Structure and expression of a yeast gene encoding the small heat-shock protein Hsp26

Induced Thermotolerance and Expression of Three Key Hsp Genes (Hsp70, Hsp21, and sHsp21) and Their Roles in the High Temperature Tolerance of Agasicles hygrophila

Thermal adaptation plays a fundamental role in the expansion and distribution of insects, and heat shock proteins (Hsps) play important roles in the temperature adaptation of various organisms. To determine the roles of Hsp genes (Hsp70, Hsp21, and sHsp21) on the high temperature tolerance of Agasicles hygrophila, we obtained complete cDNA (complementary DNA) sequences for Hsp70, Hsp21, and sHsp21 by rapid amplification of cDNA ends (RACE), analyzed their expression profiles under different high temperature treatments by quantitative reverse transcription polymerase chain reaction (RT-qPCR), and performed functional verification by RNA interference (RNAi). The open reading frames of Hsp70, Hsp21, and sHsp21 were 1940, 543, and 567 bp, encoding 650, 180, and 188 amino acids, respectively. Their molecular weights (MWs) were 71.757, 20.879, and 21.510 kDa, and the isoelectric points were 5.63, 6.45, and 6.24, respectively. Phylogenetic tree analysis showed that the Hsp70, Hsp21, and sHsp21 genes of A. hygrophila were relatively conserved in evolution. The Hsp70 and Hsp21 genes in A. hygrophila were homologous to those in Leptinotarsa decemlineata (87 and 79% similarity, respectively), and the sHsp21 gene in A. hygrophila was homologous to that in Lissorhoptrus oryzophilus (74% similarity). The amino acid polypeptide chain had highly conserved sequences of DLGGGTFD, VLVGGSTR, and GPTIEEVD. The sequence of EEVD was the characteristic motif of cytoplasmic Hsp70, and the highly conserved sequences of MALFR and MSLLP were characteristic sequences of Hsp2 and sHsp21, respectively. Relative quantitative real time PCR showed that the three Hsps could be induced by 4-h treatment at high temperatures. Significant upregulation of these Hsps was observed when the temperature was further increased. The RNAi results showed that the injection of the three Hsps' dsRNA could suppress the expression at the gene level significantly. Compared with the control group, high temperature heat shock reduced the fecundity of A. hygrophila significantly, and the fecundity decreased with the increase in temperature. Our results suggest that Hsp70, Hsp21, and sHsp21 might play key roles in high temperature adaptation of A. hygrophila and help improve our understanding of their mechanism of thermotolerance.

Absence of Gim proteins, but not GimC complex, alters stress-induced transcription

Saccharomyces cerevisiae GimC (mammalian Prefoldin) is a hexameric (Gim1-6) cytoplasmic complex involved in the folding pathway of actin/tubulin. In contrast to a shared role in GimC complex, we show that absence of individual Gim proteins results in distinct stress responses. No concomitant alteration in F-actin integrity was observed. Transcription of stress responsive genes is altered in gim2Δ, gim3Δ and gim6Δ mutants: TRX2 gene is induced in these mutants but with a profile diverging from type cells, whereas CTT1 and HSP26 fail to be induced. Remaining gimΔ mutants display stress transcript abundance comparable to wild type cells. No alteration in the nuclear localization of the transcriptional activators for TRX2 (Yap1) and CTT1/HSP26 (Msn2) was observed in gim2Δ. In accordance with TRX2 induction, RNA polymerase II occupancy at TRX2 discriminates the wild type from gim2Δ and gim6Δ. In contrast, RNA polymerase II occupancy at CTT1 is similar in wild type and gim2Δ, but higher in gim6Δ. The absence of active RNA polymerase II at CTT1 in gim2Δ, but not in wild type and gim1Δ, explains the respective CTT1 transcript outputs. Altogether our results put forward the need of Gim2, Gim3 and Gim6 in oxidative and osmotic stress activated transcription; others Gim proteins are dispensable. Consequently, the participation of Gim proteins in activated-transcription is independent from the GimC complex.

Dissociation of the H3K36 demethylase Rph1 from chromatin mediates derepression of environmental stress-response genes under genotoxic stress in Saccharomyces cerevisiae

The H3K36 demethylase Rph1 is a transcriptional repressor for stress-responsive genes in yeast. Rph1-mediated transcriptional repression is relieved by phosphorylation of Rph1, reduced Rph1 level, and dissociation of Rph1 from chromatin with genotoxic stress. Rph1 may function as a regulatory node in different stress-signaling pathways.

Cells respond to environmental signals by altering gene expression through transcription factors. Rph1 is a histone demethylase containing a Jumonji C (JmjC) domain and belongs to the C₂H₂ zinc-finger protein family. Here we investigate the regulatory network of Rph1 in yeast by expression microarray analysis. More than 75% of Rph1-regulated genes showed increased expression in the rph1-deletion mutant, suggesting that Rph1 is mainly a transcriptional repressor. The binding motif 5′-CCCCTWA-3′, which resembles the stress response element, is overrepresented in the promoters of Rph1-repressed genes. A significant proportion of Rph1-regulated genes respond to DNA damage and environmental stress. Rph1 is a labile protein, and Rad53 negatively modulates Rph1 protein level. We find that the JmjN domain is important in maintaining protein stability and the repressive effect of Rph1. Rph1 is directly associated with the promoter region of targeted genes and dissociated from chromatin before transcriptional derepression on DNA damage and oxidative stress. Of interest, the master stress-activated regulator Msn2 also regulates a subset of Rph1-repressed genes under oxidative stress. Our findings confirm the regulatory role of Rph1 as a transcriptional repressor and reveal that Rph1 might be a regulatory node connecting different signaling pathways responding to environmental stresses.

Novel Regulatory Properties of Saccharomyces cerevisiae Arp4

ARP4, an essential gene of Saccharomyces cerevisiae, codes for a nuclear actin-related protein. Arp4 is a subunit of several chromatin-modifying complexes and is known to be involved in the transcriptional regulation in yeast. We used a mutant strain with a single amino acid substitution (G161D) in the conserved actin fold domain to investigate the influence of Arp4 on stress and nitrogen catabolite repression genes. The deficiency of functional Arp4 caused a highly increased sensitivity towards nitrogen starvation and to the macrolide antibiotic rapamycin. We show the changes of mRNA levels of selected genes under these conditions. The upregulation of stress genes as a consequence of treatment with rapamycin was largely Msn2p/Msn4p-dependent. The sensitivity towards rapamycin indicates a participation of Arp4 in the regulation of the TOR pathway. Consistently, arp4G161D cells exhibited an affected cell cycle. Long-term cultivation, which leads to a G1 arrest in wild-type cells, provoked arrest in G2/M (more than 60%) in the mutant strain. The same effect was observed upon treatment with rapamycin, indicating an unexpected relationship of Arp4 to TOR-mediated cell cycle arrest.

Fungal heat-shock proteins in human disease

Heat-shock proteins (hsps) have been identified as molecular chaperones conserved between microbes and man and grouped by their molecular mass and high degree of amino acid homology. This article reviews the major hsps of Saccharomyces cerevisiae, their interactions with trehalose, the effect of fermentation and the role of the heat-shock factor. Information derived from this model, as well as from Neurospora crassa and Achlya ambisexualis, helps in understanding the importance of hsps in the pathogenic fungi, Candida albicans, Cryptococcus neoformans, Aspergillus spp., Histoplasma capsulatum, Paracoccidioides brasiliensis, Trichophyton rubrum, Phycomyces blakesleeanus, Fusarium oxysporum, Coccidioides immitis and Pneumocystis jiroveci. This has been matched with proteomic and genomic information examining hsp expression in response to noxious stimuli. Fungal hsp90 has been identified as a target for immunotherapy by a genetically recombinant antibody. The concept of combining this antibody fragment with an antifungal drug for treating life-threatening fungal infection and the potential interactions with human and microbial hsp90 and nitric oxide is discussed.

Purification and characterization of the chaperone-like Hsp26 from Saccharomyces cerevisiae

sHsps are ubiquitous ATP-independent molecular chaperones, which efficiently prevent the unspecific aggregation of non-native proteins. Here, we described the purification of the small heat shock protein Hsp26 from a Saccharomyces cerevisiae strain harboring a multicopy plasmid carrying HSP26 gene under the control of its native promoter. A 26 kDa protein was purified to apparent homogeneity with a recovery of 74% by a very reproducible three steps procedure consisting of ethanol precipitation, sucrose gradient ultracentrifugation, and heat inactivation of residual contaminants. The purified polypeptide was unequivocally identified as Hsp26 using a specific Hsp26 polyclonal antibody as a probe. The analysis of the purified protein by electron microscopy revealed near spherical particles with a diameter of 12.0 nm (n=57, standard deviation +/-1.6 nm), displaying a dispersion in size ranging from 9.2 to 16.1 nm, identical to Methanococcus jannaschii Hsp16.5 and in the range of the size estimated for yeast Hsp26, in a previous report. Purified yeast Hsp26 was able to suppress 72% of the heat-induced aggregation of citrate synthase at a ratio of 1:1 (Hsp26 24-mer complex to citrate synthase dimer), and 86% of the heat-induced aggregation of lysozyme at a molar ratio of 1:16 (Hsp26 24-mer complex to lysozyme monomer). In conclusion, the Hsp26 protein purified as described here has structure and activity similar to the previously described preparations. As advantages, this new protocol is very reproducible and requires simple apparatuses which are found in all standard biochemistry laboratories.

The Activation Mechanism of Hsp26 does not Require Dissociation of the Oligomer

Small heat shock proteins (sHsps) are molecular chaperones that specifically bind non-native proteins and prevent them from irreversible aggregation. A key trait of sHsps is their existence as dynamic oligomers. Hsp26 from Saccharomyces cerevisiae assembles into a 24mer, which becomes activated under heat shock conditions and forms large, stable substrate complexes. This activation coincides with the destabilization of the oligomer and the appearance of dimers. This and results from other groups led to the generally accepted notion that dissociation might be a requirement for the chaperone mechanism of sHsps. To understand the chaperone mechanism of sHsps it is crucial to analyze the relationship between chaperone activity and stability of the oligomer. We generated an Hsp26 variant, in which a serine residue of the N-terminal domain was replaced by cysteine. This allowed us to covalently crosslink neighboring subunits by disulfide bonds. We show that under reducing conditions the structure and function of this variant are indistinguishable from that of the wild-type protein. However, when the cysteine residues are oxidized, the dissociation into dimers at higher temperatures is no longer observed, yet the chaperone activity remains unaffected. Furthermore, we show that the exchange of subunits between Hsp26 oligomers is significantly slower than substrate aggregation and even inhibited in the presence of disulfide bonds. This demonstrates that the rearrangements necessary for shifting Hsp26 from a low to a high affinity state for binding non-native proteins occur without dissolving the oligomer.

Validation of a flour-free model dough system for throughput studies of baker's yeast

Evaluation of gene expression in baker's yeast requires the extraction and collection of pure samples of RNA. However, in bread dough this task is difficult due to the complex composition of the system. We found that a liquid model system can be used to analyze the transcriptional response of industrial strains in dough with a high sugar content. The production levels of CO2 and glycerol by two commercial strains in liquid and flour-based doughs were correlated. We extracted total RNA from both a liquid and a flour-based dough. We used Northern blotting to analyze mRNA levels of three stress marker genes, HSP26, GPD1, and ENA1, and 10 genes in different metabolic subcategories. All 13 genes had the same transcriptional profile in both systems. Hence, the model appears to effectively mimic the environment encountered by baker's yeast in high-sugar dough. The liquid dough can be used to help understand the connections between technological traits and biological functions and to facilitate studies of gene expression under commercially important, but experimentally intractable, conditions.

Hsp42 is the general small heat shock protein in the cytosol of Saccharomyces cerevisiae

Small heat shock proteins (sHsps) are ubiquitous molecular chaperones that prevent the unspecific aggregation of proteins. So far, Hsp26 was the only unambiguously identified member of the sHsp family in Saccharomyces cerevisiae. We show here that the sHsp system in the cytosol of S. cerevisiae consists of two proteins, Hsp26 and Hsp42. Hsp42 forms large dynamic oligomers with a barrel-like structure. In contrast to Hsp26, which functions predominantly at heat shock temperatures, Hsp42 is active as a chaperone under all conditions tested in vivo and in vitro. Under heat shock conditions, both Hsp42 and Hsp26 suppress the aggregation of one-third of the cytosolic proteins. This subset is about 90% overlapping for Hsp42 and Hsp26. The sHsp substrates belong to different biochemical pathways. This indicates a general protective function of sHsps for proteome stability in S. cerevisiae. Consistent with this observation, sHsp knockout strains show phenotypical defects. Taken together, our results define Hsp42 as an important player for protein homeostasis at physiological and under stress conditions.

Stop codon decoding in Candida albicans: from non-standard back to standard

The human pathogen Candida albicans translates the standard leucine-CUG codon as serine. This genetic code change is mediated by a novel ser-tRNA(CAG), which induces aberrant mRNA decoding in vitro, resulting in retardation of the electrophoretic mobility of the polypeptides synthesized in its presence. These non-standard decoding events have been attributed to readthrough of the UAG and UGA stop codons encoded by the Brome Mosaic Virus RNA 4, which codes for the virion coat protein, and the rabbit globin mRNAs, respectively. In order to fully elucidate the behaviour of the C. albicans ser-tRNA(CAG) towards stop codons, we have used other cell-free translation systems and reporter genes. However, the reporter systems used encode several CUG codons, making it impossible to distinguish whether the slow migration of the polypeptides is caused by the replacement of leucines by serines at the CUG codons, readthrough, or a combination of both. Therefore, we have constructed new reporter systems lacking CUG codons and have used them to demonstrate that aberrant mRNA decoding in vitro is not a result from stop codon readthrough or any other non-standard translational event. Our data show that a single leucine to serine replacement at only one of the four CUG codons encoded by the BMV RNA-4 gene is responsible for the aberrant migration of the BMV coat protein on SDS-PAGE, suggesting that this amino acid substitution (ser for leu) significantly alters the structure of the virion coat protein. The data therefore show that the only aberrant event mediated by the ser-tRNA(CAG) is decoding of the leu-CUG codon as serine.

Ras-mediated signaling pathway regulates the expression of a low-molecular-weight heat-shock protein in fission yeast

In fission yeast, Schizosaccharomyces pombe, deficiency of ras1 gene causes an abnormal cell shape and abolishes mating ability. However, target genes of this signaling pathway are largely unknown because of the lack of an appropriate analysis system. To overcome this problem, we have started a novel project to categorize entire genes based on their expression levels under different growth conditions. Using this strategy, we screened genes whose expression levels were affected in the presence or absence of the ras1 gene product. For this purpose, we utilized high-density arrays of clones covering the entire genome of the fission yeast, and probed with labelled cDNA derived from various strains and growth conditions. Here, we demonstrate the detection of a low-molecular-weight heat-shock protein gene, hsp16, whose expression is very likely to be regulated by a ras-mediated signaling pathway, but not by the heat-shock response.

Stationary-phase gene expression in Saccharomyces cerevisiae during wine fermentation

Genetic engineering of wine yeast strains requires the identification of gene promoters specifically activated under wine processing conditions. In this study, transcriptional activation of specific genes was followed during the time course of wine fermentation by quantifying mRNA levels in a haploid wine strain of Saccharomyces cerevisiae grown on synthetic or natural winery musts. Northern analyses were performed using radioactive probes from 19 genes previously described as being expressed under laboratory growth conditions or on molasses in S. cerevisiae during the stationary phase and/or under nitrogen starvation. Nine genes, including members of the HSP family, showed a transition-phase induction profile. For three of them, mRNA transcripts could be detected until the end of the fermentation. Expression of one of these genes, HSP30, was further studied using a HSP30::lacZ fusion on both multicopy and monocopy expression vectors. The production of beta-galactosidase by recombinant cells was measured during cell growth and fermentation on synthetic and natural winery musts. We showed that the HSP30 promoter can induce high gene expression during late stationary phase and remains active until the end of the wine fermentation process. Similar expression profiles were obtained on five natural winery musts.

Constitutive flocculation in Saccharomyces cerevisiae through overexpression of the GTS1 gene, coding for a 'Glo'-type Zn-finger-containing protein

The product of the cloned GTS1 gene is characterized by structural features found in transcription factors. It contains one Zn-finger motif (CXXCX16CXXC) situated in the N-terminal end with a high degree of homology to the newly identified 'Glo' family of Zn-finger proteins (Ireland et al., 1994, EMBO J. 13, 3812-3821). The C-terminal end of the protein is characterized by poly (Ala-Gln) and poly-Gln stretches. Poly-Gln are part of trans-acting motifs in known transcription factors. Overexpression of the GTS1 gene results in constitutive flocculation. Whole cell electrophoretic mobility and hydrophobicity of GTS1 overexpressing cells was respectively lower and higher relative to control cells. GTS1-induced flocculation is hardly sensitive to mannose in contrast to FLO1-determined flocculation. Overexpression of the GTS1 gene in a flo1 background does not abolish flocculation, suggesting that the FLO1 gene is not linked with the GTS1 gene in a 'flocculation pathway'.

HySP26 gene transcription is strongly induced during Saccharomyces cerevisiae growth at low pH

During exponential growth of Saccharomyces cerevisiae at the inhibitory pH 2.5, the transcription of the major small-heat-shock-protein-encoding gene HSP26 was strongly induced while at the optimal pH 5.0, the mRNA levels from the HSP26 gene were undetectable. When yeast cells entered the stationary phase of growth at pH 5.0, transcription was dramatically enhanced and the level of the HSP26 transcripts reached similar values in stationary cells grown at optimal or inhibitory low pH.

Cloning, sequencing and regulation of a cDNA encoding a small heat-shock protein from Schizosaccharomyces pombe

We have isolated a Schizosaccharomyces pombe cDNA encoding a small heat-shock protein, designated Hsp9. The deduced amino acid sequence shares significant homology with the Saccharomyces cerevisiae Hsp12 gene product. Northern blot analysis identified a 600-base transcript which is expressed at a low level in S. pombe exponentially growing cells, but is strongly induced by heat-shock and upon entry into the stationary phase. An increase in the transcript level is also observed in response to glucose deprivation.

Sequence analysis of a 31 kb DNA fragment from the right arm of Saccharomyces cerevisiae chromosome II

The nucleotide sequence of a 31,352 bp fragment from chromosome II of Saccharomyces cerevisiae has been determined and analysed. The fragment originates from the right arm of chromosome II, located between the GAL7,10,1 and the PHO3,5 loci, at a distance of about 130 kb from the centromere. The sequence contains a tRNA tandem repeat and 17 open reading frames (ORFs) larger than 100 amino acids. One of them extends into adjacent DNA and is incomplete. The two tRNA genes, coding for a tRNA(asp) and a tRNA(arg), and three of the ORFs, had been sequenced previously, i.e. HSP26, SEC18, and UBC4. Four other ORFs showed similarity with yeast genes; amino acid transporter genes, the RAD54, SNF2 and STH1 family, the SPS2 gene and the bromodomain of SPT7, respectively. Two showed homology with sequences from other organisms, i.e. with a Plasmodium falciparum gene encoding a surface antigen and with a gene from Saimirine herpes virus respectively. Three ORFs, YBR0726, YBR0735 and YBR0740 are completely contained in YBR0727, YBR0734 and YBR0739 respectively, and thus probably do not represent real genes. Two ORFs, YBR0727 and YBR0745 most likely contain an intron.

Known heat-shock proteins are not responsible for stress-induced rapid degradation of ribosomal protein mRNAs in yeast

We have previously shown that the heat-induced enhanced decay of yeast mRNAs encoding ribosomal proteins (rp-mRNAs) requires ongoing transcription during the heat treatment [Herruer et al. (1988) Nucl. Acids Res. 16, 7917]. In order to determine whether this requirement reflects the need for heat-shock protein (hsp), we analysed the effect of heat shock on rp-mRNA levels in several yeast strains in which each of the heat-shock genes encoding hsp26, hsp35 or hsp83 had been individually disrupted. In all three strains we still observed increased degradation of rp-mRNAs immediately after the temperature shift, demonstrating that hsp26, hsp35 and hsp83 are not required for this effect. Accelerated turnover of rp-mRNA was also found to occur upon raising the growth temperature of a mutant strain that contains a disruption of the gene specifying the heat-shock transcription factor and in wild-type yeast cells treated with canavanine, an arginine analogue that will be incorporated into all known hsps and that is known to cause misfolding of the polypeptide chain. Latter observation suggests that enhanced rp-mRNA decay is a more general stress-related phenomenon. Taken together, these data strongly indicate that the trans-acting factor required for the increase in the rate of degradation of rp-mRNAs upon stress is not one of the known yeast hsps.

Stress response of yeast

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Phylogeny of the alpha-crystallin-related heat-shock proteins

Phylogenetic relationships were examined among 35 alpha-crystallin-related heat-shock proteins from animals, plants, and fungi. Approximately one-third of the aligned amino acids in these proteins were conserved in 74% of the proteins, and three blocks of consensus sequence were identified. Relationships were established by maximum parsimony and distance matrix analyses of the aligned amino acid sequences. The inferred phylogeny trees show the plant proteins clearly divided into three major groups that are unrelated to taxonomy: the chloroplast-localized proteins and two groups that originate from a common ancestral plant protein. The animal proteins, in contrast, branch in accordance with taxonomy, the only clear exception being the alpha-crystallin subgrouping of vertebrates. This analysis indicates that the small heat-shock proteins of animals have diverged more widely than have the plant proteins, one group of which is especially stable.

The effects of 5'-capping, 3'-polyadenylation and leader composition upon the translation and stability of mRNA in a cell-free extract derived from the yeast Saccharomyces cerevisiae

A new modular expression system was developed to direct the in vitro synthesis of defined transcripts that were used as templates for translation in yeast cell-free extracts. The system was used to examine the influence of 5'-capping, 3'-polyadenylation and leader sequence upon the translation and stability of the synthetic Tn9 cat (chloramphenicol acetyl transferase), yeast PGK (phosphoglycerate kinase) and yeast HSP26 (heat-shock protein 26) mRNAs. The addition of a methylated cap (m7Gppp) or of a poly(A) tail enhanced translation and stabilized the mRNA. The dependence of translation upon capping was reduced in the presence of the HSP26 leader sequence. This may indicate the existence of a translational mechanism that enhances cap-independent translation. The enhancement of the translation and stability of mRNA was relatively insensitive to changes in the position of the poly(A) tail relative to the reading frame.

Osmostress-induced changes in yeast gene expression

When Saccharomyces cerevisiae cells are exposed to high concentration of NaCl, they show reduced viability, methionine uptake and protein biosynthesis. Cells can acquire tolerance against a severe salt shock (up to 1.4 M NaCl) by a previous treatment with 0.7 M NaCl, but not by a previous heat shock. Two-dimensional analysis of [3H]-leucine-labelled proteins from salt-shocked cells (0.7 M NaCl) revealed the elevated rate of synthesis of nine proteins, among which were the heat-shock proteins hsp12 and hsp26. Northern analysis using gene-specific probes confirmed the identity of the latter proteins and, in addition, demonstrated the induction of glycerol-3-phosphate dehydrogenase gene expression. The synthesis of the same set of proteins is induced or enhanced upon exposure of cells to 0.8 M sucrose, although not as dramatically as in an iso-osmolar NaCl concentration (0.7 M).

The 14,000-molecular-weight antigen of Mycobacterium tuberculosis is related to the alpha-crystallin family of low-molecular-weight heat shock proteins

Eight monoclonal antibodies (MAbs) directed against the 14,000-molecular-weight (14K) antigen of Mycobacterium tuberculosis reacted specifically with mycobacteria of the M. tuberculosis complex. The nucleotide sequence of the gene encoding the 14K antigen was determined by using recombinant DNA clones isolated from lambda gt11 and cosmid libraries of the M. tuberculosis genome. The DNA sequence of the 14K protein gene coded for a polypeptide of 144 amino acids with a calculated molecular mass of 16,277 Da. The 14K antigen has a marked homology with proteins belonging to the alpha-crystallin family of low-molecular-weight heat shock proteins, which includes the 18K antigen of M. leprae. The eight MAbs recognized at least four distinct epitopes localized within the following three regions of the 14K protein: amino acids 10 to 92 (MAbs F67-8 and F67-16), amino acids 41 to 92 (F159-1 and F159-11), and amino acids 41 to 144 (F23-41, F24-2, F23-49, and TB68).

The small heat-shock protein Hsp26 of Saccharomyces cerevisiae assembles into a high molecular weight aggregate

Hsp26 is one of the major small heat-shock proteins (Hsp) of the yeast Saccharomyces cerevisiae, yet its cellular role remains to be discovered. To examine the cellular consequences of overexpression of Hsp26, the gene encoding this protein (HSP26) was overexpressed from a multicopy plasmid using either its own promoter or by coupling it to the efficient constitutive PGK promoter. The PGK promoter provided the opportunity to overexpress Hsp26 under non-stress conditions and such high level synthesis, prior to a lethal heat shock (50 degrees C), gave a small but reproducible elevation in thermotolerance. In transformed strains overexpressing Hsp26 under either stressed or non-stress conditions, the Hsp26 polypeptide was recovered almost exclusively as a high molecular weight aggregate. This high molecular weight aggregate (or heat-shock granule; HSG) was purified by differential centrifugation and sucrose gradient density centrifugation and shown, by electron microscopic analysis, to be of a uniform size (15-25 nm diameter). Analysis of the purified HSG demonstrated that it had a molecular weight of 550 kDa, yet contained no other integral polypeptides or other macromolecules.

Translocation and induction of alpha B crystallin by heat shock in rat glioma (GA-1) cells

Response to heat shock of alpha B crystallin expressed in rat astrocytoma GA-1 cells was analysed quantitatively using an immunoassay method. GA-1 cells contained a considerable amount of alpha B crystallin at growing phase. When the growing cells were heated at 45 degrees C, concentrations of alpha B crystallin in cell extracts were decreased to less than one-fifth of the original level within 15 min, with an increase in the insoluble fraction which was detected by immunoblotting. The low level of alpha B crystallin in the cytoplasm, that was observed for a few hours after heat shock, gradually recovered to the control level within several hours. At 10 h following heat shock (45 degrees C for 15 min), the concentration of alpha B crystallin in the soluble extract was about twice that of the control level, with little detectable amounts in the insoluble fraction. These results are additional evidence that suggest that alpha B crystallin is a small heat shock protein.

Protein disulfide isomerase is essential for viability in Saccharomyces cerevisiae

Protein disulfide isomerase (PDI) is an enzyme involved in the catalysis of disulfide bond formation in secretory and cell-surface proteins. Using an oligodeoxyribonucleotide designed to detect the conserved 'thioredoxin-like' active site of vertebrate PDIs, we have isolated a gene encoding PDI from the lower eukaryote, Saccharomyces cerevisiae. The nucleotide sequence and deduced open reading frame of the cloned gene predict a 530-amino-acid (aa) protein of Mr 59,082 and a pI of 4.1, physical properties characteristic of mammalian PDIs. Furthermore, the aa sequence shows 30-32% identity with mammalian and avian PDI sequences and has a very similar overall organisation, namely the presence of two approx. 100-aa segments, each of which is repeated, with the most significant homologies to mammalian and avian PDIs being in the regions (a, a') that contain the conserved 'thioredoxin-like' active site. The N-terminal region has the characteristics of a cleavable secretory signal sequence and the C-terminal four aa (-His-Asp-Glu-Leu) are consistent with the protein being a component of the S. cerevisiae endoplasmic reticulum. Transformants carrying multiple copies of this gene (designated PDI1) have tenfold higher levels of PDI activity and overproduce a protein of the predicted Mr. The PDI1 gene is unique in the yeast genome and encodes a single 1.8-kb transcript that is not found in stationary phase cells. Disruption of the PDI1 gene is haplo-lethal indicating that the product of this gene is essential for viability.

Is 20S RNA naked?

The 20S RNA of Saccharomyces cerevisiae is a single-stranded, circular RNA virus. A previous study suggested that this RNA is part of a 32S ribonucleoprotein particle, being associated with multiple copies of a 23-kilodalton protein. We show here that this protein is, in fact, the chromosome-encoded heat shock protein Hsp26. Furthermore, it is apparently not associated with 20S RNA and plays no obvious role in the life cycle of the virus.

Is 20S RNA naked?

The 20S RNA of Saccharomyces cerevisiae is a single-stranded, circular RNA virus. A previous study suggested that this RNA is part of a 32S ribonucleoprotein particle, being associated with multiple copies of a 23-kilodalton protein. We show here that this protein is, in fact, the chromosome-encoded heat shock protein Hsp26. Furthermore, it is apparently not associated with 20S RNA and plays no obvious role in the life cycle of the virus.

HSP12, a new small heat shock gene of Saccharomyces cerevisiae: analysis of structure, regulation and function

We have isolated a new small heat shock gene, HSP12, from Saccharomyces cerevisiae. It encodes a polypeptide of predicted Mr 12 kDa, with structural similarity to other small heat shock proteins. HSP12 gene expression is induced several hundred-fold by heat shock and on entry into stationary phase. HSP12 mRNA is undetectable during exponential growth in rich medium, but low levels are present when cells are grown in minimal medium. Analysis of HSP12 expression in mutants affected in cAMP-dependent protein phosphorylation suggests that the gene is regulated by cAMP as well as heat shock. A disruption of the HSP12 coding region results in the loss of an abundant 14.4 kDa protein present in heat shocked and stationary phase cells. It also leads to the induction of the heat shock response under conditions normally associated with low-level HSP12 expression. The HSP12 disruption has no observable effect on growth at various temperatures, nor on the ability to acquire thermotolerance.