesome approach to life. Beidong, excellent drinking(!) and table-tennis partner(!). Xin-Xin for always having time for a friendly smile. Junsheng for always having time for a laugh. Åsa for thorough advice. Örjan and Annabelle for your awesome sense of humour. Chikako, hai and best of luck! Zhaolei, good luck back in China. Lihua Chen, Ju Zheng and Qian Liu, Ni Hao Peng You Ma? Project-workers for hard and dedicated work: Gustav, Tobias, Sangar, Andrea, Carin, Sofia and Anna. I would also like to thank the guys and girls on the top-floor. Ellinor for making online-shopping for antibodies and fluorophores so easy. Stefan Hohmann for examination, Spätzle and Riesling. Jimmy, Mikael, Lars-Göran and Kristian Walterman for the occasional beer over the years. Also, thank you dudes down in the basement for technical assistance: Lars and Bruno Last, I'm grateful to my friends whom indirectly helped me in producing this thesis by being present. You know who you are. Life would be duller without you. 50 6. References Aguilaniu H, Gustafsson L, Rigoulet M, Nystrom T (2003) Asymmetric inheritance of oxidatively damaged proteins during cytokinesis. Science 299: 1751-1753 Alavez S, Vantipalli MC, Zucker DJ, Klang IM, Lithgow GJ (2011) Amyloid-binding compounds maintain protein homeostasis during ageing and extend lifespan. Nature 472: 226-229 Alberti S, Halfmann R, Lindquist S (2010) Biochemical, cell biological, and genetic assays to analyze amyloid and prion aggregation in yeast. Methods in enzymology 470: 709-734 Amerik A, Swaminathan S, Krantz BA, Wilkinson KD, Hochstrasser M (1997) In vivo disassembly of free polyubiquitin chains by yeast Ubp14 modulates rates of protein degradation by the proteasome. The EMBO journal 16: 4826-4838 Andersson V, Hanzen S, Liu B, Molin M, Nystrom T (2013) Enhancing protein disaggregation restores proteasome activity in aged cells. Aging 5: 802-812 Aparicio OM, Billington BL, Gottschling DE (1991) Modifiers of position effect are shared between telomeric and silent mating-type loci in S. cerevisiae. Cell 66: 1279-1287 Auty R, Steen H, Myers LC, Persinger J, Bartholomew B, Gygi SP, Buratowski S (2004) Purification of active TFIID from Saccharomyces cerevisiae. Extensive promoter contacts and co-activator function. The Journal of biological chemistry 279: 49973-49981 Ayala FJ (1977) "Nothing in biology makes sense except in the light of evolution": Theodosius Dobzhansky: 1900-1975. The Journal of heredity 68: 3-10 Bar-Nun S, Glickman MH (2012) Proteasomal AAA-ATPases: structure and function. Biochimica et biophysica acta 1823: 67-82 Baxter BK, Abeliovich H, Zhang X, Stirling AG, Burlingame AL, Goldfarb DS (2005) Atg19p ubiquitination and the cytoplasm to vacuole trafficking pathway in yeast. The Journal of biological chemistry 280: 39067-39076 Baxter BK, Craig EA (1998) Isolation of UBP3, encoding a de-ubiquitinating enzyme, as a multicopy suppressor of a heat-shock mutant strain of S. cerevisiae. Current genetics 33: 412-419 Bence NF, Sampat RM, Kopito RR (2001) Impairment of the ubiquitin-proteasome system by protein aggregation. Science 292: 1552-1555 51 Blagosklonny MV (2010) Revisiting the antagonistic pleiotropy theory of aging: TOR-driven program and quasi-program. Cell Cycle 9: 3151-3156 Bratic A, Larsson NG (2013) The role of mitochondria in aging. The Journal of clinical investigation 123: 951-957 Brew CT, Huffaker TC (2002) The yeast ubiquitin protease, Ubp3p, promotes protein stability. Genetics 162: 1079-1089 Brewer BJ, Fangman WL (1988) A replication fork barrier at the 3' end of yeast ribosomal RNA genes. Cell 55: 637-643 Bufalino MR, DeVeale B, van der Kooy D (2013) The asymmetric segregation of damaged proteins is stem cell-type dependent. The Journal of cell biology 201: 523-530 Chen L, Widom J (2005) Mechanism of transcriptional silencing in yeast. Cell 120: 37-48 Chen T, Dent SY (2014) Chromatin modifiers and remodellers: regulators of cellular differentiation. Nature reviews Genetics 15: 93-106 Chernova TA, Romanyuk AV, Karpova TS, Shanks JR, Ali M, Moffatt N, Howie RL, O'Dell A, McNally JG, Liebman SW, Chernoff YO, Wilkinson KD (2011) Prion induction by the short-lived, stress-induced protein Lsb2 is regulated by ubiquitination and association with the actin cytoskeleton. Molecular cell 43: 242-252 Chew BS, Siew WL, Xiao B, Lehming N (2010) Transcriptional activation requires protection of the TATA-binding protein Tbp1 by the ubiquitin-specific protease Ubp3. The Biochemical journal 431: 391-399 Chiti F, Dobson CM (2006) Protein misfolding, functional amyloid, and human disease. Annual review of biochemistry 75: 333-366 Cohen M, Stutz F, Belgareh N, Haguenauer-Tsapis R, Dargemont C (2003) Ubp3 requires a cofactor, Bre5, to specifically de-ubiquitinate the COPII protein, Sec23. Nature cell biology 5: 661-667 Cooper AA, Gitler AD, Cashikar A, Haynes CM, Hill KJ, Bhullar B, Liu K, Xu K, Strathearn KE, Liu F, Cao S, Caldwell KA, Caldwell GA, Marsischky G, Kolodner RD, Labaer J, Rochet JC, Bonini NM, Lindquist S (2006) Alpha-synuclein blocks ER-Golgi traffic and Rab1 rescues neuron loss in Parkinson's models. Science 313: 324-328 D'Mello NP, Jazwinski SM (1991) Telomere length constancy during aging of Saccharomyces cerevisiae. Journal of bacteriology 173: 6709-6713 52 Draskovic I, Londono Vallejo A (2013) Telomere recombination and alternative telomere lengthening mechanisms. Front Biosci (Landmark Ed) 18: 1-20 Drummond DA, Wilke CO (2008) Mistranslation-induced protein misfolding as a dominant constraint on coding-sequence evolution. Cell 134: 341-352 Egilmez NK, Jazwinski SM (1989) Evidence for the involvement of a cytoplasmic factor in the aging of the yeast Saccharomyces cerevisiae. Journal of bacteriology 171: 37-42 Erjavec N, Bayot A, Gareil M, Camougrand N, Nystrom T, Friguet B, Bulteau AL (2013) Deletion of the mitochondrial Pim1/Lon protease in yeast results in accelerated aging and impairment of the proteasome. Free radical biology & medicine 56: 9-16 Erjavec N, Larsson L, Grantham J, Nystrom T (2007) Accelerated aging and failure to segregate damaged proteins in Sir2 mutants can be suppressed by overproducing the protein aggregation- remodeling factor Hsp104p. Genes & development 21: 2410-2421 Erjavec N, Nystrom T (2007) Sir2p-dependent protein segregation gives rise to a superior reactive oxygen species management in the progeny of Saccharomyces cerevisiae. Proceedings of the National Academy of Sciences of the United States of America 104: 10877-10881 Escusa-Toret S, Vonk WI, Frydman J (2013) Spatial sequestration of misfolded proteins by a dynamic chaperone pathway enhances cellular fitness during stress. Nature cell biology 15: 1231-1243 Etlinger JD, Goldberg AL (1977) A soluble ATP-dependent proteolytic system responsible for the degradation of abnormal proteins in reticulocytes. Proceedings of the National Academy of Sciences of the United States of America 74: 54-58 Finley D, Bartel B, Varshavsky A (1989) The tails of ubiquitin precursors are ribosomal proteins whose fusion to ubiquitin facilitates ribosome biogenesis. Nature 338: 394-401 Galan JM, Haguenauer-Tsapis R (1997) Ubiquitin lys63 is involved in ubiquitination of a yeast plasma membrane protein. The EMBO journal 16: 5847-5854 Ganley AR, Ide S, Saka K, Kobayashi T (2009) The effect of replication initiation on gene amplification in the rDNA and its relationship to aging. Molecular cell 35: 683-693 Gao L, Gross DS (2008) Sir2 silences gene transcription by targeting the transition between RNA polymerase II initiation and elongation. Molecular and cellular biology 28: 3979-3994 Gardner RG, Nelson ZW, Gottschling DE (2005) Degradation-mediated protein quality control in the nucleus. Cell 120: 803-815 53 Gehlen LR, Nagai S, Shimada K, Meister P, Taddei A, Gasser SM (2011) Nuclear geometry and rapid mitosis ensure asymmetric episome segregation in yeast. Current biology : CB 21: 25-33 Ghidelli S, Donze D, Dhillon N, Kamakaka RT (2001) Sir2p exists in two nucleosome-binding complexes with distinct deacetylase activities. The EMBO journal 20: 4522-4535 Glabe CG (2008) Structural classification of toxic amyloid oligomers. The Journal of biological chemistry 283: 29639-29643 Glover JR, Lindquist S (1998) Hsp104, Hsp70, and Hsp40: a novel chaperone system that rescues previously aggregated proteins. Cell 94: 73-82 Goldberg AL (2003) Protein degradation and protection against misfolded or damaged proteins. Nature 426: 895-899 Goldsmith TC (2008) Aging, evolvability, and the individual benefit requirement; medical implications of aging theory controversies. Journal of theoretical biology 252: 764-768 Gregori L, Fuchs C, Figueiredo-Pereira ME, Van Nostrand WE, Goldgaber D (1995) Amyloid beta- protein inhibits ubiquitin-dependent protein degradation in vitro. The Journal of biological chemistry 270: 19702-19708 Guarente L (2010) Forever young. Cell 140: 176-178 Guarente L (2013) Calorie restriction and sirtuins revisited. Genes & development 27: 2072-2085 Hamilton WD (1966) The moulding of senescence by natural selection. Journal of theoretical biology 12: 12-45 Harley CB (1991) Telomere loss: mitotic clock or genetic time bomb? Mutation research 256: 271-282 Hartl FU, Hayer-Hartl M (2009) Converging concepts of protein folding in vitro and in vivo. Nature structural & molecular biology 16: 574-581 Hartwell LH, Unger MW (1977) Unequal division in Saccharomyces cerevisiae and its implications for the control of cell division. The Journal of cell biology 75: 422-435 Haslberger T, Weibezahn J, Zahn R, Lee S, Tsai FT, Bukau B, Mogk A (2007) M domains couple the ClpB threading motor with the DnaK chaperone activity. Molecular cell 25: 247-260 54 Hayflick L (1965) The Limited in Vitro Lifetime of Human Diploid Cell Strains. Experimental cell research 37: 614-636 Hecht A, Strahl-Bolsinger S, Grunstein M (1996) Spreading of transcriptional repressor SIR3 from telomeric heterochromatin. Nature 383: 92-96 Heck JW, Cheung SK, Hampton RY (2010) Cytoplasmic protein quality control degradation mediated by parallel actions of the E3 ubiquitin ligases Ubr1 and San1. Proceedings of the National Academy of Sciences of the United States of America 107: 1106-1111 Heeren G, Jarolim S, Laun P, Rinnerthaler M, Stolze K, Perrone GG, Kohlwein SD, Nohl H, Dawes IW, Breitenbach M (2004) The role of respiration, reactive oxygen species and oxidative stress in mother cell-specific ageing of yeast strains defective in the RAS signalling pathway. FEMS yeast research 5: 157-167 Henderson KA, Gottschling DE (2008) A mother's sacrifice: what is she keeping for herself? Current opinion in cell biology 20: 723-728 Hershko A, Ciechanover A (1998) The ubiquitin system. Annual review of biochemistry 67: 425-479 Hershko A, Ciechanover A, Varshavsky A (2000) Basic Medical Research Award. The ubiquitin system. Nature medicine 6: 1073-1081 Heydari AR, Wu B, Takahashi R, Strong R, Richardson A (1993) Expression of heat shock protein 70 is altered by age and diet at the level of transcription. Molecular and cellular biology 13: 2909-2918 Higuchi R, Vevea JD, Swayne TC, Chojnowski R, Hill V, Boldogh IR, Pon LA (2013) Actin dynamics affect mitochondrial quality control and aging in budding yeast. Current biology : CB 23: 2417-2422 Hill KL, Catlett NL, Weisman LS (1996) Actin and myosin function in directed vacuole movement during cell division in Saccharomyces cerevisiae. The Journal of cell biology 135: 1535-1549 Hill SM, Hao X, Liu B, Nystrom T (2014) Life-span extension by a metacaspase in the yeast Saccharomyces cerevisiae. Science 344: 1389-1392 Hochstrasser M (2006) Lingering mysteries of ubiquitin-chain assembly. Cell 124: 27-34 Hoppe GJ, Tanny JC, Rudner AD, Gerber SA, Danaie S, Gygi SP, Moazed D (2002) Steps in assembly of silent chromatin in yeast: Sir3-independent binding of a Sir2/Sir4 complex to silencers and role for Sir2-dependent deacetylation. Molecular and cellular biology 22: 4167-4180 55 Huang J, Brito IL, Villen J, Gygi SP, Amon A, Moazed D (2006) Inhibition of homologous recombination by a cohesin-associated clamp complex recruited to the rDNA recombination enhancer. Genes & development 20: 2887-2901 Huang J, Moazed D (2003) Association of the RENT complex with nontranscribed and coding regions of rDNA and a regional requirement for the replication fork block protein Fob1 in rDNA silencing. Genes & development 17: 2162-2176 Huang J, Moazed D (2006) Sister chromatid cohesion in silent chromatin: each sister to her own ring. Genes & development 20: 132-137 Hughes AL, Gottschling DE (2012) An early age increase in vacuolar pH limits mitochondrial function and lifespan in yeast. Nature 492: 261-265 Huyer G, Longsworth GL, Mason DL, Mallampalli MP, McCaffery JM, Wright RL, Michaelis S (2004) A striking quality control subcompartment in Saccharomyces cerevisiae: the endoplasmic reticulum- associated compartment. Molecular biology of the cell 15: 908-921 Johnston JA, Ward CL, Kopito RR (1998) Aggresomes: a cellular response to misfolded proteins. The Journal of cell biology 143: 1883-1898 Jones OR, Scheuerlein A, Salguero-Gomez R, Camarda CG, Schaible R, Casper BB, Dahlgren JP, Ehrlen J, Garcia MB, Menges ES, Quintana-Ascencio PF, Caswell H, Baudisch A, Vaupel JW (2014) Diversity of ageing across the tree of life. Nature 505: 169-173 Kaeberlein M, McVey M, Guarente L (1999) The SIR2/3/4 complex and SIR2 alone promote longevity in Saccharomyces cerevisiae by two different mechanisms. Genes & development 13: 2570-2580 Kaganovich D, Kopito R, Frydman J (2008) Misfolded proteins partition between two distinct quality control compartments. Nature 454: 1088-1095 Kamhi-Nesher S, Shenkman M, Tolchinsky S, Fromm SV, Ehrlich R, Lederkremer GZ (2001) A novel quality control compartment derived from the endoplasmic reticulum. Molecular biology of the cell 12: 1711-1723 Kawaguchi Y, Kovacs JJ, McLaurin A, Vance JM, Ito A, Yao TP (2003) The deacetylase HDAC6 regulates aggresome formation and cell viability in response to misfolded protein stress. Cell 115: 727-738 Kim JH, Park KC, Chung SS, Bang O, Chung CH (2003) Deubiquitinating enzymes as cellular regulators. Journal of biochemistry 134: 9-18 Kirkin V, McEwan DG, Novak I, Dikic I (2009) A role for ubiquitin in selective autophagy. Molecular cell 34: 259-269 56 Kirkwood TB (1977) Evolution of ageing. Nature 270: 301-304 Kirkwood TB, Austad SN (2000) Why do we age? Nature 408: 233-238 Kirschner DA, Abraham C, Selkoe DJ (1986) X-ray diffraction from intraneuronal paired helical filaments and extraneuronal amyloid fibers in Alzheimer disease indicates cross-beta conformation. Proceedings of the National Academy of Sciences of the United States of America 83: 503-507 Klinger H, Rinnerthaler M, Lam YT, Laun P, Heeren G, Klocker A, Simon-Nobbe B, Dickinson JR, Dawes IW, Breitenbach M (2010) Quantitation of (a)symmetric inheritance of functional and of oxidatively damaged mitochondrial aconitase in the cell division of old yeast mother cells. Experimental gerontology 45: 533-542 Kobayashi T (2011) Regulation of ribosomal RNA gene copy number and its role in modulating genome integrity and evolutionary adaptability in yeast. Cellular and molecular life sciences : CMLS 68: 1395-1403 Kobayashi T, Ganley AR (2005) Recombination regulation by transcription-induced cohesin dissociation in rDNA repeats. Science 309: 1581-1584 Kobayashi T, Heck DJ, Nomura M, Horiuchi T (1998) Expansion and contraction of ribosomal DNA repeats in Saccharomyces cerevisiae: requirement of replication fork blocking (Fob1) protein and the role of RNA polymerase I. Genes & development 12: 3821-3830 Koegl M, Hoppe T, Schlenker S, Ulrich HD, Mayer TU, Jentsch S (1999) A novel ubiquitination factor, E4, is involved in multiubiquitin chain assembly. Cell 96: 635-644 Komander D, Rape M (2012) The ubiquitin code. Annual review of biochemistry 81: 203-229 Kraft C, Deplazes A, Sohrmann M, Peter M (2008) Mature ribosomes are selectively degraded upon starvation by an autophagy pathway requiring the Ubp3p/Bre5p ubiquitin protease. Nature cell biology 10: 602-610 Kruegel U, Robison B, Dange T, Kahlert G, Delaney JR, Kotireddy S, Tsuchiya M, Tsuchiyama S, Murakami CJ, Schleit J, Sutphin G, Carr D, Tar K, Dittmar G, Kaeberlein M, Kennedy BK, Schmidt M (2011) Elevated proteasome capacity extends replicative lifespan in Saccharomyces cerevisiae. PLoS genetics 7: e1002253 Kunisada T, Yamagishi H, Ogita Z, Kirakawa T, Mitsui Y (1985) Appearance of extrachromosomal circular DNAs during in vivo and in vitro ageing of mammalian cells. Mechanisms of ageing and development 29: 89-99 57 Kwan EX, Foss EJ, Tsuchiyama S, Alvino GM, Kruglyak L, Kaeberlein M, Raghuraman MK, Brewer BJ, Kennedy BK, Bedalov A (2013) A natural polymorphism in rDNA replication origins links origin activation with calorie restriction and lifespan. PLoS genetics 9: e1003329 Kvint K, Uhler JP, Taschner MJ, Sigurdsson S, Erdjument-Bromage H, Tempst P, Svejstrup JQ (2008) Reversal of RNA polymerase II ubiquitylation by the ubiquitin protease Ubp3. Molecular cell 30: 498- 506 Lamark T, Johansen T (2012) Aggrephagy: selective disposal of protein aggregates by macroautophagy. International journal of cell biology 2012: 736905 Lander GC, Estrin E, Matyskiela ME, Bashore C, Nogales E, Martin A (2012) Complete subunit architecture of the proteasome regulatory particle. Nature 482: 186-191 Lasker K, Forster F, Bohn S, Walzthoeni T, Villa E, Unverdorben P, Beck F, Aebersold R, Sali A, Baumeister W (2012) Molecular architecture of the 26S proteasome holocomplex determined by an integrative approach. Proceedings of the National Academy of Sciences of the United States of America 109: 1380-1387 Lee WC, Lee M, Jung JW, Kim KP, Kim D (2008) SCUD: Saccharomyces cerevisiae ubiquitination database. BMC genomics 9: 440 Li Y, Wang Y (2013) Ras protein/cAMP-dependent protein kinase signaling is negatively regulated by a deubiquitinating enzyme, Ubp3, in yeast. The Journal of biological chemistry 288: 11358-11365 Lindstrom DL, Gottschling DE (2009) The mother enrichment program: a genetic system for facile replicative life span analysis in Saccharomyces cerevisiae. Genetics 183: 413-422, 411SI-413SI Longo VD, Shadel GS, Kaeberlein M, Kennedy B (2012) Replicative and chronological aging in Saccharomyces cerevisiae. Cell metabolism 16: 18-31 Lum R, Tkach JM, Vierling E, Glover JR (2004) Evidence for an unfolding/threading mechanism for protein disaggregation by Saccharomyces cerevisiae Hsp104. The Journal of biological chemistry 279: 29139-29146 Lundblad V, Szostak JW (1989) A mutant with a defect in telomere elongation leads to senescence in yeast. Cell 57: 633-643 Lupas A, Flanagan JM, Tamura T, Baumeister W (1997) Self-compartmentalizing proteases. Trends in biochemical sciences 22: 399-404 Lupas A, Koster AJ, Baumeister W (1993) Structural features of 26S and 20S proteasomes. Enzyme & protein 47: 252-273 58 Malinovska L, Kroschwald S, Munder MC, Richter D, Alberti S (2012) Molecular chaperones and stress-inducible protein-sorting factors coordinate the spatiotemporal distribution of protein aggregates. Molecular biology of the cell 23: 3041-3056 Mao P, Smerdon MJ (2010) Yeast deubiquitinase Ubp3 interacts with the 26 S proteasome to facilitate Rad4 degradation. The Journal of biological chemistry 285: 37542-37550 Masoro EJ (2005) Overview of caloric restriction and ageing. Mechanisms of ageing and development 126: 913-922 McFaline-Figueroa JR, Vevea J, Swayne TC, Zhou C, Liu C, Leung G, Boldogh IR, Pon LA (2011) Mitochondrial quality control during inheritance is associated with lifespan and mother-daughter age asymmetry in budding yeast. Aging cell 10: 885-895 Medawar (1952) An Unsolved Problem of Biology, London,: Lewis. Moazed D, Johnson D (1996) A deubiquitinating enzyme interacts with SIR4 and regulates silencing in S. cerevisiae. Cell 86: 667-677 Moretti P, Freeman K, Coodly L, Shore D (1994) Evidence that a complex of SIR proteins interacts with the silencer and telomere-binding protein RAP1. Genes & development 8: 2257-2269 Mortimer RK, Johnston JR (1959) Life span of individual yeast cells. Nature 183: 1751-1752 Murray AW, Szostak JW (1983) Pedigree analysis of plasmid segregation in yeast. Cell 34: 961-970 Nystrom T, Liu B (2014) The mystery of aging and rejuvenation-a budding topic. Current opinion in microbiology 18C: 61-67 Ogrodnik M, Salmonowicz H, Brown R, Turkowska J, Sredniawa W, Pattabiraman S, Amen T, Abraham AC, Eichler N, Lyakhovetsky R, Kaganovich D (2014) Dynamic JUNQ inclusion bodies are asymmetrically inherited in mammalian cell lines through the asymmetric partitioning of vimentin. Proceedings of the National Academy of Sciences of the United States of America 111: 8049-8054 Oppikofer M, Kueng S, Martino F, Soeroes S, Hancock SM, Chin JW, Fischle W, Gasser SM (2011) A dual role of H4K16 acetylation in the establishment of yeast silent chromatin. The EMBO journal 30: 2610-2621 Ossareh-Nazari B, Cohen M, Dargemont C (2010) The Rsp5 ubiquitin ligase and the AAA-ATPase Cdc48 control the ubiquitin-mediated degradation of the COPII component Sec23. Experimental cell research 316: 3351-3357 59 Ossareh-Nazari B, Nino CA, Bengtson MH, Lee JW, Joazeiro CA, Dargemont C (2014) Ubiquitylation by the Ltn1 E3 ligase protects 60S ribosomes from starvation-induced selective autophagy. The Journal of cell biology 204: 909-917 Parsell DA, Kowal AS, Singer MA, Lindquist S (1994) Protein disaggregation mediated by heat-shock protein Hsp104. Nature 372: 475-478 Pickart CM, Eddins MJ (2004) Ubiquitin: structures, functions, mechanisms. Biochimica et biophysica acta 1695: 55-72 Powers ET, Morimoto RI, Dillin A, Kelly JW, Balch WE (2009) Biological and chemical approaches to diseases of proteostasis deficiency. Annual review of biochemistry 78: 959-991 Prasad R, Kawaguchi S, Ng DT (2010) A nucleus-based quality control mechanism for cytosolic proteins. Molecular biology of the cell 21: 2117-2127 Qin Z, Hu D, Zhu M, Fink AL (2007) Structural characterization of the partially folded intermediates of an immunoglobulin light chain leading to amyloid fibrillation and amorphous aggregation. Biochemistry 46: 3521-3531 Rando OJ, Winston F (2012) Chromatin and transcription in yeast. Genetics 190: 351-387 Reggiori F, Klionsky DJ (2013) Autophagic processes in yeast: mechanism, machinery and regulation. Genetics 194: 341-361 Ross CA, Poirier MA (2004) Protein aggregation and neurodegenerative disease. Nature medicine 10 Suppl: S10-17 Ross JM, Stewart JB, Hagstrom E, Brene S, Mourier A, Coppotelli G, Freyer C, Lagouge M, Hoffer BJ, Olson L, Larsson NG (2013) Germline mitochondrial DNA mutations aggravate ageing and can impair brain development. Nature 501: 412-415 Rubinsztein DC, Marino G, Kroemer G (2011) Autophagy and aging. Cell 146: 682-695 Rusche LN, Kirchmaier AL, Rine J (2003) The establishment, inheritance, and function of silenced chromatin in Saccharomyces cerevisiae. Annual review of biochemistry 72: 481-516 Saka K, Ide S, Ganley AR, Kobayashi T (2013) Cellular senescence in yeast is regulated by rDNA noncoding transcription. Current biology : CB 23: 1794-1798 60 Sauer RT, Baker TA (2011) AAA+ proteases: ATP-fueled machines of protein destruction. Annual review of biochemistry 80: 587-612 Scheckhuber CQ, Erjavec N, Tinazli A, Hamann A, Nystrom T, Osiewacz HD (2007) Reducing mitochondrial fission results in increased life span and fitness of two fungal ageing models. Nature cell biology 9: 99-105 Seichertova O, Beran K, Holan Z, Pokorny V (1975) The chitin-glucan complex of Saccharomyces cerevisiae. III. Electron-microscopic study of the prebudding stage. Folia microbiologica 20: 371-378 Sekinger EA, Gross DS (2001) Silenced chromatin is permissive to activator binding and PIC recruitment. Cell 105: 403-414 Shcheprova Z, Baldi S, Frei SB, Gonnet G, Barral Y (2008) A mechanism for asymmetric segregation of age during yeast budding. Nature 454: 728-734 Sinclair DA, Guarente L (1997) Extrachromosomal rDNA circles--a cause of aging in yeast. Cell 91: 1033-1042 Skulachev VP (2011) Aging as a particular case of phenoptosis, the programmed death of an organism (a response to Kirkwood and Melov "On the programmed/non-programmed nature of ageing within the life history"). Aging 3: 1120-1123 Sole C, Nadal-Ribelles M, Kraft C, Peter M, Posas F, de Nadal E (2011) Control of Ubp3 ubiquitin protease activity by the Hog1 SAPK modulates transcription upon osmostress. The EMBO journal 30: 3274-3284 Song J, Yang Q, Yang J, Larsson L, Hao X, Zhu X, Malmgren-Hill S, Cvijovic M, Fernandez-Rodriguez J, Grantham J, Gustafsson CM, Liu B, Nystrom T (2014) Essential Genetic Interactors of SIR2 Required for Spatial Sequestration and Asymmetrical Inheritance of Protein Aggregates. PLoS genetics 10: e1004539 Sontag EM, Vonk WI, Frydman J (2014) Sorting out the trash: the spatial nature of eukaryotic protein quality control. Current opinion in cell biology 26: 139-146 Specht S, Miller SB, Mogk A, Bukau B (2011) Hsp42 is required for sequestration of protein aggregates into deposition sites in Saccharomyces cerevisiae. The Journal of cell biology 195: 617-629 Spokoini R, Moldavski O, Nahmias Y, England JL, Schuldiner M, Kaganovich D (2012) Confinement to organelle-associated inclusion structures mediates asymmetric inheritance of aggregated protein in budding yeast. Cell reports 2: 738-747 61 Springael JY, Galan JM, Haguenauer-Tsapis R, Andre B (1999) NH4+-induced down-regulation of the Saccharomyces cerevisiae Gap1p permease involves its ubiquitination with lysine-63-linked chains. Journal of cell science 112 ( Pt 9): 1375-1383 Stadtman ER, Levine RL (2000) Protein oxidation. Annals of the New York Academy of Sciences 899: 191-208 Steinkraus KA, Kaeberlein M, Kennedy BK (2008) Replicative aging in yeast: the means to the end. Annual review of cell and developmental biology 24: 29-54 Strahl-Bolsinger S, Hecht A, Luo K, Grunstein M (1997) SIR2 and SIR4 interactions differ in core and extended telomeric heterochromatin in yeast. Genes & development 11: 83-93 Sun F, Zhang R, Gong X, Geng X, Drain PF, Frizzell RA (2006) Derlin-1 promotes the efficient degradation of the cystic fibrosis transmembrane conductance regulator (CFTR) and CFTR folding mutants. The Journal of biological chemistry 281: 36856-36863 Swaminathan S, Amerik AY, Hochstrasser M (1999) The Doa4 deubiquitinating enzyme is required for ubiquitin homeostasis in yeast. Molecular biology of the cell 10: 2583-2594 Tanaka K (2009) The proteasome: overview of structure and functions. Proceedings of the Japan Academy Series B, Physical and biological sciences 85: 12-36 Tanny JC, Moazed D (2001) Coupling of histone deacetylation to NAD breakdown by the yeast silencing protein Sir2: Evidence for acetyl transfer from substrate to an NAD breakdown product. Proceedings of the National Academy of Sciences of the United States of America 98: 415-420 Taylor RC, Dillin A (2011) Aging as an event of proteostasis collapse. Cold Spring Harbor perspectives in biology 3 Tenreiro S, Reimao-Pinto MM, Antas P, Rino J, Wawrzycka D, Macedo D, Rosado-Ramos R, Amen T, Waiss M, Magalhaes F, Gomes A, Santos CN, Kaganovich D, Outeiro TF (2014) Phosphorylation modulates clearance of alpha-synuclein inclusions in a yeast model of Parkinson's disease. PLoS genetics 10: e1004302 Tessarz P, Schwarz M, Mogk A, Bukau B (2009) The yeast AAA+ chaperone Hsp104 is part of a network that links the actin cytoskeleton with the inheritance of damaged proteins. Molecular and cellular biology 29: 3738-3745 Theodoraki MA, Nillegoda NB, Saini J, Caplan AJ (2012) A network of ubiquitin ligases is important for the dynamics of misfolded protein aggregates in yeast. The Journal of biological chemistry 287: 23911-23922 62 Tyedmers J, Mogk A, Bukau B (2010) Cellular strategies for controlling protein aggregation. Nature reviews Molecular cell biology 11: 777-788 Wang L, Schubert D, Sawaya MR, Eisenberg D, Riek R (2010) Multidimensional structure-activity relationship of a protein in its aggregated states. Angew Chem Int Ed Engl 49: 3904-3908 Veatch JR, McMurray MA, Nelson ZW, Gottschling DE (2009) Mitochondrial dysfunction leads to nuclear genome instability via an iron-sulfur cluster defect. Cell 137: 1247-1258 Weisberg SJ, Lyakhovetsky R, Werdiger AC, Gitler AD, Soen Y, Kaganovich D (2012) Compartmentalization of superoxide dismutase 1 (SOD1G93A) aggregates determines their toxicity. Proceedings of the National Academy of Sciences of the United States of America 109: 15811-15816 Weismann (1882) Ueber die Dauer des Lebens, ein Vortrag. Weismann (1891) Essays upon Heredity and Kindred Biological Problems, Oxford: Clarendon. Vembar SS, Brodsky JL (2008) One step at a time: endoplasmic reticulum-associated degradation. Nature reviews Molecular cell biology 9: 944-957 Verhoef LG, Lindsten K, Masucci MG, Dantuma NP (2002) Aggregate formation inhibits proteasomal degradation of polyglutamine proteins. Human molecular genetics 11: 2689-2700 Werner-Washburne M, Stone DE, Craig EA (1987) Complex interactions among members of an essential subfamily of hsp70 genes in Saccharomyces cerevisiae. Molecular and cellular biology 7: 2568-2577 Vevea JD, Swayne TC, Boldogh IR, Pon LA (2014) Inheritance of the fittest mitochondria in yeast. Trends in cell biology 24: 53-60 Wierman MB, Smith JS (2013) Yeast sirtuins and the regulation of aging. FEMS yeast research Williams (1957) Pleiotropy, natural selection, and the evolution of senescence. Evolution 11: 398-411 Winkler J, Tyedmers J, Bukau B, Mogk A (2012) Hsp70 targets Hsp100 chaperones to substrates for protein disaggregation and prion fragmentation. The Journal of cell biology 198: 387-404 Wollenberg K, Swaffield JC (2001) Evolution of proteasomal ATPases. Molecular biology and evolution 18: 962-974 63 Yamagata K, Kato J, Shimamoto A, Goto M, Furuichi Y, Ikeda H (1998) Bloom's and Werner's syndrome genes suppress hyperrecombination in yeast sgs1 mutant: implication for genomic instability in human diseases. Proceedings of the National Academy of Sciences of the United States of America 95: 8733-8738 Yuan J, Luo K, Zhang L, Cheville JC, Lou Z (2010) USP10 regulates p53 localization and stability by deubiquitinating p53. Cell 140: 384-396 Zhou C, Slaughter BD, Unruh JR, Eldakak A, Rubinstein B, Li R (2011) Motility and segregation of Hsp104-associated protein aggregates in budding yeast. Cell 147: 1186-1196 Zietkiewicz S, Krzewska J, Liberek K (2004) Successive and synergistic action of the Hsp70 and Hsp100 chaperones in protein disaggregation. The Journal of biological chemistry 279: 44376-44383