The essential Escherichia coli msgB gene, a multicopy suppressor of a temperature-sensitive allele of the heat shock gene grpE, is identical to dapE

The grpE gene product is one of three Escherichia coli heat shock proteins (DnaK, DnaJ, and GrpE) that are essential for both bacteriophage lambda DNA replication and bacterial growth at all temperatures. In an effort to determine the role of GrpE and to identify other factors that it may interact with, we isolated multicopy suppressors of the grpE280 point mutation, as judged by their ability to reverse the temperature-sensitive phenotype of grpE280. Here we report the characterization of one of them, designated msgB. The msgB gene maps at approximately 53 min on the E. coli chromosome. The minimal gene possesses an open reading frame that encodes a protein with a predicted size of 41,269 M(r). This open reading frame was confirmed the correct one by direct amino-terminal sequence analysis of the overproduced msgB gene product. Genetic experiments demonstrated that msgB is essential for E. coli growth in the temperature range of 22 to 37 degrees C. Through a sequence homology search, MsgB was shown to be identical to N-succinyl-L-diaminopimelic acid desuccinylase (the dapE gene product), which participates in the diaminopimelic acid-lysine pathway involved in cell wall biosynthesis. Consistent with this finding, the msgB null allele mutant is viable only when the growth medium is supplemented with diaminopimelic acid. These results suggest that GrpE may have a previously unsuspected function(s) in cell wall biosynthesis in E. coli.

The DnaK chaperone modulates the heat shock response of Escherichia coli by binding to the sigma 32 transcription factor

The heat shock response and the heat shock proteins have been conserved across evolution. In Escherichia coli, the heat shock response is positively regulated by the sigma 32 transcriptional factor and negatively regulated by a subset of the heat shock proteins themselves. In an effort to understand the regulation of the heat shock response, we have purified the sigma 32 polypeptide to homogeneity. During the purification procedure, we found that a large fraction of the overexpressed sigma 32 polypeptide copurified with the universally conserved DnaK heat shock protein (the prokaryotic equivalent of the 70-kDa heat shock protein, HSP70). Further experiments established that purified sigma 32 bound to DnaK and that this complex was disrupted in the presence of ATP. Consistent with the fact that dnaK756 mutant bacteria overexpress heat shock proteins at all temperatures, purified DnaK756 mutant protein did not appreciably bind to sigma 32.

Isolation and characterization of the Escherichia coli htrD gene, whose product is required for growth at high temperatures

Those genes in Escherichia coli defined by mutations which result in an inability to grow at high temperatures are designated htr, indicating a high temperature requirement. A new htr mutant of E. coli was isolated and characterized and is designated htrD. The htrD gene has been mapped to 19.3 min on the E. coli chromosome. Insertional inactivation of htrD with a mini-Tn10 element resulted in a pleiotropic phenotype characterized by a severe inhibition of growth at 42 degrees C and decreased survival at 50 degrees C in rich media. Furthermore, htrD cells were sensitive to H2O2. Growth rate analysis revealed that htrD cells grow very slowly in minimal media supplemented with amino acids. This inhibitory effect has been traced to the presence of cysteine in the growth medium. Further studies indicated that the rate of cysteine transport is higher in htrD cells relative to the wild type. All of these results, taken together, indicate that the htrD gene product may be required for proper regulation of intracellular cysteine levels and that an increased rate of cysteine transport greatly affects the growth characteristics of E. coli.

Isolation and characterization of the Escherichia coli msbB gene, a multicopy suppressor of null mutations in the high-temperature requirement gene htrB

Previous work established that the htrB gene of Escherichia coli is required for growth in rich media at temperatures above 32.5 degrees C but not at lower temperatures. In an effort to determine the functional role of the htrB gene product, we have isolated a multicopy suppressor of htrB, called msbB. The msbB gene has been mapped to 40.5 min on the E. coli genetic map, in a 12- to 15-kb gap of the genomic library made by Kohara et al. (Y. Kohara, K. Akiyama, and K. Isono, Cell 50:495-508, 1987). Mapping data show that the order of genes in the region is eda-edd-zwf-pykA-msbB. The msbB gene codes for a protein of 37,410 Da whose amino acid sequence is similar to that of HtrB and, like HtrB, the protein is very basic in nature. The similarity of the HtrB and MsbB proteins could indicate that they play functionally similar roles. Mutational analysis of msbB shows that the gene is not essential for E. coli growth; however, the htrB msbB double mutant exhibits a unique morphological phenotype at 30 degrees C not seen with either of the single mutants. Analysis of both msbB and htrB mutants shows that these bacteria are resistant to four times more deoxycholate than wild-type bacteria but not to other hydrophobic substances. The addition of quaternary ammonium compounds rescues the temperature-sensitive phenotype of htrB bacteria, and this rescue is abolished by the simultaneous addition of Mg2+ or Ca2+. These results suggest that MsbB and HtrB play an important role in outer membrane structure and/or function.

The purification and properties of the scaffolding protein of bacteriophage lambda

The Nu3 gene of bacteriophage lambda resides within a cluster of genes that specify structural components of the bacteriophage head. Previous experiments indicate that the Nu3 gene product (gpNu3) is associated with immature proheads but is not detectable in mature proheads or bacteriophage particles, hence its classification as a scaffolding protein. The Nu3 gene has been cloned and overexpressed, and its protein product has been purified. The purified protein is biologically active, as demonstrated by its ability to complement a gpNu3-deficient extract in an in vitro assembly reaction. The sequence of the amino terminus of the protein indicates that translation of Nu3 starts at nucleotide position 5,342 on the standard lambda DNA sequence, yielding a protein with a calculated Mr of 13,396. A combination of gel exclusion chromatography and velocity sedimentation gradient data indicates that gpNu3 possesses an unusually elongated shape.

The Escherichia coli htrP gene product is essential for bacterial growth at high temperatures: mapping, cloning, sequencing, and transcriptional regulation of htrP

We identified and characterized a new Escherichia coli gene, htrP. The htrP gene was identified because its insertional inactivation by the Tn10 transposon results in the inability of E. coli to form colonies at temperatures above 37 degrees C and a slow growth phenotype at 30 degrees C. The htrP gene was cloned and mapped to 66.3 min on the E. coli genetic map, 4 kbp clockwise from the tolC gene. The htrP gene was sequenced and shown to code for an acidic, 27,471-Da polypeptide and to be transcribed counterclockwise with respect to the genetic map. The predicted HtrP protein has two potential transmembrane segments and shares an identity of 64.4% over a length of 210 amino acids with the LuxH protein. Despite the fact that the htrP gene is essential for E. coli growth exclusively at high temperatures, the levels of htrP-specific transcripts decrease with increasing temperature.

Sequencing, mutational analysis, and transcriptional regulation of the Escherichia coli htrB gene

The Escherichia coli htrB gene was originally discovered because its insertional inactivation led to an exquisitely temperature-sensitive phenotype in rich media, i.e. the ability to form colonies at temperatures below 32 degrees C, but not above 33 degrees C. The htrB gene has been sequenced. It can potentially code for two proteins, with Mr values of 35,407 Da and 8669 Da, that are encoded by overlapping, divergent open reading frames. Our data are consistent with the 35,407 Da protein being HtrB. Northern blot analysis clearly shows that the monocistronic htrB message is not under heat-shock regulation. We have also sequenced the flanking DNA and have discovered a new gene, designated orf39.9, located immediately adjacent to htrB, but divergently transcribed.

Identification of the Escherichia coli sohB gene, a multicopy suppressor of the HtrA (DegP) null phenotype

We cloned and sequenced the sohB gene of Escherichia coli. The temperature-sensitive phenotype of bacteria that carry a Tn10 insertion in the htrA (degP) gene is relieved when the sohB gene is present in the cell on a multicopy plasmid (30 to 50 copies per cell). The htrA gene encodes a periplasmic protease required for bacterial viability only at high temperature, i.e., above 39 degrees C. The sohB gene maps to 28 min on the E. coli chromosome, precisely between the topA and btuR genes. The gene encodes a 39,000-Mr precursor protein which is processed to a 37,000-Mr mature form. Sequencing of a DNA fragment containing the gene revealed an open reading frame which could encode a protein of Mr 39,474 with a predicted signal sequence cleavage site between amino acids 22 and 23. Cleavage at this site would reduce the size of the processed protein to 37,474 Mr. The predicted protein encoded by the open reading frame has homology with the inner membrane enzyme protease IV of E. coli, which digests cleaved signal peptides. Therefore, it is possible that the sohB gene encodes a previously undiscovered periplasmic protease in E. coli that, when overexpressed, can partially compensate for the missing HtrA protein function.

The Escherichia coli DnaK chaperone, the 70-kDa heat shock protein eukaryotic equivalent, changes conformation upon ATP hydrolysis, thus triggering its dissociation from a bound target protein

The DnaK protein of Escherichia coli and its eukaryotic hsp70 analogues are known to bind some polypeptides and to release or dissociate from them following ATP hydrolysis. Here we demonstrate that hydrolysis (and not simply binding) of nucleotide triphosphates leads to a change in the DnaK protein, from the "closed" to the "open" conformation. A conformational change is not observed with the mutant DnaK756 protein, which is always found in the open conformation. Although ATP is the preferred substrate, the hydrolysis of CTP, GTP, UTP, and dATP also results in DnaK's conversion from a closed to an open conformation. The ability of DnaK to hydrolyze various triphosphates correlates perfectly with its ability to release the bound denatured bovine pancreatic trypsin inhibitor polypeptide.

The htrM gene, whose product is essential for Escherichia coli viability only at elevated temperatures, is identical to the rfaD gene

We have identified a new E. coli gene, htrM. The htrM gene was identified because its insertional inactivation by the Tn5 transposon results in E. coli's inability to form colonies at temperatures above 43 degrees C. The corresponding htrM+ gene was cloned on the basis of its ability to correct the temperature-sensitive phenotype of the htrM::Tn5 insertion mutations. The htrM gene has been mapped to 81.2 min on the conventional E. coli genetic map. It was sequenced and shown to code for an acidic, 34,893-Da polypeptide. Three transcriptional starts were located 48, 90 and 123 nucleotides upstream of the ATG, initiation codon referred to as the P1, P2 and P3(hs) promoters, respectively. The -10 and -35 regions of the P1 promoter bear a close similarity to the E sigma 70-recognized consensus sequences, while the -12 region of the P2 promoter resembles the consensus promoter sequence transcribed by the rpoN gene product. Transcripts of the htrM gene accumulate with increasing temperature. The -10 and -35 regions of the P3(hs) promoter, represented by nucleotides 160 to 130 upstream of the ATG initation codon, are similar to the E sigma 32-recognized consensus sequences. The sigma 32 transcription factor is essential for maximal htrM gene transcription, since htrM RNA transcripts are made at reduced rates in a rpoH null mutant background. Surprisingly, the htrM gene turns out to be identical to rfaD, whose product is required for the biosynthesis of the ADP-L-glycero-D manoheptose lipopolyaccharide precursor [Pegues et al. (1990) J. Bacteriol. 172, 4652-4660].

Escherichia coli DnaJ and GrpE heat shock proteins jointly stimulate ATPase activity of DnaK

The products of the Escherichia coli dnaK, dnaJ, and grpE heat shock genes have been previously shown to be essential for bacteriophage lambda DNA replication at all temperatures and for bacterial survival under certain conditions. DnaK, the bacterial heat shock protein hsp70 analogue and putative chaperonin, possesses a weak ATPase activity. Previous work has shown that ATP hydrolysis allows the release of various polypeptides complexed with DnaK. Here we demonstrate that the ATPase activity of DnaK can be greatly stimulated, up to 50-fold, in the simultaneous presence of the DnaJ and GrpE heat shock proteins. The presence of either DnaJ or GrpE alone results in a slight stimulation of the ATPase activity of DnaK. The action of the DnaJ and GrpE proteins may be sequential, since the presence of DnaJ alone leads to an acceleration in the rate of hydrolysis of the DnaK-bound ATP. The presence of GrpE alone increases the rate of release of bound ATP or ADP without affecting the rate of hydrolysis. The stimulation of the ATPase activity of DnaK may contribute to its more efficient recycling, and it helps explain why mutations in dnaK, dnaJ, or grpE genes often exhibit similar pleiotropic phenotypes.

Analysis of an Escherichia coli dnaB temperature-sensitive insertion mutation and its cold-sensitive extragenic suppressor

An Escherichia coli mutant, ts121, was isolated following random insertional mutagenesis using phage lambda Mu transposition. The mutant phenotype includes inability to form colonies at temperatures above 38 degrees C and inability to propagate phage lambda at all temperatures. A lambda i434 cI- (ts121)+ transducing phage was isolated on the basis of its ability to form plaques on ts121 mutant bacteria. Using this transducing phage, it was shown through complementation and protein analyses, that the ts121 mutation is located in the dnaB gene. The exact insertion event was identified by polymerase chain reaction amplification of the DNA sequences containing the insertion junction. The mutational insertion event in ts121 was mapped precisely between base pairs 1514 and 1515 of the dnaB gene. This result predicts that the mutant dnaB protein has lost its six terminal amino acids. The reading frame shifts into Mu-specific DNA sequences resulting in an additional 20 amino acid residues. The E. coli wild type dnaB protein participates in host replication and interacts with lambda P protein to initiate phage lambda DNA replication. Our results demonstrate that the extreme carboxyl end of the dnaB protein is required for productive interaction with the lambda P replication protein at all temperatures, and is important for dnaB function at temperatures above 38 degrees C. Cold-sensitive extragenic suppressors of the ts121 mutation were isolated on the basis of their ability to restore colony formation at 42 degrees C. One of these extragenic suppressors was mapped at 54 min on the E. coli genetic map and localized to the suhB gene, whose product may affect the expression of a number of genes at the translational level.

Complex phenotypes of null mutations in the htr genes, whose products are essential for Escherichia coli growth at elevated temperatures

Transposon insertion, followed by screening, has allowed the identification of a set of genes, called htr, whose products are required for Escherichia coli growth at elevated temperatures. The htrB gene has been shown to map at 23.5 min on the E. coli genetic map. It codes for a very basic, hydrophobic, 35,000-Mr polypeptide, possessing a putative membrane-spanning domain. At the non-permissive temperature, htrB mutant bacteria stop dividing, followed by the formation of bulges and eventual lysis. The htrC gene maps at 90 min, is under sigma 32 regulation and codes for a 21, 130-Mr polypeptide. At 43 degrees C, htrC mutant bacteria gradually lyse, whereas at intermediate temperatures they filament extensively. Finally, the htrM gene maps at 81 min, is under sigma 32 regulation and codes for a 35,000-Mr polypeptide. The HtrM null phenotype included inability to grow above 42 degrees C, extreme mucoidness and sensitivity to bile salts, even at the permissive temperatures. The htrM gene is identical to the rfaD gene, whose product is required for the biosynthesis of the lipopolysaccharide precursor ADP-L-glycero-D-mannoheptose (Pegues et al., J. Bact., 1990, 172, 4652-4660).

Isolation and characterization of the Escherichia coli htrB gene, whose product is essential for bacterial viability above 33 degrees C in rich media

We have identified and studied the htrB gene of Escherichia coli. Insertional inactivation of the htrB gene leads to bacterial death at temperatures above 33 degrees C. The mutant bacterial phenotype at nonpermissive temperatures includes an arrest of cell division followed by the formation of bulges or filaments. The htrB+ gene has been cloned by complementation and shown to reside at 23.4 min on the E. coli genetic map, the relative order of the neighboring loci being mboA-htrB-pyrC. The htrB gene is transcribed in a counterclockwise fashion, relative to the E. coli genetic map, and its product has been identified as a membrane-associated protein of 35,000 Da. Growth experiments in minimal media indicate that the HtrB function becomes dispensable at low growth rates.

Role of Escherichia coli heat shock proteins DnaK and HtpG (C62.5) in response to nutritional deprivation

Because of the highly conserved pattern of expression of the eucaryotic heat shock genes hsp70 and hsp84 or their cognates during sporulation in Saccharomyces cerevisiae and development in higher organisms, the role of the Escherichia coli homologs dnaK and htpG was examined during the response to starvation. The htpG deletion mutant was found to be similar to its wild-type parent in its ability to survive starvation for essential nutrients and to induce proteins specific to starvation conditions. The dnaK103 mutant, however, was highly susceptible to killing by starvation for carbon and, to a lesser extent, for nitrogen and phosphate. Analysis of proteins induced under starvation conditions on two-dimensional gels showed that the dnaK103 mutant was defective for the synthesis of some proteins induced in wild-type cells by carbon starvation and of some proteins induced under all starvation conditions, including the stationary phase in wild-type cells. In addition, unique proteins were synthesized in the dnaK103 mutant in response to starvation. Although the synthesis of some proteins under glucose starvation control was drastically affected by the dnaK103 mutation, the synthesis of proteins specifically induced by nitrogen starvation was essentially unaffected. Similarly, the dnaK103 mutant was able to grow, utilizing glutamine or arginine as a source of nitrogen, at a rate approximate to that of the wild-type parent, but it inefficiently utilized glycerol or maltose as carbon sources. Several differences between the protein synthetic pattern of the dnaK103 mutant and the wild type were observed after phosphate starvation, but these did not result in a decreased ability to survive phosphate starvation, compared with nitrogen starvation.

The E. coli dnaK gene product, the hsp70 homolog, can reactivate heat-inactivated RNA polymerase in an ATP hydrolysis-dependent manner

Pelham previously proposed that the hsp70 family of heat shock proteins could prevent the formation and/or allow the dissolution of protein aggregates created during stress conditions. We confirmed this hypothesis by showing that the E. coli hsp70 homolog, the dnaK gene product, protects the host RNA polymerase enzyme from heat inactivation in an ATP-independent reaction. In addition, we show that heat-inactivated and aggregated RNA polymerase is both disaggregated and reactivated following simultaneous incubation with DnaK protein and hydrolyzable ATP. The DnaK756 mutant protein has lost the ability to disaggregate the inactivated RNA polymerase enzyme. Our results demonstrate that the DnaK protein contributes to E. coli's growth not only by protecting some enzymes from denaturation but also by reactivating some once they are misfolded or aggregated.

Isolation and characterization of dnaJ null mutants of Escherichia coli

Bacteriophage lambda requires the lambda O and P proteins for its DNA replication. The rest of the replication proteins are provided by the Escherichia coli host. Some of these host proteins, such as DnaK, DnaJ, and GrpE, are heat shock proteins. Certain mutations in the dnaK, dnaJ, or grpE gene block lambda growth at all temperatures and E. coli growth above 43 degrees C. We have isolated bacterial mutants that were shown by Southern analysis to contain a defective, mini-Tn10 transposon inserted into either of two locations and in both orientations within the dnaJ gene. We have shown that these dnaJ-insertion mutants did not grow as well as the wild type at temperatures above 30 degrees C, although they blocked lambda DNA replication at all temperatures. The dnaJ-insertion mutants formed progressively smaller colonies at higher temperatures, up to 42 degrees C, and did not form colonies at 43 degrees C. The accumulation of frequent, uncharacterized suppressor mutations allowed these insertion mutants to grow better at all temperatures and to form colonies at 43 degrees C. None of these suppressor mutations restored the ability of the host to propagate phage lambda. Radioactive labeling of proteins synthesized in vivo followed by immunoprecipitation or immunoblotting with anti-DnaJ antibodies demonstrated that no DnaJ protein could be detected in these mutants. Labeling studies at different temperatures demonstrated that these dnaJ-insertion mutations resulted in altered kinetics of heat shock protein synthesis. An additional eight dnaJ mutant isolates, selected spontaneously on the basis of blocking phage lambda growth at 42 degrees C, were shown not to synthesize DnaJ protein as well. Three of these eight spontaneous mutants had gross DNA alterations in the dnaJ gene. Our data provide evidence that the DnaJ protein is not absolutely essential for E. coli growth at temperatures up to 42 degrees C under standard laboratory conditions but is essential for growth at 43 degrees C. However, the accumulation of extragenic suppressors is necessary for rapid bacterial growth at higher temperatures.

The Escherichia coli heat shock proteins GroEL and GroES modulate the folding of the beta-lactamase precursor

One of the fundamental problems in biochemistry is the role of accessory proteins in the process of protein folding. The Escherichia coli heat shock protein complex GroEL/ES has been suggested to be a 'chaperonin' and be involved in both oligomer assembly as well as protein transport through the membrane. We show here that the folding of the purified precursor of beta-lactamase is inhibited by purified GroEL or the GroEL/ES complex with a stoichiometry of one particle per molecule of pre-beta-lactamase. Purified GroES alone has no effect on folding. After Mg2+ ATP addition folding resumes and the yield of active enzyme is higher than in the absence of GroEL or GroEL/ES. Unexpectedly, GroEL or GroEL/ES, when added to folded pre-beta-lactamase, lead to an apparent net 'unfolding', probably to a collapsed state of the protein, which can be reversed by the addition of Mg2+ ATP. The reversible and Mg2+ ATP-dependent association of GroEL/ES with non-native proteins might explain its postulated role in both protein transport and oligomer assembly.

A new Escherichia coli heat shock gene, htrC, whose product is essential for viability only at high temperatures

We identified and characterized a new Escherichia coli gene, htrC. Inactivation of the htrC gene results in the inability to form colonies at 42 degrees C. An identical bacterial phenotype is found whether the htrC gene is inactivated either by Tn5 insertions or by a deletion spanning the entire gene. The htrC gene has been localized at 90 min, immediately downstream of the rpoC gene, and has been previously sequenced. It codes for a basic polypeptide with an Mr of 21,130. The htrC gene is under heat shock regulation, since it is transcribed actively only in bacteria possessing functional sigma 32. Inactivation of htrC results in (i) bacterial filamentation at intermediate temperatures, (ii) cell lysis at temperatures above 42 degrees C, (iii) overproduction of sigma 32-dependent heat shock proteins at all temperatures, (iv) overproduction of a few additional polypeptides, (v) underproduction of many polypeptides, and (vi) an overall defect in cellular proteolysis as judged by the reduced rate of puromycyl polypeptide degradation. In addition, the presence of an htrC mutation eliminates the UV sensitivity normally exhibited by lon mutant bacteria.