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Query: EC:2.3.3.1 (
citrate synthase
)
4,488
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
The mechanism by which correctly folded proteins are recovered from stable complexes with groEL is not well understood. Certain target proteins require ATP and groES, while others seemingly dispense with the cochaperonin. Here, we examine the
chaperonin
-assisted folding of ribulose-1,5-bisphosphate carboxylase, malate dehydrogenase, and
citrate synthase
, three proteins that are believed to require both
chaperonin
components for successful reactivation. Surprisingly, in all cases, the need for groES depended on the folding environment. Under "non-permissive" conditions, where unassisted spontaneous folding could not occur, reactivation to the native state required the complete
chaperonin
system (e.g. groEL, groES, and MgATP). However, under "permissive" conditions where spontaneous folding could occur groES was no longer mandatory. Instead, upon the addition of ATP alone, all three target proteins could be released from groEL, in a form that was capable of reaching the native state. In the permissive setting, groES merely accelerated the rate of the ATP-dependent release process. The results suggest that the incompletely folded protein species that are released from groEL, in the absence of groES, are not necessarily committed to the native state. Similar to the unassisted folding reaction, they still partition between productive and unproductive folding pathways in an environment-dependent manner. It follows that the mechanistic contribution of the co-chaperonin, groES, and its physiological significance in cellular protein folding, could be entirely missed in a permissive in vitro environment.
...
PMID:On the role of groES in the chaperonin-assisted folding reaction. Three case studies. 790 92
Chaperonin-facilitated folding of proteins involves two partial reactions. The first partial reaction, the formation of stable binary complexes between
chaperonin
-60 and non-native states of the target protein, is common to the
chaperonin
-facilitated folding of all target proteins investigated to date. The structural basis for this interaction is not presently understood. The second partial reaction, the dissociation of the target protein in a form committed to the native state, appears to proceed by a variety of mechanisms, dependent upon the nature of the target protein in question. Those target proteins (e.g. rubisco, rhodanese,
citrate synthase
) which require the presence of
chaperonin
-10, also appear to require the hydrolysis of ATP to bring about the dissociation of the target protein from
chaperonin
-60. With one exception (pre-beta-lactamase) those target proteins which do not require the presence of
chaperonin
-10 to be released from
chaperonin
-60, also do not require the hydrolysis of ATP, since non-hydrolysable analogues of ATP support the release of the target protein in a state committed to the native state. The question of whether or not
chaperonin
-facilitated folding constitutes a catalysed event is addressed.
...
PMID:Chaperonins and protein folding: unity and disunity of mechanisms. 809 34
A general role for
chaperonin
ring structures in mediating folding of newly translated proteins has been suggested. Here we have directly examined the role of the E. coli
chaperonin
GroEL in the bacterial cytoplasm by production of temperature-sensitive lethal mutations in this essential gene. After shift to nonpermissive temperature, the rate of general translation in the mutant cells was reduced, but, more specifically, a defined group of cytoplasmic proteins--including
citrate synthase
, ketoglutarate dehydrogenase, and polynucleotide phosphorylase--were translated but failed to reach native form. Similarly, a monomeric test protein, maltose-binding protein, devoid of its signal domain, was translated but failed to fold to its native conformation. We conclude that GroEL indeed is a machine at the distal end of the pathway of transfer of genetic information, assisting a large and specific set of newly translated cytoplasmic proteins to reach their native tertiary structures.
...
PMID:Folding in vivo of bacterial cytoplasmic proteins: role of GroEL. 810 2
Ligand-induced conformational changes of GroEL alone and with bound rhodanese,
citrate synthase
, or dihydrofolate reductase were studied by limited proteolysis. Similar digestion patterns of GroEL, with or without bound substrate polypeptide, were obtained in the absence and presence of the
chaperonin
ligands, K+, Mg2+, or ATP. The rates of formation and degradation of the six produced proteolytic fragments were significantly different, however. Strikingly, only with Mg2+/ATP or K+/Mg2+/ATP an additional fragment of approximately 25 kDa was generated during digestion of GroEL alone or with bound rhodanese or dihydrofolate reductase, but not with bound
citrate synthase
. Most of the trypsin-sensitive sites in GroEL were localized in the flexible apical domain, which contains the putative polypeptide-binding region. Our data indicate that subtle structural changes in the trypsin-sensitive regions of GroEL occur as a result of the binding of the
chaperonin
ligands. However, these structural changes are influenced by the GroEL substrate polypeptides.
...
PMID:Ligand-induced conformational changes of GroEL are dependent on the bound substrate polypeptide. 866 87
The heat-shock protein Cpn60 (
chaperonin
, GroEL homologue) from the phototrophic bacterium Rhodobacter capsulatus B10 was purified to homogeneity and biochemically characterized. Native Cpn60 from R. capsulatus was shown to be a tetradecamer of 840 kDa similar to that of homologous chaperones characterized so far. Cpn60 possesses ATPase activity and promotes refolding of chaotropically denatured
citrate synthase
. The groESL operon of R. capsulatus was cloned using a degenerate oligonucleotide and sequenced. Two open reading frames (285 and 1,635 bp) were found; they encode Cpn10 and Cpn60, with corresponding deduced molecular masses of 10.6 and 57.6 kDa. The deduced amino acid sequences coincided perfectly with those of the amino terminus and of three tryptic peptides of purified Cpn60 from R. capsulatus. Strong evidence that R. capsulatus encodes only one copy of the groESL operon was obtained. Primer-extension analysis revealed that the groESL operon is transcribed by a -35/-10-type promoter, and that transcription was initiated from the same positions before and after heat-shock under both chemotrophic and phototrophic conditions. The major initiation site is immediately followed by the inverted repeat structure CIRCE, which has been found upstream of many bacterial heat-shock operons. A second minor transcript starts just after the CIRCE element. Although heat-shock induction of a groEL-lacZ fusion failed because of thermal inactivation of the fusion protein, Western blot analysis revealed a two- to threefold induction of cellular Cpn60 levels 45-75 min after shifting from 28 degrees C to 39 degrees C. Deletion mapping of the groESL promoter identified upstream of the promoter a 19-bp element that enhances groESL transcription eightfold and contains the AT-rich sequence dAAATTTTT, which is found at similar positions in heat-shock operons of other gram-negative bacteria.
...
PMID:Molecular analysis of the Rhodobacter capsulatus chaperonin (groESL) operon: purification and characterization of Cpn60. 870 96
The structure of the Escherichia coli
chaperonin
GroEL has been investigated by tapping-mode atomic force microscopy (AFM) under liquid. High-resolution images can be obtained, which show the up-right position of GroEL adsorbed on mica with the substrate-binding site on top. Because of this orientation, the interaction between GroEL and two substrate proteins,
citrate synthase
from Saccharomyces cerevisiae with a destabilizing Gly-->Ala mutation and RTEM beta-lactamase from Escherichia coli with two Cys-->Ala mutations, could be studied by force spectroscopy under different conditions. The results show that the interaction force decreases in the presence of ATP (but not of ATPgammaS) and that the force is smaller for native-like proteins than for the fully denatured ones. It also demonstrates that the interaction energy with GroEL increases with increasing molecular weight. By measuring the interaction force changes between the
chaperonin
and the two different substrate proteins, we could specifically detect GroEL conformational changes upon nucleotide binding.
...
PMID:Atomic force microscopy detects changes in the interaction forces between GroEL and substrate proteins. 963 79
A gene encoding 544 amino acids for a subunit of group II
chaperonin
(thermosome) was cloned from a thermophilic methanogen, Methanococcus thermolithotrophicus. The deduced amino acid sequence showed 66.5, 56.1, and 20.1% similarities to those of Methanopyrus kandleri and Thermoplasma acidophilum and group I
chaperonin
of Escherichia coli, respectively. We call this
chaperonin
MTTS (M. thermolithotrophicus thermosome). The MTTS gene was expressed in E. coli. The purified recombinant MTTS seemed to be monomeric on gel filtration in the absence of Mg2+ and ATP. The monomer assembled to an oligomer (complex) in the presence of 50 mM MgCl2, 0.25 mM ATP, and 0.3 M (NH4)2SO4. It was eluted immediately before the elution volume of E. coli GroEL tetradecamer on gel filtration with a TSKgel G3000SWXL column. This reconstructed MTTS complex showed the cylindrical structure with two stacked rings in electron microscopy. The MTTS complex formed filamentous structures in the presence of Mg2+ and ATP at the protein concentration above 3.0 mg/ml. This filament formation was reversible. The MTTS filament was dissociated to the complex by dilution to the protein concentration of 0.2 mg/ml, even in the presence of Mg2+ and ATP. The MTTS complex exhibited weak ATPase activity with the hydrolysis rate of 74 mol of ATP hydrolysis/mol of MTTS complex/min at 70 degreesC. The MTTS complex promoted the refolding of chemically denatured thermophilic archaeal
citrate synthase
and glucose dehydrogenase at 50 degreesC in an ATP-dependent fashion. The analysis of nucleotide specificity of chaperone activity of MTTS suggested that it was coupled with hydrolysis of ATP, CTP, or UTP.
...
PMID:Group II chaperonin in a thermophilic methanogen, Methanococcus thermolithotrophicus. Chaperone activity and filament-forming ability. 977 67
The archaeon Methanopyrus kandleri is the most thermophilic methanogen presently known. It contains a
chaperonin
(thermosome) which represents a 951 kDa homo-hexadecameric protein complex with NH4+-dependent ATPase activity. Since its synthesis is not increased upon heat shock, we set out to test its chaperone function. In order to obtain the
chaperonin
in amounts sufficient for functional investigations, the gene encoding the 60 kDa subunit was expressed in E. coili BL21 (DE3) cells. Purification yielded soluble, high-molecular-mass double-ring complexes, indistinguishable from the natural thermosome. In order to study the functional properties of the recombinant protein complex, pig
citrate synthase
, yeast alcohol dehydrogenase, yeast alpha-glucosidase, bovine insulin, and Thermotoga phosphoglycerate kinase were used as model substrates. The results demonstrate that the recombinant M. kandleri thermosome possesses a chaperone-like activity in vitro, inhibiting aggregation as the major off-pathway-reaction during thermal unfolding and refolding of proteins after chemical denaturation. However, the
chaperonin
only forms dead-end complexes with its non-native substrates, no release is detectable at temperatures between 25 and 60 degrees C.
...
PMID:The recombinant thermosome from the hyperthermophilic archaeon Methanopyrus kandleri: in vitro analysis of its chaperone activity. 1006 37
Chloroplast
chaperonin
20 (Cpn20) in higher plants is a functional homologue of the Escherichia coli GroES, which is a critical regulator of
chaperonin
-mediated protein folding. The cDNA for a Cpn20 homologue of Arabidopsis thaliana was isolated. It was 958 bp long, encoding a protein of 253 amino acids. The protein was composed of an N-terminal chloroplast transit peptide, and the predicted mature region comprised two distinct GroES domains that showed 42% amino acid identity to each other. The isolated cDNA was constitutively expressed in transgenic tobacco. Immunogold labelling showed that Cpn20 is accumulated in chloroplasts of transgenic tobacco. A Northern blot analysis revealed that mRNA for the chloroplast Cpn20 is abundant in leaves and is increased by heat treatment. To examine the oligomeric structure of Cpn20, a histidine-tagged construct lacking the transit peptide was expressed in E. coli and purified by affinity chromatography. Gel-filtration and cross-linking analyses showed that the expressed products formed a tetramer. The expressed products could substitute for GroES to assist the refolding of
citrate synthase
under non-permissive conditions. The analysis on the subunit stoichiometry of the GroEL-Cpn20 complex also revealed that the functional complex is composed of a GroEL tetradecamer and a Cpn20 tetramer.
...
PMID:Chloroplast Cpn20 forms a tetrameric structure in Arabidopsis thaliana. 1020 3
Bacteriophage T4-encoded Gp31 is a functional ortholog of the Escherichia coli GroES cochaperonin protein. Both of these proteins form transient, productive complexes with the GroEL
chaperonin
, required for protein folding and other related functions in the cell. However, Gp31 is specifically required, in conjunction with GroEL, for the correct folding of Gp23, the major capsid protein of T4. To better understand the interaction between GroEL and its cochaperonin cognates, we determined whether the so-called "pseudo-T-even bacteriophages" are dependent on host GroEL function and whether they also encode their own cochaperonin. Here, we report the isolation of an allele-specific mutation of bacteriophage RB49, called epsilon22, which permits growth on the E. coli groEL44 mutant but not on the isogenic wild type host. RB49 epsilon22 was used in marker rescue experiments to identify the corresponding wild type gene, which we have named cocO (cochaperonin cognate). CocO has extremely limited identity to GroES but is 34% identical and 55% similar at the protein sequence level to T4 Gp31, sharing all of the structural features of Gp31 that distinguish it from GroES. CocO can substitute for Gp31 in T4 growth and also suppresses the temperature-sensitive phenotype of the E. coli groES42 mutant. CocO's predicted mobile loop is one residue longer than that of Gp31, with the epsilon22 mutation resulting in a Q36R substitution in this extra residue. Both the CocO wild type and epsilon22 proteins have been purified and shown in vitro to assist GroEL in the refolding of denatured
citrate synthase
.
...
PMID:Pseudo-T-even bacteriophage RB49 encodes CocO, a cochaperonin for GroEL, which can substitute for Escherichia coli's GroES and bacteriophage T4's Gp31. 1110 67
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