Both ambient temperature and the DnaK chaperone machine modulate the heat shock response in Escherichia coli by regulating the switch between sigma 70 and sigma 32 factors assembled with RNA polymerase

DnaJ and ClpX are required for HitRS and HssRS two-component system signaling in Bacillus anthracis

Bacillus anthracis is the causative agent of anthrax. This Gram-positive bacterium poses a substantial risk to human health due to high mortality rates and the potential for malicious use as a bioterror weapon. To survive within the vertebrate host, B. anthracis relies on two-component system (TCS) signaling to sense host-induced stresses and respond to alterations in the environment through changes in target gene expression. HitRS and HssRS are cross-regulating TCSs in B. anthracis that respond to cell envelope disruptions and high heme levels, respectively. In this study, an unbiased and targeted genetic selection was designed to identify gene products that are involved in HitRS and HssRS signaling. This selection led to the identification of inactivating mutations within dnaJ and clpX that disrupt HitRS- and HssRS-dependent gene expression. DnaJ and ClpX are the substrate-binding subunits of the DnaJK protein chaperone and ClpXP protease, respectively. DnaJ regulates the levels of HitR and HitS to facilitate signal transduction, while ClpX specifically regulates HitS levels. Together these results reveal that the protein homeostasis regulators, DnaJ and ClpX, function to maintain B. anthracis signal transduction activities through TCS regulation. One sentence summary: Use of a genetic selection strategy to identify modulators of two-component system signaling in Bacillus anthracis.

The role of the bacterial protease Prc in the uropathogenesis of extraintestinal pathogenic Escherichia coli

Background

Extraintestinal pathogenic E. coli (ExPEC) remains one of the most prevalent bacterial pathogens that cause extraintestinal infections, including neonatal meningitis, septicemia, and urinary tract (UT) infections (UTIs). Antibiotic therapy has been the conventional treatment for such infections, but its efficacy has decreased due to the emergence of antibiotic-resistant bacteria. Identification and characterization of bacterial factors that contribute to the severity of infection would facilitate the development of novel therapeutic strategies. The ExPEC periplasmic protease Prc contributes to the pathogen’s ability to evade complement-mediated killing in the serum. Here, we further investigated the role of the Prc protease in ExPEC-induced UTIs and the underlying mechanism.

Methods

The uropathogenic role of Prc was determined in a mouse model of UTIs. Using global quantitative proteomic analyses, we revealed that the expression of FliC and other outer membrane-associated proteins was altered by Prc deficiency. Comparative transcriptome analyses identified that Prc deficiency affected expression of the flagellar regulon and genes that are regulated by five extracytoplasmic signaling systems.

Results

A mutant ExPEC with a prc deletion was attenuated in bladder and kidney colonization. Global quantitative proteomic analyses of the prc mutant and wild-type ExPEC strains revealed significantly reduced flagellum expression in the absence of Prc, consequently impairing bacterial motility. The prc deletion triggered downregulation of the flhDC operon encoding the master transcriptional regulator of flagellum biogenesis. Overexpressing flhDC restored the prc mutant’s motility and ability to colonize the UT, suggesting that the impaired motility is responsible for attenuated UT colonization of the mutant. Further comparative transcriptome analyses revealed that Prc deficiency activated the σ^E and RcsCDB signaling pathways. These pathways were responsible for the diminished flhDC expression. Finally, the activation of the RcsCDB system was attributed to the intracellular accumulation of a known Prc substrate Spr in the prc mutant. Spr is a peptidoglycan hydrolase and its accumulation destabilizes the bacterial envelope.

Conclusions

We demonstrated for the first time that Prc is essential for full ExPEC virulence in UTIs. Our results collectively support the idea that Prc is essential for bacterial envelope integrity, thus explaining how Prc deficiency results in an attenuated ExPEC.

Protein aggregation in bacteria

Protein aggregation occurs as a consequence of perturbations in protein homeostasis that can be triggered by environmental and cellular stresses. The accumulation of protein aggregates has been associated with aging and other pathologies in eukaryotes, and in bacteria with changes in growth rate, stress resistance and virulence. Numerous past studies, mostly performed in Escherichia coli, have led to a detailed understanding of the functions of the bacterial protein quality control machinery in preventing and reversing protein aggregation. However, more recent research points toward unexpected diversity in how phylogenetically different bacteria utilize components of this machinery to cope with protein aggregation. Furthermore, how persistent protein aggregates localize and are passed on to progeny during cell division and how their presence impacts reproduction and the fitness of bacterial populations remains a controversial field of research. Finally, although protein aggregation is generally seen as a symptom of stress, recent work suggests that aggregation of specific proteins under certain conditions can regulate gene expression and cellular resource allocation. This review discusses recent advances in understanding the consequences of protein aggregation and how this process is dealt with in bacteria, with focus on highlighting the differences and similarities observed between phylogenetically different groups of bacteria.

Thermal proteome profiling in bacteria: probing protein state in vivo

Increasing antibiotic resistance urges for new technologies for studying microbes and antimicrobial mechanism of action. We adapted thermal proteome profiling (TPP) to probe the thermostability of Escherichia coli proteins in vivoE. coli had a more thermostable proteome than human cells, with protein thermostability depending on subcellular location-forming a high-to-low gradient from the cell surface to the cytoplasm. While subunits of protein complexes residing in one compartment melted similarly, protein complexes spanning compartments often had their subunits melting in a location-wise manner. Monitoring the E. coli meltome and proteome at different growth phases captured changes in metabolism. Cells lacking TolC, a component of multiple efflux pumps, exhibited major physiological changes, including differential thermostability and levels of its interaction partners, signaling cascades, and periplasmic quality control. Finally, we combined in vitro and in vivo TPP to identify targets of known antimicrobial drugs and to map their downstream effects. In conclusion, we demonstrate that TPP can be used in bacteria to probe protein complex architecture, metabolic pathways, and intracellular drug target engagement.

An essential regulatory function of the DnaK chaperone dictates the decision between proliferation and maintenance in Caulobacter crescentus

Hsp70 chaperones are well known for their important functions in maintaining protein homeostasis during thermal stress conditions. In many bacteria the Hsp70 homolog DnaK is also required for growth in the absence of stress. The molecular reasons underlying Hsp70 essentiality remain in most cases unclear. Here, we demonstrate that DnaK is essential in the α-proteobacterium Caulobacter crescentus due to its regulatory function in gene expression. Using a suppressor screen we identified mutations that allow growth in the absence of DnaK. All mutations reduced the activity of the heat shock sigma factor σ³², demonstrating that the DnaK-dependent inactivation of σ³² is a growth requirement. While most mutations occurred in the rpoH gene encoding σ³², we also identified mutations affecting σ³² activity or stability in trans, providing important new insight into the regulatory mechanisms controlling σ³² activity. Most notably, we describe a mutation in the ATP dependent protease HslUV that induces rapid degradation of σ³², and a mutation leading to increased levels of the house keeping σ⁷⁰ that outcompete σ³² for binding to the RNA polymerase. We demonstrate that σ³² inhibits growth and that its unrestrained activity leads to an extensive reprogramming of global gene expression, resulting in upregulation of repair and maintenance functions and downregulation of the growth-promoting functions of protein translation, DNA replication and certain metabolic processes. While this re-allocation from proliferative to maintenance functions could provide an advantage during heat stress, it leads to growth defects under favorable conditions. We conclude that Caulobacter has co-opted the DnaK chaperone system as an essential regulator of gene expression under conditions when its folding activity is dispensable.

Molecular chaperones of the Hsp70 family belong to the most conserved cellular machineries throughout the tree of life. These proteins play key roles in maintaining protein homeostasis, especially under heat stress conditions. In diverse bacteria the Hsp70 homolog DnaK is essential for growth even in the absence of stress. However, the molecular mechanisms underlying the essential nature of DnaK have in most cases not been studied. We found in the α-proteobacterium Caulobacter crescentus that the function of DnaK as a folding catalyst is dispensable in the absence of stress. Instead, its sole essential function under such conditions is to inhibit the activity of the heat shock sigma factor σ³². Our findings highlight that some bacteria have co-opted chaperones as essential regulators of gene expression under conditions when their folding activity is not required. Furthermore, our work illustrates that essential genes can perform different essential functions in discrete growth conditions.

When, how and why? Regulated proteolysis by the essential FtsH protease in Escherichia coli

Cellular proteomes are dynamic and adjusted to permanently changing conditions by ATP-fueled proteolytic machineries. Among the five AAA+ proteases in Escherichia coli FtsH is the only essential and membrane-anchored metalloprotease. FtsH is a homohexamer that uses its ATPase domain to unfold and translocate substrates that are subsequently degraded without the need of ATP in the proteolytic chamber of the protease domain. FtsH eliminates misfolded proteins in the context of general quality control and properly folded proteins for regulatory reasons. Recent trapping approaches have revealed a number of novel FtsH substrates. This review summarizes the substrate diversity of FtsH and presents details on the surprisingly diverse recognition principles of three well-characterized substrates: LpxC, the key enzyme of lipopolysaccharide biosynthesis; RpoH, the alternative heat-shock sigma factor and YfgM, a bifunctional membrane protein implicated in periplasmic chaperone functions and cytoplasmic stress adaptation.

Suppression of a dnaKJ deletion by multicopy dksA results from non-feedback-regulated transcripts that originate upstream of the major dksA promoter

DksA is an RNA polymerase (RNAP) binding transcription factor that controls expression of a large number of genes in concert with the small-molecule "alarmone" ppGpp. DksA also aids in the resolution of conflicts between RNAP and DNA polymerase (DNAP) during genome replication. DksA was originally identified as a multicopy suppressor of the temperature sensitivity caused by deletion of the genes coding for the DnaKJ chaperone system. Here, we address a longstanding question regarding the role of DksA in ΔdnaKJ suppression. We demonstrate that DksA expression from a multicopy plasmid is necessary and sufficient for suppression, that overexpression occurs despite the fact that the major dksA promoter is feedback regulated in wild-type cells, and that weak, non-feedback-regulated transcription originating upstream of the major promoter for the dksA gene accounts for overexpression. We tentatively rule out three potential explanations for suppression related to known functions of DnaKJ. Because a determinant in DksA needed for the regulation of transcription initiation, but not for resolution of RNAP-DNAP conflicts, is needed to bypass the need for DnaKJ, we suggest that suppression results from an unidentified product whose promoter is directly or indirectly regulated by DksA.

DnaK and GroEL are induced in response to antibiotic and heat shock in Acinetobacter baumannii

We studied the expression of DnaK and GroEL in Acinetobacter baumannii cells (strains ATCC 19606 and RS4) under stress caused by heat shock or antibiotics. A Western blot assay showed that DnaK and GroEL levels increased transiently more than 2-fold after exposure of bacterial cells to heat shock for 20 min at 50 °C. Heat induction of DnaK and GroEL was blocked completely when an inhibitor of transcription, rifampicin, was added 1 min before a temperature upshift to 50 °C, suggesting that the induction of these chaperones depends on transcription. A. baumannii cells pretreated at 45 °C for 30 min were better able to survive at 50 °C for 60 min than cells pretreated at 37 °C, indicating that A. baumannii is able to acquire thermotolerance. DnaK and GroEL were successfully induced in cells pre-incubated with a subinhibitory concentration of streptomycin. Moreover, bacterial cells pretreated for 30 min at 45 °C were better able to survive streptomycin exposure than cells pretreated at physiological temperatures. DnaK expression was upregulated in a multidrug-resistant strain of A. baumannii (RS4) in the presence of different antimicrobials (ampicillin+sulbactam, cefepime, meropenem and sulphamethoxazole+trimethoprim). This study is to the best of our knowledge the first to show that A. baumannii DnaK and GroEL could play an important role in the stress response induced by antibiotics.

Contribution of rpoS and bolA genes in biofilm formation in Escherichia coli K-12 MG1655

Flexibility of gene expression in bacteria permits its survival in varied environments. The genetic adaptation of bacteria through systematized gene expression is not only important, but also clinically relevant in their ability to grow biofilms in stress environments. Stress responses enable their survival under more severe conditions, enhanced resistance and/or virulence. In Escherichia coli (E. coli), two of the possible important genes for biofilm growth are rpoS and bolA gene. RpoS is also called as a master regulator of general stress response. Even though many studies have revealed the importance of rpoS in planktonic cells, little is known about the functions of rpoS in biofilms. In contrast, bolA which is a morphogene in E. coli is overexpressed under stressed environments resulting in round morphology. The hypothesis is that bolA could be implicated in biofilm development. This study reviewed the literature with the aim of understanding the stress tolerance response of E. coli in relation with rpoS and bolA genes in different environmental conditions including heat shock, cold shock, and stress in response to oxidation, acidic condition and in presence of cadmium. Knowledge of the genetic regulation of biofilm formation may lead to the understanding of the factors that drive the bacteria to switch to the biofilm mode of growth.

Conformational properties of aggregated polypeptides determine ClpB-dependence in the disaggregation process

Severe thermal stress induces massive intracellular protein aggregation. The concerted action of Hsp70 (DnaK, DnaJ, GrpE) and Hsp100 (ClpB) chaperones results in solubilization of aggregates followed by reactivation of proteins. It was shown that the Hsp70 chaperone system works at the initial step of the disaggregation reaction and is able to disentangle polypeptides from aggregates. Studies of the protein disaggregation reaction performed in vitro showed that ClpB may be dispensable in disaggregation of certain proteins and/or aggregates of certain size. Here we focus our attention on those properties of firefly luciferase aggregates, which determine whether ClpB chaperone is required in the disaggregation process. We report that the size of the aggregates is not a major determinant. Instead, we postulate that certain conformational properties (in particular, beta-structures) of subunits forming these aggregates are the most important factor determining the necessity of the ClpB chaperone in the disaggregation process.

An online monitoring system based on a synthetic sigma32-dependent tandem promoter for visualization of insoluble proteins in the cytoplasm of Escherichia coli

The expression of heterologous proteins in the cytoplasm of Escherichia coli is often accompanied by limitations resulting in uncontrollable fermentation processes, increased rates of cell lysis, and thus limited yields of target protein. To deal with these problems, reporter tools are required to improve the folding properties of recombinant protein. In this work, the well-known sigma(32)-dependent promoters ibpAB and fxsA were linked in a tandem promoter (ibpfxs), fused with the luciferase reporter gene lucA to allow enhanced monitoring of the formation of misfolded proteins and their aggregates in E. coli cells. Overexpression of MalE31, a folding-defective variant of the maltose-binding protein, and other partially insoluble heterologous proteins showed that the lucA reporter gene was activated in the presence of these misfolded proteins. Contrary to this, the absence of damaged proteins or overexpression of mostly soluble proteins led to a reduced level of luciferase induction. Through performing expression of aggregation-prone proteins, we were able to demonstrate that the ibpfxs::lucA reporter unit is 2.5-4.5 times stronger than the single reporter units ibp::lucA and fxs::lucA. Data of misfolding studies showed that this reporter system provides an adequate tool for in vivo folding studies in E. coli from microtiter up to fermentation scales.

Global gene expression analysis of the heat shock response in the phytopathogen Xylella fastidiosa

Xylella fastidiosa is a phytopathogenic bacterium that is responsible for diseases in many economically important crops. Although different strains have been studied, little is known about X. fastidiosa stress responses. One of the better characterized stress responses in bacteria is the heat shock response, which induces the expression of specific genes to prevent protein misfolding and aggregation and to promote degradation of the irreversibly denatured polypeptides. To investigate X. fastidiosa genes involved in the heat shock response, we performed a whole-genome microarray analysis in a time course experiment. Globally, 261 genes were induced (9.7%) and 222 genes were repressed (8.3%). The expression profiles of the differentially expressed genes were grouped, and their expression patterns were validated by quantitative reverse transcription-PCR experiments. We determined the transcription start sites of six heat shock-inducible genes and analyzed their promoter regions, which allowed us to propose a putative consensus for sigma(32) promoters in Xylella and to suggest additional genes as putative members of this regulon. Besides the induction of classical heat shock protein genes, we observed the up-regulation of virulence-associated genes such as vapD and of genes for hemagglutinins, hemolysin, and xylan-degrading enzymes, which may indicate the importance of heat stress to bacterial pathogenesis. In addition, we observed the repression of genes related to fimbriae, aerobic respiration, and protein biosynthesis and the induction of genes related to the extracytoplasmic stress response and some phage-related genes, revealing the complex network of genes that work together in response to heat shock.

How high G+C Gram-positive bacteria and in particular bifidobacteria cope with heat stress: protein players and regulators

The Actinobacteridae group of bacteria includes pathogens, plant commensals, endosymbionts as well as inhabitants of the gastrointestinal tract. For various reasons, these microorganisms represent a growing area of interest with respect to genomics, molecular biology and genetics. This review will discuss the current knowledge on the molecular players that allow actinobacteria to contend with heat stress, with an emphasis on bifidobacteria. We describe the principal molecular chaperones involved in heat stress. Temporal expression of heat-shock genes based on functional genomics in members of the Actinobacteridae group is also discussed, as well as the emerging molecular mechanisms controlling the heat-stress response.

dnaJ and gyrB gene sequence relationship among species and strains of genus Streptococcus

The dnaJ and gyrB nucleotide sequences were determined for members of the genus Streptococcus. The average similarity between the species tested was 76.4% (69.7-100%) for dnaJ and 75.9 (70.1-98.7%) for gyrB. These data indicated that the dnaJ and gyrB genes are more divergent and more discriminatory than the 16S rDNA gene. Furthermore, the variation in the dnaJ nucleotide sequences among the mitis group was greater than that of the gyrB nucleotide sequences, especially between Streptococcus pneumoniae and Streptococcus mitis. Subsequently, the high discrimination power of dnaJ within the mitis group was confirmed. Thus, we conclude that the dnaJ and gyrB genes are efficient alternative targets for the classification of the genus Streptococcus, and that dnaJ is suitable for phylogenetic analysis of closely related Streptococcus strains.

Cells lacking ClpB display a prolonged shutoff phase of the heat shock response in Caulobacter crescentus

The heat shock response in Caulobacter crescentus was previously shown to be positively regulated by the alternative sigma factor of RNA polymerase (RNAP) sigma(32), and negatively modulated by DnaK during the induction phase of the heat shock response but not during the recovery phase. In the present work we have investigated the involvement of the chaperone ClpB in the control of the heat shock response in C. crescentus. Data obtained indicated a role of ClpB in downregulation of heat shock protein (HSP) synthesis, as cells lacking this chaperone showed a prolonged shutoff phase of the heat shock response. In Escherichia coli, it has been proposed that the DnaK chaperone system switches transcription back to constitutively expressed genes through simultaneous reactivation of heat-aggregated sigma(70), as well as sequestration of sigma(32) away from RNAP. In C. crescentus, results obtained with a clpB null mutant indicate that ClpB could be involved in the reactivation of the major sigma factor sigma(73). In support of this hypothesis, we showed that transcription directed from sigma(73)-dependent promoters is not switched back in the clpB null mutant during the recovery phase. Furthermore, we observed that resolubilization of heat-aggregated sigma(73) is dependent on the presence of ClpB. Our findings also indicated that the absence of ClpB made cells more sensitive to heat shock and ethanol but not to other stresses, and unable to acquire thermotolerance.

Identification of a turnover element in region 2.1 of Escherichia coli sigma32 by a bacterial one-hybrid approach

Induction of the heat shock response in Escherichia coli requires the alternative sigma factor sigma32 (RpoH). The cellular concentration of sigma32 is controlled by proteolysis involving FtsH, other proteases, and the DnaKJ chaperone system. To identify individual sigma32 residues critical for degradation, we used a recently developed bacterial one-hybrid system and screened for stabilized versions of sigma32. The five single point mutations that rendered the sigma factor more stable mapped to positions L47, A50, and I54 in region 2.1. Strains expressing the stabilized sigma32 variants exhibited elevated transcriptional activity, as determined by a groE-lacZ fusion. Structure calculations predicted that the three mutated residues line up on the same face of an alpha-helix in region 2.1, suggesting that they are positioned to interact with proteins of the degradation machinery.

A chaperone network controls the heat shock response in E. coli

The heat shock response controls levels of chaperones and proteases to ensure a proper cellular environment for protein folding. In Escherichia coli, this response is mediated by the bacterial-specific transcription factor, sigma32. The DnaK chaperone machine regulates both the amount and activity of sigma32, thereby coupling sigma32 function to the cellular protein folding state. In this manuscript, we analyze the ability of other major chaperones in E. coli to regulate sigma32, and we demonstrate that the GroEL/S chaperonin is an additional regulator of sigma32. We show that increasing the level of GroEL/S leads to a decrease in sigma32 activity in vivo and this effect can be eliminated by co-overexpression of a GroEL/S-specific substrate. We also show that depletion of GroEL/S in vivo leads to up-regulation of sigma32 by increasing the level of sigma32. In addition, we show that changing the levels of GroEL/S during stress conditions leads to measurable changes in the heat shock response. Using purified proteins, we show that that GroEL binds to sigma32 and decreases sigma32-dependent transcription in vitro, suggesting that this regulation is direct. We discuss why using a chaperone network to regulate sigma32 results in a more sensitive and accurate detection of the protein folding environment.

Successive and synergistic action of the Hsp70 and Hsp100 chaperones in protein disaggregation

Proteins belonging to the B-subtype of the Hsp100/Clp chaperone family execute a crucial role in cellular thermotolerance. They cooperate with the Hsp70 chaperones in reactivation of thermally aggregated protein substrates. We investigated the initial events of the disaggregation reaction in real time using denatured, aggregated green fluorescent protein (GFP) as a substrate. Bacterial Hsp70 (DnaK), its co-chaperones (DnaJ and GrpE), and Hsp100 (ClpB) were incubated with aggregated GFP, and the increase in GFP fluorescence was monitored. Incubation of aggregated GFP with DnaK/DnaJ/GrpE but not with ClpB resulted in the rapid initiation of the disaggregation reaction. Under the same conditions a complex between DnaK, DnaJ, and GFP, but not ClpB, was formed as demonstrated by sedimentation analysis and light scattering experiments. Chaperone-dependent disaggregation of chemically denatured aggregated luciferase showed that, similar to GFP disaggregation, incubation with Hsp70 results in the rapid start of the reactivation reaction. For both aggregated GFP and luciferase, incubation with Hsp70 chaperones changes the initial rate but not the overall efficiency or rate of the refolding reaction. Our results clearly demonstrate that the interaction of DnaK and its co-chaperones with aggregated substrate is the rate-limiting reaction at the initial steps of disaggregation.

Use of the dnaJ gene for the detection and identification of all Legionella pneumophila serogroups and description of the primers used to detect 16S rDNA gene sequences of major members of the genus Legionella

We sequenced about 930 bp of the dnaJ gene from 15 Legionella pneumophila serogroups and some other members of the genus Legionella. As L. pneumophila 16S rDNA sequences could not discriminate between all subspecies and serogroups, we assessed the use of dnaJ gene sequences to differentiate between Legionella subspecies as well as between L. pneumophila serogroups. A phylogenetic analysis revealed that dnaJ gene sequences were more variable between the L. pneumophila serogroups than mip gene and 16S rDNA sequences. By studying 61 strains from 41 species of the genus Legionella, as well as other genera, we established a PCR method that could amplify 285 bp of dnaJ gene from all L. pneumophila serogroups. This primer set was more sensitive than mip gene primers and was able to detect 0.25 ng of purified DNA. We also describe the 16S rDNA primers that were used to detect most Legionella genus members.

Downregulation of the heat shock response is independent of DnaK and sigma32 levels in Caulobacter crescentus

Expression of heat shock genes in Gram-negative proteobacteria is positively modulated by the transcriptional regulator RpoH, the sigma(32) subunit of RNA polymerase (RNAP). In this study we investigated the chaperones DnaK/DnaJ and GroES/GroEL as possible modulators of the heat response in Caulobacter crescentus. We have shown that cells overexpressing DnaK show poor induction of heat shock protein (HSP) synthesis, even though sigma(32) levels present a normal transient increase upon heat stress. On the other hand, depletion of DnaK led to higher levels of sigma(32) and increased transcription of HSP genes, at normal growth temperature. In contrast, changes in the amount of GroES/EL had little effect on sigma(32) levels and HSP gene transcription. Despite the strong effect of DnaK levels on the induction phase of the heat shock response, downregulation of HSP synthesis was not affected by changes in the amount this chaperone. Thus, we propose that competition between sigma(32) and sigma(73), the major sigma factor, for the core RNAP could be the most important factor controlling the shut-off of HSP synthesis during recovery phase. In agreement with this hypothesis, we have shown that expression of sigma(73) gene is heat shock inducible.

The bacterial universal stress protein: function and regulation

The universal stress protein A (UspA) superfamily encompasses an ancient and conserved group of proteins that are found in bacteria, Archea, fungi, flies and plants. The Escherichia coli UspA is produced in response to a large number of different environmental onslaughts and UspA is one of the most abundant proteins in growth-arrested cells. Although insights into the regulation of the E. coli uspA gene have been gained, the exact roles of the Usp proteins and Usp domains remain enigmatic; they appear, in some cases, to be linked to resistance to DNA-damaging agents and to respiratory uncouplers.

Lack of a robust unfoldase activity confers a unique level of substrate specificity to the universal AAA protease FtsH

FtsH, a member of the AAA family of proteins, is the only membrane ATP-dependent protease universally conserved in prokaryotes, and the only essential ATP-dependent protease in Escherichia coli. We investigated the mechanism of degradation by FtsH. Other well-studied ATP-dependent proteases use ATP to unfold their substrates. In contrast, both in vitro and in vivo studies indicate that degradation by FtsH occurs efficiently only when the substrate is a protein of low intrinsic thermodynamic stability. Because FtsH lacks robust unfoldase activity, it is able to use the protein folding state of substrates as a criterion for degradation. This feature may be key to its role in the cell and account for its ubiquitous distribution among prokaryotic organisms.

Characterization of HscC (Hsc62), homologue of Hsp70 in Escherichia coli: over-expression of HscC modulates the activity of house keeping sigma factor sigma70

BACKGROUND

HscC, the third member of the Hsp70 family in Escherichia coli, shares 33% identity with the other two homologues, DnaK and HscA, and displays ATPase activity. Genetic and biochemical evidence indicates that the DnaK-DnaJ chaperone system interacts with sigma32 and is involved in the negative regulation of the heat shock response. Although HscC is a highly conserved protein in the Hsp70 family, its function is still unknown.

RESULTS

We observed that the over-expression of HscC caused severe growth inhibition. To explore this effect, we performed primer extension analysis and a beta-galactosidase assay and found that HscC reduced the sigma70-dependent promoter activity. An in vitro transcription assay revealed that HscC inhibited sigma70-dependent transcription. In addition, the co-purification analysis showed that sigma70 co-eluted with HscC.

CONCLUSION

These results indicate that HscC forms a complex with sigma70 and may function as its negative modulator.

Alpha-crystallin-type heat shock proteins: socializing minichaperones in the context of a multichaperone network

Alpha-crystallins were originally recognized as proteins contributing to the transparency of the mammalian eye lens. Subsequently, they have been found in many, but not all, members of the Archaea, Bacteria, and Eucarya. Most members of the diverse alpha-crystallin family have four common structural and functional features: (i) a small monomeric molecular mass between 12 and 43 kDa; (ii) the formation of large oligomeric complexes; (iii) the presence of a moderately conserved central region, the so-called alpha-crystallin domain; and (iv) molecular chaperone activity. Since alpha-crystallins are induced by a temperature upshift in many organisms, they are often referred to as small heat shock proteins (sHsps) or, more accurately, alpha-Hsps. Alpha-crystallins are integrated into a highly flexible and synergistic multichaperone network evolved to secure protein quality control in the cell. Their chaperone activity is limited to the binding of unfolding intermediates in order to protect them from irreversible aggregation. Productive release and refolding of captured proteins into the native state requires close cooperation with other cellular chaperones. In addition, alpha-Hsps seem to play an important role in membrane stabilization. The review compiles information on the abundance, sequence conservation, regulation, structure, and function of alpha-Hsps with an emphasis on the microbial members of this chaperone family.

Stochastic kinetic analysis of the Escherichia coli stress circuit using sigma(32)-targeted antisense

A stochastic Petri net model was developed for simulating the sigma(32) stress circuit in E. coli. Transcription factor sigma(32) is the principal regulator of the response of E. coli to heat shock. Stochastic Petri net (SPN) models are well suited for kinetics characterization of fluxes in biochemical pathways. Notably, there exists a one-to-one mapping of model tokens and places to molecules of particular species. Our model was validated against experiments in which ethanol (inducer of heat shock response) and sigma(32)-targeted antisense (downward regulator) were used to perturb the sigma(32) regulatory pathway. The model was also extended to simulate the effects of recombinant protein production. Results show that the stress response depends heavily on the partitioning of sigma(32) within the cell; that is, sigma(32) becomes immediately available to mediate a stress response because it exists primarily in a sequestered, inactive form, complexed with chaperones DnaK, DnaJ, and GrpE. Recombinant proteins, however, also compete for chaperone proteins, particularly when folded improperly. Our simulations indicate that when the expression of recombinant protein has a low requirement for DnaK, DnaJ, and GrpE, the overall sigma(32) levels may drop, but the level of heat shock proteins will increase. Conversely, when the overexpressed recombinant protein has a strong requirement for the chaperones, a severe response is predicted. Interestingly, both cases were observed experimentally.

DnaK chaperone-mediated control of activity of a sigma(32) homolog (RpoH) plays a major role in the heat shock response of Agrobacterium tumefaciens

RpoH (Escherichia coli sigma(32) and its homologs) is the central regulator of the heat shock response in gram-negative proteobacteria. Here we studied salient regulatory features of RpoH in Agrobacterium tumefaciens by examining its synthesis, stability, and activity while increasing the temperature from 25 to 37 degrees C. Heat induction of RpoH synthesis occurred at the level of transcription from an RpoH-dependent promoter, coordinately with that of DnaK, and followed by an increase in the RpoH level. Essentially normal induction of heat shock proteins was observed even with a strain that was unable to increase the RpoH level upon heat shock. Moreover, heat-induced accumulation of dnaK mRNA occurred without protein synthesis, showing that preexisting RpoH was sufficient for induction of the heat shock response. These results suggested that controlling the activity, rather than the amount, of RpoH plays a major role in regulation of the heat shock response. In addition, increasing or decreasing the DnaK-DnaJ chaperones specifically reduced or enhanced the RpoH activity, respectively. On the other hand, the RpoH protein was normally stable and remained stable during the induction phase but was destabilized transiently during the adaptation phase. We propose that the DnaK-mediated control of RpoH activity plays a primary role in the induction of heat shock response in A. tumefaciens, in contrast to what has been found in E. coli.

Co-operative binding of human fibronectin to Sfbl protein triggers streptococcal invasion into respiratory epithelial cells

Streptococcal fibronectin binding protein I (SfbI) mediates adherence to and invasion of Streptococcus pyogenes into human epithelial cells. In this study, we analysed the binding activity of distinct domains of SfbI protein towards its ligand, the extracellular matrix component fibronectin, as well as the biological implication of the binding events during the infection process. By using purified recombinant SfbI derivatives as well as in vivo expressed SfbI domains on the surface of heterologous organism Streptococcus gordonii, we were able to dissociate the two major streptococcal target domains on the human fibronectin molecule. The SfbI repeat region exclusively bound to the 30 kDa N-terminal fragment of fibronectin, whereas the SfbI spacer region exclusively bound to the 45 kDa collagen-binding fragment of fibronectin. In the case of native surface-expressed SfbI protein, an induced fit mode of bacteria-fibronectin interaction was identified. We demonstrate that binding of the 30 kDa fibronectin fragment to the repeat region of SfbI protein co-operatively activates the adjacent SfbI spacer domain to bind the 45 kDa fibronectin fragment. The biological consequence arising from this novel mode of fibronectin targeting was analysed in eukaryotic cell invasion assays. The repeat region of SfbI protein is mediating adherence and constitutes a prerequisite for subsequent invasion, whereas the SfbI spacer domain efficiently triggers the invasion process of streptococci into the eukaryotic cell. Thus, we were able to dissect bacterial adhesion from invasion by manipulating one protein. SfbI protein therefore represents a highly evolved prokaryotic molecule that exploits the host factor fibronectin not only for extracellular targeting but also for its subsequent activation that leads to efficient cellular invasion.

Antisense downregulation of sigma(32) as a transient metabolic controller in Escherichia coli: effects on yield of active organophosphorus hydrolase

Plasmids containing an antisense fragment of the sigma(32) gene were constructed and introduced into Escherichia coli cells. Downregulation of the sigma(32)-mediated stress response was evaluated under heat shock and ethanol stress and during the production of organophosphorus hydrolase (OPH). Northern blot analyses revealed that sigma(32) sense mRNA was virtually undetected in antisense-producing cultures from 5 to 20 min after antisense induction. However, lower-molecular-weight bands were found, presumably due to partial degradation of sigma(32) mRNA. While a >10-fold increase in sigma(32) protein level was found under ethanol stress in the control cultures, antisense producing cultures resulted in a <3-fold increase, indicating downregulation of sigma(32). Correspondingly, antisense synthesis resulted in a decreased level of a sigma(32) regulated chaperone (GroEL) for the first 2 h after induction relative to control cultures without sigma(32) antisense mRNA. The total yield of OPH in the presence of sigma(32) antisense was, on average, 62% of the yield without antisense. However, during sigma(32) antisense production, a sixfold-higher specific OPH activity was observed compared to non-antisense-producing cultures.

Differential degradation of Escherichia coli sigma32 and Bradyrhizobium japonicum RpoH factors by the FtsH protease

The Escherichia coli heat shock sigma factor sigma32 (RpoH) is rapidly degraded under non-stress conditions. The integrity of the DnaK chaperone machinery and the ATP-dependent FtsH protease are required for sigma32 proteolysis in vivo. Bradyrhizobium japonicum expresses three sigma32-type transcription factors, RpoH1, RpoH2, and RpoH3, which are functional in E. coli. We compared the stability of these sigma factors with E. coli sigma32 stability. In E. coli C600 (wild-type), the half-lives of sigma32, RpoH1, RpoH2 and RpoH3 were 30 s, 7 min, 4 min and 4 min, respectively. The first three proteins were stabilized in ftsH mutant backgrounds, indicating that they are degraded by FtsH in the wild-type. Proteolysis of RpoH3 was FtsH-independent because this sigma factor was not stabilized in ftsH mutants. Interestingly, in a purified in vitro system, all four RpoH proteins were degraded by FtsH, indicating that in vivo protein degradation depends on additional cellular factors. Rationally designed point mutations of sigma32 and RpoH1 suggested that the highly conserved RpoH box does not play a major role in conferring stability to RpoH factors. Presumably, several regions distributed along the primary sequence of the sigma factor are important for FtsH-mediated proteolysis. Finally, we provide evidence that proteolysis of RpoH factors in vivo depends on the DnaK machinery, irrespective of the protease involved.

The heat shock response of Escherichia coli

A large variety of stress conditions including physicochemical factors induce the synthesis of more than 20 heat shock proteins (HSPs). In E. coli, the heat shock response to temperature upshift from 30 to 42 degrees C consists of the rapid induction of these HSPs, followed by an adaptation period where the rate of HSP synthesis decreases to reach a new steady-state level. Major HSPs are molecular chaperones, including DnaK, DnaJ and GrpE, and GroEL and GroES, and proteases. They constitute the two major chaperone systems of E. coli (15-20% of total protein at 46 degrees C). They are important for cell survival, since they play a role in preventing aggregation and refolding proteins. The E. coli heat shock response is positively controlled at the transcriptional level by the product of the rpoH gene, the heat shock promoter-specific sigma32 subunit of RNA polymerase. Because of its rapid turn-over, the cellular concentration of sigma32 is very low under steady-state conditions (10-30 copies/cell at 30 degrees C) and is limiting for heat shock gene transcription. The heat shock response is induced as a consequence of a rapid increase in sigma32 levels and stimulation of sigma32 activity. The shut off of the response occurs as a consequence of declining sigma32 levels and inhibition of sigma32 activity. Stress-dependent changes in heat shock gene expression are mediated by the antagonistic action of sigma32 and negative modulators which act upon sigma32. These modulators are the DnaK chaperone system which inactivate sigma32 by direct association and mediate its degradation by proteases. Degradation of sigma32 is mediated mainly by FtsH (HflB), an ATP-dependent metallo-protease associated with the inner membrane. There is increasing evidence that the sequestration of the DnaK chaperone system through binding to misfolded proteins is a direct determinant of the modulation of the heat shock genes expression. A central open question is the identity of the binding sites within sigma32 for DnaK, DnaJ, FtsH and the RNA polymerase, and the functional interplay between these sites. We have studied the role of two distinct regions of sigma32 in its activity and stability control: region C and the C-terminal part. Both regions are involved in RNA polymerase binding.

Marked instability of the sigma(32) heat shock transcription factor at high temperature. Implications for heat shock regulation

The heat shock response in Escherichia coli depends on a transient increase in the intracellular level of sigma(32) that results from both increased synthesis and transient stabilization of normally unstable sigma(32). Although the membrane-bound ATP-dependent protease FtsH (HflB) plays an important role in degradation of sigma(32), our previous results suggested that several cytosolic ATP-dependent proteases including HslVU (ClpQY) are also involved in sigma(32) degradation (Kanemori, M., Nishihara, K., Yanagi, H., and Yura, T. (1997) J. Bacteriol. 179, 7219-7225). We now report on the ATP-dependent proteolysis of sigma(32) by purified HslVU protease and its unusual dependence on high temperature: sigma(32) was rapidly degraded at 44 degrees C, but with much slower rates ( approximately 15-fold) at 35 degrees C. FtsH-dependent degradation of sigma(32) also gave similar results. In agreement with these results in vitro, the turnover of sigma(32) in normally growing cells at high temperature (42 degrees C) was much faster than at low temperature (30 degrees C). Taken together with other evidence, these results suggest that the sigma(32) level during normal growth is primarily determined by the stability (susceptibility to proteases) and synthesis rate of sigma(32) set by ambient temperature, whereas fine adjustment such as transient stabilization of sigma(32) observed upon heat shock is brought about through monitoring changes in the cellular state of protein folding.

Role of region C in regulation of the heat shock gene-specific sigma factor of Escherichia coli, sigma32

Expression of heat shock genes is controlled in Escherichia coli by the antagonistic action of the sigma32 subunit of RNA polymerase and the DnaK chaperone system, which inactivates sigma32 by stress-dependent association and mediates sigma32 degradation by the FtsH protease. A stretch of 23 residues (R122 to Q144) conserved among sigma32 homologs, termed region C, was proposed to play a role in sigma32 degradation, and peptide analysis identified two potential DnaK binding sites central and peripheral to region C. Region C is thus a prime candidate for mediating stress control of sigma32, a hypothesis that we tested in the present study. A peptide comprising the central DnaK binding site was an excellent substrate for FtsH, while a peptide comprising the peripheral DnaK binding site was a poor substrate. Replacement of a single hydrophobic residue in each DnaK binding site by negatively charged residues (I123D and F137E) strongly decreased the binding of the peptides to DnaK and the degradation by FtsH. However, introduction of these and additional region C alterations into the sigma32 protein did not affect sigma32 degradation in vivo and in vitro or DnaK binding in vitro. These findings do not support a role for region C in sigma32 control by DnaK and FtsH. Instead, the sigma32 mutants had reduced affinities for RNA polymerase and decreased transcriptional activities in vitro and in vivo. Furthermore, cysteines inserted into region C allowed cysteine-specific cross-linking of sigma32 to RNA polymerase. Region C thus confers on sigma32 a competitive advantage over other sigma factors to bind RNA polymerase and thereby contributes to the rapidity of the heat shock response.

The anti-sigma factors

A mechanism for regulating gene expression at the level of transcription utilizes an antagonist of the sigma transcription factor known as the anti-sigma (anti-sigma) factor. The cytoplasmic class of anti-sigma factors has been well characterized. The class includes AsiA form bacteriophage T4, which inhibits Escherichia coli sigma 70; FlgM, present in both gram-positive and gram-negative bacteria, which inhibits the flagella sigma factor sigma 28; SpoIIAB, which inhibits the sporulation-specific sigma factor, sigma F and sigma G, of Bacillus subtilis; RbsW of B. subtilis, which inhibits stress response sigma factor sigma B; and DnaK, a general regulator of the heat shock response, which in bacteria inhibits the heat shock sigma factor sigma 32. In addition to this class of well-characterized cytoplasmic anti-sigma factors, a new class of homologous, inner-membrane-bound anti-sigma factors has recently been discovered in a variety of eubacteria. This new class of anti-sigma factors regulates the expression of so-called extracytoplasmic functions, and hence is known as the ECF subfamily of anti-sigma factors. The range of cell processes regulated by anti-sigma factors is highly varied and includes bacteriophage phage growth, sporulation, stress response, flagellar biosynthesis, pigment production, ion transport, and virulence.

On the mechanism of FtsH-dependent degradation of the sigma 32 transcriptional regulator of Escherichia coli and the role of the Dnak chaperone machine

The Escherichia coli sigma 32 transcriptional regulator has been shown to be degraded both in vivo and in vitro by the FtsH (HflB) protease, a member of the AAA protein family. In our attempts to study this process in detail, we found that two sigma 32 mutants lacking 15-20 C-terminal amino acids had substantially increased half-lives in vivo or in vitro, compared with wild-type sigma 32. A truncated version of sigma 32, sigma 32 C delta, was purified to homogeneity and shown to be resistant to FtsH-dependent degradation in vitro, suggesting that FtsH initiates sigma 32 degradation from its extreme C-terminal region. Purified sigma 32 C delta interacted with the DnaK and DnaJ chaperone proteins in a fashion similar to that of wild-type sigma 32. However, in contrast to wild-type sigma 32, sigma 32 C delta was largely deficient in its in vivo and in vitro interaction with core RNA polymerase. As a consequence, the truncated sigma 32 protein was completely non-functional in vivo, even when overproduced. Furthermore, it is shown that wild-type sigma 32 is protected from degradation by FtsH when complexed to the RNA polymerase core, but sensitive to proteolysis when in complex with the DnaK chaperone machine. Our results are in agreement with the proposal that the capacity of the DnaK chaperone machine to autoregulate its own synthesis negatively is simply the result of its ability to sequester sigma 32 from RNA polymerase, thus making it accessible to degradation by the FtsH protease.

Differential inhibition of transcription from sigma70- and sigma32-dependent promoters by rifampicin

Rifampicin is an antibiotic which binds to the beta subunit of prokaryotic RNA polymerases and prevents initiation of transcription. It was found previously that production of heat shock proteins in Escherichia coli cells after a shift from 30 degrees C to 43 degrees C is not completely inhibited by this antibiotic. Here we demonstrate that while activity of a pL-lacZ fusion (pL is a sigma70-dependent promoter) in E. coli cells is strongly inhibited by rifampicin, a p(groE)-lacZ fusion, whose activity is dependent on the sigam32 factor, retains significant residual activity even at relatively high rifampicin concentrations. Differential sensitivity to this antibiotic of RNA polymerase holoenzymes containing either the sigma70 or the sigma32 subunit was confirmed in vitro. Since the effects of an antibiotic that binds to the beta subunit can be modulated by the presence of either the sigma70 or the sigma32 subunit in the holoenzyme, it is tempting to speculate that binding of various sigma factors to the core of RNA polymerase results in different conformations of particular holoenzymes, including changes in the core enzyme.

Heat shock regulation in the ftsH null mutant of Escherichia coli: dissection of stability and activity control mechanisms of sigma32 in vivo

The heat shock response of Escherichia coli is regulated by the cellular level and the activity of sigma32, an alternative sigma factor for heat shock promoters. FtsH, a membrane-bound AAA-type metalloprotease, degrades sigma32 and has a central role in the control of the sigma32 level. The ftsH null mutant was isolated, and establishment of the DeltaftsH mutant allowed us to investigate control mechanisms of the stability and the activity of sigma32 separately in vivo. Loss of the FtsH function caused marked stabilization and consequent accumulation of sigma32 ( approximately 20-fold of the wild type), leading to the impaired downregulation of the level of sigma32. Surprisingly, however, DeltaftsH cells express heat shock proteins only two- to threefold higher than wild-type cells, and they also show almost normal heat shock response upon temperature upshift. These results indicate the presence of a control mechanism that downregulates the activity of sigma32 when it is accumulated. Overproduction of DnaK/J reduces the activity of sigma32 in DeltaftsH cells without any detectable changes in the level of sigma32, indicating that the DnaK chaperone system is responsible for the activity control of sigma32 in vivo. In addition, CbpA, an analogue of DnaJ, was demonstrated to have overlapping functions with DnaJ in both the activity and the stability control of sigma32.

ATP-dependent proteolysis in mitochondria. m-AAA protease and PIM1 protease exert overlapping substrate specificities and cooperate with the mtHsp70 system

To analyze protein degradation in mitochondria and the role of molecular chaperone proteins in this process, bovine apocytochrome P450scc was employed as a model protein. When imported into isolated yeast mitochondria, P450scc was mislocalized to the matrix and rapidly degraded. This proteolytic breakdown was mediated by the ATP-dependent PIM1 protease, a Lon-like protease in the mitochondrial matrix, in cooperation with the mtHsp70 system. In addition, a derivative of P450scc was studied to which a heterologous transmembrane region was fused at the amino terminus. This protein became anchored to the inner membrane upon import and was degraded by the membrane-embedded, ATP-dependent m-AAA protease. Again, degradation depended on the mtHsp70 system; it was inhibited at non-permissive temperature in mitochondria carrying temperature-sensitive mutant forms of Ssc1p, Mdj1p, or Mge1p. These results demonstrate overlapping substrate specificities of PIM1 and the m-AAA protease, and they assign a central role to the mtHsp70 system during the degradation of misfolded polypeptides by both proteases.

Structure-function analyses of the Ssc1p, Mdj1p, and Mge1p Saccharomyces cerevisiae mitochondrial proteins in Escherichia coli

The DnaK, DnaJ, and GrpE proteins of Escherichia coli have been universally conserved across the biological kingdoms and work together to constitute a highly efficient molecular chaperone machine. We have examined the extent of functional conservation of Saccharomyces cerevisiae Ssc1p, Mdj1p, and Mge1p by analyzing their ability to substitute for their corresponding E. coli homologs in vivo. We found that the expression of yeast Mge1p, the GrpE homolog, allowed for the deletion of the otherwise essential grpE gene of E. coli, albeit only up to 40 degrees C. The inability of Mge1p to substitute for GrpE at very high temperatures is consistent with our previous finding that it specifically failed to stimulate DnaK's ATPase at such extreme conditions. In contrast to Mge1p, overexpression of Mdj1p, the DnaJ homolog, was lethal in E. coli. This toxicity was specifically relieved by mutations which affected the putative zinc binding region of Mdj1p. Overexpression of a truncated version of Mdj1p, containing the J- and Gly/Phe-rich domains, partially substituted for DnaJ function at high temperature. A chimeric protein, consisting of the J domain of Mdj1p coupled to the rest of DnaJ, acted as a super-DnaJ protein, functioning even more efficiently than wild-type DnaJ. In contrast to the results with Mge1p and Mdj1p, both the expression and function of Ssc1p, the DnaK homolog, were severely compromised in E. coli. We were unable to demonstrate any functional complementation by Ssc1p, even when coexpressed with its Mdj1p cochaperone in E. coli.

In vivo effect of DNA relaxation on the transcription of gene rpoH in Escherichia coli

The in vivo effect of Novobiocin, a gyrase inhibitor, on the transcription of gene rpoH which codes for sigma32, the main positive regulator of the heat-shock response, was studied. Novobiocin induced a three-fold increase and a slight decrease in the activity of the rpoH promoters P1 and P4, respectively. The Novobiocin-induced increase in the activity of promoter P1 correlates with an increase in the amount of proteins sigma32 and DnaK. These results suggest that the increase in expression of the heat-shock proteins induced by gyrase inhibitors is probably due to the increased activity of P1 on relaxed DNA.

Interaction of Hsp70 chaperones with substrates

Determination of the structure of the substrate binding domain of the Escherichia coli Hsp70 chaperone, DnaK, and the biochemical characterisation of the motif it recognizes within substrates provide insights into the principles governing Hsp70 interaction with polypeptide chains. DnaK recognizes extended peptide strands composed of up to five consecutive hydrophobic residues within and positively charged residues outside the substrate binding cavity.

DnaK heat shock protein of Escherichia coli maintains the negative supercoiling of DNA against thermal stress

Plasmid DNA in exponentially growing Escherichia coli immediately relaxes after heat shock, and the relaxed state of DNA rapidly reverts to the original state with exposure to conditions of heat shock. We have now obtained genetic and biochemical evidence indicating that DnaK heat shock protein of E. coli, a prokaryotic homologue of hsp70, is involved in this re-supercoiling of DNA. As re-supercoiling of DNA did not occur in an rpoH amber mutant, it seems likely that heat shock proteins are required for this reaction. Plasmid DNA in a dnaK deletion mutant relaxed excessively after temperature shift-up, and the re-supercoiling of DNA was not observed. DNAs incubated with a crude cell extract prepared from the dnaK mutant were more relaxed than seen with the extract from its isogenic wild-type strain, and the addition of purified DnaK protein to the mutant extract led to an increase in the negative supercoiling of DNA. Moreover, reaction products of purified DNA gyrase more negatively supercoiled in the presence of DnaK protein. Based on these results, we propose that DnaK protein plays a role in maintaining the negative supercoiling of DNA against thermal stress.

Transcription of the mutL repair, miaA tRNA modification, hfq pleiotropic regulator, and hflA region protease genes of Escherichia coli K-12 from clustered Esigma32-specific promoters during heat shock

The amiB-mutL-miaA-hfq-hflX-hflK-hflC superoperon of Escherichia coli contains genes that are important for diverse cellular functions, including DNA mismatch repair (mutL), tRNA modification (miaA), pleiotropic regulation (hfq), and proteolysis (hflX-hflK-hflC). We show that this superoperon contains three E simga(32)-dependent heat shock promoters, P(mutL)HS,P(miaA)HS, and P1(hfq)HS, in addition to four E sigma(70)-dependent promoters, P(mutL), P(miaA), P2(hfq), and P3(hfq). Transcripts from P(mutL)HS and P(miaA)HS were most prominent in vivo during extreme heat shock (50 degrees C), whereas P1(hfq)HS transcripts were detectable under nonshock conditions and increased significantly after heat shock at 50 degrees C. The P(mutL)HS, P(miaA)HS, and P1(hfq)HS transcripts were not detected in an rpoH null mutant. All three promoters were transcribed by E sigma (32) in vitro at 37 degrees C and contain -35 and -10 regions that resemble the E sigma(32) consensus. In experiments to assess the possible physiological relevance of the P(mutL)HS and P(miaA)HS promoters, we found that E. coli prototrophic strain MG 1655 increased in cell mass and remained nearly 100% viable for several hours at 50 degrees C in enriched media. In these cells, a significant fraction of mutL and hfq-hflA region transcripts were from P(mutL)HS and P1(hfq)HS, respectively, and the amounts of the miaA, hfq, hflX, hflK, and hflC transcripts increased in comparison with those in nonstressed cells. The cellular amounts of MutL and the hfq gene product (HF-I protein) were maintained during heat shock at 44 or 50 degrees C. Consistent with their expression patterns, miaA and hfq were essential for growth and viability, respectively, at temperatures of 45 degrees C and above. Together, these results suggest that there is a class of E sigma(32) promoters that functions mainly at high temperatures to ensure E. coli function and survival.

The rpoD gene functions as a multicopy suppressor for mutations in the chaperones, CbpA, DnaJ and DnaK, in Escherichia coli

The CbpA protein is an analog of the DnaJ molecular chaperone of Escherichia coli. The dnaJ- cbpA- double-null mutant exhibits severe defects in cell growth, namely, a very narrow temperature range for growth. To gain insight into the functions of CbpA as well as DnaJ, we isolated a multicopy suppressor gene that permits this dnaJ- cbpA- mutant to grow normally at low temperatures. The suppressor gene was identified as rpoD, the gene that encodes the major sigma 70. The biological implications of this finding are examined and discussed.

Real time kinetics of the DnaK/DnaJ/GrpE molecular chaperone machine action

Applying stopped-flow fluorescence spectroscopy for measuring conformational changes of the DnaK molecular chaperone (bacterial Hsp70 homologue) and its binding to target peptide, we found that after ATP hydrolysis, DnaK is converted to the DnaK*(ADP) conformation, which possesses limited affinity for peptide substrates and the GrpE cochaperone but efficiently binds the DnaJ chaperone. In the presence of DnaJ (bacterial Hsp40 homologue), the DnaK*(ADP) form is converted back to the DnaK conformation, and the resulting DnaJ-DnaK(ADP) complex binds to peptide substrates more tightly. Formation of the DnaJ(substrate-DnaK(ADP)) complex is a rate-limiting reaction. The presence of GrpE and ATP hydrolysis promotes the fast release of the peptide substrate from the chaperone complex and converts DnaK to the DnaK*(ADP) conformation. We conclude that in the presence of DnaJ and GrpE, the binding-release cycle of DnaK is stoichiometrically coupled to the adenosine triphosphatase activity of DnaK.