Analysis of [SWI+] formation and propagation events

The budding yeast, Saccharomyces cerevisiae, harbors several prions that are transmitted as altered, heritable protein conformations. [SWI⁺] is one such prion whose determinant is Swi1, a subunit of the evolutionarily conserved chromatin‐remodeling complex SWI/SNF. Despite the importance of Swi1, the molecular events that lead to [SWI⁺] prionogenesis remain poorly understood. In this study, we have constructed floccullin‐promoter‐based URA3 reporters for [SWI⁺] identification. Using these reporters, we show that the spontaneous formation frequency of [SWI⁺] is significantly higher than that of [PSI⁺] (prion form of Sup35). We also show that preexisting [PSI⁺] or [PIN⁺] (prion form of Rnq1), or overproduction of Swi1 prion‐domain (PrD) can considerably promote Swi1 prionogenesis. Moreover, our data suggest a strain‐specific effect of overproduction of Sse1 – a nucleotide exchange factor of the molecular chaperone Hsp70, and its interaction with another molecular chaperone Hsp104 on [SWI⁺] maintenance. Additionally, we show that Swi1 aggregates are initially ring/ribbon‐like then become dot‐like in mature [SWI⁺] cells. In the presence of [PSI⁺] or [PIN⁺], Swi1 ring/ribbon‐like aggregates predominantly colocalize with the Sup35 or Rnq1 aggregates; without a preexisting prion, however, such colocalizations are rarely seen during Swi1‐PrD overproduction‐promoted Swi1 prionogenesis. We have thus demonstrated a complex interacting mechanism of yeast prionogenesis.     

Sup35 methionine oxidation is a trigger for de novo [PSI+] prion formation

ABSTRACT. The molecular basis by which fungal and mammalian prions arise spontaneously is poorly understood. A number of different environmental stress conditions are known to increase the frequency of yeast [PSI⁺] prion formation in agreement with the idea that conditions which cause protein misfolding may promote the conversion of normally soluble proteins to their amyloid forms. A recent study from our laboratory has shown that the de novo formation of the [PSI⁺] prion is significantly increased in yeast mutants lacking key antioxidants suggesting that endogenous reactive oxygen species are sufficient to promote prion formation. Our findings strongly implicate oxidative damage of Sup35 as an important trigger for the formation of the heritable [PSI⁺] prion in yeast. This review discusses the mechanisms by which the direct oxidation of Sup35 might lead to structural transitions favoring conversion to the transmissible amyloid-like form. This is analogous to various environmental factors which have been proposed to trigger misfolding of the mammalian prion protein (PrP^C) into the aggregated scrapie form (PrP^Sc).     

A Systematic Evaluation of the Function of the Protein-Remodeling Factor Hsp104 in [PSI+] Prion Propagation in S. cerevisiae by Comprehensive Chromosomal Mutations

The yeast prion [PSI⁺] represents an aggregated state of the translational release factor Sup35 (eRF3) and deprives termination complexes of functional Sup35, resulting in nonsense codon suppression. Protein-remodeling factor Hsp104 is involved in thermotolerance and [PSI⁺] propagation, however the structure-and-function relationship of Hsp104 for [PSI⁺] remains unclear. In this study, we engineered 58 chromosomal hsp104 mutants that affect residues considered structurally or functionally relevant to Hsp104 remodeling activity, yet most remain to be examined for their significance to [PSI⁺] in the same genetic background. Many of these hsp104 mutants were affected both in thermotolerance and [PSI⁺] propagation. However, nine mutants were impaired exclusively for [PSI⁺], while two mutants were impaired exclusively for thermotolerance. Mutations exclusively affecting [PSI⁺] are clustered around the lateral channel of the Hsp104 hexamer. These findings suggest that Hsp104 possesses shared as well as distinct remodeling activities for stress-induced protein aggregates and [PSI⁺] prion aggregates and that the lateral channel plays a role specific to [PSI⁺] prion propagation.     

Extracellular environment modulates the formation and propagation of particular amyloid structures

Amyloidogenic proteins, including prions, assemble into multiple forms of structurally distinct fibres. The [PSI⁺] prion, endogenous to the yeast Saccharomyces cerevisiae, is a dominantly inherited, epigenetic modifier of phenotypes. [PSI⁺] formation relies on the coexistence of another prion, [RNQ⁺]. Here, in order to better define the role of amyloid diversity on cellular phenotypes, we investigated how physiological and environmental changes impact the generation and propagation of diverse protein conformations from a single polypeptide. Utilizing the yeast model system, we defined extracellular factors that influence the formation of a spectrum of alternative self‐propagating amyloid structures of the Sup35 protein, called [PSI⁺] variants. Strikingly, exposure to specific stressful environments dramatically altered the variants of [PSI⁺] that formed de novo. Additionally, we found that stress also influenced the association between the [PSI⁺] and [RNQ⁺] prions in a way that it superceded their typical relationship. Furthermore, changing the growth environment modified both the biochemical properties and [PSI⁺]‐inducing capabilities of the [RNQ⁺] template. These data suggest that the cellular environment contributes to both the generation and the selective propagation of specific amyloid structures, providing insight into a key feature that impacts phenotypic diversity in yeast and the cross‐species transmission barriers characteristic of prion diseases.     

Sup35 methionine oxidation is a trigger for de novo [PSI+] prion formation

ABSTRACT. The molecular basis by which fungal and mammalian prions arise spontaneously is poorly understood. A number of different environmental stress conditions are known to increase the frequency of yeast [PSI⁺] prion formation in agreement with the idea that conditions which cause protein misfolding may promote the conversion of normally soluble proteins to their amyloid forms. A recent study from our laboratory has shown that the de novo formation of the [PSI⁺] prion is significantly increased in yeast mutants lacking key antioxidants suggesting that endogenous reactive oxygen species are sufficient to promote prion formation. Our findings strongly implicate oxidative damage of Sup35 as an important trigger for the formation of the heritable [PSI⁺] prion in yeast. This review discusses the mechanisms by which the direct oxidation of Sup35 might lead to structural transitions favoring conversion to the transmissible amyloid-like form. This is analogous to various environmental factors which have been proposed to trigger misfolding of the mammalian prion protein (PrP^C) into the aggregated scrapie form (PrP^Sc).     

A bipolar personality of yeast prion proteins

Prions are infectious, self-propagating protein conformations. [PSI⁺], [RNQ⁺] and [URE3] are well characterized prions in Saccharomyces cerevisiae and represent the aggregated states of the translation termination factor Sup35, a functionally unknown protein Rnq1, and a regulator of nitrogen metabolism Ure2, respectively. Overproduction of Sup35 induces the de novo appearance of the [PSI⁺] prion in [RNQ⁺] or [URE3] strain, but not in non-prion strain. However, [RNQ⁺] and [URE3] prions themselves, as well as overexpression of a mutant Rnq1 protein, Rnq1Δ100, and Lsm4, hamper the maintenance of [PSI⁺]. These findings point to a bipolar activity of [RNQ⁺], [URE3], Rnq1Δ100, and Lsm4, and probably other yeast prion proteins as well, for the fate of [PSI⁺] prion. Possible mechanisms underlying the apparent bipolar activity of yeast prions will be discussed.     

The story of stolen chaperones

Prions are self-seeding alternate protein conformations. Most yeast prions contain glutamine/asparagine (Q/N)-rich domains that promote the formation of amyloid-like prion aggregates. Chaperones, including Hsp104 and Sis1, are required to continually break these aggregates into smaller “seeds.” Decreasing aggregate size and increasing the number of growing aggregate ends facilitates both aggregate transmission and growth. Our previous work showed that overexpression of 11 proteins with Q/N-rich domains facilitates the de novo aggregation of Sup35 into the [PSI⁺] prion, presumably by a cross-seeding mechanism. We now discuss our recent paper, in which we showed that overexpression of most of these same 11 Q/N-rich proteins, including Pin4C and Cyc8, destabilized pre-existing Q/N rich prions. Overexpression of both Pin4C and Cyc8 caused [PSI⁺] aggregates to enlarge. This is incompatible with a previously proposed “capping” model where the overexpressed Q/N-rich protein poisons, or “caps,” the growing aggregate ends. Rather the data match what is expected of a reduction in prion severing by chaperones. Indeed, while Pin4C overexpression does not alter chaperone levels, Pin4C aggregates sequester chaperones away from the prion aggregates. Cyc8 overexpression cures [PSI⁺] by inducing an increase in Hsp104 levels, as excess Hsp104 binds to [PSI⁺] aggregates in a way that blocks their shearing.     

Spatial sequestration and oligomer remodeling during de novo [PSI+] formation

Prions are misfolded, aggregated, infectious proteins found in a range of organisms from mammals to bacteria. In mammals, prion formation is difficult to study because misfolding and aggregation take place prior to symptom presentation. The study of the yeast prion [PSI⁺], which is the misfolded infectious form of Sup35p, provides a tractable system to monitor prion formation in real time. Recently, we showed that the de novo formation of prion aggregates begins with the appearance of highly mobile cytoplasmic foci, called early foci, which assemble into larger ring or dot structures. We also observed SDS-resistant oligomers during formation, and lysates containing newly formed oligomers can convert [psi^?] cells to the [PSI⁺] state, suggesting that these oligomers have infectious potential. Here, we further characterize two aspects of prion formation: spatial sequestration of early foci and oligomerization of endogenous Sup35p. Our data provides important insights into the process of prion formation and explores the minimal oligomer requirement for infectivity.     

Yeast J-protein Sis1 prevents prion toxicity by moderating depletion of prion protein

[PSI⁺] is a prion of Saccharomyces cerevisiae Sup35, an essential ribosome release factor. In [PSI⁺] cells, most Sup35 is sequestered into insoluble amyloid aggregates. Despite this depletion, [PSI⁺] prions typically affect viability only modestly, so [PSI⁺] must balance sequestering Sup35 into prions with keeping enough Sup35 functional for normal growth. Sis1 is an essential J-protein regulator of Hsp70 required for the propagation of amyloid-based yeast prions. C-terminally truncated Sis1 (Sis1JGF) supports cell growth in place of wild-type Sis1. Sis1JGF also supports [PSI⁺] propagation, yet [PSI⁺] is highly toxic to cells expressing only Sis1JGF. We searched extensively for factors that mitigate the toxicity and identified only Sis1, suggesting Sis1 is uniquely needed to protect from [PSI⁺] toxicity. We find the C-terminal substrate-binding domain of Sis1 has a critical and transferable activity needed for the protection. In [PSI⁺] cells that express Sis1JGF in place of Sis1, Sup35 was less soluble and formed visibly larger prion aggregates. Exogenous expression of a truncated Sup35 that cannot incorporate into prions relieved [PSI⁺] toxicity. Together our data suggest that Sis1 has separable roles in propagating Sup35 prions and in moderating Sup35 aggregation that are crucial to the balance needed for the propagation of what otherwise would be lethal [PSI⁺] prions.     

The sensitive [SWI+] prion

Yeast prions are heritable protein-based genetic elements which rely on molecular chaperone proteins for stable transmission to cell progeny. Within the past few years, five new prions have been validated and 18 additional putative prions identified in Saccharomyces cerevisiae. The exploration of the physical and biological properties of these “nouveau prions” has begun to reveal the extent of prion diversity in yeast. We recently reported that one such prion, [SWI⁺], differs from the best studied, archetypal prion [PSI⁺] in several significant ways.¹ Notably, [SWI⁺] is highly sensitive to alterations in Hsp70 system chaperone activity and is lost upon growth at elevated temperatures. In that report we briefly noted a correlation amongst prions regarding amino acid composition, seed number and sensitivity to the activity of the Hsp70 chaperone system. Here we extend that analysis and put forth the idea that [SWI⁺] may be representative of a class of asparagine-rich yeast prions which also includes [URE3], [MOT3⁺] and [ISP⁺], distinct from the glutamine-rich prions such as [PSI⁺] and [RNQ⁺]. While much work remains, it is apparent that our understanding of the extent of the diversity of prion characteristics is in its infancy.     

Oxidative stress conditions increase the frequency of de novo formation of the yeast [PSI+] prion

Prions are self‐perpetuating amyloid protein aggregates which underlie various neurodegenerative diseases in mammals and heritable traits in yeast. The molecular basis of how yeast and mammalian prions form spontaneously into infectious amyloid‐like structures is poorly understood. We have explored the hypothesis that oxidative stress is a general trigger for prion formation using the yeast [PSI⁺] prion, which is the altered conformation of the Sup35 translation termination factor. We show that the frequency of [PSI⁺] prion formation is elevated under conditions of oxidative stress and in mutants lacking key antioxidants. We detect increased oxidation of Sup35 methionine residues in antioxidant mutants and show that overexpression of methionine sulphoxide reductase abrogates both the oxidation of Sup35 and its conversion to the [PSI⁺] prion. [PSI⁺] prion formation is particularly elevated in a mutant lacking the Sod1 Cu,Zn‐superoxide dismutase. We have used fluorescence microscopy to show that the de novo appearance of [PSI⁺] is both rapid and increased in frequency in this mutant. Finally, electron microscopy analysis of native Sup35 reveals that similar fibrillar structures are formed in both the wild‐type and antioxidant mutants. Together, our data indicate that oxidative stress is a general trigger of [PSI⁺] formation, which can be alleviated by antioxidant defenses.     

The small heat shock protein Hsp31 cooperates with Hsp104 to modulate Sup35 prion aggregation

The yeast homolog of DJ-1, Hsp31, is a multifunctional protein that is involved in several cellular pathways including detoxification of the toxic metabolite methylglyoxal and as a protein deglycase. Prior studies ascribed Hsp31 as a molecular chaperone that can inhibit α-Syn aggregation in vitro and alleviate its toxicity in vivo. It was also shown that Hsp31 inhibits Sup35 aggregate formation in yeast, however, it is unknown if Hsp31 can modulate [PSI⁺] phenotype and Sup35 prionogenesis. Other small heat shock proteins, Hsp26 and Hsp42 are known to be a part of a synergistic proteostasis network that inhibits Sup35 prion formation and promotes its disaggregation. Here, we establish that Hsp31 inhibits Sup35 [PSI⁺] prion formation in collaboration with a well-known disaggregase, Hsp104. Hsp31 transiently prevents prion induction but does not suppress induction upon prolonged expression of Sup35 indicating that Hsp31 can be overcome by larger aggregates. In addition, elevated levels of Hsp31 do not cure [PSI⁺] strains indicating that Hsp31 cannot intervene in a pre-existing prion oligomerization cycle. However, Hsp31 can modulate prion status in cooperation with Hsp104 because it inhibits Sup35 aggregate formation and potentiates [PSI⁺] prion curing upon overexpression of Hsp104. The absence of Hsp31 reduces [PSI⁺] prion curing by Hsp104 without influencing its ability to rescue cellular thermotolerance. Hsp31 did not synergize with Hsp42 to modulate the [PSI⁺] phenotype suggesting that both proteins act on similar stages of the prion cycle. We also showed that Hsp31 physically interacts with Hsp104 and together they prevent Sup35 prion toxicity to greater extent than if they were expressed individually. These results elucidate a mechanism for Hsp31 on prion modulation that suggest it acts at a distinct step early in the Sup35 aggregation process that is different from Hsp104. This is the first demonstration of the modulation of [PSI⁺] status by the chaperone action of Hsp31. The delineation of Hsp31's role in the chaperone cycle has implications for understanding the role of the DJ-1 superfamily in controlling misfolded proteins in neurodegenerative disease and cancer.     

Heterologous Aggregates Promote De Novo Prion Appearance via More than One Mechanism

Prions are self-perpetuating conformational variants of particular proteins. In yeast, prions cause heritable phenotypic traits. Most known yeast prions contain a glutamine (Q)/asparagine (N)-rich region in their prion domains. [PSI⁺], the prion form of Sup35, appears de novo at dramatically enhanced rates following transient overproduction of Sup35 in the presence of [PIN⁺], the prion form of Rnq1. Here, we establish the temporal de novo appearance of Sup35 aggregates during such overexpression in relation to other cellular proteins. Fluorescently-labeled Sup35 initially forms one or a few dots when overexpressed in [PIN⁺] cells. One of the dots is perivacuolar, colocalizes with the aggregated Rnq1 dot and grows into peripheral rings/lines, some of which also colocalize with Rnq1. Sup35 dots that are not near the vacuole do not always colocalize with Rnq1 and disappear by the time rings start to grow. Bimolecular fluorescence complementation failed to detect any interaction between Sup35-VN and Rnq1-VC in [PSI ⁺][PIN ⁺] cells. In contrast, all Sup35 aggregates, whether newly induced or in established [PSI ⁺], completely colocalize with the molecular chaperones Hsp104, Sis1, Ssa1 and eukaryotic release factor Sup45. In the absence of [PIN⁺], overexpressed aggregating proteins such as the Q/N-rich Pin4C or the non-Q/N-rich Mod5 can also promote the de novo appearance of [PSI ⁺]. Similar to Rnq1, overexpressed Pin4C transiently colocalizes with newly appearing Sup35 aggregates. However, no interaction was detected between Mod5 and Sup35 during [PSI⁺] induction in the absence of [PIN ⁺]. While the colocalization of Sup35 and aggregates of Rnq1 or Pin4C are consistent with the model that the heterologous aggregates cross-seed the de novo appearance of [PSI ⁺], the lack of interaction between Mod5 and Sup35 leaves open the possibility of other mechanisms. We also show that Hsp104 is required in the de novo appearance of [PSI⁺] aggregates in a [PIN ⁺]-independent pathway.     

Requirements of Hsp104p activity and Sis1p binding for propagation of the [RNQ+] prion

The formation and maintenance of prions in the yeast Saccharomyces cerevisiae is highly regulated by the cellular chaperone machinery. The most important player in this regulation is Hsp104p, which is required for the maintenance of all known prions. The requirements for other chaperones, such as members of the Hsp40 or Hsp70 families, vary with each individual prion. [RNQ⁺] cells do not have a phenotype that is amenable to genetic screens to identify cellular factors important in prion propagation. Therefore, we used a chimeric construct that reports the [RNQ⁺] status of cells to perform a screen for mutants that are unable to maintain [RNQ⁺]. We found eight separate mutations in Hsp104p that caused [RNQ⁺] cells to become [rnq⁻]. These mutations also caused the loss of the [PSI⁺] prion. The expression of one of these mutants, Hsp104p-E190K, showed differential loss of the [RNQ⁺] and [PSI⁺] prions in the presence of wild type Hsp104p. Hsp104p-E190K inefficiently propagated [RNQ⁺] and was unable to maintain [PSI⁺]. The mutant was unable to act on other in vivo substrates, as strains carrying it were not thermotolerant. Purified recombinant Hsp104p-E190K showed a reduced level of ATP hydrolysis as compared to wild type protein. This is likely the cause of both prion loss and lack of in vivo function. Furthermore, it suggests that [RNQ⁺] requires less Hsp104p activity to maintain transmissible protein aggregates than Sup35p. Additionally, we show that the L94A mutation in Rnq1p, which reduces its interaction with Sis1p, prevents Rnq1p from maintaining a prion and inducing [PSI⁺].Key words: [RNQ⁺], [PSI⁺], Hsp104p, Sis1p, mutagenesis     

A new perspective on Hsp104-mediated propagation and curing of the yeast prion [PSI+]

Most prions in yeast form amyloid fibrils that must be severed by the protein disaggregase Hsp104 to be propagated and transmitted efficiently to newly formed buds. Only one yeast prion, [PSI⁺], is cured by Hsp104 overexpression. We investigated the interaction between Hsp104 and Sup35, the priongenic protein in yeast that forms the [PSI⁺] prion.¹ We found that a 20-amino acid segment within the highly-charged, unstructured middle domain of Sup35 contributes to the physical interaction between the middle domain and Hsp104. When this segment was deleted from Sup35, the efficiency of [PSI⁺] severing was substantially reduced, resulting in larger Sup35 particles and weakening of the [PSI⁺] phenotype. Furthermore, [PSI⁺] in these cells was completely resistant to Hsp104 curing. The affinity of Hsp104 was considerably weaker than that of model Hsp104-binding proteins and peptides, implying that Sup35 prions are not ideal substrates for Hsp104-mediated remodeling. In light of this finding, we present a modified model of Hsp104-mediated [PSI⁺] propagation and curing that requires only partial remodeling of Sup35 assembled into amyloid fibrils.     

Functional Diversification of Hsp40: Distinct J-Protein Functional Requirements for Two Prions Allow for Chaperone-Dependent Prion Selection

Yeast prions are heritable amyloid aggregates of functional yeast proteins; their propagation to subsequent cell generations is dependent upon fragmentation of prion protein aggregates by molecular chaperone proteins. Mounting evidence indicates the J-protein Sis1 may act as an amyloid specificity factor, recognizing prion and other amyloid aggregates and enabling Ssa and Hsp104 to act in prion fragmentation. Chaperone interactions with prions, however, can be affected by variations in amyloid-core structure resulting in distinct prion variants or ‘strains’. Our genetic analysis revealed that Sis1 domain requirements by distinct variants of [PSI ⁺] are strongly dependent upon overall variant stability. Notably, multiple strong [PSI ⁺] variants can be maintained by a minimal construct of Sis1 consisting of only the J-domain and glycine/phenylalanine-rich (G/F) region that was previously shown to be sufficient for cell viability and [RNQ ⁺] prion propagation. In contrast, weak [PSI ⁺] variants are lost under the same conditions but maintained by the expression of an Sis1 construct that lacks only the G/F region and cannot support [RNQ ⁺] propagation, revealing mutually exclusive requirements for Sis1 function between these two prions. Prion loss is not due to [PSI ⁺]-dependent toxicity or dependent upon a particular yeast genetic background. These observations necessitate that Sis1 must have at least two distinct functional roles that individual prions differentially require for propagation and which are localized to the glycine-rich domains of the Sis1. Based on these distinctions, Sis1 plasmid-shuffling in a [PSI ⁺]/[RNQ ⁺] strain permitted J-protein-dependent prion selection for either prion. We also found that, despite an initial report to the contrary, the human homolog of Sis1, Hdj1, is capable of [PSI ⁺] prion propagation in place of Sis1. This conservation of function is also prion-variant dependent, indicating that only one of the two Sis1-prion functions may have been maintained in eukaryotic chaperone evolution.     

Growth phase‐dependent changes in the size and infectivity of SDS‐resistant Sup35p assemblies associated with the [PSI+] prion in yeast

The translation termination factor Sup35p can form self‐replicating fibrillar aggregates responsible for the [PSI⁺] prion state. Sup35p aggregation yields detergent‐resistant assemblies detectable on agarose gels under semi‐denaturant conditions and fluorescent puncta within the yeast cytosol when the protein is fused to GFP. It is still unclear whether any of these manifestations of [PSI⁺] truly correspond to the Sup35p assemblies that faithfully transmit the [PSI⁺] prion from mother to daughter cells. The infectious titer of prions in cells can be indirectly assessed by the ability of [PSI⁺] cells lysates to induce the prion state when introduced into naïve cells. Here, we report that the dramatic changes in the size and amounts of SDS‐resistant Sup35p that occur during growth do not correlate with the infectious titer. Our results suggest that fluorescent Sup35‐GFP puncta and detergent‐resistant Sup35p assemblies are good indicators of Sup35p conversion to the prion state but not of infectious particles number.     

A role for the proteasome in the turnover of Sup35p and in [PSI+] prion propagation

Yeast prions are superb models for understanding the mechanisms of self‐perpetuating protein aggregates formation. [PSI⁺] stands among the most documented yeast prions and results from self‐assembly of the translation termination factor Sup35p into protein fibrils. A plethora of cellular factors were shown to affect [PSI⁺] formation and propagation. Clearance of Sup35p prion particles is however poorly understood and documented. Here, we investigated the role of the proteasome in the degradation of Sup35p and in [PSI⁺] prion propagation. We found that cells lacking the RPN4 gene, which have reduced intracellular proteasome pools, accumulated Sup35p and have defects in [PSI⁺] formation and propagation. Sup35p is degraded in vitro by the 26S and 20S proteasomes in a ubiquitin‐independent manner, generating an array of amyloidogenic peptides derived from its prion‐domain. We also demonstrate the formation of a proteasome‐resistant fragment spanning residues 83–685 which is devoid of the prion‐domain that is essential for [PSI⁺] propagation. Most important was the finding that the 26S and 20S proteasomes degrade Sup35p fibrils in vitro and abolish their infectivity. Our results point to an overlooked role of the proteasome in clearing toxic protein aggregates, and have important implications for a better understanding of the life cycle of infectious protein assemblies.     

New insights into prion biology from the novel [SWI+] system

Our laboratory recently reported a novel prion [SWI⁺], in the budding yeast Saccharomyces cerevisiae. [SWI⁺] is the prion form of Swi1, a component of the SWI/SNF chromatin-remodeling complex. Cells harboring [SWI⁺] exhibit a partial loss-of-function phenotype for SWI/SNF, which can be easily assayed by poor growth on some non-fermentable carbon sources such as raffinose. Swi1 is unique among yeast prion proteins for its nuclear localization and the fact that it comprises part of a large, multi-subunit protein complex. The discovery of [SWI⁺] demonstrates for the first time a link between prion function and chromatin remodeling, implying a possible role for prions in gene regulation. We believe that the unique features of this novel yeast prion will provide new insight into prion biology.     

Microbial specialization by prions

ABSTRACT

Microbial prions facilitate a variety of phenotypic switches. Recently-developed tools that can directly interrogate, in the living cell, the aggregation state of a protein have enabled a wider range of experiments for prion-mediated behaviors. With such tools, the roles of the yeast prion [SWI⁺] in migration and mating were studied. Although [SWI⁺] cells were consistently less fit than their [swi^?] counterparts under traditional laboratory conditions, in these new phenotypic paradigms [SWI⁺] cells demonstrated a distinct advantage. [SWI⁺] cells dispersed over a larger area under conditions resembling rainfall and outcrossed more frequently. We postulate that many behaviors in microorganisms may be modulated by stochastic prion switching. In diverse and changing natural environments, prion switching at low frequency may promote greater fitness of the population by specializing a small number of individuals with altered responses to their environments.