The dnaK gene of Escherichia coli functions in initiation of chromosome replication

Energy Starvation Induces a Cell Cycle Arrest in Escherichia coli by Triggering Degradation of the DnaA Initiator Protein

During steady-state Escherichia coli growth, the amount and activity of the initiator protein, DnaA, controls chromosome replication tightly so that initiation only takes place once per origin in each cell cycle, regardless of growth conditions. However, little is known about the mechanisms involved during transitions from one environmental condition to another or during starvation stress. ATP depletion is one of the consequences of long-term carbon starvation. Here we show that DnaA is degraded in ATP-depleted cells. A chromosome replication initiation block is apparent in such cells as no new rounds of DNA replication are initiated while replication events that have already started proceed to completion.

The Nuclear and DNA-Associated Molecular Chaperone Network

Maintenance of a healthy and functional proteome in all cellular compartments is critical to cell and organismal homeostasis. Yet, our understanding of the proteostasis process within the nucleus is limited. Here, we discuss the identified roles of the major molecular chaperones Hsp90, Hsp70, and Hsp60 with client proteins working in diverse DNA-associated pathways. The unique challenges facing proteins in the nucleus are considered as well as the conserved features of the molecular chaperone system in facilitating DNA-linked processes. As nuclear protein inclusions are a common feature of protein-aggregation diseases (e.g., neurodegeneration), a better understanding of nuclear proteostasis is warranted.

X-ray crystal structure of Escherichia coli HspQ, a protein involved in the retardation of replication initiation

The heat shock protein HspQ (YccV) of Escherichia coli has been proposed to participate in the retardation of replication initiation in cells with the dnaA508 allele. In this study, we have determined the 2.5-Å-resolution X-ray structure of the trimer of HspQ, which is also the first structure of a member of the YccV superfamily. The acidic character of the HspQ trimer suggests an interaction surface with basic proteins. From these results, we discuss the cellular function of HspQ, including its relationship with the DnaA508 protein.

Bacterial growth rates are influenced by cellular characteristics of individual species when immersed in electromagnetic fields

Previous studies have shown that exposure to extremely low-frequency electromagnetic fields (ELF-EMFs) have negative effects on the rate of growth of bacteria. In the present study, two Gram-positive and two Gram-negative species were exposed to six magnetic field conditions in broth cultures. Three variations of the 'Thomas' pulsed frequency-modulated pattern; a strong-static "puck" magnet upwards of 5000G in intensity; a pair of these magnets rotating opposite one another at ∼30rpm; and finally a strong dynamic magnetic field generator termed the 'Resonator' with an average intensity of 250μT were used. Growth rate was discerned by optical density (OD) measurements every hour at 600nm. ELF-EMF conditions significantly affected the rates of growth of the bacterial cultures, while the two static magnetic field conditions were not statistically significant. Most interestingly, the 'Resonator' dynamic magnetic field increased the rates of growth of three species (Staphylococcus epidermidis, Staphylococcus aureus, and Escherichia coli), while slowing the growth of one (Serratia marcescens). We suggest that these effects are due to individual biophysical characteristics of the bacterial species.

Mitochondrial heat shock protein machinery hsp70/hsp40 is indispensable for proper mitochondrial DNA maintenance and replication

Mitochondrial chaperones have multiple functions that are essential for proper functioning of mitochondria. In the human-pathogenic protist Trypanosoma brucei, we demonstrate a novel function of the highly conserved machinery composed of mitochondrial heat shock proteins 70 and 40 (mtHsp70/mtHsp40) and the ATP exchange factor Mge1. The mitochondrial DNA of T. brucei, also known as kinetoplast DNA (kDNA), is represented by a single catenated network composed of thousands of minicircles and dozens of maxicircles packed into an electron-dense kDNA disk. The chaperones mtHsp70 and mtHsp40 and their cofactor Mge1 are uniformly distributed throughout the single mitochondrial network and are all essential for the parasite. Following RNA interference (RNAi)-mediated depletion of each of these proteins, the kDNA network shrinks and eventually disappears. Ultrastructural analysis of cells depleted for mtHsp70 or mtHsp40 revealed that the otherwise compact kDNA network becomes severely compromised, a consequence of decreased maxicircle and minicircle copy numbers. Moreover, we show that the replication of minicircles is impaired, although the lack of these proteins has a bigger impact on the less abundant maxicircles. We provide additional evidence that these chaperones are indispensable for the maintenance and replication of kDNA, in addition to their already known functions in Fe-S cluster synthesis and protein import.

Impairment or loss of mitochondrial DNA is associated with mitochondrial dysfunction and a wide range of neural, muscular, and other diseases. We present the first evidence showing that the entire mtHsp70/mtHsp40 machinery plays an important role in mitochondrial DNA replication and maintenance, a function likely retained from prokaryotes. These abundant, ubiquitous, and multifunctional chaperones share phenotypes with enzymes engaged in the initial stages of replication of the mitochondrial DNA in T. brucei.

Mitochondrial heat shock protein machinery hsp70/hsp40 is indispensable for proper mitochondrial DNA maintenance and replication

Mitochondrial chaperones have multiple functions that are essential for proper functioning of mitochondria. In the human-pathogenic protist Trypanosoma brucei, we demonstrate a novel function of the highly conserved machinery composed of mitochondrial heat shock proteins 70 and 40 (mtHsp70/mtHsp40) and the ATP exchange factor Mge1. The mitochondrial DNA of T. brucei, also known as kinetoplast DNA (kDNA), is represented by a single catenated network composed of thousands of minicircles and dozens of maxicircles packed into an electron-dense kDNA disk. The chaperones mtHsp70 and mtHsp40 and their cofactor Mge1 are uniformly distributed throughout the single mitochondrial network and are all essential for the parasite. Following RNA interference (RNAi)-mediated depletion of each of these proteins, the kDNA network shrinks and eventually disappears. Ultrastructural analysis of cells depleted for mtHsp70 or mtHsp40 revealed that the otherwise compact kDNA network becomes severely compromised, a consequence of decreased maxicircle and minicircle copy numbers. Moreover, we show that the replication of minicircles is impaired, although the lack of these proteins has a bigger impact on the less abundant maxicircles. We provide additional evidence that these chaperones are indispensable for the maintenance and replication of kDNA, in addition to their already known functions in Fe-S cluster synthesis and protein import.

IMPORTANCE

Impairment or loss of mitochondrial DNA is associated with mitochondrial dysfunction and a wide range of neural, muscular, and other diseases. We present the first evidence showing that the entire mtHsp70/mtHsp40 machinery plays an important role in mitochondrial DNA replication and maintenance, a function likely retained from prokaryotes. These abundant, ubiquitous, and multifunctional chaperones share phenotypes with enzymes engaged in the initial stages of replication of the mitochondrial DNA in T. brucei.

Oleanolic and ursolic acids influence affect the expression of the cysteine regulon and the stress response in Escherichia coli

The pentacyclic triterpenoids, oleanolic, and ursolic acids, affect peptidoglycan metabolism, altering bacterial morphology, and inhibit the growth and survival of several bacterial species, including pathogenic ones. We investigated the effect of subinhibitory concentrations of these compounds on the expression of three operons from the E. coli cysteine regulon, cysPTWA, cysJIH, and cysB, by using transcriptional fusions with the lacZ reporter gene. An inhibitory effect on β-galactosidase expression directed by all three chromosomal fusions was observed with both compounds. In addition, oleanolic acid, but not ursolic acid, caused a weak increase in DnaK synthesis, suggesting moderate ability of inducing heat-shock response.

Effects of temperature stress on bean-nodulating Rhizobium strains

High soil temperatures in tropical areas limit nodulation and dinitrogen fixation by strains of Rhizobium. Several heat-tolerant bean-nodulating Rhizobium strains have been isolated previously. However, the basis of their resistance to heat remains unknown. In this study, we compared the effects of heat on symbiotic nitrogen fixation, cell survival, amino acid uptake, and protein synthesis in a heat-tolerant (CIAT899) and a heat-sensitive (CNPAF512) bean-nodulating Rhizobium strain. Acetylene reduction activity of nodulated roots excised from unstressed plants was strongly diminished at 35 or 40 degrees C when plants were nodulated either by CIAT899 or by CNPAF512. When these strains were tested under free-living conditions, survival at 40 degrees C as well as the kinetics of l-[S]methionine uptake and protein synthesis at 35 and 40 degrees C indicated the higher tolerance of CIAT899 than of CNPAF512 to thermal stress. The synthesis of heat shock proteins was detected in both strains, although at different temperatures. Increased synthesis of 14 heat shock proteins in CNPAF512 and of 6 heat shock proteins in CIAT899 was observed at 40 and 45 degrees C, respectively. A heat shock protein of approximately 21 kDa, of which the synthesis was strongest in both Rhizobium strains upon a temperature shift up, was also conserved in several other bean-nodulating rhizobia. Acquired thermotolerance in CIAT899 was shown to depend on protein synthesis.

The DnaK chaperone machinery converts the native FlhD2C2 hetero-tetramer into a functional transcriptional regulator of flagellar regulon expression in Salmonella

The DnaK chaperone binds non-specifically to many unfolded polypeptides and also binds selectively to specific substrates. Although its involvement in targeting the unfolded polypeptides to assist proper folding is well documented, less is known about its role in targeting the folded polypeptides. We demonstrate that DnaK regulates the expression of the Salmonella flagellar regulon by modulating the FlhD and FlhC proteins, which function as master regulators at the apex of a transcription hierarchy comprising three classes of genes. FlhD and FlhC form an FlhD2C2 complex that activates sigma70 promoter of class 2 genes. In DeltadnaK cells, FlhD and FlhC proteins seemed to be assembled into hetero-tetrameric FlhD2C2 but the complex was not fully active in class 2 gene transcription, suggesting that the DnaK chaperone is involved in activating native FlhD2C2 complex into a regulator of flagellar regulon expression. This is the first time that involvement of the DnaK chaperone machinery in activating folded oligomerized proteins has been demonstrated.

Influence of Escherichia coli DnaK and DnaJ molecular chaperones on tryptophanase (TnaA) amount and GreA, GreB stability

The amount of tryptophanase was estimated in Escherichia coli deltadnaJ and deltadnaKdnaJ mutants. Densitometric analysis of polyacrylamide gels demonstrated that the amount of tryptophanase was diminished in both mutants. DnaK and DnaJ molecular chaperones apparently influence the amount of tryptophanase, the expression of which is regulated at all transcription steps, including transcription elongation. The half-life of GreA and GreB proteins (being activators of transcription elongation of the tna operon) are diminished in both mutants suggesting the involvement of DnaK and DnaJ in the stability of these proteins.

Role ofEscherichia coliDnaK and DnaJ chaperones in spontaneous and induced mutagenesis and their effect on UmuC stability

The frequency of spontaneous as well as induced reversions of auxotrophic mutations in Escherichia coli AB1157 and its DeltadnaK and DeltadnaKdnaJ derivatives was estimated. The obtained results demonstrate that both mutants tested are characterized by elevated frequency of spontaneous reversions compared to their AB1157 parent. In contrast, the frequency of reversions induced by UV and MMS, i.e. agents inducing the SOS response, is reduced in DeltadnaJ and DeltadnaKdnaJ mutants, pointing to the possible defect of these mutants in error prone repair. Due to the fact that UmuC protein is one of the main players executing the error prone repair, its stability in DeltadnaJ and DeltadnaKdnaJ mutants was also studied. Reduced UmuC stability was demonstrated only in the DeltadnaKdnaJ mutant.

Role of adenine nucleotides, molecular chaperones and chaperonins in stabilization of DnaA initiator protein of Escherichia coli

DnaA protein of Escherichia coli is a sequence-specific DNA binding protein required for the initiation of DNA replication from the chromosomal origin, oriC, and of several E. coli plasmids. At a moderate ionic strength, purified DnaA protein has a strong tendency to aggregate; the self-aggregate form is inactive in DNA replication. Binding of ATP or ADP to DnaA protein protected it from aggregation to maintain its replication activity. AMP or cyclic AMP had no protective effect. The molecular chaperone DnaK protected DnaA protein from aggregation with or without ATP. DnaJ and GrpE were not stimulatory. Chaperonins GroEL and GroES were also able to prevent aggregation but only in the presence of ATP. The studies presented here show that for DnaA protein to be active in the initiation of DNA replication, it must be prevented from forming a self-aggregate by the binding of adenine nucleotides, and/or by the action of molecular chaperones.

Linkage map of Escherichia coli K-12, edition 10: the traditional map

This map is an update of the edition 9 map by Berlyn et al. (M. K. B. Berlyn, K. B. Low, and K. E. Rudd, p. 1715-1902, in F. C. Neidhardt et al., ed., Escherichia coli and Salmonella: cellular and molecular biology, 2nd ed., vol. 2, 1996). It uses coordinates established by the completed sequence, expressed as 100 minutes for the entire circular map, and adds new genes discovered and established since 1996 and eliminates those shown to correspond to other known genes. The latter are included as synonyms. An alphabetical list of genes showing map location, synonyms, the protein or RNA product of the gene, phenotypes of mutants, and reference citations is provided. In addition to genes known to correspond to gene sequences, other genes, often older, that are described by phenotype and older mapping techniques and that have not been correlated with sequences are included.

Characterization of the thermal stress response of Campylobacter jejuni

Campylobacter jejuni, a microaerophilic, gram-negative bacterium, is a common cause of gastrointestinal disease in humans. Heat shock proteins are a group of highly conserved, coregulated proteins that play important roles in enabling organisms to cope with physiological stresses. The primary aim of this study was to characterize the heat shock response of C. jejuni. Twenty-four proteins were preferentially synthesized by C. jejuni immediately following heat shock. Upon immunoscreening of Escherichia coli transformants harboring a Campylobacter genomic DNA library, one recombinant plasmid that encoded a heat shock protein was isolated. The recombinant plasmid, designated pMEK20, contained an open reading frame of 1,119 bp that was capable of encoding a protein of 372 amino acids with a calculated molecular mass of 41,436 Da. The deduced amino acid sequence of the open reading frame shared similarity with that of DnaJ, which belongs to the Hsp-40 family of molecular chaperones, from a number of bacteria. An E. coli dnaJ mutant was successfully complemented with the pMEK20 recombinant plasmid, as judged by the ability of bacteriophage lambda to form plaques, indicating that the C. jejuni gene encoding the 41-kDa protein is a functional homolog of the dnaJ gene from E. coli. The ability of each of two C. jejuni dnaJ mutants to form colonies at 46 degreesC was severely retarded, indicating that DnaJ plays an important role in C. jejuni thermotolerance. Experiments revealed that a C. jejuni DnaJ mutant was unable to colonize newly hatched Leghorn chickens, suggesting that heat shock proteins play a role in vivo.

Cloning and sequencing of the dnaK and grpE genes of Legionella pneumophila

A 4.4-kb DNA fragment from Legionella pneumophila (Lp) was isolated, which could complement an Escherichia coli (Ec) dnaK ts mutant, HC4102. Nucleotide sequence analysis of the region revealed two complete open reading frames (ORFs) encoding both a predicted DnaK protein of 644 aa and a predicted GrpE protein of 199 aa, and also the 5'-end of the predicted dnaJ gene organized in the order of grpE-dnaK-dnaJ. Consensus heat shock (HS) promoter sequences were identified upstream of the start of both grpE and dnaK transcripts. However, no obvious promoter sequences were detected upstream of dnaJ. The transcription start points of grpE and dnaK were determined by primer extension analysis and the amount of each of the transcripts increased four- to eightfold after HS.

Modification of two distinct COOH-terminal domains is required for murine p53 activation by bacterial Hsp70

Activation of the latent DNA binding function of human p53 protein by the bacterial Hsp70, DnaK, represents a unique reaction in which a heat shock protein can interact with a native protein to affect its function. We have localized a likely DnaK interaction site on native human p53 tetramers to a motif flanking the COOH-terminal casein kinase II and protein kinase C phosphorylation sites. Murine p53 is less efficiently activated by DnaK, which has permitted a search for factors that might cooperate in p53 activation by DnaK. We show that optimal activation by DnaK may be dependent upon the phosphorylation state of murine p53, in particular, modification of p53 at the cdc2 phosphorylation site by point mutation decreases the extent of activation by DnaK. Additionally, the monoclonal antibody PAb241, binding in the vicinity of the cdc2 phosphorylation site, is able to activate the specific DNA binding function of p53. This has led us to propose a second regulatory motif flanking the tetramerization domain of p53 that cooperates with factors binding at the negative regulatory domain in the extreme COOH terminus.

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.

The cold sensitivity of a mutant of Saccharomyces cerevisiae lacking a mitochondrial heat shock protein 70 is suppressed by loss of mitochondrial DNA

SSH1, a newly identified member of the heat shock protein (hsp70) multigene family of the budding yeast Saccharomyces cerevisiae, encodes a protein localized to the mitochondrial matrix. Deletion of the SSH1 gene results in extremely slow growth at 23 degrees C or 30 degrees C, but nearly wild-type growth at 37 degrees C. The matrix of the mitochondria contains another hsp70, Ssc1, which is essential for growth and required for translocation of proteins into mitochondria. Unlike SSC1 mutants, an SSH1 mutant showed no detectable defects in import of several proteins from the cytosol to the matrix compared to wild type. Increased expression of Ssc1 partially suppressed the cold-sensitive growth defect of the SSH1 mutant, suggesting that when present in increased amounts, Ssc1 can at least partially carry out the normal functions of Ssh1. Spontaneous suppressors of the cold-sensitive phenotype of an SSH1 null mutant were obtained at a high frequency at 23 degrees C, and were all found to be respiration deficient. 15 of 16 suppressors that were analyzed lacked mitochondrial DNA, while the 16th had reduced amounts. We suggest that Ssh1 is required for normal mitochondrial DNA replication, and that disruption of this process in ssh1 cells results in a defect in mitochondrial function at low temperatures.

Overproduction of the Brucella melitensis heat shock protein DnaK in Escherichia coli and its localization by use of specific monoclonal antibodies in B. melitensis cells and fractions

The Brucella melitensis dnaK gene was amplified by the polymerase chain reaction using primers chosen according to the published sequence of B. ovis and cloned in multiple copy plasmids enabling expression under the control of the Plac promoter. Monoclonal antibodies (mAb) obtained by immunizing mice with B. melitensis B115 cell wall (CW) fraction or by infecting mice with virulent B. melitensis strain H38 and recognizing a 73-kDa band in immunoblotting of the B. melitensis CW fraction reacted with the cloned dnaK gene product and were thus shown to be specific for the heat shock protein DnaK. The anti-Dnak protein mAbs did not react with Escherichia coli control cells or cell lysates and could therefore be specific to Brucella DnaK protein epitopes. These mAbs were further used to study overproduction of the DnaK protein. B. melitensis DnaK overproduction in E. coli resulted in a defect in cell septation and formation of cell filaments. Immunogold labelling with the mAbs and electron microscopy localized the DnaK protein inside as well as outside the E. coli cells, probably resulting from lysis due to toxicity of the overproduced DnaK protein. These results indicated that overproduction of the B. melitensis DnaK protein in E. coli had similar physiological consequences as that of E. coli overproduced in E. coli. The DnaK protein localization in B. melitensis cells was essentially cytoplasmic, as shown by immunoelectron microscopy. Heat shock treatment of these cells resulted in increased binding of mAbs and labelling in the cytoplasm. However, in subcellular fractions the DnaK protein was predominantly found in the cell envelope fraction of B. melitensis, which could perhaps be due to interaction of the DnaK protein with membrane proteins.

Analysis of three DnaK mutant proteins suggests that progression through the ATPase cycle requires conformational changes

DnaK, the bacterial homolog of the eukaryotic hsp70 proteins, is an ATP-dependent chaperone whose basal ATPase is stimulated by synthetic peptides and its cohort heat shock proteins, DnaJ and GrpE. We have used three mutant DnaK proteins, E171K, D201N, and A174T (corresponding to Glu175, Asp206, and Ala179, respectively, in bovine heat stable cognate 70) to probe the ATPase cycle. All of the mutant proteins exhibit some alteration in basal ATP hydrolysis. However, they all exhibit more severe defects in the regulated activities. D201N and E171K are completely defective in all regulated activities of the protein and also in making the conformational change exhibited by the wt protein upon binding ATP. We suggest that the inability of D201N and E171K to achieve the ATP activated conformation prevents both stimulation by all effectors and the ATP-mediated release of GrpE. In contrast, the defect of A174T is much more specific. It exhibits normal binding and release of GrpE and normal stimulation of ATPase activity by DnaJ. However, it is defective in the synergistic activation of its ATPase by DnaJ and GrpE. We suggest that this mutant protein is specifically defective in a DnaJ/GrpE mediated conformational change in DnaK necessary for the synergistic action of DnaJ+GrpE.

Molecular comparison of the mitochondrial and cytoplasmic hsp70 of Trypanosoma cruzi, Trypanosoma brucei and Leishmania major

We compared the expression and localization of the mitochondrial and cytoplasmic hsp70 of the protozoans Trypanosoma cruzi, Trypanosoma brucei and Leishmania major. The mitochondrial protein is encoded by multiple mRNA in all species, while the cytoplasmic protein is encoded by a single mRNA. In all three species, the mitochondrial hsp70 is concentrated in the kinetoplast, a submitochondrial structure that houses the unusual DNA (kDNA) that characterizes this group of organisms, while the cytoplasmic protein is distributed throughout the cell. These results suggest that, in all kinetoplastid species, mt-hsp70 has a specific function in kDNA biology, possibly in the processes of kDNA replication, RNA editing or kinetoplast structure.

Resistance to trifluoroperazine, a calmodulin inhibitor, maps to the fabD locus in Escherichia coli

A mutant, tfpA1, resistant to the calmodulin inhibitor trifluoroperazine (TFP) at 30 degrees C, was isolated in Escherichia coli. The mutant showed a reduced growth rate at 30 degrees C and was temperature sensitive (ts) at 42 degrees C for growth, forming short filaments. The mutation was mapped to the 24 min region of the chromosome and the gene was cloned by complementation of the ts defect. Subsequent subcloning, complementation analysis, marker rescue mapping and sequencing, identified tfpA as fabD, encoding the 35 kDa, malonyl-coenzyme A transacylase (MCT) enzyme, required for the initial step in the elongation cycle for fatty acid biosynthesis. Resistance to TFP may result from altered permeability of the cell envelope, although the mutant remained sensitive to other calmodulin inhibitors and to other antibacterial agents. Alternatively, resistance may be more indirect, resulting from alterations in intracellular Ca++ levels which affect the activity of the TFP target in some way.

Isolation and analysis of mutants of the dnaK operon of Bacillus subtilis

Bacillus subtilis contains at least three classes of heat-shock genes regulated by different mechanisms. We are studying class I heat-shock genes encoded by the operons dnaK and groE. These two operons are both expressed from a vegetative promoter, and their regulation involves a novel heat-shock element designated CIRCE. Here we show that induction of both operons results from enhanced synthesis of mRNA and is independent of de novo protein synthesis. To answer the question of whether dnaK is involved in the deregulation of the heat-shock response as reported for Escherichia coli, two different insertion mutations were isolated within the tetracistronic dnaK operon (orf39-grpE-dnaK-dnaJ). In one mutant a cat cassette was inserted at the beginning of orf39. Transcriptional analysis revealed that this mutation abolished expression of the whole operon. In contrast, the basal level of groE mRNA was significantly increased at 37 degrees C, followed by a prolonged delay in the shut off after temperature upshift. These data point to a crucial role for the orf39 gene in the regulation of class I heat-shock genes. In the other mutant an internal 0.8 kb Bg/II fragment of dnaK was replaced by the cat cassette. In contrast to E. coli dnaK null mutants, the two B. subtilis dnaK operon mutants could grow within a temperature range from 16-52 degrees C. At temperatures above 52 degrees C, they failed to form colonies on agar plates, started to filament, and lost motility. Furthermore, the induction profile of the groE and dnaK operons was not impaired in the dnaK::cat mutant.(ABSTRACT TRUNCATED AT 250 WORDS)

Studies of bacteriophage P2 DNA replication: localization of the cleavage site of the A protein

Bacteriophage P2 replicates via a modified rolling circle-type of mechanism, where the P2 A protein acts as an initiator of the replication by inducing a single-stranded cut at the origin of replication (ori). The exact location of the cut induced by the A protein in vivo is determined in this report by: (i) restriction analysis; (ii) DNA sequence analysis; and (iii) primer extensions. It is located 89.2% from the left end of the P2 genome, which is within the coding part of the A gene, in a region devoid of secondary structures. The A gene has been cloned into an expression vector, and the A protein has been purified. The purified A protein does not bind to double-stranded ori containing DNA, but it cleaves single-stranded ori containing DNA, which indicates that a special DNA structure and/or protein is required to make the ori accessible for the A protein.

Cloning and sequencing of the Lactococcus lactis subsp. lactis dnaK gene using a PCR-based approach

The coding region for the dnaK gene from Lactococcus lactis subsp. lactis LM0230 was isolated and sequenced. An internal 789-bp fragment was amplified by the polymerase chain reaction (PCR) using a pair of degenerate oligodeoxyribonucleotide primers designed on the basis of amino acid (aa) sequences conserved in a number of DnaK. This PCR product was cloned, sequenced and used as a Southern hybridization probe to locate the flanking regions of the gene. The sequence of this central region from dnaK was also used to design two sets of inverse PCR primers to amplify, separately, the upstream and downstream regions. The inverse PCR products were then cloned and partially sequenced. The complete nucleotide sequence was obtained from overlapping cloned fragments of the gene and found to consist of a single 1824-bp open reading frame coding for a 602-aa protein. Alignment of the deduced aa sequence with those of other bacterial DnaK showed a high degree of homology and is most similar to the Bacillus megaterium DnaK.

DnaK mutants defective in ATPase activity are defective in negative regulation of the heat shock response: expression of mutant DnaK proteins results in filamentation

Site-directed mutagenesis has previously been used to construct Escherichia coli dnaK mutants encoding proteins that are altered at the site of in vitro phosphorylation (J. S. McCarty and G. C. Walker, Proc. Natl. Acad. Sci. USA 88:9513-9517, 1991). These mutants are unable to autophosphorylate and are severely defective in ATP hydrolysis. These mutant dnaK genes were placed under the control of the lac promoter and were found not to complement the deficiencies of a delta dnaK mutant in negative regulation of the heat shock response. A decrease in the expression of DnaK and DnaJ below their normal levels at 30 degrees C was found to result in increased expression of GroEL. The implications of these results for DnaK's role in the negative regulation of the heat shock response are discussed. Evidence is also presented indicating the existence of a 70-kDa protein present in a delta dnaK52 mutant that cross-reacts with antibodies raised against DnaK. Derivatives of the dnaK+ E. coli strain MC4100 expressing the mutant DnaK proteins filamented severely at temperatures equal to or greater than 34 degrees C. In the dnaK+ E. coli strain W3110, expression of these mutant proteins caused extreme filamentation even at 30 degrees C. Together with other observations, these results suggest that DnaK may play a direct role in the septation pathway, perhaps via an interaction with FtsZ. Although delta dnaK52 derivatives of strain MC4100 filament extensively, a level of underexpression of DnaK and DnaJ that results in increased expression of the other heat shock proteins did not result in filamentation. The delta dnaK52 allele could be transduced successfully, at temperatures of up to 45 degrees C, into strains carrying a plasmid expressing dnaK+ dnaJ+, although the yield of transductants decreased above 37 degrees C. In contrast, with a strain that did not carry a plasmid expressing dnaK+ dnaJ+, the yield of delta dnaK52 transductants decreased extremely sharply between 39 and 40 degrees C, suggesting that DnaK and DnaJ play one or more roles critical for growth at temperatures of 40 degrees C or greater.

Synthesis of DnaK protein during the division cycle of Escherichia coli

DnaK protein is involved in the initiation of DNA synthesis from the Escherichia coli chromosome as well as from the replication origins of phage lambda and P1. The synthesis of dnaK mRNA and protein has been reported to vary during the cell cycle of Caulobacter crescentus (Gomes et al., 1990). We have measured the expression of DnaK protein during the E. coli division cycle using the membrane-elution method. Cells labelled with a radioactive amino acid at different times during the division cycle were analysed for radiolabelled DnaK protein by quantitative immunoprecipitation, gel electrophoresis and autoradiography. In contrast to reports of cell-cycle-specific synthesis of DnaK protein in C. crescentus, we find the synthesis of DnaK protein to be invariant during the E. coli division cycle. Its synthesis occurs exponentially, as does the synthesis of total cell protein.

Impairment of nucleoid segregation and cell division at high osmolarity in a strain of Escherichia coli overproducing the chaperone DnaK

Escherichia coli strain WM1390, which overproduces 20-fold the chaperone protein DnaK, was able to grow exponentially without apparent abnormality in 300 mosM medium. In contrast, it showed both aberrant nucleoid segregation and strong inhibition of septation when shifted to high osmolarity. These impairments could not be accounted for by a bacteriocidal effect of the high DnaK content. Rather, the DnaK content appeared to promote faster growth than that of the parent C600, at least at high osmolarity in the presence of the osmoprotectant glycine betaine.

Cooperation of the prs and dnaA gene products for initiation of chromosome replication in Escherichia coli

A new Escherichia coli mutant allele, named dnaR, that causes thermosensitive initiation of chromosome replication has been identified to be an allele of the prs gene, the gene for phosphoribosylpyrophosphate synthetase (Y. Sakakibara, J. Mol. Biol. 226:979-987, 1992; Y. Sakakibara, J. Mol. Biol. 226:989-996, 1992). The dnaR mutant became temperature resistant by acquisition of a mutation in the dnaA gene that did not affect the intrinsic activity for the initiation of replication. The suppressor mutant was capable of initiating replication from oriC at a high temperature restrictive for the dnaR single mutant. The thermoresistant DNA synthesis was inhibited by the presence of the wild-type dnaA allele at a high but not a low copy number. The synthesis was also inhibited by an elevated dose of a mutant dnaR allele retaining dnaR activity. Therefore, thermoresistant DNA synthesis in the suppressor mutant was dependent on both the dnaA and the dnaR functions. On the basis of these results, I conclude that the initiation of chromosome replication requires cooperation of the prs and dnaA products.

Cloning and sequencing of the dnaK region of Streptomyces coelicolor A3(2)

The dnaK homologue of Streptomyces coelicolor A3(2) strain M145 has been cloned and sequenced. Nucleotide sequence analysis of a 2.5-kb region revealed an open reading frame (ORF) encoding a predicted DnaK protein of 618 amino acids (M(r) = 66,274). The dnaK coding sequence displays extreme codon bias and shows a strong preference for CGY and GGY, for Arg and Gly codons, respectively. The predicted DnaK sequence has a high Lys:Arg ratio which is not typical of streptomycete proteins. The region immediately downstream from dnaK contains an ORF for a GrpE-like protein; the predicted start codon of grpE overlaps the last two codons of dnaK, indicating that the two genes are translationally coupled. This organisation differs from that reported for other prokaryotes.

Modulation of the heat shock response by one-carbon metabolism in Escherichia coli

A genetic screen designed to isolate mutants of Escherichia coli W3110 altered in the ability to induce the heat shock response identified a strain unable to induce the heat shock proteins in a rich, defined medium lacking methionine after exposure to 2,4-dinitrophenol. This strain also grew slowly at 28 degrees C and linearly at 42 degrees C in this medium. The abnormal induction of the heat shock proteins and abnormal growth at both high and low temperatures were reversed when methionine was included in the growth medium. The mutation responsible for these phenotypes mapped to the glyA gene, a biosynthetic gene encoding the enzyme that converts serine and tetrahydrofolate to glycine and 5,10-methylenetetrahydrofolate. This reaction is the major source of glycine and one-carbon units in the cell. Because fixed one-carbon units, in the form of methionine, allowed mutant cells to induce the heat shock response after exposure to 2,4-dinitrophenol, a one-carbon restriction may be responsible for the phenotypes described above.

Isolation of dnaJ, dnaK, and grpE homologues from Borrelia burgdorferi and complementation of Escherichia coli mutants

The heat-shock proteins DnaJ, DnaK, and GrpE are involved in the replication of various species of DNA in Escherichia coli, in addition to their roles in other processes, including protein disaggregation and export. We have cloned the Borrelia burgdorferi homologues of these genes. DNA sequence analysis revealed an open reading frame encoding a protein that is 62% identical to the E. coli DnaK protein. Genes homologous to the E. coli grpE and dnaJ genes, encoding products 28% and 39% identical to their homologues, are located up- and downstream, respectively, of the B. burgdorferi dnaK gene. No obvious promoters were detected in the sequenced DNA, although a potential transcription terminator was found downstream of the dnaJ gene, so these three genes may form an operon, perhaps with a fourth gene located upstream of the grpE gene. The grpE homologue complemented an E. coli grpE mutant and the dnaJ homologue complemented an E. coli dnaJ mutant, whereas the B. burgdorferi dnaK gene did not complement dnaK mutants.

Levels of epsilon, an essential replication subunit of Escherichia coli DNA polymerase III, are controlled by heat shock proteins

In Escherichia coli, epsilon, the proofreading subunit of DNA polymerase III, is encoded by dnaQ. A random search for mutants that affect the expression of dnaQ revealed that mutations in the genes encoding the heat shock proteins (HSPs) DnaK, DnaJ, and GrpE result in dramatic decreases in the cellular levels of epsilon. dnaQ is arranged in an overlapping divergent transcriptional unit with rnhA, which encodes RNase H1, and mutations in the same HSPs also reduced the apparent levels of RNase H1. The HSPs had only small effects on transcriptional fusions to these genes; thus, it is likely that they operate primarily at the protein level. Since survival and mutagenesis after DNA damage are affected by epsilon and RNase H1, HSPs may have a broad influence on various aspects of DNA replication and repair.

Regulation of the specific DNA binding function of p53

The DNA binding activity of p53 is required for its tumor suppressor function; we show here that this activity is cryptic but can be activated by cellular factors acting on a C-terminal regulatory domain of p53. A gel mobility shift assay demonstrated that recombinant wild-type human p53 binds DNA sequence specifically only weakly, but a monoclonal antibody binding near the C terminus activated the cryptic DNA binding activity stoichiometrically. p53 DNA binding could be activated by a C-terminal deletion of p53, mild proteolysis of full-length p53, E. coli dnaK (which disrupts protein-protein complexes), or casein kinase II (and coincident phosphorylation of a C-terminal site on p53). Activation of p53 DNA binding may be critical in regulation of its ability to arrest cell growth and thus its tumor suppressor function.

dnaR function of the prs gene of Escherichia coli in initiation of chromosome replication

A new Escherichia coli mutant named dnaR, which was temperature sensitive in initiation of DNA replication, has been characterized through identification of the mutant gene. A 1.65 x 10(3) base-pair chromosomal DNA fragment isolated from wild-type cells, but not the corresponding fragment from the dnaR mutant, exhibited an activity that reversed temperature-sensitive growth of the mutant. The DNA fragment was found to include the entire prs-coding sequence and specify a 34,000 M(r) protein with phosphoribosylpyrophosphate synthetase activity. The dnaR mutation resided within the prs-coding segment and made the synthetase thermolabile. The coding segment for the dnaR product was determined, by introduction of various mutations into the cloned fragment, to be the same as that for the synthetase. The dnaR function of the prs gene product in DNA replication is discussed on the basis of an observation that thermal treatment of the dnaR mutant caused a delay in initiation of chromosome replication after the downshift, despite the presence of the synthetase activity at the preheat level.

Novel Escherichia coli mutant, dnaR, thermosensitive in initiation of chromosome replication

A newly isolated Escherichia coli mutant thermosensitive in DNA synthesis had an allele named dnaR130, which was located at 26.3 minutes on the genetic map. The mutant was defective in initiation of chromosome replication but not in propagation at a high temperature. This mutant was capable of growing in the absence of the rnh function at the high temperature by means of a dnaA-independent replication mechanism. In the mutant exposed to the high temperature, an oriC plasmid was able to replicate, although at a lower rate than at the low temperature. The plasmid replication at the high temperature depended on the dnaA function essential for the initiation of replication from oriC. The mutant lacking the rnh function persistently maintained the oriC plasmid at the high temperature in a dnaA-dependent manner. Thus, the dnaR function was required for initiation of replication of the bacterial chromosome from oriC but not the oriC plasmid. This result reveals that a dnaR-dependent initiation mechanism that is dispensable for oriC plasmid replication operates in the bacterial chromosome replication.

Cloning, sequencing, and molecular analysis of the dnaK locus from Bacillus subtilis

By using an internal part of the dnaK gene from Bacillus megaterium as a probe, a 5.2-kb HindIII fragment of chromosomal DNA of Bacillus subtilis was cloned. Downstream sequences were isolated by in vivo chromosome walking. Sequencing of 5,085 bp revealed four open reading frames in the order orf39-grpE-dnaK-dnaJ. orf39 encodes a 39-kDa polypeptide of unknown biological function with no noticeable homology to any other protein within the data bases. Alignment of the GrpE protein with those of three other bacterial species revealed a low overall homology, but a higher homology restricted to two regions which might be involved in interactions with other proteins. Alignment of the DnaK protein with six bacterial DnaK polypeptides revealed that a contiguous region of 24 amino acids is absent from the DnaK proteins of all known gram-positive species. Primer extension studies revealed three potential transcription start sites, two preceding orf39 (S1 and S2) and a third one in front of grpE (S3). S2 and S3 were activated at a high temperature. Northern (RNA) analysis led to the detection of three mRNA species of 4.9, 2.6, and 1.5 kb. RNA dot blot experiments revealed an at-least-fivefold increase in the amount of specific mRNA from 0 to 5 min postinduction and then a rapid decrease. A transcriptional fusion between dnaK and the amyL reporter gene exhibited a slight increase in alpha-amylase activity after heat induction. A 9-bp inverted repeat was detected in front of the coding region of orf39. This inverted repeat is present in a number of other heat shock operons in other microorganisms ranging from cyanobacteria to mycobacteria. The biological property of this inverted repeat as a putative key element in the induction of heat shock genes is discussed. The dnaK locus was mapped at about 223 degrees on the B. subtilis genetic map.

Involvement of Fis protein in replication of the Escherichia coli chromosome

We report evidence indicating that Fis protein plays a role in initiation of replication at oriC in vivo. At high temperatures, fis null mutants form filamentous cells, show aberrant nucleoid segregation, and are unable to form single colonies. DNA synthesis is inhibited in these fis mutant strains following upshift to 44 degrees C. The pattern of DNA synthesis inhibition upon temperature upshift and the requirement for RNA synthesis, but not protein synthesis, for resumed DNA synthesis upon downshift to 32 degrees C indicate that synthesis is affected in the initiation phase. fis mutations act synergistically with gyrB alleles known to affect initiation. oriC-dependent plasmids are poorly established and maintained in fis mutant strains. Finally, purified Fis protein interacts in vitro with sites in oriC. These interactions could be involved in mediating the effect of Fis on DNA synthesis in vivo.

Heat shock gene expression in continuous cultures of Escherichia coli

Temperature inducible systems for the controlled expression of recombinant genes are finding increasing industrial applications. These involve either short or long term exposure of the process culture to superoptimum temperatures. It is well known that bacteria respond to a sudden increase in their environmental temperature with an immediate transient increase in the synthesis rates of specific heat shock proteins. The use of continuous flow processes for the production of recombinant proteins would allow higher productivity and smaller scale bioreactors. However, the induction patterns of heat shock proteins in continuous culture after defined heat shocks are not well defined despite a large amount of information which is now available concerning heat shock protein induction in batch cultures. An overview of this information is presented to enable a better understanding of the response in continuous cultures. The latter was investigated by monitoring the transient expression of a representative heat shock gene, htpG, in E. coli in continuous culture. The relative magnitude of the response was found to be both temperature and exposure time dependent, but growth rate independent. Changing medium composition resulted in both different steady and transient state expression levels.