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Query: UNIPROT:P06889 (Mol)
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In contrast to other bacterial species, mycobacteria were thus far considered to contain groEL and groES genes that are present on separate loci on their chromosomes, Here, by screening a Mycobacterium leprae lambda gt11 expression library with serum from an Ethiopian lepromatous leprosy patient, two DNA clones were isolated that contain a groEL gene arranged in an operon with a groES gene. The complete DNA sequence of this groESL operon was determined. The predicted amino acid sequences of the GroES and GroEL proteins encoded by this operon are 85-90% and 59-61% homologous to the sequences from previously characterized mycobacterial GroES and GroEL proteins. Southern blotting analyses with M. leprae groES- and groEL-specific probes demonstrate that similar groESL homologous DNA is present in the genomes of other mycobacteria, including Mycobacterium tuberculosis. This strongly suggests that mycobacteria contain a groESL operon in addition to a separately arranged second groEL gene. Using five T-cell clones from two leprosy patients as probes, expression of the M. leprae GroES protein in Escherichia coli after heat shock was demonstrated. Four of these clones recognized the same M. leprae-specific GroES-derived peptide in a DR2-restricted fashion. No expression of the groEL gene from this operon was detected in E. coli after heat shock, as tested with a panel of T-cell clones and monoclonal antibodies reactive to previously described GroEL proteins of mycobacteria.
Mol Microbiol 1992 Jul
PMID:Mycobacteria contain two groEL genes: the second Mycobacterium leprae groEL gene is arranged in an operon with groES. 135 34

Cell division of F+ bacteria is coupled to DNA replication of the F plasmid. Two plasmid coded genes, letA (ccdA) and letD (ccdB) are indispensable for this coupling. To investigate bacterial genes that participate in this coupling, we attempted to identify the target of the division inhibitor (the letD gene product) of the F plasmid. Two temperature-sensitive growth defective mutants were screened from bacterial mutants that escaped the letD product growth inhibition that occurs in hosts carrying an FletA mutant. Phage P1-mediated transduction and complementation analysis indicated that the temperature-sensitive mutations are located in the groES (mopB) gene, which is essential for the morphogenesis of several bacteriophages and also for growth of the bacteria. The nucleotide sequence of the promoter region of the gene in which the temperature-sensitive mutations had occurred was virtually identical with that of the groES gene of Escherichia coli; furthermore the sequence of the first five amino acid residues and the overall amino acid composition predicted from the nucleotide sequence of the gene match those of the purified GroES protein. The temperature-sensitive mutants did not allow the propagation of phage lambda at 28 degrees C and formed long filamentous structures without septa at 41 degrees C, as is observed in the case of groES mutants. Growth of the two groES mutants tested was not inhibited by the F plasmid with the letA mutation. These observations suggest to us that the morphogenesis gene groES plays a key role in coupling between replication of the F plasmid and cell division of the host cells.
J Mol Biol 1988 May 20
PMID:Control of cell division by sex factor F in Escherichia coli. III. Participation of the groES (mopB) gene of the host bacteria. 290 93

We have investigated heat-shock response in a marine bacterium Vibrio harveyi. We have found that 39 degrees C was the highest temperature at which V. harveyi was able to grow steadily. A shift from 30 degrees C to 39 degrees C caused increased synthesis of at least 10 proteins, as judged by SDS-PAGE, with molecular masses of 90, 70, 58, 41, 31, 27, 22, 15, 14.5 and 14kDa. The 70, 58, 41 and 14.5 kDa proteins were immunologically homologous to DnaK, GroEL, DnaJ and GroES heat-shock proteins of Escherichia coli, respectively. V. harveyi GroES protein had a lower molecular mass (14.5 kDa) than E. coli GroES, migrating in SDS-PAGE as 15kDa protein. We showed that a protein of approximately 43 kDa, immunologically reactive with antiserum against E. coli sigma 32 subunit (sigma 32) of RNA polymerase, was induced by heat-shock and co-purified with V. harveyi RNA polymerase. These results suggest that the 43 kDa protein is a heat-shock sigma protein of V. harveyi. Preparation containing the V. harveyi sigma 32 homologue, supplemented with core RNA polymerase of E. coli, was able to transcribe heat-shock promoters of E. coli in vitro.
Mol Microbiol 1995 May
PMID:Characterization of heat-shock response of the marine bacterium Vibrio harveyi. 747 74

Escherichia coli DnaK, DnaJ and GrpE are required for renaturation of heat-inactivated lambda Cl857 repressor (Gaitanaris et al., 1990). Here we demonstrate that in addition to the above three proteins, GroEL and GroES are necessary for the Cl857 repressor to acquire full activity at the permissive temperature. Although full-length soluble repressor is present at normal amounts, the protein has reduced specific activity and migrates abnormally on native gels. To determine where the different chaperones act in protein folding, we identified their cellular locations. DnaK and DnaJ are associated with nascent polypeptide chains in translating ribosomes. In contrast, GroEL, although it is transiently associated with newly synthesized proteins, is absent from the ribosomes. This suggests that DnaK and DnaJ play an early role in protein maturation, whereas GroEL acts at a later stage.
Mol Microbiol 1994 Dec
PMID:Successive action of Escherichia coli chaperones in vivo. 771 48

All Helicobacter pylori isolates synthesize a 54 kDa immunodominant protein that was reported to be associated with the nickel-dependent urease of H. pylori. This protein was recently recognized as a homologue of the heat-shock protein of the GroEL class. The gene encoding the GroEL-like protein of H. pylori (HspB) was cloned (pILL689) and was shown to belong to a bicistronic operon including the hspA and hspB genes. In Escherichia coli, the constitutive expression of the hspA and hspB genes was initiated from a promoter located within an IS5 insertion element that mapped upstream to the two open reading frames (ORFs). IS5 was absent from the H. pylori genome, and was thus acquired during the cosmid cloning process. hspA and hspB encoded polypeptides of 118 and 545 amino acid residues, corresponding to calculated molecular masses of 13.0 and 58.2 kDa, respectively. Amino acid sequence comparison studies revealed that, although H. pylori HspA and HspB proteins were highly similar to their bacterial homologues, the H. pylori HspA featured a striking motif at the C-terminus. This unique motif consists of a series of cysteine and histidine residues resembling a nickel-binding domain, which is not present in any of the other bacterial GroES homologues so far characterized. When the pILL689 recombinant plasmid was introduced together with the H. pylori urease gene cluster (pILL763) into an E. coli host strain, an increase of urease activity was observed. This suggested a close interaction between the HspA and HspB proteins and the urease enzyme, and a possible role for HspA in the chelation of nickel ions. The genes encoding each of the HspA and HspB polypeptides were cloned, expressed independently as proteins fused to the maltose-binding protein (MBP) and purified in large scale. The MBP-HspA and MBP-HspB fusion proteins were shown to retain their antigenic properties. Both HspA and HspB represent antigens that are specifically recognized by the sera from H. pylori-infected patients. Whereas HspB was known to be immunogenic in humans, this is the first demonstration that HspA per se is also immunogenic.
Mol Microbiol 1994 Dec
PMID:Helicobacter pylori hspA-hspB heat-shock gene cluster: nucleotide sequence, expression, putative function and immunogenicity. 771 57

The members of the 10 kDa and 60 kDa heat-shock chaperonin proteins (Hsp10 and Hsp60 or Cpn10 and Cpn60), which form an operon in bacteria, are present in all eubacteria and eukaryotic cell organelles such as mitochondria and chloroplasts. In archaebacteria and eukaryotic cell cytosol, no close homologues of Hsp10 or Hsp60 have been identified. However, these species (or cell compartments) contain the Tcp-1 family of proteins (distant homologues of Hsp60). Phylogenetic analysis based on global alignments of Hsp60 and Hsp10 sequences presented here provide some evidence regarding the evolution of mitochondria from a member of the alpha-subdivision of Gram-negative bacteria and chloroplasts from cyanobacterial species, respectively. This interference is strengthened by the presence of sequence signatures that are uniquely shared between Hsp60 homologues from alpha-purple bacteria and mitochondria on one hand, and the chloroplasts and cyanobacterial hsp60s on the other. Within the alpha-purple subdivision, species such as Rickettsia and Ehrlichia, which live intracellularly within eukaryotic cells, are indicated to be the closest relatives of mitochondrial homologues. In the Hsp60 evolutionary tree, rooted using the Tcp-1 homologue, the order of branching of the major groups was as follows: Gram-positive bacteria--cyanobacteria and chloroplasts--chlamydiae and spirochaetes--beta- and gamma-Gram-negative purple bacteria--alpha-purple bacteria--mitochondria. A similar branching order was observed independently in the Hsp10 tree. Multiple Hsp60 homologues, when present in a group of species, were found to be clustered together in the trees, indicating that they evolved by independent gene-duplication events. This review also considers in detail the evolutionary relationship between Hsp60 and Tcp-1 families of proteins based on two different models (viz. archaebacterial and chimeric) for the origin of eukaryotic cell nucleus. Some predictions of the chimeric model are also discussed.
Mol Microbiol 1995 Jan
PMID:Evolution of the chaperonin families (Hsp60, Hsp10 and Tcp-1) of proteins and the origin of eukaryotic cells. 859 29

The binding of nucleotides and chaperonin-10 (cpn10) to the Escherichia coli chaperonin-60 (cpn60) and their effect upon the molecular symmetry has been examined both kinetically and at equilibrium. ATP binds tightly and is hydrolysed on only one heptameric ring of the cpn60 tetradecamer at a time, thus inducing asymmetry in the cpn60 oligomer even in the absence of cpn10. In the absence of cpn10 these seven ATP molecules hydrolyse to form a cpn60:ADP7 complex in which ADP is tightly bound (Kd = 2-7 microM); further ADP binding to form a cpn60:ADP14 complex is weak (K1/2 = 2.3 mM). We conclude that symmetrical nucleotide complexes (with 14 ATP or 14 ADPs) are unstable, demonstrating negative co-operativity between the rings. When cpn60 is mixed with cpn10 and ATP the resultant cpn60:ATP7:cpn10 complex is formed rapidly (the rate constant for cpn10 association is > 4 x 10(7) M-1 s-1) and before ATP is hydrolysed (k = 0.12 s-1 per active subunit) to produce an extremely stable cpn60:ADP7:cpn10 complex. This allows ATP association on the unoccupied ring and nucleotide asymmetry in the double toroid is preserved. In "trapping" experiments, where the cpn60:ADP7:cpn10 is challenged with ATP, cpn10 was observed to dissociate at a rate identical to that of steady-state ATP hydrolysis in the presence of cpn10 (k = 0.042 s-1 per active subunit). The spontaneous decay of cpn60:ADP7:cpn10 and any of the major steady-state complexes, under conditions where free nucleotides had been removed, occurred at a rate tenfold lower than ATP hydrolysis. Since the binding of the non-hydrolysable analogue AMP-PNP was unable to induce dissociation of the co-chaperonin it was concluded that a transient state following ATP hydrolysis is necessary for the rapid dissociation of cpn10, which occurs once in every cycle. Trapping experiments using sub-stoichiometric concentrations of cpn10, relative to cpn60, show an unchanged rate of cpn10 exchange upon ATP hydrolysis, indicating that the formation of a symmetric, "football"-shaped complex in which two molecules of the co-chaperonin are bound to cpn60, is not an obligatory intermediate in the exchange process.
J Mol Biol 1995 May 26
PMID:The origins and consequences of asymmetry in the chaperonin reaction cycle. 777 68

Pseudobactin 358 is the yellow-green fluorescent siderophore [microbial iron(III) transport agent] produced by Pseudomonas putida WCS358 under iron-limiting conditions. The genes encoding pseudobactin 358 biosynthesis are iron-regulated at the level of transcription. In this study, the molecular characterization is reported of a cosmid clone of WCS358 DNA that can stimulate, in an iron-dependent manner, the activity of a WCS358 siderophore gene promoter in the heterologous Pseudomonas strain A225. The functional region in the clone was identified by subcloning, transposon mutagenesis and DNA sequencing as the groESL operon of strain WCS358. This increase in promoter activity was not observed when the groESL genes of strain WCS358 were integrated via a transposon vector into the genome of Pseudomonas A225, indicating that multiple copies of the operon are necessary for the increase in siderophore gene promoter activity. Amplification of the Escherichia coli and WCS358 groESL genes also increased iron-regulated promoter activity in the parent strain WCS358. The groESL operon codes for the chaperone proteins GroES and GroEL, which are responsible for mediating the folding and assembly of many proteins.
Mol Gen Genet 1994 Oct 17
PMID:Amplification of the groESL operon in Pseudomonas putida increases siderophore gene promoter activity. 784 55

Significant sequence similarity has been noted between a segment of the 60 kDa heat shock family of proteins (designated as GroEL, cpn60 or hsp60) and its functional partner, the 10-12 kDa GroES (or cpn10) family of proteins. Upon introduction of a few gaps, 31 identical and 19 conserved residues were observed in a 93 amino acid overlap between the region comprising of a.a. 314 to 431 in E. coli GroEL and the entire GroES sequence from Bacillus subtilis. The functional forms of both GroEL and GroES proteins, which function as a team in the protein folding process, are toroidal rings exhibiting a highly unusual seven-fold rotational axis of symmetry. It is suggested that the information for assuming this structural form is contained within the shared sequence region between these proteins.
Biochem Mol Biol Int 1994 Jun
PMID:Identification of a GroES (CPN10)-related sequence motif in the GroEL (CPN60) chaperonins. 795 Oct 76

Fluorescently labeled rhodanese was synthesized by coupled transcription/translation in a cell-free Escherichia coli system. A derivative of coumarin was co-translationally incorporated at the N terminus of the polypeptide. Molecules released from the ribosomes during the incubation are enzymatically active; however, continued incubation results in accumulation of enzymatically inactive full-length rhodanese polypeptides on the ribosomes. These can be activated and released in the presence of the added chaperones, DnaJ, DnaK, GrpE, GroEL, GroES and ATP. Fluorescence parameters (quantum yield, anisotropy and the emission maximum) of ribosome-bound coumarin-labeled rhodanese are affected differentially by addition of the chaperones individually or sequentially. Rhodanese released from the ribosomes in the presence of all chaperones (enzymatically active) differs in fluorescence properties from rhodanese released by GroES or DnaK only or by puromycin (enzymatically inactive) indicating a difference in conformation. Using sparsomycin, an inhibitor of the peptidyl transferase reaction, full-length rhodanese can be trapped on the ribosomes. A ribosome-bound intermediate formed by DnaJ or DnaJ plus DnaK was demonstrated by the effect of these chaperones on fluorescence spectra resulting from binding of anticoumarin antibodies to the N terminus of newly synthesized rhodanese. The results support the hypothesis that folding of nascent proteins can take place on the ribosome.
J Mol Biol 1994 Dec 02
PMID:Chaperone-dependent folding and activation of ribosome-bound nascent rhodanese. Analysis by fluorescence. 796 42


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