Leaky termination at premature stop codons antagonizes nonsense-mediated mRNA decay in S. cerevisiae

The Nonsense-Mediated mRNA Decay (NMD) pathway mediates the rapid degradation of mRNAs that contain premature stop mutations in eukaryotic organisms. It was recently shown that mutations in three yeast genes that encode proteins involved in the NMD process, UPF1, UPF2, and UPF3, also reduce the efficiency of translation termination. In the current study, we compared the efficiency of translation termination in a upf1Delta strain and a [PSI(+)] strain using a collection of translation termination reporter constructs. The [PSI(+)] state is caused by a prion form of the polypeptide chain release factor eRF3 that limits its availability to participate in translation termination. In contrast, the mechanism by which Upf1p influences translation termination is poorly understood. The efficiency of translation termination is primarily determined by a tetranucleotide termination signal consisting of the stop codon and the first nucleotide immediately 3' of the stop codon. We found that the upf1Delta mutation, like the [PSI(+)] state, decreases the efficiency of translation termination over a broad range of tetranucleotide termination signals in a unique, context-dependent manner. These results suggest that Upf1p may associate with the termination complex prior to polypeptide chain release. We also found that the increase in readthrough observed in a [PSI(+)]/upf1Delta strain was larger than the readthrough observed in strains carrying either defect alone, indicating that the upf1Delta mutation and the [PSI(+)] state influence the termination process in distinct ways. Finally, our analysis revealed that the mRNA destabilization associated with NMD could be separated into two distinct forms that correlated with the extent the premature stop codon was suppressed. The minor component of NMD was a 25% decrease in mRNA levels observed when readthrough was >/=0.5%, while the major component was represented by a larger decrease in mRNA abundance that was observed only when readthrough was </=0.5%. This low threshold for the onset of the major component of NMD indicates that mRNA surveillance is an ongoing process that occurs throughout the lifetime of an mRNA.

beta-Helix is a likely core structure of yeast prion Sup35 amyloid fibers

We have studied the core structure of amyloid fibers of yeast prion protein Sup35. We developed procedures to prepare straight fibers of relatively uniform diameters from three kinds of fragments; N (1-123), NMp (1-189), and NM (1-253). X-ray fiber diffraction patterns from dried oriented fibers gave common reflections in all three cases; a sharp meridional reflection at 4.7A, and a diffuse equatorial peak at around 9A, apparently supporting the typical "cross-beta" structure with stacked beta-sheets proposed for many different amyloid fibers. However, X-ray fiber diffraction from hydrated fibers showed the meridional reflection at 4.7A but no equatorial reflections at 9A in all three cases, indicating that the stack of beta-sheets in dried fibers is an artifact produced by drying process. Thus, the core structure of these amyloid fibers made of the N domain is likely to be beta-helix nanotube as proposed by Perutz et al.

Population genetic variation in gene expression is associated with phenotypic variation in Saccharomyces cerevisiae

BACKGROUND

The relationship between genetic variation in gene expression and phenotypic variation observable in nature is not well understood. Identifying how many phenotypes are associated with differences in gene expression and how many gene-expression differences are associated with a phenotype is important to understanding the molecular basis and evolution of complex traits.

RESULTS

We compared levels of gene expression among nine natural isolates of Saccharomyces cerevisiae grown either in the presence or absence of copper sulfate. Of the nine strains, two show a reduced growth rate and two others are rust colored in the presence of copper sulfate. We identified 633 genes that show significant differences in expression among strains. Of these genes, 20 were correlated with resistance to copper sulfate and 24 were correlated with rust coloration. The function of these genes in combination with their expression pattern suggests the presence of both correlative and causative expression differences. But the majority of differentially expressed genes were not correlated with either phenotype and showed the same expression pattern both in the presence and absence of copper sulfate. To determine whether these expression differences may contribute to phenotypic variation under other environmental conditions, we examined one phenotype, freeze tolerance, predicted by the differential expression of the aquaporin gene AQY2. We found freeze tolerance is associated with the expression of AQY2.

CONCLUSIONS

Gene expression differences provide substantial insight into the molecular basis of naturally occurring traits and can be used to predict environment dependent phenotypic variation.

Nmr Studies Of The Prionogenic Peptide Derived From Sup35 Protein

The NMR studies of the prionogenic peptide derived from Sup35 are presented. The peptide molecules were dissolved in the half-aqueous solution to prevent severe aggregation, and were found to be in an extended conformation from the chemical shift and the coupling constant data. They could form higher order multimers by making intermolecular hydrogen bonds, judging from the observation that the NMR sample became a gel-like state at lower temperatures. This work reports the first structural information in the solution state about the prionogenic peptide mimicking the state of amyloid fibrils, and provides a solid foundation for further structural analysis of peptide molecules forming insoluble aggregates.

Amyloid Formation of a Yeast Prion Determinant

The [PSI+] factor of the yeast Saccharomyces cerevisiae is a cytoplasmic, epigenetic regulator of translation termination and can be transmitted from mother to daughter cells in a non-Mendelian manner. The transmission is caused by self-perpetuating noncovalent changes in the physical state of the protein determinant Sup35p, rather than by changes in its encoding gene. This phenomenon is reminiscent of the protein-only mechanism proposed for the infectious agent in a group of unusual, fatal neurodegenerative diseases in mammals. These diseases, known as prion diseases, are thought to involve a self-perpetuating change in the conformation of the prion protein (PrP) from a soluble form to one reflecting amyloid structure. In contrast to mammalian PrPs, Sup35p[PSI+] is not associated with disease in yeast and is not infectious for humans. Because of the mechanistic similarities of transmission of a specific, nonsoluble protein conformation, the epigenetic inheritance of [PSI+] in yeast was called a yeast prion phenomenon, and the yeast prion hypothesis was born. The elucidation of the mechanism by which alternative protein conformations transmit their structural information is key to understanding how proteins function as elements of epigenetic inheritance and how amyloidogenic conformations can be propagated. Yeast provides an ideal system to analyze both the epigenetic traits in vivo and the phenomenon of amyloid formation in vitro. The combination of these tools will help to determine the general mechanism of prion and amyloid appearance and propagation.

Destabilizing Interactions Among [PSI +] and [PIN +] Yeast Prion Variants

The yeast Sup35 and Rnq1 proteins can exist in either the noninfectious soluble forms, [psi–]or[pin–], respectively, or the multiple infectious amyloid-like forms called [PSI+]or[PIN+] prion variants (or prion strains). It was previously shown that [PSI+] and [PIN+] prions enhance one another's de novo appearance. Here we show that specific prion variants of [PSI+] and [PIN+] disrupt each other's stable inheritance. Acquiring [PSI+] often impedes the inheritance of particular [PIN+] variants. Conversely, the presence of some [PIN+] variants impairs the inheritance of weak [PSI+] but not strong [PSI+] variants. These same [PIN+] variants generate a single-dot fluorescence pattern when a fusion of Rnq1 and green fluorescent protein is expressed. Another [PIN+] variant, which forms a distinctly different multiple-dot fluorescence pattern, does not impair [PSI+] inheritance. Thus, destabilization of prions by heterologous prions depends upon the variants involved. These findings may have implications for understanding interactions among other amyloid-forming proteins, including those associated with certain human diseases.

Drosophila S2 cells: an alternative infection model for Listeria monocytogenes

Listeria monocytogenes is a Gram-positive facultative intracellular bacterial pathogen that infects humans and animals. Its pathogenic strategy involves the expression of virulence proteins that mediate intracytosolic growth and cell-to-cell spread. A key virulence protein is the cholesterol-dependent cytolysin, listeriolysin O (LLO), which is largely responsible for mediating escape from the phagosome into the host cytosol. To study further the host processes exploited during L. monocytogenes infection, we sought to develop Drosophila S2 cells as a model for infection. Here, we show that S2 cells share a number of properties with mammalian cell culture models of infection. As with mouse macrophages, LLO was required for phagosomal escape from S2 cells. Furthermore, vacuolar escape was dependent on their acidification via the ATPase proton pumps, as bafilomycin A1 treatment sharply decreased escape. However, unlike in mouse macrophages, LLO mutants replicated in the phagosome of S2 cells. Drosophila cells are cholesterol auxotrophs, and exogenous cholesterol increased the infection rate of L. monocytogenes (LLO independent) and also augmented the efficiency of vacuolar escape (LLO dependent). With available genetic tools such as RNA interference, S2 cells could become an important model in the study of host-pathogen interactions.

Yeast [PSI+] prion aggregates are formed by small Sup35 polymers fragmented by Hsp104

The yeast [PSI+] determinant is related to formation of large prion-like aggregates of the conformationally altered Sup35 protein. Here, we show that these aggregates are composed of small Sup35 prion polymers and associated proteins. In contrast to other protein complexes of yeast lysates, but similarly to amyloid fibers, these polymers are insoluble in SDS at room temperature. The polymers on average are about 30-fold smaller than the aggregates and comprise from 8 to 50 Sup35 monomers. The size of polymers is characteristic of a given [PSI+] variant and differs between the variants. Blocked expression of Hsp104 chaperone causes gradual increase in the size of prion polymers, while inactivation of Hsp104 by guanidine HCl completely stops their fragmentation, which shows indispensability of Hsp104 for this process.

Susceptibility of Listeria monocytogenes to antimicrobial peptides

We assessed the susceptibility of several pathogenic and non-pathogenic Listeria species to antimicrobial peptides of animal and plant origin. Human defensins and thionins were highly inhibitory, whereas protamine, snakin and magainin showed an intermediate effect. A temperature dependence in the activity of potato defensin was observed for Listeria monocytogenes and Listeria ivanovii. PrfA* L. monocytogenes mutants, that overexpress constitutively PrfA-dependent genes, were sensitive to the peptide independently of the temperature whereas isogenic PrfA(-) derivatives were constitutively resistant. These data indicate that the thermoregulated transcription factor PrfA controls the expression of bacterial products that influence the susceptibility or resistance to some antimicrobial peptides.

Analysis of the Generation and Segregation of Propagons: Entities That Propagate the [PSI+] Prion in Yeast

The propagation of the prion form of the yeast Sup35p protein, the so-called [PSI+] determinant, involves the generation and partition of a small number of particulate determinants that we propose calling “propagons.” The numbers of propagons in [PSI+] cells can be inferred from the kinetics of elimination of [PSI+] during growth in the presence of a low concentration of guanidine hydrochloride (GdnHCl). Using this and an alternative method of counting the numbers of propagons, we demonstrate considerable clonal variation in the apparent numbers of propagons between different [PSI+] yeast strains, between different cultures of the same [PSI+] yeast strain, and between different cells of the same [PSI+] culture. We provide further evidence that propagon generation is blocked by growth in GdnHCl and that it is largely confined to the S phase of the cell cycle. In addition, we show that at low propagon number there is a bias toward retention of propagons in mother cells and that production of new propagons is very rapid when cells with depleted numbers of propagons are rescued into normal growth medium. The implications of our findings with respect to yeast prion propagation mechanisms are discussed.

Models for Yeast Prions

The cytoplasmic heritable determinant [PSI+] of the yeast Saccharomyces cerevisiae exhibits prion-like properties. The properties of yeast prions are studied in the hope that this will enhance the understanding of mammalian prions, which cause mad-cow, Creutzfeldt-Jakob, and related neurodegenerative diseases. When host cells divide, the yeast prions distribute themselves without loss over the daughter cells. Experimental data provide information on how the proportion of cells with prions decreases over time when priori replication is inhibited. One feature of scientific interest is the unknown mean number, n0, of prions assumed to be present in the cells at the start of the experiment. We develop several stochastic models and by fitting them to the data, we obtain substantially larger estimates of n0 compared with a previous analysis. An interesting feature of a model with constant cell generation times is that the predicted proportion of cells with prions varies over time as a sequence of linked hyperbolic curves. Avenues for future research are outlined, which relax simplifying assumptions made in the models. We make several recommendations for the design of future experiments.

Generation of prion transmission barriers by mutational control of amyloid conformations

Self-propagating beta-sheet-rich protein aggregates are implicated in a wide range of protein-misfolding phenomena, including amyloid diseases and prion-based inheritance. Two properties have emerged as common features of amyloids. Amyloid formation is ubiquitous: many unrelated proteins form such aggregates and even a single polypeptide can misfold into multiple forms--a process that is thought to underlie prion strain variation. Despite this promiscuity, amyloid propagation can be highly sequence specific: amyloid fibres often fail to catalyse the aggregation of other amyloidogenic proteins. In prions, this specificity leads to barriers that limit transmission between species. Using the yeast prion [PSI+], we show in vitro that point mutations in Sup35p, the protein determinant of [PSI+], alter the range of 'infectious' conformations, which in turn changes amyloid seeding specificity. We generate a new transmission barrier in vivo by using these mutations to specifically disfavour subsets of prion strains. The ability of mutations to alter the conformations of amyloid states without preventing amyloid formation altogether provides a general mechanism for the generation of prion transmission barriers and may help to explain how mutations alter toxicity in conformational diseases.

Importance of low-oligomeric-weight species for prion propagation in the yeast prion system Sup35/Hsp104

The [PSI+] determinant of Saccharomyces cerevisiae, consisting of the cytosolic translation termination factor Sup35, is a prion-type genetic element that induces an inheritable conformational change and converts the Sup35 protein into amyloid fibers. The molecular chaperone Hsp104 is required to maintain self-replication of [PSI+]. We observe in vitro that addition of catalytic amounts of Hsp104 to the prion-determining region of the NM domain of Sup35, Sup355-26, results in the dissociation of oligomeric Sup35 into monomeric species. Several intermediates of Sup355-26 could be detected during this process. Strong interactions are found between Hsp104 and hexameric/tetrameric Sup355-26, whereas the intermediate and monomeric "release" forms show a decreased affinity with respect to Hsp104, as monitored by saturation transfer difference and diffusion-ordered NMR spectroscopic experiments. Interactions are mediated mostly by the side chains of Gln, Asn, and Tyr residues in Sup355-26. No interaction can be detected between Hsp104 and higher oligomeric states (>/=8) of Sup355-26. Taking into account the fact that Hsp104 is required for maintenance of [PSI+], we suggest that low-oligomeric-weight species of Sup35 are important for prion propagation in yeast.

Prion protein gene polymorphisms in Saccharomyces cerevisiae

The yeast Saccharomyces cerevisiae genome encodes several proteins that, in laboratory strains, can take up a stable, transmissible prion form. In each case, this requires the Asn/Gln-rich prion-forming domain (PrD) of the protein to be intact. In order to further understand the evolutionary significance of this unusual property, we have examined four different prion genes and their corresponding PrDs, from a number of naturally occurring strains of S. cerevisiae. In 4 of the 16 strains studied we identified a new allele of the SUP35 gene (SUP35delta19) that contains a 19-amino-acid deletion within the N-terminal PrD, a deletion that eliminates the prion property of Sup35p. In these strains a second prion gene, RNQ1, was found to be highly polymorphic, with eight different RNQ1 alleles detected in the six diploid strains studied. In contrast, for one other prion gene (URE2) and the sequence of the NEW1 gene encoding a PrD, no significant degree of DNA polymorphism was detected. Analysis of the naturally occurring alleles of RNQ1 and SUP35 indicated that the various polymorphisms identified were associated with DNA tandem repeats (6, 12, 33, 42 or 57 bp) within the coding sequences. The expansion and contraction of DNA repeats within the RNQ1 gene may provide an evolutionary mechanism that can ensure rapid change between the [PRION+] and [prion-] states.

Cross-beta order and diversity in nanocrystals of an amyloid-forming peptide

The seven-residue peptide GNNQQNY from the N-terminal region of the yeast prion protein Sup35, which forms amyloid fibers, colloidal aggregates and highly ordered nanocrystals, provides a model system for characterizing the elusively protean cross-beta conformation. Depending on preparative conditions, orthorhombic and monoclinic crystals with similar lath-shaped morphology have been obtained. Ultra high-resolution (<0.5A spacing) electron diffraction patterns from single nanocrystals show that the peptide chains pack in parallel cross-beta columns with approximately 4.86A axial spacing. Mosaic striations 20-50 nm wide observed by electron microscopy indicate lateral size-limiting crystal growth related to amyloid fiber formation. Frequently obtained orthorhombic forms, with apparent space group symmetry P2(1)2(1)2(1), have cell dimensions ranging from /a/=22.7-21.2A, /b/=39.9-39.3A, /c/=4.89-4.86A for wet to dried states. Electron diffraction data from single nanocrystals, recorded in tilt series of still frames, have been mapped in reciprocal space. However, reliable integrated intensities cannot be obtained from these series, and dynamical electron diffraction effects present problems in data analysis. The diversity of ordered structures formed under similar conditions has made it difficult to obtain reproducible X-ray diffraction data from powder specimens; and overlapping Bragg reflections in the powder patterns preclude separated structure factor measurements for these data. Model protofilaments, consisting of tightly paired, half-staggered beta strands related by a screw axis, can be fit in the crystal lattices, but model refinement will require accurate structure factor measurements. Nearly anhydrous packing of this hydrophilic peptide can account for the insolubility of the crystals, since the activation energy for rehydration may be extremely high. Water-excluding packing of paired cross-beta peptide segments in thin protofilaments may be characteristic of the wide variety of anomalously stable amyloid aggregates.

[PHI+], a novel Sup35-prion variant propagated with non-Gln/Asn oligopeptide repeats in the absence of the chaperone protein Hsp104

BACKGROUND

The [PSI+] element of the budding yeast is an aggregated form of the translation release factor Sup35 that is propagated and transmitted cytoplasmically in a manner analogous to that of mammalian prions. The N-terminal of Sup35, necessary for [PSI+], contains oligopeptide repeats and multiple Gln/Asn residues.

RESULTS

We replaced the Gln/Asn-rich prion repeats of Sup35 with non-Gln/Asn repeats from heterologous yeast strains. These non-Gln/Asn repeat Sup35s propagated a novel [PSI+] variant, [PHI+], that appeared de novo 103 times more frequent than [PSI+]. [PHI+] was stably inherited in a non-Mendelian fashion, but not eliminated upon the inactivation of Hsp104, unlike known [PSI+] elements. In vitro, non-Gln/Asn repeat domains formed amyloid fibres that were shorter and grew more slowly than did Gln/Asn-rich prion domains, while [PHI+] aggregates were smaller than [PSI+] aggregates in vivo.

CONCLUSIONS

These findings suggest the existence of an alternative, Hsp104-independent pathway to replicate non-Gln/Asn variant Sup35 prion seeds.

The evolution of the evolvability properties of the yeast prion [PSI+]

Saccharomyces cerevisiae's ability to form the prion [PSI+] may increase the rate of evolvability, defined as the rate of appearance of heritable and potentially adaptive phenotypic variants. The increase in evolvability occurs when the appearance of the prion causes read-through translation and reveals hidden variation in untranslated regions. Eventually the portion of the phenotypic variation that is adaptive loses its dependence on the revealing mechanism. The mechanism is reversible, so the restoration of normal translation termination conceals the revealed deleterious variation, leaving the yeast without a permanent handicap. Given that the ability to form [PSI+] is known to be fixed and conserved in yeast, we construct a mathematical model to calculate whether this ability is more likely to have become fixed due to chance alone or due to its evolvability characteristics. We find that evolvability is a more likely explanation, as long as environmental change makes partial read-through of stop codons adaptive at a frequency of at least once every million years.

[Listeria pathogenicity factors and their role in pathogenesis and laboratory diagnosis of listeriosis]

The mechanisms of relationships between Listeria and eukaryotic cells on the level of the main biomolecules are analyzed. These mechanisms determine the penetration and multiplication of Listeria and their importance for the pathogenesis of listeriosis. The theoretical and practical aspects of the regulation of the expression of pathogenicity factors in Listeria, connected with the activation of the regulatory protein PrfA and autoregulatory mechanisms, are considered. The elimination of the autorepressor from the cultivation medium results in the activation of the regulatory protein and the induction of the pathogenicity factors. The effective identification method for L. monocytogenes, permitting the differentiation of pathogenic and non-pathogenic Listeria, has been developed on the basis of the study of lecithinase expression in the presence of activated charcoal.

Isolation of Listeria monocytogenes mutants with high-level in vitro expression of host cytosol-induced gene products

The facultative intracellular bacterial pathogen Listeria monocytogenes dramatically increases the expression of several key virulence factors upon entry into the host cell cytosol. actA, the protein product of which is required for cell-to-cell spread of the bacterium, is expressed at low to undetectable levels in vitro and increases in expression more than 200-fold after L. monocytogenes escape from the phagosome. To identify bacterial factors that participate in the intracellular induction of actA expression, L. monocytogenes mutants expressing high levels of actA during in vitro growth were selected after chemical mutagenesis. The resulting mutant isolates displayed a wide range of actA expression levels, and many were less sensitive to environmental signals that normally mediate repression of virulence gene expression. Several isolates contained mutations affecting actA gene expression that mapped at least 40 kb outside the PrfA regulon, supporting the existence of additional regulatory factors that contribute to virulence gene expression. Two actA in vitro expression mutants contained novel mutations within PrfA, a key regulator of L. monocytogenes virulence gene expression. PrfA E77K and PrfA G155S mutations resulted in high-level expression of PrfA-dependent genes, increased bacterial invasion of epithelial cells and increased virulence in mice. Both prfA mutant strains were significantly less motile than wild-type L. monocytogenes. These results suggest that, although constitutive activation of PrfA and PrfA-dependent gene expression may enhance L. monocytogenes virulence, it may conversely hamper the bacterium's ability to compete in environments outside host cells.

Deletion of the Hsp70 chaperone gene SSB causes hypersensitivity to guanidine toxicity and curing of the [PSI+] prion by increasing guanidine uptake in yeast

Yeast Ssb proteins (Ssbp) are ribosome-associated Hsp70 chaperones that function in translation. Elevated levels of Ssbp enhance the ability of over-expressed Hsp104 chaperone to eliminate the yeast [PSI+] prion, while depletion of Ssbp reduces this effect. Millimolar concentrations of guanidine in the growth medium cure yeast cells of prions by inactivating Hsp104. Guanidine is also toxic to yeast, irrespective of the status of Hsp104 and [PSI+]. Strains that lack Ssbp are hypersensitive to guanidine toxicity. Here we show that ssb- cells have normal numbers of [PSI+] "seeds", but can be cured of [PSI+] using one-sixth of the guanidine concentration required to eliminate [PSI+] from SSB cells. Correspondingly, the level of intracellular guanidine was eight-fold higher in ssb- cells than in wild-type cells, which explains all effects of Ssbp depletion on susceptibility to guanidine. The sensitivity of wild-type cells to the effects of guanidine also correlated with guanidine uptake, which was enhanced at low temperature. Guanidine sensitivity of strains mutated in any of 16 ABC membrane transporters, which are implicated in multidrug resistance, was normal. We found that an erg6 mutant that has an altered membrane lipid composition was hypersensitive to guanidine toxicity, but the lipid composition of ssb- cells was identical to that of wild-type cells. Our results suggest that Ssbp depletion does not affect prion seed regeneration, and that elevated guanidine uptake by ssb- cells may be due to increased retention rather than to an alteration in active or passive transport of the compound.

Analysis of yeast prion aggregates with amyloid-staining compound in vivo

Yeast prions are protein-based genetic elements whose non-Mendelian patterns of inheritance are explained by their inheritance of altered conformations. Here we showed that aggregates made by overexpression of two different prion domains of Sup35 and Rnq1, were stained in yeast by thioflavin-S, an amyloid binding compound. These results suggested that yeast prion domains take the form of amyloid in vivo, and supported the idea that the self-propagating property of amyloids is responsible for the heritable traits of yeast prions.

Guanidine reduces stop codon read-through caused by missense mutations in SUP35 or SUP45

Sup35 and Sup45 are essential protein components of the Saccharomyces cerevisiae translation termination factor. Yeast cells harbouring the [PSI(+)] prion form of Sup35 have impaired stop codon recognition (nonsense suppression). It has long been known that the [PSI(+)] prion is not stably transmitted to daughter cells when yeast are grown in the presence of mM concentrations of guanidine hydrochloride (GuHCl). In this paper, Mendelian suppressor mutations whose phenotypes are likewise hidden during growth in the presence of millimolar GuHCl are described. Such GuHCl-remedial Mendelian suppressors were selected under conditions where [PSI(+)] appearance was limiting, and were caused by missense mutations in SUP35 or SUP45. Clearly, anti-suppression caused by growth in the presence of GuHCl is not sufficient to distinguish missense mutations in SUP35 or SUP45, from [PSI(+)]. However, the Mendelian and prion suppressors can be distinguished by subsequent growth in the absence of GuHCl, where only the nonsense suppression caused by the [PSI(+)] prion remains cured. Recent reports indicate that GuHCl blocks the inheritance of [PSI(+)] by directly inhibiting the activity of the protein remodelling factor Hsp104, which is required for the transmission of [PSI(+)] from mother to daughter cells. However, the nonsense suppressor activity caused by the GuHCl-remedial sup35 or sup45 suppressors does not require Hsp104. Thus, GuHCl must anti-suppress the sup35 and sup45 mutations via an in vivo target distinct from Hsp104.

The role of side-chain interactions in the early steps of aggregation: Molecular dynamics simulations of an amyloid-forming peptide from the yeast prion Sup35

Understanding the early steps of aggregation at atomic detail might be crucial for the rational design of therapeutics preventing diseases associated with amyloid deposits. In this paper, aggregation of the heptapeptide GNNQQNY, from the N-terminal prion-determining domain of the yeast protein Sup35, was studied by 20 molecular dynamics runs for a total simulation time of 20 micros. The simulations generate in-register parallel packing of GNNQQNY beta-strands that is consistent with x-ray diffraction and Fourier transform infrared data. The statistically preferred aggregation pathway does not correspond to a purely downhill profile of the energy surface because of the presence of enthalpic barriers that originate from out-of-register interactions. The parallel beta-sheet arrangement is favored over the antiparallel because of side-chain contacts; in particular, stacking interactions of the tyrosine rings and hydrogen bonds between amide groups. No ordered aggregation was found in control simulations with the mutant sequence SQNGNQQRG in accord with experimental data and the strong sequence dependence of aggregation.

Tailoring host immune responses to Listeria by manipulation of virulence genes -- the interface between innate and acquired immunity

Although attenuated strains of microbial pathogens have triggered vaccine development from its origin, the role of virulence factors in determining host immunity has remained largely unexplored. Using the murine listeriosis model, we investigated whether the induction and expansion of protective and inflammatory T cell responses may be modified by selective manipulation of virulence genes. We intentionally deleted specific genes of Listeria monocytogenes, including those encoding the positive regulatory factor (prfA), hemolysin (hly), the actin nucleator (actA), and phospholipase B (plcB). The resulting strains showed decisive differences in their immunogenic properties. In particular, we identified a double-deletion mutant that retained Listeria's profound ability to induce protective CD8(+) T cells, but that is strongly attenuated and exhibits a significantly reduced ability to induce CD4(+) T cell-mediated inflammation. We conclude that this mutant, L. monocytogenes DeltaactADeltaplcB, is at present the most promising mutant for a bacterial vaccine vector and is able to safely induce potent CD8(+) T cell-mediated immunity.