dnaK Operon Research Articles

Integrative vectors for constructing single-copy transcriptional fusions between Bacillus subtilis promoters and various reporter genes encoding heat-stable enzymes

Here, we report on the construction of three integrative plasmids for Bacillus subtilis (Bs) allowing in vitro construction of transcriptional fusions. These plasmids contain a neomycin- or tetracycline-resistance cassette and one of three promoterless genes: bgaB (encoding β-galactosidase), cat (chloramphenicol acetyltransferase), or xylE (catechol 2,3-dioxygenase). All cassettes are flanked by the 3′- and 5′-ends of the amyE gene (encoding fα-amylase) allowing integration of these cassettes at the amyE locus of the Bs chromosome. For propagation and selection in Escherichia coli, the plasmids contain the pBR322 origin of DNA replication and the β-lactamase-encoding bla gene. Four unique restriction sites can be used for insertion of restriction fragments carrying promoter fragments. All three reporter genes express heat-stable enzymes (stabie up to at least 50°C for 30 min) as shown here. We would like to point to the modular nature of these plasmids where the three reporter genes and the two resistance cassettes can be combined in any permutation. The versatility of the promoter-probe vectors was demonstrated by the integration of the promoters of the dnaK and groE operons of Bs and following their heat-inducible expression.

Systematic sequencing of the 283 kb 210 degrees-232 degrees region of the Bacillus subtilis genome containing the skin element and many sporulation genes.

As part of the Bacillus subtilis genome sequencing project, we have determined a 283 kb contiguous sequence from 210 degrees to 232 degrees of the B. subtilis genome. This region contains the 48 kb skin element which is excised during sporulation by a site-specific recombinase. In this region, 310 complete ORFs and one tRNA gene were identified: 66 ORFs have been sequenced and characterized previously by other workers, e.g. acc, ans, bfm, blt, bmr, comE, comG, dnaK, rpoD and sin operons; cwiA, gpr and lysA genes; many sporulation genes and operons, spo0A, spoIIA, spoIIM, spoiiP, spoIIIA, spoIIIC, spoIVB, spoIVCA, spoIVCB and spoVA, etc. The products of 84 ORFs were found to display significant similarity to proteins with known function in data banks, e.g., proteins involved in nucleotide metabolism, lipid biosynthesis, amino acid transport (ABC transporter), phosphate-specific transport, the glycine cleavage system, the two-component regulatory system, cell wall autolysis, ferric uptake and sporulation. However, the functions of more than half of the ORFs (52%, 160 ORFs) are still unknown. In the skin element containing 60 ORFs, 32 ORFs (53%) encode proteins which have significant homology to gene products of the B. subtilis temperate phage phi 105 and/or the defective phage PBSX.

The genes lepA and hemN form a bicistronic operon in Bacillus subtilis

The IepA operon of Bacillus subtilis was found to be bicistronic and to consist of the two genes IepA and hemN, which encode a putative GTP-binding protein and an oxygen-independent coproporhyrinogen III oxidase, respectively. The IepA operon is located immediately upstream of the dnaK operon. Both operons are transcribed in the same direction and are not separated by an obvious transcription-terminator-like structure. The IepA operon is preceded by a potential vegetative promoter, and there is a putative strong intergenic terminator between IepA and hemN. Northern blot experiments revealed only a transcript corresponding to IepA, but expression of hemN was demonstrated in slot-blot and immunoblot experiments using antibodies raised against His-tagged HemN. The data suggest that most of the transcripts originating at the potential vegetative promoter are terminated at the intergenic terminator. Readthrough transcription into the downstream dnaK operon was not found.

Analysis of heat shock gene expression in Lactococcus lactis MG1363.

The induction of the heat shock response in Lactococcus lactis subsp. cremoris strain MG1363 was analysed at the RNA level using a novel RNA isolation procedure to prevent degradation. Cloning of the dnaJ and groEL homologues was carried out. Northern blot analysis showed a similar induction pattern for dnaK, dnaJ and groELS after transfer from 30 degrees C to 43 degrees C when MG1363 was grown in defined medium. The dnaK gene showed a 100-fold induction level 15 min after temperature shifting. Induction of the first two genes in the dnaK operon, orf1 and grpE, resembled the pattern observed for the above genes, although maximum induction was observed earlier for orf1 and grpE. Novel transcript sizes were detected in heat-shocked cells. The induction kinetics observed for ftsH suggested a different regulation for this gene. Experimental evidence for a pronounced transcriptional regulation being involved in the heat shock response in L. lactis MG1363 is presented. A gene located downstream of the dnaK operon in strain MG1363, named orf4, was shown not to be regulated by heat shock.

Regulation and organization of the groE and dnaK operons in Eubacteria

groEL and dnaK are the most highly conserved protein-coding genes known. Most groEL operons and several dnaK and dnaJ operons contain a highly conserved inverted repeat (IR) sequence in their regulatory region. So far, this IR has been found only as part of the groE, dnaK and dnaJ operons and genes. In most cases, the IR is part of the operon transcript, and is involved in the regulation of expression at both the DNA and the mRNA levels. A detailed analysis of groE and dnaK operons indicates that the organization of the groE operons is highly conserved. They contain only the groES and groEL genes and always in the same order. In contrast, the organization of the dnaK operons has changed during evolution: genes have been added and deleted from it, and the gene order within the operon is variable.

Regulation and organization of the groE and dnaK operons in Eubacteria.

groEL and dnaK are the most highly conserved protein-coding genes known. Most groEL operons and several dnaK and dnaJ operons contain a highly conserved inverted repeat (IR) sequence in their regulatory region. So far, this IR has been found only as part of the groE, dnaK and dnaJ operons and genes. In most cases, the IR is part of the operon transcript, and is involved in the regulation of expression at both the DNA and mRNA levels. A detailed analysis of groE and dnaK operons indicates that the organization of the groE operons is highly conserved. They contain only the groES and groEL genes and always in the same order. In contrast, the organization of the dnaK operons has changed during evolution: genes have been added and deleted from it, and the gene order within the operon is variable.

Cloning and sequencing of the dnaK operon of Bacillus stearothermophilus

Here, we report the cloning of a 5.8-kb PstI fragment of chromosomal DNA from Bacillus stearothermophilus (Bt) carrying the three genes, grpE, dnaK and dnaJ. This fragment contains, in addition, the 3′-end of an open reading frame which has been shown to be part of the dnaK operon in three bacterial species. The dnaJ gene could complement an Escherichia coli dnaJts mutant for growth at high temperature. Sequencing and hybridization data strongly suggest that the Bt chromosome contains an analog of dnaJ.

HrcA, the first gene of the Bacillus subtilis dnaK operon encodes a negative regulator of class I heat shock genes

Whereas in Escherichia coli only one heat shock regulon is transiently induced by mild heat stress, for Bacillus subtilis three classes of heat shock genes regulated by different mechanisms have been described. Regulation of class I heat shock genes (dnaK and groE operons) involves an inverted repeat (CIRCE element) which most probably serves as an operator for a repressor. Here, we report on the analyses of an hrcA null mutant (delta hrcA), in which hrcA, the first gene of the dnaK operon, was deleted from the B. subtilis chromosome. This strain was perfectly viable at low and high temperatures. Transcriptional analysis of the deletion mutant revealed a high level of constitutive expression of both the dnaK and groE operons even at a low temperature. A further increase in the amount of groE transcript was observed after temperature upshift, suggesting a second induction mechanism for this operon. Overproduction of HrcA protein from a second copy of hrcA derived from a plasmid (phrcA+) in B. subtilis wild-type and delta hrcA strains prevented heat shock induction of the dnaK and groE operons at the level of transcription almost completely and strongly reduced the amounts of mRNA at a low temperature as well. Whereas the wild-type strain needed 4 h to resume growth after temperature upshift, the delta hrcA strain stopped growth only for about 1 h. Overproduction of HrcA protein prior to a heat shock almost completely prevented growth at a high temperature. These data clearly demonstrate that the hrcA product serves as a negative regulator of class I heat shock genes.

Heat-shock and general stress response in Bacillus subtilis.

The induction of stress proteins is an important component of the adaptional network of a non-growing cell of Bacillus subtilis. A diverse range of stresses such as heat shock, salt stress, ethanol, starvation for oxygen or nutrients etc. induce the same set of proteins, called general stress proteins. Although the adaptive functions of these proteins are largely unknown, they are proposed to provide general and rather non-specific protection of the cell under these adverse conditions. In addition to these non-specific general stress proteins, all extracellular signals induce a set of specific stress proteins that may confer specific protection against a particular stress factor. In B. subtilis at least three different classes of heat-inducible genes can be defined by their common regulatory characteristics: Class I genes, as exemplified by the dnaK and groE operons, are most efficiently induced by heat stress. Their expression involves a sigma A-dependent promoter, an inverted repeat (called the CIRCE element) highly conserved among eubacteria, and probably a repressor interacting with the CIRCE element. The majority of general stress genes (class II, more than 40) are induced at sigma B-dependent promoters by different growth-inhibiting conditions. The activation of sigma B by stress or starvation is the crucial event in the induction of this large stress regulon. Only a few genes, including Ion, clpC, clpP, and ftsH, can respond to different stress factors independently of sigma B or CIRCE (class III). Stress induction of these genes occurs at promoters presumably recognized by sigma A and probably involves additional regulatory elements which remain to be defined.

Cloning and sequencing of the dnaK locus in Streptomyces coelicolor A3(2).

The dnaK operon of Streptomyces coelicolor A3(2) was cloned by the DNA-probing method using synthetic oligonucleotides designed on the basis of two of the most conserved regions in 30 different DnaK proteins (HSP70). The isolated insert-a BamHI 5.6-kb fragment-was sequenced and shown to contain three open-reading frames organized in an operon and coding for proteins analogous to DnaK, GrpE and DnaJ, successively.

Isolation and characterization of Bacillus subtilis groE regulatory mutants: evidence for orf39 in the dnaK operon as a repressor gene in regulating the expression of both groE and dnaK

An inverted repeat sequence known as CIRCE (controlling inverted repeat of chaperone expression) in the Bacillus subtilis groE operon has been suggested to function as an operator. To identify the regulatory gene directly or indirectly involved in CIRCE-mediated heat-inducible groE expression, B. subtilis WBG2, carrying an integrated groE-bgaB transcription fusion in the amyE locus, was mutagenized. Dark blue colonies formed at 37 degrees C represent mutants which constitutively produce BgaB (a thermostable beta-galactosidase) at high levels. Seven mutants (WBG101 to WBG107) were selected for further characterization. They all overproduced BgaB, GroEL, and DnaK simultaneously at 37 degrees C. These mutants could be restored to normal by introducing a plasmid carrying a functional copy of orf39, the first gene in the B. subtilis dnaK operon. Genomic sequencing of these mutants demonstrated that they all carried a single mutation in orf39. These mutations can be divided into three groups: (i) Gly-307 to Asp, (ii) Ser-122 to Phe, and (iii) Gly-63 to Glu. By using a binary vector system in E. coli, production of ORF39 was found to negatively regulate the expression of groE-bgaB in a CIRCE-specific manner. Under the heat shock condition, the negative regulation mediated by ORF39 was abolished. Mobility shift of the CIRCE-containing probe was also observed with the crude extract prepared from the E. coli strain that overproduced ORF39. Therefore, ORF39 is the negative regulatory factor which regulates both groE and dnaK expression in B. subtilis. It is likely to function as a CIRCE-specific repressor.

Expression of heat shock genes inClostridium acetobutylicum

Characterization of the heat shock response in Clostridium acetobutylicum has indicated that at least 15 proteins are induced by a temperature upshift from 30 to 42 degrees C. These so-called heat shock proteins include DnaK and GroEL, two highly conserved molecular chaperones. Several genes encoding heat shock proteins of C. acetobutylicum have been cloned and analysed. The dnaK operon includes the genes orfA (a heat shock gene with an unknown function), grpE, dnaK, and dnaJ; and the groE operon the genes groES and groEL. The hsp18 gene coding for a member of the small heat shock protein family constitutes a monocistronic operon. Interestingly, the heat shock response in this bacterium is regulated by a mechanism, which is obviously different from that found in Escherichia coli. So far, no evidence for a heat shock-specific sigma factor of the RNA polymerase in C. acetobutylicum has been found. In this bacterium, like in many Gram-positive and several Gram-negative bacteria, a conserved inverted repeat is located upstream of chaperone/chaperonin-encoding stress genes such as dnaK and groEL and may be implicated as a cis-acting regulatory site. The inverted repeat is not present in the promoter region of hsp18. Therefore, in C. acetobutylicum there are at least two classes of heat shock genes with respect to the type of regulation. Evidence has been found that a repressor is involved in the regulation of the heat shock response in C. acetobutylicum. However, this regulation seems to be independent of the inverted repeat motif, and the mechanism by which the inverted repeat motif mediates regulation remains to be elucidated.(ABSTRACT TRUNCATED AT 250 WORDS)

The dnaK operon of Streptomyces coelicolor encodes a novel heat-shock protein which binds to the promoter region of the operon.

Transcriptional studies have demonstrated that the dnaK gene of Streptomyces coelicolor A3(2) is contained within a 4.3 kb operon. The operon is transcribed from a single (transiently) heat-inducible promoter, dnaKp, that resembles the typical vegetative (sigma 70-recognized) eubacterial consensus promoter sequence. dnaK transcription was found to be heat-inducible at all stages of development in surface-grown cultures. In addition, at the normal growth temperature of 30 degrees C, dnaK transcript levels were shown to vary at different stages of development, being more abundant in young germinating cultures and in mycelium undergoing sporogenesis. The nucleotide sequence of the dnaK operon has been completed, revealing the gene organization 5'dnaK-grpE-dnaJ orfX. orfX represents a novel heat-shock gene. Its predicted product displays high similarity to the GlnR repressor proteins of Bacillus spp. and to the MerR family of eubacterial transcriptional regulators. The S. coelicolor OrfX protein has been over-produced in Escherichia coli, and DNA-binding experiments indicate that it interacts specifically with the dnaKp region, binding to three partially related inverted repeat sequences; they are centered at -75, -49 and +4, respectively, relative to the transcription start site of the operon. These results suggest that OrfX plays a direct role in the regulation of the dnaK operon.

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)

Expression of heat shock genes in Clostridium acetobutylicum

Characterization of the heat shock response in Clostridium acetobutylicum has indicated that at least 15 proteins are induced by a temperature upshift from 30 to 42°C. These so-called heat shock proteins include DnaK and GroEL, two highly conserved molecular chaperones. Several genes encoding heat shock proteins of C. acetobutylicum have been cloned and analysed. The dnaK operon includes the genes orfA (a heat shock gene with an unknown function), grpE, dnaK, and dnaJ; and the groE operon the genes groES and groEL. The hsp18 gene coding for a cell member of the small heat shock protein family constitutes a monocistronic operon. Interestingly, the heat shock response in this bacterium is regulated by a mechanism, which is obviously different from that found in Escherichia coli. So far, no evidence for a heat shock-specific sigma factor for the RNA polymerase in C. acetobutylicum has been found. In this bacterium, like in many Gram-positive and several Gram-negative bacteria, a conserved inverted repeat is located upstream of chaperone/chaperonin-encoding stress genes such as dnaK and groEL and may be implicated as a cis-acting regulatory site. The inverted repeat is not present in the promoter region of hsp18. Therefore, in C. acetobutylicum there are at least two classes of heat shock genes with respect to the type of regulation. Evidence has been found that a repressor is involved in the regulation of the heat shock response in C. acetobutylicum. However, this regulation seems to be independent of the inverted repeat motif, and the mechanism by which the inverted repeat motif mediates regulation remains to be elucidated. Another protein with a potential regulatory function might be the 21-kDa heat shock protein, which is induced significantly earlier than the majority of heat shock proteins. This protein has similarity to the redox carrier rubredoxin. Interestingly, heat shock genes are expressed in C. acetobutylicum at an increased rate not only after heat stress but also during the initiation of solvent formation. The mRNA level of some heat shock genes, e.g. dnaK, reached a maximum at the same time during the metabolic shift as the mRNA levels of genes necessary for solvent production. Therefore, the heat shock response in C. acetobutylicum might be part of a global regulatory network including different stress responses like heat shock, metabolic switch, and also sporulation.

CIRCE, a novel heat shock element involved in regulation of heat shock operon dnaK of Bacillus subtilis

The dnaK and groESL operons of Bacillus subtilis are preceded by a potential sigma 43 promoter sequence (recognized by the vegetative sigma factor) and by an inverted repeat (IR) consisting of 9 bp separated by a 9-bp spacer. Since this IR has been found in many bacterial species, we suspected that it might be involved in heat shock regulation. In order to test this hypothesis, three different mutational alterations of three bases were introduced within the IR preceding the dnaK operon. These mutations were crossed into the chromosome of B. subtilis, and expression of the dnaK and of the unlinked groESL operons was studied. The dnaK operon exhibited increased expression at low temperature and a reduction in the stimulation after temperature upshift. Furthermore, these mutations reduced expression of the groESL operon at low temperature by 50% but did not interfere with stimulation after heat shock. These experiments show that the IR acts as a negative cis element of the dnaK operon. This conclusion was strengthened by the observation that the IR reduced expression of two different transcriptional fusions significantly after its insertion between the promoter and the reporter gene. Since this IR has been described in many bacterial species as preceding only genes of the dnaK and groESL operons, both encoding molecular chaperones (39 cases are documented so far), we designated this heat shock element CIRCE (controlling IR of chaperone expression). Furthermore, we suggest that this novel mechanism is more widespread among eubacteria than the regulation mechanism described for Escherichia coli and has a more ancient origin.

Cloning and sequence analysis of the dnaK gene region of Lactococcus lactis subsp. lactis.

A 5.4 kb HindIII fragment of Lactococcus lactis subsp. lactis was identified using a homologous dnaK probe generated by PCR and cloned in Escherichia coli. Upstream sequences were generated by inverse PCR. The two cloned fragments partially overlapped, and sequencing of 5915 bp revealed the presence of four open reading frames in the order orf1-grpE-dnaK-orf4. orf1 encodes a 39 kDa protein of unknown function which shows considerable sequence homology with the Orf39 and Orfa proteins of Bacillus subtilis and Clostridium acetobutylicum, respectively. The downstream ORFs showed high homology to the grpE and dnaK genes of other prokaryotes. The DnaK protein has a characteristic 24-amino-acid deletion exhibited by all the known DnaK proteins of Gram-positive species. In many bacteria the dnaK and dnaJ genes are found as part of the same operon. The L. lactis dnaK operon is unusual in that the dnaK gene is followed by a putative transcription terminator and a fourth large ORF which shares no homology with the dnaJ genes of other bacteria but has a small degree of homology with various membrane proteins. Vegetative promoter sequences are found upstream of both orf1 and orf4. A 12 bp inverted repeat is found upstream of the putative promoter of orf1 and an 8 bp inverted repeat is found between this promoter and the orf1 initiation codon. These repeats are thought to be involved in regulation of the heat-shock genes. The DnaK homologue is induced approximately 3-fold on heat shock at 42 degrees C.

Cloning, nucleotide sequence and structural analysis of the Clostridium acetobutylicum dnaJ gene.

The complete dnaJ gene of Clostridium acetobutylicum was isolated by chromosome walking using the previously cloned 5' end of the gene as a probe. Nucleotide sequencing of a positively reacting 2.2-kb HincII fragment, contained in the recombinant plasmid pKG4, revealed that the reading frame of the dnaJ gene of C. acetobutylicum consists of 1125 bp, encoding a protein of 374 amino acids with a calculated M(r) of 40376 and an isoelectric point of 9.54. The deduced amino acid sequence showed high similarity to the DnaJ proteins of other bacteria (e.g. Escherichia coli, Bacillus subtilis) as well as of an archaeon (Methanosarcina mazei) and to the corresponding proteins of eukaryotes (Saccharomyces cerevisiae, Homo sapiens). The areas of similarity included a conserved N-terminal domain of about 70 amino acids, a glycine-rich region of about 30 residues, and a central domain containing four repeats of a CXXCXGXG motif, whereas the C-terminal domain was less conserved. Northern (RNA) blot analysis indicated that dnaJ is induced by heat shock and that it is part of the dnaK operon of C. acetobutylicum. The 5' end (901 bp) of another gene (orfB), downstream of dnaJ and not heat-inducible, showed no significant similarity to other sequences available in EMBL and GenBank databases.

Cloning, nucleotide sequence and structural analysis of the Clostridium acetobutylicum dnaJ gene

The complete dnaJ gene of Clostridium acetobutylicum was isolated by chromosome walking using the previously cloned 5′ end of the gene as a probe. Nucleotide sequencing of a positively reacting 2.2-kb HincII fragment, contained in the recombinant plasmid pKG4, revealed that the reading frame of the dnaJ gene of C. acetobutylicum consists of 1125 bp, encoding a protein of 374 amino acids with a calculated Mr of 40376 and an isoelectric points of 9.54. The deduced amino acid sequence showed high similarity to the DnaJ proteins of other bacteria (e.g. Escherichia coli, Bacillus subtilis) as well as of an archaeon (Methanosarcina mazei) and to the corresponding proteins of eukaryotes (Saccharomyces cerevisiae, Homo sapiens). The areas of similarity included a conserved N-terminal domain of about 70 amino acids, a glycine-rich region of about 30 residues, and a central domain containing four repeats of a CXXCXGXG motif, whereas the C-terminal domain was less conserved. Northern (RNA) blot analysis indicated that dnaJ is induced by heat shock and that it is part of the dnaK operon of C. acetobutylicum. The 5′ end (901 bp) of another gene (orfB), downstream of dnaJ and not heat-inducible, showed no significant similarity to other sequences available in EMBL and GenBank databases.