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.     

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.     

A Nonconserved Carboxy-Terminal Segment of GroEL Contributes to Reaction Temperature

The role of the C-terminal segment of the GroEL equatorial domain was analyzed. To understand the molecular basis for the different active temperatures of GroEL from three bacteria, we constructed a series of chimeric GroELs combining the C-terminal segment of the equatorial domain from one species with the remainder of GroEL from another. In each case, the foreign C-terminal segment substantially altered the active temperature range of the chimera. Substitution of L524 of Escherichia coli GroEL with the corresponding residue (isoleucine) from psychrophilic GroEL resulted in a GroE with approximately wild-type activity at 25 °C, but also at 10 °C, a temperature at which wild-type E. coli GroE is inactive. In a detailed look at the temperature dependence of the GroELs, normal E. coli GroEL and the L524I mutant became highly active above 14 °C and 12 °C respectively. Similar temperature dependences were observed in a surface plasmon resonance assay of GroES binding. These results suggested that the C-terminal segment of the GroEL equatorial domain has an important role in the temperature dependence of GroEL. Moreover, E. coli acquired the ability to grow at low temperature through the introduction of cold-adapted chimeric or L524I mutant groEL genes.     

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.     

Evidence for Hox Gene Duplication in Rainbow Trout (Oncorhynchus mykiss): A Tetraploid Model Species

We examined the genomic organization of Hox genes in rainbow trout (Oncorhynchus mykiss), a tetraploid teleost derivative species, in order to test models of presumptive genomic duplications during vertebrate evolution. Thirteen putative clusters were localized in the current rainbow trout genetic map; however, analysis of the sequence data suggests the presence of at least 14 Hox clusters. Many duplicated genes appear to have been retained in the genome and share a high percentage of amino acid similarity with one another. We characterized two Hox genes located within the HoxCb cluster that may have been lost independently in other teleost species studied to date. Finally, we identified conserved syntenic blocks between salmonids and human, and provide data supporting two new linkage group homeologies (i.e., RT-3/16, RT-12/29) and three previously described homeologies (RT-2/9, RT-17/22, and RT-27/31) in rainbow trout. Electronic Supplementary Material Electronic Supplementary material is available for this article at and accessible for authorised users. The sequence data for this study have been submitted to GenBank under the following accession numbers: AY567792, AY567793, AY567794, AY567795, AY567796, AY567797, AY567798, AY567799, AY567800, AY567801, AY567802, AY567803, AY567804, AY567805, AY567806, AY567807, AY567808, AY567809, AY567810, AY567812, AY567813, AY567814, AY567815, AY567816, and AY567817. [Reviewing Editor : Dr. Axel Meyer]     

幽门螺杆菌分子伴侣GroEL相互作用蛋白分析

【目的】获得幽门螺杆菌(Helicobacter pylori,HP) GroEL结合蛋白质组构成谱,为进一步探究GroEL及其与相互作用蛋白在HP致病机制中的作用提供新思路。【方法】在构建HP GroEL原核表达重组大肠杆菌(Escherichia coli) BL21(DE3)⁽pET-28a(+)-groEL)基础上,纯化带有His标签的GroEL蛋白,与HP全菌蛋白提取液共孵育后,利用Protein G磁珠和抗His标签抗体免疫沉淀法对复合物进行捕获,然后对复合物中GroEL及其结合的蛋白质进行质谱法鉴定,根据主要功能对其进行分类,并完成蛋白质相互关系网络分析。【结果】对GroEL蛋白捕获成分进行分析,共鉴定出59种可能与GroEL结合的蛋白质,其中包括19种代谢酶类(KatA、GltA和AhpC等参与氧化还原相关酶类7种,PepA、RocF和HtrA等肽酶5种,以及2种参与脂肪代谢酶、2种参与ATP合成酶、2种尿素酶和HP17＿08079蛋白等)、15种外膜蛋白(黏附素BabA、SabA、HapA及其他膜蛋白等)、8种转录翻译相关蛋白(Tuf、RpoBC...     

Identification and immunological characteristics of chaperonin GroEL in <Emphasis Type="Italic">Riemerella anatipestifer</Emphasis>

Riemerella anatipestifer (RA) infections cause major economic losses in the duck industry. In this study, an immunogenic protein, chaperonin GroEL (GroEL), was identified from the outer membrane of RA strain WJ4 by immunoproteomic assay based on matrix-assisted laser desorption/ionization time of flight mass spectrometry. The complete sequence of the encoding gene, chaperonin groEL (groEL) was amplified and determined to be 1,629 base pairs in length. groEL was then cloned into expression vector pGEX-6P-1, and the expression of the recombinant GroEL (rGroEL) in Escherichia coli strain BL21 was confirmed by sodium dodecyl sulfate polyacrylamide gel electrophoresis and Western blotting analysis. Immunization assay showed that ducklings or rabbits immunized with purified rGroEL generated 53- or 160-fold more anti-GroEL antibodies than those with no immunization. Importantly, bactericidal assay showed that rabbit anti-GroEL serum killed 30.0–57.3% of bacteria representing different serotypes, while rabbit anti-bacterin serum killing activity exhibits large serotype-dependent variations between 0.2% and 63.6%. Animal challenge experiment showed that ducklings immunized with rGroEL were 50%, 37.5%, and 37.5% protected from the challenge with RA strains WJ4 (serotype 1), Th4 (serotype 2), and YXb-2 (serotype 10), respectively. In addition, groEL from 34 additional RA strains was amplified by polymerase chain reaction (PCR), and products from nine were sequenced. groEL is highly conserved among RA strains, as the DNA sequence identity was over 97.5% between WJ4 and the nine additional strains. Our results suggest that GroEL may be a good candidate for new RA vaccine development.     

Gene fusion in <Emphasis Type="Italic">Helicobacter pylori</Emphasis>: making the ends meet

Fusion genes have been reported as a means of enabling the development of novel or enhanced functions. In this report, we analyzed fusion genes in the genomes of two Helicobacter pylori strains (26695 and J99) and identified 32 fusion genes that are present as neighbours in one strain (components) and are fused in the second (composite), and vice-versa. The mechanism for each case of gene fusion is explored. 28 out of 32 genes identified as fusion products in this analysis were reported as essential genes in the previously documented transposon mutagenesis of H. pylori strain G27. This observation suggests the potential of the products of fusion genes as putative microbial drug targets. These results underscore the utility of bacterial genomic sequence comparisons for understanding gene evolution and for in silico drug target identification in the post-genomic era. Electronic Supplementary Material Supplementary material is available for this article at and is accessible for authorized users.     

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.     

A New Retroposed Gene in <Emphasis Type="Italic">Drosophila</Emphasis> Heterochromatin Detected by Microarray-Based Comparative Genomic Hybridization

A genomic pattern of new gene origination is often dependent on a genomic method that can efficiently identify a statistically adequate number of recently originated genes. The heterochromatic regions have often been viewed as genomic deserts with low coding potential and thus a low flux of new genes. However, increasing reports revealed unexpected roles of heterochromatic regions in the evolution of genes and genomes. We identified recently retroposed genes that originated in heterochromatic regions in Drosophila, by developing microarray-based comparative genomic hybridization (CGH) with multiple species. This new gene family, named Ifc-2h, originated in the common ancestor of the clade of D. simulans, D. mauritiana, and D. sechellia. The sequence features and phylogenetic distribution indicated that Ifc-2h resulted from the retroposition from its parental gene, Infertile crescent (Ifc), and integrated into heterochromatic region of common ancester of the three sibling species 2 million years ago. Expression analysis revealed that Ifc-2h had developed a new expression pattern by recruiting a putative regulatory element from its target sequence. The distribution of indel variation in Ifc-2h of D. simulans and D. mauritiana revealed a significant sequence constraint, suggesting that the Ifc-2h gene may be functional. These analyses cast fresh insight into the evolution of heterochromatin and the origin of its coding regions. Electronic Supplementary Material Electronic Supplementary material is available for this article at and accessible for authorised users. [Reviewing Editor: Dr. Martin Kreitman]     

Effect of gamma radiation on heat shock protein expression of four foodborne pathogens

Aims: The effects of gamma radiation on three heat shock proteins (Hsps) (GroEL, DnaK and GroES) synthesis in two Gram-negative (Escherichia coli and Salmonella serotype Typhimurium) and two Gram-positive (Staphylococcus aureus and Listeria monocytogenes) bacteria were investigated. Methods and Results: The bacterial strains were treated with three radiation doses to induce cell damage, to obtain a viable but nonculturable state, and to cause cell death. Western blot analysis and quantification of Hsps in bacteria were performed immediately after irradiation treatment. In the four foodborne pathogens, GroEL was strongly induced by gamma rays in a dose-dependent manner, confirming the involvement of this protein in the cellular response to the stress generated by ionizing radiation. In addition, it was found that E. coli exposed to gamma radiation showed a significantly induction of DnaK and GroES proteins when compared with nonirradiated bacteria, whereas a GroES slight induction and a DnaK inhibition were observed in Salm. Typhimurium. Conclusions: The gamma rays influence the synthesis of Hsps in foodborne pathogen in a way that critically depends on the radiation dose. Significance and Impact of the Study: The study of stress response to several radiation doses was undertaken to elucidate how bacteria can survive in harsh conditions and cope with gamma radiation used to control foodborne pathogens and to characterize their adaptative response to this treatment.     

Role of the amino terminal domain in GroES oligomerization

Digestions of the GroES oligomer with trypsin, chymotrypsin and Glu-C protease from Staphylococcus aureus V8 (V8) have helped to locate three regions in the GroES sequence that are sensitive to limited proteolysis and have provided information of the GroES domains involved in monomer-monomer and GroEL interaction. The removal of the first 20 or 27 amino acids of the N-terminal region of each GroES monomer by trypsin or chymotrypsin respectively, abolish the oligomerization of the GroES complex and its binding to GroEL. The V8-treatment of GroES promotes the breakage of the peptide bond between Glu₁₈ and Thr₁₉ but not the liberation of the N-terminal fragment from the GroES oligomer, which is capable of forming with GroEL a complex active in protein folding. It is deduced from these results that the N-terminal region of the GroES monomer is involved in monomer-monomer interaction, providing experimental evidence that relates some biochemical properties of GroES with its three-dimensional structure at atomic resolution.     

A newly synthesized protein interacts with GroES on the surface of chaperonin GroEL.

To facilitate folding and assembly of different proteins, chaperonin GroEL requires the presence of its helper protein GroES. Using a photochemical cross-linking approach, we show that GroES and newly synthesized pre-beta-lactamase (pre-beta lac) contact with each other only within the ternary complex with GroEL. Possibly owing to this contact GroES is able to directly influence the pre-beta lac/GroEL interaction. Furthermore, the cross-linking of pre-beta lac to GroES suggests that the binding of the protein ligands to GroEL occurs near the GroES binding site, known to be in the central hole space of GroEL.     

Dual function of protein confinement in chaperonin-assisted protein folding.

The GroEL/GroES chaperonin system mediates the folding of a range of newly synthesized polypeptides in the bacterial cytosol. Using a rapid biotin-streptavidin-based inhibition of chaperonin function, we show that the cage formed by GroEL and its cofactor GroES can have a dual role in promoting folding. First, enclosure of nonnative protein in the GroEL:GroES complex is essential for folding to proceed unimpaired by aggregation. Second, folding inside the cage can be significantly faster than folding in free solution, independently of ATP-driven cycles of GroES binding and release. This suggests that confinement of unfolded protein in the narrow hydrophilic space of the chaperonin cage smoothes the energy landscape for the folding of some proteins, increasing the flux of folding intermediates toward the native state.     

Differential regulation of groESL operon expression in response to heat and light in Anabaena

The HrcA protein is known to bind the cis-element CIRCE and repress expression of hsp60 in certain bacteria. However, recent data from cyanobacteria have seriously questioned the HrcA/CIRCE interaction paradigm. A hrcA null mutant showed constitutive expression of Hsp60 proteins [GroEL/Cpn60(GroEL2)], and an unexpected further increase in GroEL during temperature upshift, suggesting involvement of regulatory mechanisms other than HrcA in groESL expression in Anabaena. The negative regulation of both hsp60 genes [groEL and cpn60 (groEL2)] at CIRCE element was established by: (1) constitutive expression of Green Fluorescent Protein gene, tagged to Anabaena hsp60 promoters, in E. coli, and its repression upon co-expression of Anabaena HrcA and (2) specific binding of Anabaena HrcA to the CIRCE element. Deletion analysis of other cis-elements further distinguished (a) a photo-regulation by the K-box and (b) thermoregulation from a novel H-box, over and above the negative regulation by HrcA at CIRCE.     

Horizontal Gene Transfer in Aminoacyl-tRNA Synthetases Including Leucine-Specific Subtypes

Aminoacyl-tRNA synthetases catalyze a fundamental reaction for the flow of genetic information from RNA to protein. Their presence in all organisms known today highlights their important role in the early evolution of life. We investigated the evolutionary history of aminoacyl-tRNA synthetases on the basis of sequence data from more than 200 Archaea, Bacteria, and Eukaryota. Phylogenetic profiles are in agreement with previous observations that many genes for aminoacyl-tRNA synthetases were transferred horizontally between species from all domains of life. We extended these findings by a detailed analysis of the history of leucyl-tRNA synthetases. Thereby, we identified a previously undetected case of horizontal gene transfer from Bacteria to Archaea based on phylogenetic profiles, trees, and networks. This means that, finally, the last subfamily of aminoacyl-tRNA synthetases has lost its exceptional position as the sole subfamily that is devoid of horizontal gene transfer. Furthermore, the leucyl-tRNA synthetase phylogenetic tree suggests a dichotomy of the archaeal/eukaryotic-cytosolic and bacterial/eukaryotic-mitochondrial proteins. We argue that the traditional division of life into Prokaryota (non-chimeric) and Eukaryota (chimeric) is favorable compared to Woese’s trichotomy into Archaea/Bacteria/Eukaryota. Electronic Supplementary Material Electronic Supplementary material is available for this article at and accessible for authorised users. [Reviewing Editor: Dr. Yves Van de Peer]     

The disordered mobile loop of GroES folds into a defined beta-hairpin upon binding GroEL

The GroES mobile loop is a stretch of approximately 16 amino acids that exhibits a high degree of flexible disorder in the free protein. This loop is responsible for the interaction between GroES and GroEL, and it undergoes a folding transition upon binding to GroEL. Results derived from a combination of transferred nuclear Overhauser effect NMR experiments and molecular dynamics simulations indicate that the mobile loop adopts a beta-hairpin structure with a Type I, G1 Bulge turn. This structure is distinct from the conformation of the loop in the co-crystal of GroES with GroEL-ADP but identical to the conformation of the bacteriophage-panned "strongly binding peptide" in the co-crystal with GroEL. Analysis of sequence conservation suggests that sequences of the mobile loop and strongly binding peptide were selected for the ability to adopt this hairpin conformation.     

Duplicate Gene Evolution Toward Multiple Fates at the <Emphasis Type="Italic">Drosophila melanogaster HIP</Emphasis>/<Emphasis Type="Italic">HIP-Replacement</Emphasis> Locus

Hsc/Hsp70-interacting protein (HIP) is a rapidly evolving Hsp70 cofactor. Analyses of multiple Drosophila species indicate that the HIP gene is duplicated only in D. melanogaster. The HIP region, in fact, contains seven distinctly evolving duplicated genes. The regional duplication occurred in two steps, fixed rapidly, and illustrates multiple modes of duplicate gene evolution. HIP and its duplicate HIP-R are adaptively evolving in a manner unique to the region: they exhibit elevated divergence from other drosophilids and low polymorphism within D. melanogaster. HIP and HIP-R are virtually identical, share polymorphisms, and are subject to gene conversion. In contrast, two other duplicate genes in the region, CG33221 and GP-CG32779, are pseudogenes, and the chimeric gene Crg1 is subject to balancing selection. HIP and HIP-R are evolving rapidly and adaptively; however, positive selection is not sufficient to explain the molecular evolution of the region as a whole. Electronic supplementary material  The online version of this article (doi:) contains supplementary material, which is available to authorized users.