EC:2.3.3.1 - FACTA Search

Gene/Protein Disease Symptom Drug Enzyme Compound
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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)

Tuberculosis continues to be a major disease threatening millions of lives worldwide. Several antigens of Mycobacterium tuberculosis, identified by monoclonal antibodies, have been cloned and are being exploited in the development of improved vaccines and diagnostic reagents. We have expressed and purified the 16-kDa antigen, an immunodominant antigen with serodiagnostic value, which has been previously cloned and shown to share low sequence homology with the alpha-crystallin-related small heat shock protein family. Sedimentation equilibrium analytical ultracentrifugation and dynamic light scattering demonstrate the formation of a specific oligomer, 149 +/- 8 kDa, consisting of approximately nine monomers. In 4 M urea, a smaller oligomer of 47 +/- 6 kDa (or trimer) is produced. Analysis by electron cryomicroscopy reveals a triangular shaped oligomeric structure arising from the presence of three subparticles or globules. Taken together, the data suggest an antigen complex structure of a trimer of trimers. This antigen, independent of ATP addition, effectively suppresses the thermal aggregation of citrate synthase at 40 degrees C, indicating that it can function as a molecular chaperone in vitro. A complex between the antigen and heat-denatured citrate synthase can be detected and isolated using high performance liquid chromatography. We propose to rename the 16-kDa antigen Hsp16.3 to be consistent with other members of the small heat shock protein family.
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PMID:Mycobacterium tuberculosis 16-kDa antigen (Hsp16.3) functions as an oligomeric structure in vitro to suppress thermal aggregation. 863 60

Cytokines exert autocrine and paracrine effects on the heart, some of which may be mediated by inducible nitric oxide synthase (i-NOS) expression. We studied the effects of cytokine-mediated NO synthesis on cell injury in the presence of deoxyglucose (DOG) and cyanide (CV)(20 mM DOG and 2 mM CN) for up to 3 hours and during recovery (18 hours). The influence of heat shock protein-70 on the extent of myocyte damage was also assessed. IL-1 beta and gamma-IFN act synergistically to enhance NO synthesis by cardiac myocytes. When these cytokines are present, the rate of ATP depletion after DOG and CN is significantly greater than in their absence. When IL-1 beta and gamma-IFN are added with the NOS inhibitor, L-monomethyl-L-arginine (L-NMMA), or when a cytokine that does not produce NO (TNF-alpha) is present, the rate of ATP depletion is no different from the rate seen with DOG and CN alone. After recovery for 18 hours, myocytes that were exposed to IL-1 beta and gamma-IFN release more lactic dehydrogenase and have significantly lower levels of ATP. L-NMMA decreases lactic dehydrogenase release and maintains ATP at levels similar to metabolically inhibited cells in the absence of these cytokines. Consistent with the decreased recovery in ATP with cells incubated with DOG and CN plus IL-1 beta and gamma-IFN is a decrease in cytochrome oxidase activity. Decreases in cellular ATP correspond to increased levels of heat shock protein-70 measured in myocytes after 18 hours of recovery after metabolic inhibition in the presence of IL-1 beta and gamma-IFN. In contrast, prior induction of heat shock protein-70 reduces the rate of ATP depletion in myocytes treated with DOG and CN and maintains ATP at levels that are significantly higher than those seen in non-heat-shocked cells. Recovery of cells exposed to heat shock is also greater, as seen by decreased lactic dehydrogenase and citrate synthase release. The heat-shocked myocytes contain significantly more glycogen than the cells that were not heat shocked. The increased cellular glycogen is likely responsible for the greater lactate production and slower rates of ATP depletion in the heat-shocked, metabolically inhibited cells. Cell survival under conditions of metabolic inhibition is closely related to cellular ATP preservation.
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PMID:Response of the neonatal rat cardiomyocyte in culture to energy depletion: effects of cytokines, nitric oxide, and heat shock proteins. 897 76

The small heat shock protein (smHSP) and alpha-crystallin genes encode a family of 12-43-kDa proteins which assemble into large multimeric structures, function as chaperones by preventing protein aggregation, and contain a conserved region termed the alpha-crystallin domain. Here we report on the structural and functional characterization of Caenorhabditis elegans HSP16-2, a 16-kDa smHSP produced only under stress conditions. A combination of sedimentation velocity, size exclusion chromatography, and cross-linking analyses on wild-type HSP16-2 and five derivatives demonstrate that the N-terminal domain but not most of the the C-terminal extension which follows the alpha-crystallin domain is essential for the oligomerization of the smHSP into high molecular weight complexes. The N terminus of HSP16-2 is found to be buried within complexes which can accommodate at least an additional 4-kDa of heterologous sequence per subunit. Studies on the interaction of HSP16-2 with fluorescently-labeled and radiolabeled actin and tubulin reveal that this smHSP possesses a high affinity for unfolded intermediates which form early on the aggregation pathway, but has no apparent substrate specificity. Furthermore, both wild-type and C-terminally-truncated HSP16-2 can function as molecular chaperones by suppressing the thermally-induced aggregation of citrate synthase. Taken together, our data on HSP16-2 and a unique 12.6-kDa smHSP we have recently characterized demonstrate that multimerization is a prerequisite for the interaction of smHSPs with unfolded protein as well as for chaperone activity.
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PMID:Structure-function studies on small heat shock protein oligomeric assembly and interaction with unfolded polypeptides. 930 34

We report direct experimental evidence that human alphaB-crystallin, a member of the small heat shock protein family, actively participates in the refolding of citrate synthase (CS) in vitro. In the presence of 3.5 mM ATP, CS reactivation by alphaB-crystallin was enhanced approximately twofold. Similarly, 3.5 mM ATP enhanced the chaperone activity of alphaB-crystallin on the unfolding and aggregation of CS at 45 degrees C. Consistent with these findings, cell viability at 50 degrees C was improved nearly five orders of magnitude in Escherichia coli expressing alphaB-crystallin. SDS/PAGE analysis of cell lysates suggested that alphaB-crystallin protects cells against physiological stress in vivo by maintaining cytosolic proteins in their native and functional conformations. This report confirms the action of alphaB-crystallin as a molecular chaperone both in vitro and in vivo and describes the enhancement of alphaB-crystallin chaperone functions by ATP.
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PMID:ATP-enhanced molecular chaperone functions of the small heat shock protein human alphaB crystallin. 944 75

Endurance exercise training increases the oxidative capacity of skeletal muscles, reflecting the induction of genes encoding enzymes of intermediary metabolism. To test the hypothesis that changes in gene expression may be triggered specifically during recovery from contractile activity, we quantified c-fos, alpha B-crystallin, 70-kDa heat shock protein (hsp70), myoglobin, and citrate synthase RNA in rabbit tibialis anterior muscle during recovery from intermittent (8 h/day), low-frequency (10 Hz) motor nerve stimulation. Recovery from a single 8-h bout of stimulation was characterized by large (> 10-fold) transient increases in c-fos, alpha B-crystallin, and hsp70 mRNA. Similar changes were noted during recovery after 7 or 14 days of stimulation (8 h/day). Myoglobin and citrate synthase mRNA were also induced during recovery, but the changes were of lesser magnitude (2- to 2.5-fold) and were observed only following repeated bouts of muscle activity (7th or 14th day) that promoted sustained (> 24 h) increases in these transcripts. These findings indicate that recovery from exercise is associated with specific transient changes in the expression of immediate early and stress protein genes, suggesting that the products of these genes may have specific roles in the remodeling process evoked by repeated bouts of contractile activity.
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PMID:Transient regulation of c-fos, alpha B-crystallin, and hsp70 in muscle during recovery from contractile activity. 948 22

The murine small heat shock protein Hsp25 carries a single cysteine residue in position 141 of its amino acid sequence. Interestingly, Hsp25 can exist within the cell as covalently bound dimer which is linked by an intermolecular disulfide bond between two monomers. Oxidative stress caused by treatment of the cells with diamide, arsenite, or hydrogen peroxide leads to an increase in Hsp25-dimerisation which can be blocked by simultaneous treatment with reducing agents. Recombinant Hsp25 was prepared in an oxidized dimeric (oxHsp25) and reduced monomeric (redHsp25) from. The two species were compared with regard to secondary structure, stability, oligomerization properties and their chaperone activity. It is demonstrated by CD measurements in the far UV region that there are no significant differences in the secondary structure and temperature- or pH-stability of oxHsp25 and redHsp25. However, according to CD measurements in the near UV region an increase in the asymmetry of the microenvironment of aromatic residues in oxHsp25 is observed. Furthermore, an increase in stability of the hydrophobic environment of the tryptophan residues mainly located in the N-terminal domain of the protein against urea denaturation is detected in oxHsp25. Both reduced and oxidized Hsp25 from oligomeric complexes of similar size and stability against detergents and both species prevent thermal aggregation of citrate synthase and assist significantly in oxaloacetic acid-induced refolding of the enzyme. Hence, the overall secondary structure, the degree of oligomerization and the chaperone activity of Hsp25 seem independent of the formation of the intermolecular disulfide bond and only the stability of the hydrophobic N-terminal part of the molecule is influenced by formation of this bound. The obtained data do not exclude the possible involvement of dimerization of this protein in other cellular functions, e.g. in intracellular sulfhydryl-buffering or in the protection of actin filaments from fragmentation upon oxidative stress.
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PMID:The effect of the intersubunit disulfide bond on the structural and functional properties of the small heat shock protein Hsp25. 965 71

The 90-kDa heat shock protein (HSP90) acts as a specific molecular chaperone in the folding and regulates a wide range of associated proteins such as steroid hormone receptors. It is known that HSP90 possesses two different chaperone sites, both in the N- and C-domains, and that the chaperone activity of HSP90 is blocked by binding of geldanamycin (GA) to the N-domain, the same as the ATP-binding site. Here we show that Cisplatin [cis-diamminedichloroplatinum (II), CDDP], an antineoplastic agent, associates with HSP90 and reduces its chaperone activity. In order to analyse the binding proteins, bovine brain cytosols were applied to a CDDP-affinity column and binding proteins were eluted by CDDP. In the elutants, only 90-kDa protein bands were detected on SDS/PAGE, and the protein was cross-reacted with the anti-HSP90 antibody on immunoblotting. No protein bands were detected in the elutants from the control column on SDS/PAGE. These results indicated that CDDP has a high affinity for HSP90. On CD spectrum analysis, the binding of CDDP to HSP90 resulted in a conformational change in the protein. Although HSP90 inhibited the aggregation of citrate synthase as a molecular chaperone in vitro, the activity was suppressed almost completely in the presence of CDDP. Mg/ATP has an influence on the chaperone activity to some extent. The CDDP binding region of HSP90 is near the C-terminal which is quite different from the GA-binding site. Our results suggest that the chaperone activity of HSP90 may be inhibited by the binding of CDDP or GA by different mechanisms.
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PMID:A novel chaperone-activity-reducing mechanism of the 90-kDa molecular chaperone HSP90. 1052 51

HtrA, which has a high molecular mass of about 500 kDa, is a periplasmic heat shock protein whose proteolytic activity is essential for the survival of Escherichia coli at high temperatures. To determine the structural organization of HtrA, we have used electron microscopy and chemical cross-linking analysis. The averaged image of HtrA with end-on orientation revealed a six-membered, ring-shaped structure with a central cavity, and its side-on view showed a two-layered structure. Thus, HtrA behaves as a dodecamer consisting of two stacks of hexameric ring. HtrA can degrade thermally unfolded citrate synthase and malate dehydrogenase but cannot when in their native form. HtrA degraded partially unfolded casein more rapidly upon increasing the incubation temperature. However, it hydrolyzed oxidized insulin B-chain, which is fully unfolded, at nearly the same rate at all of the temperatures tested. HtrA also rapidly degraded reduced insulin B-chain generated by treatment of insulin with dithiothreitol but not A-chain or intact insulin. Moreover, HtrA degraded fully unfolded alpha-lactalbumin, of which all four disulfide bonds were reduced, but not the native alpha-lactalbumin and its unfolded intermediates containing two or three disulfide bonds. These results indicate that unfolding of the protein substrates, such as by exposure to high temperatures or reduction of disulfide bonds, is essential for their access into the inner chamber of the double ring-shaped HtrA, where cleavage of peptide bonds may occur. Thus, HtrA with a self-compartmentalizing structure may play an important role in elimination of unfolded proteins in the periplasm of Escherichia coli.
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PMID:Selective degradation of unfolded proteins by the self-compartmentalizing HtrA protease, a periplasmic heat shock protein in Escherichia coli. 1060 Mar 91

We cloned and sequenced a full-length cDNA encoding the precursor of the mitochondria-located small heat shock protein (MT-sHSP) gene (LeHSP23.8) from tomato (Lycopersicon esculentum). The deduced protein precursor with a calculated molecular weight of 23.8 kDa was predicted to target mitochondria and was classified as a plant MT-sHSP. A single copy of LeHSP23.8 was found in tomato genomic DNA by southern-blot analysis. Northern-blot analysis revealed the heat inducible character of LeHSP23.8 mRNA. The LeHSP23.8 mRNA was hardly detectable at about 36 degrees C but accumulated markedly at 40 degrees C. The molecular chaperone function of LeHSP23.8 was confirmed in vitro. The recombinant LeHSP23.8 was able to enhance the renaturation of chemically denatured citrate synthase (CS). Moreover, the recombinant LeHSP23.8 protected CS from thermal inactivation and also promoted the renaturation of thermally inactivated citrate synthase.
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PMID:Characterization of mitochondria-located small heat shock protein from tomato (Lycopersicon esculentum). 1068 50

The mechanism(s) by which heat shock protein 25 (hsp25) protects cells from stress may involve one or more of the biochemical properties attributed to hsp25 and other small M(r) hsp. In this report, structural and functional properties of an N-terminal 33 amino acid deletion variant of hsp25 (termed hsp25.c) were considered by comparison with hsp25. 6-His tagged recombinant hsp25 and hsp25.c (termed (H6)hsp25.a and (H6)hsp25.c) were expressed and purified. Oligomeric proteins formed and possessed properties previously attributed to hsp25. The 33 amino acid deletion represented by hsp27.c did not affect the ability of the recombinant protein to act as an inhibitor of elastase, as a molecular chaperone in the refolding of denatured citrate synthase, or as an actin-binding protein. The overexpression of either hsp25 or hsp25.c, enhanced the stress resistance of stable transformed eukaryotic cells. This N-terminal variant protein may be used in further cellular and biochemical assessment of hsp25 oligomerization and function.
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PMID:An N-terminal 33-amino-acid-deletion variant of hsp25 retains oligomerization and functional properties. 1073 25

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