Suppression of the Escherichia coli dnaA46 mutation by amplification of the groES and groEL genes

Summary A hybrid phage (Sda1), containing an 8.1 kb EcoRI DNA fragment from the Escherichia coli chromosome, was selected on the basis of its ability to suppress bacterial thermosensitivity caused by the dnaA46 mutation. We have shown that this suppression is due to a recA ⁺-dependent amplification of the 8.1 kb fragment; consistent with this observation, cloning of the 8.1 kb fragment into a high copy number plasmid (pBR325) leads also to suppression of dnaA46. In the suppressed strains growing at high temperature, bidirectional replication starts in or near the oriC region and requires the presence of the DnaA polypeptide. These findings suggest that the overproduction of a gene product(s), encoded by the cloned 8.1 kb fragment, can restore dnaA-dependent initiation of replication at high temperature in the oriC region. Genetic mapping shows that the groES (mopB) and groEL (mopA) genes are located on the 8.1 kb suppressor fragment. Further analysis, including in vitro mutagenesis and subcloning, demonstrates that the amplification of the groES and groEL genes is both necessary and sufficient to suppress the temperature sensitive phenotype of the dnaA46 mutation.     

GroES and GroEL are essential chaperones for refolding of recombinant human phospholipid scramblase 1 in <Emphasis Type="Italic">E. coli</Emphasis>

Human phospholipid scramblase 1(hPLSCR1), when expressed in E. coli (BL-21 DE3), forms inclusion bodies that are functionally inactive. We studied the effects of various stress inducing agents and chaperones on soluble expression of hPLSCR1 in E. coli (BL-21 DE3). Addition of 3% (v/v) ethanol before induction and decreasing the post-induction temperature to 15°C increased the solubility of hPLSCR1 to ~10 and ~15% respectively. Presence of groES-groEL complex solubilized the hPLSCR1 to ~30% of the total hPLSCR1. Absence of groES-groEL did not improve the solubility of hPLSCR1 suggesting that groES and groEL are the essential chaperones for the correct folding of hPLSCR1 when over-expressed in E. coli.     

Multiple Gene Duplication and Rapid Evolution in the groEL Gene: Functional Implications

The chaperonins, GroEL and GroES, are present ubiquitously and provide a paradigm in the understanding of assisted protein folding. Due to its essentiality of function, GroEL exhibits high sequence conservation across species. Complete genome sequencing has shown the occurrence of duplicate or multiple copies of groEL genes in bacteria such as Mycobacterium tuberculosis and Corynebacterium glutamicum. Monophyly of each bacterial clade in the phylogenetic tree generated for the GroEL protein suggests a lineage-specific duplication. The duplicated groEL gene in Actinobacteria is not accompanied by the operonic groES despite the presence of upstream regulatory elements. Our analysis suggests that in these bacteria the duplicated groEL genes have undergone rapid evolution and divergence to function in a GroES-independent manner. Evaluation of multiple sequence alignment demonstrates that the duplicated genes have acquired mutations at functionally significant positions including those involved in substrate binding, ATP binding, and GroES binding and those involved in inter-ring and intra-ring interactions. We propose that the duplicate groEL genes in different bacterial clades have evolved independently to meet specific requirements of each clade. We also propose that the groEL gene, although essential and conserved, accumulates nonconservative substitutions to exhibit structural and functional variations. Electronic Supplementary Material Electronic Supplementary material is available for this article at and accessible for authorised users. [Reviewing Editor: Dr. Debashish Bhattacharya]     

Extracellular Production of Yeast Protease

The groEL gene of the alkaliphilic Bacillus sp. strain C-125 was cloned in Escherichia coli and sequenced. The groEL gene encoded a polypeptide of 544 amino acids and was preceded by the incomplete groES gene, lacking its 5′-end. The sequence of the derived amino acids was 87.5% identical to that of B. subtilis, 85.4% identical to that of B. stearothemophilus, and 60.9% identical to that of E. coli. The GroEL protein was expressed in E. coli. Purified GroEL protected yeast a-glucosidase from irreversible aggregation at a high temperature and the addition of Mg-ATP was essential for reactivation of the a-glucosidase. The addition of E. coli GroES increased recovery of the enzyme activity, indicating that C-125 GroEL could function in coordination with E. coli GroES.     

Non‐housekeeping,non‐essential GroEL (chaperonin) has acquired novel structure and function beneficial under stress in cyanobacteria

GroELs which are prokaryotic members of the chaperonin (Cpn)/Hsp60 family are molecular chaperones of which Escherichia coli GroEL is a model for subsequent research. The majority of bacterial species including E. coli and Bacillus subtilis have only one essential groEL gene that forms an operon with the co‐chaperone groES gene. In contrast to these model bacteria, two or three groEL genes exist in cyanobacterial genomes. One of them, groEL2, does not form an operon with the groES gene, whereas the other(s) does. In the case of cyanobacteria containing two GroEL homologs, one of the GroELs, GroEL1, substitutes for the native GroEL in an E. coli cell, but GroEL2 does not. Unlike the E. coli GroEL, GroEL2 is not essential, but it plays an important role which is not substitutable by GroEL1 under stress. Regulation of expression and biochemical properties of GroEL2 are different/diversified from GroEL1 and E. coli GroEL in many aspects. We postulate that the groEL2 gene has acquired a novel, beneficial function especially under stresses and become preserved by natural selection, with the groEL1 gene retaining the original, house‐keeping function. In this review, we will focus on difference between the two GroELs in cyanobacteria, and divergence of GroEL2 from the E. coli GroEL. We will also compare cyanobacterial GroELs with the chloroplast Cpns (60α and 60β) which are thought to be evolved from the cyanobacterial GroEL1. Chloroplast Cpns appear to follow the different path from cyanobacterial GroELs in the evolution after gene duplication of the corresponding ancestral groEL gene.     

Structure of the dnaA region of the endosymbiont, Buchnera aphidicola, of aphid Schizaphis graminum

Buchnera aphidicola is an intracellular prokaryote (endosymbiont)that lives in the body cavity of the aphid. Phylogenetic studiesindicated that it is closely related to Escherichia coli andmembers of Enterobacteria. The gene order of the region containingthe dnaA gene is well conserved in many bacteria. Seven genesof the endosymbiont of the aphid Schizaphis graminum, gyrB,dnaN, dnaA, rpmH, rnpA, yidD, and 60K, were found to be homologousin sequence and relative location to those of E. coli. We havefurther sequenced the region downstream of the 60K gene to elucidatethe boundary of the conserved region, and found that one moregene, thdF , is conserved. The comparison of gene organizationsof the dnaA region of the related bacteria supported the closephylogenetic relationship of B. aphidicola to E. coli. In addition,we have identified groES and groEL genesnext to the thdF gene.GroEL protein was reported to be expressed at an elevated levelin the endosymbionts of aphids, and is considered to play animportant role in their association with the aphid host. Comparisonof the structure of the groE operon with that of the endosymbiontof the aphid Acyrthosiphon pisum revealed the conservation ofa sequence resembling the E. coli consensus heat shock promoter,and this sequence may be responsible for the high expressionof the groEL gene in aphid endosymbionts.     

PotD protein stimulates biofilm formation by Escherichia coli

In natural environments bacteria often adopt a biofilm-growth mode. PotD is a spermidine/putrescine-binding periplasmic protein belonging to polyamine transport system and we have examined its role during biofilm formation and for planktonic growth in Escherichia coli BL21(DE3) strains that either over-express PotD (PotD+), or under-express it (PotDi) and also in a control strain with vector pET26b(+) (PotD0). The three strains displayed similar growth in planktonic growth-mode, but over expression of PotD protein greatly stimulated the formation of biofilms, while less biofilm formed by strain PotDi in comparison to strain PotD0. The expressions of five genes, recA, sfiA, groEL, groES, and gyrA, were increasingly expressed in PotD+ biofilm cells. Thus, PotD is likely to change the rate of polyamine synthesis, which stimulates the expression of SOS genes and biofilm formation.     

The groEL gene as an additional marker for finer differentiation of ‘Candidatus Phytoplasma asteris'‐related strains

Phytoplasma classification established using 16S ribosomal groups and ‘Candidatus Phytoplasma’ taxon are mainly based on the 16S rDNA properties and do not always provide molecular distinction of the closely related strains such as those in the aster yellows group (16SrI or ‘Candidatus Phytoplasma asteris'‐related strains). Moreover, because of the highly conserved nature of the 16S rRNA gene, and of the not uncommon presence of 16S rDNA interoperon sequence heterogeneity, more variable single copy genes, such as ribosomal protein (rp), secY and tuf, were shown to be suitable for differentiation of closely related phytoplasma strains. Specific amplification of fragments containing phytoplasma groEL allowed studying its variability in 27 ‘Candidatus Phytoplasma asteris'‐related strains belonging to different 16SrI subgroups, of which 11 strains were not studied before and 8 more were not studied on other genes than 16S rDNA. The restriction fragment length polymorphism (RFLP) analyses of the amplified fragments confirmed differentiation among 16SrI‐A, I‐B, I‐C, I‐F and I‐P subgroups, and showed further differentiation in strains assigned to 16SrI‐A, 16SrI‐B and 16SrI‐C subgroups. However, analyses of groEL gene failed to discriminate strains in subgroups 16SrI‐L and 16SrI‐M (described on the basis of 16S rDNA interoperon sequence heterogeneity) from strains in subgroup 16SrI‐B. On the contrary, the 16SrI unclassified strain ca2006/5 from carrot (showing interoperon sequence heterogeneity) was differentiable on both rp and groEL genes from the strains in subgroup 16SrI‐B. These results indicate that interoperon sequence heterogeneity of strains AY2192, PRIVA (16SrI‐L), AVUT (16SrI‐M) and ca2006/5 resulted in multigenic changes – one evolutionary step further – only in the latter case. Phylogenetic analyses carried out on groEL are in agreement with 16Sr, rp and secY based phylogenies, and confirmed the differentiation obtained by RFLP analyses on groEL amplicons.     

Sequence Polymorphism of GroEL Gene in Natural Population of Bacillus and Brevibacillus spp. that Showed Variation in Thermal Tolerance Capacity and mRNA Expression

GroEL, a class I chaperonin, plays an important role in the thermal adaptation of the cell and helps to maintain the viability of the cell under heat shock condition. Function of groEL in vivo depends on the maintenance of proper structure of the protein which in turn depends on the nucleotide and amino acid sequence of the gene. In this study, we investigated the changes in nucleotide and amino acid sequences of the partial groEL gene that may affect the thermotolerance capacity as well as mRNA expression of bacterial isolates. Sequences among the same species having differences in the amino acid level were identified as different alleles. The effect of allelic variation on the groEL gene expression was analyzed by comparison and relative quantification in each allele under thermal shock condition by RT-PCR. Evaluation of K _a/K _s ratio among the strains of same species showed that the groEL gene of all the species had undergone similar functional constrain during evolution. The strains showing similar thermotolerance capacity was found to carry same allele of groEL gene. The isolates carrying allele having amino acid substitution inside the highly ATP/ADP or Mg²⁺-binding region could not tolerate thermal stress and showed lower expression of the groEL gene. Our results indicate that during evolution of these bacterial species the groEL gene has undergone the process of natural selection, and the isolates have evolved with the groEL allelic sequences that help them to withstand the thermal stress during their interaction with the environment.     

Cloning and functional analysis of molecular chaperone genes from Bacillus stearothermophilus SIC1

Genes homologous to groES and groEL, which are recognized as molecular chaperone genes, from Bacillus stearothermophilus SIC1 were cloned and sequenced. By addition of GroES, GroEL and ATP in vitro, remaning activity of the alcohol dehydrogenase from Saccharomyces cerevisiae after heat treatment at 50°C for 6 min was improved from 55% to 90%. Furthermore, even though inclusion bodies were formed when a single chain Fv(sFv) was expressed in E. coli cells, during in vivo coexpression with molecular chaperone, a significant amount of the antibody protein could be recovered from the soluble fraction.     

The orotidine-5′-phosphate decarboxylase gene (URA3) of a methylotrophic yeast,Candida boidinii: Nucleotide sequence and its expression in Escherichia coli

Previously, we cloned a DNA fragment from a genomic library of a methylotrophic yeast, Candida boidinii. This 3.5-kb SalI fragment was capable of complementing the pyrF mutation in Escherichia coli. In this report, we identify this fragment as that harboring an orotidine-5′-phosphate decarboxylase (ODCase) gene (C. boidinii URA3); we have also determined the complete DNA sequence of the C. boidinii URA3 gene. The deduced amino acid sequence of the gene showed homology to ODCase genes from other sources, and it could complement the ura3 mutation of Saccharomyces cerevisiae. The DNA fragment, which harbored the C. boidinii URA3 gene, was able to express ODCase activity in the E. coli pyrF mutant strain without an exogenous E. coli promoter. From nested-deletion analysis, both the 5′-(136 bp) and 3′-(58 bp) flanking regions were shown to be required for pyrF-complementation of the E. coli mutant. The 5′-flanking region had sequences homologous to E. coli promoter consensus sequences (−35 and −10 regions) which may function in the expression of the C. boidinii URA3 gene in E. coli.     

Sequence analysis and functional studies of a chromosomal region of alkaliphilic Bacillus firmus OF4 encoding an ABC-type transporter with similarity of sequence and Na+ exclusion capacity to the Bacillus subtilis NatAB transporter

A 14.1-kb DNA fragment was cloned from a lambda library containing inserts of DNA from alkaliphilic Bacillus firmus OF4 on the basis of its hybridization to a probe from a previously sequenced alkaliphile homolog of the natA gene from Bacillus subtilis. Sequence analysis of the entire fragment revealed that, as in B. subtilis, the natA gene was part of a putative gene locus encoding an ABC-type transporter. In the alkaliphile, the transporter involved three genes, designated natCAB, that are part of a larger operon of unknown function. This is in contrast to the two-gene natAB operon and to another homolog from B. subtilis, the yhaQP genes. Like natAB, however, the alkaliphile natCAB catalyzes Na⁺ extrusion as assessed in a mutant of Escherichia coli that is deficient in Na⁺ extrusion. The full 14.1-kb fragment of alkaliphile DNA sequenced in this study contained several probable operons as well as likely monocistronic units. Among the 17 predicted ORFs apart from natCAB were acsA, a homolog of a halobacterial gene encoding acetylCoA synthetase; sspA, a homolog of a small acid-soluble spore protein; and malK, an ATP-binding component that was unaccompanied by candidates for other mal transport genes but was able to complement a malK-deficient mutant of E. coli. No strong candidates for genes encoding a secondary Na⁺/H⁺ antiporter were found in the fragment, either from the sequence analysis or from analyses of complementation of E. coli mutants by subclones of the 14.1-kb piece. There were a total of 12 ORFs whose closest and significant homologs were genes from B. subtilis; of these, one-third were in apparently different contexts, as assessed by the sequence of the neighboring genes, than the B. subtilis homologs. Received: August 30, 1998 / Accepted: November 13, 1998     

A Novel Synthesis of (±)-Serricornin 4,6-Dimethyl-7-hydroxy-nonan-3-one The Sex Pheromone of Cigarette Beetle (Lasioderma serricorne F.)

A 5.5-kb HindIII fragment of Synechocystis PCC6803 containing a liverwort (ORF316) homolog encoding a putative zinc finger protein was cloned. Nucleotide sequence analysis showed that the homology of the amino acid sequence deduced from the ORF326 of Synechocystis PCC6803 with the counterparts of a liverwort and tobacco was 50% and 46%, respectively. Synechocystis ORF326 also showed 38% homology with the dedB gene in Escherichia coli. The gene organization of the region in these species of organisms was quite different. This suggests that the Synechocystis ORF326 and liverwort ORF316 genes may be related to a common regulatory gene, but not photosynthetic gene characteristic to chloroplasts.     

Molecular characterization of GroES and GroEL homologues from Clostridium botulinum

We report novel findings of significant amounts of 60- and 10-kDa proteins on SDS-PAGE in a culture supernatant of the Clostridium botulinum type D strain 4947 (D-4947). The N-terminal amino acid sequences of the purified proteins were closely related to those of other bacterial GroEL and GroES proteins, and both positively cross-reacted with Escherichia coli GroEL and GroES antibodies. Native GroEL homologue as an oligomeric complex is a weak ATPase whose activity is inhibited by the presence of GroES homologue. The 2634-bp groESL operon of D-4947 was isolated by PCR and sequenced. The sequence included two complete open reading frames (282 and 1629 bp), which were homologous to the groES and groEL gene family of bacterial proteins. Southern and Northern blot analyses indicate that the groESL operon is encoded on the genomic DNA of D-4947 as a single copy, and not on that of its specific toxin-converting phage.     

Phylogenetic Analysis of Bacillus subtilis Strains Applicable to Natto (Fermented Soybean) Production

Spore-forming Bacillus strains that produce extracellular poly-γ-glutamic acid were screened for their application to natto (fermented soybean food) fermentation. Among the 424 strains, including Bacillus subtilis and B. amyloliquefaciens, which we isolated from rice straw, 59 were capable of fermenting natto. Biotin auxotrophism was tightly linked to natto fermentation. A multilocus nucleotide sequence of six genes (rpoB, purH, gyrA, groEL, polC, and 16S rRNA) was used for phylogenetic analysis, and amplified fragment length polymorphism (AFLP) analysis was also conducted on the natto-fermenting strains. The ability to ferment natto was inferred from the two principal components of the AFLP banding pattern, and natto-fermenting strains formed a tight cluster within the B. subtilis subsp. subtilis group.