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)

Genomic libraries of Mycobacterium leprae DNA partially digested with Pst I were constructed in the expression vector pYA626, which contains the promoter region from the Streptococcus mutans gene encoding aspartate beta-semialdehyde dehydrogenase, which is very efficiently expressed in Escherichia coli. We have detected several clones that complement a mutation in the citrate synthase gene of E. coli. Southern blot analysis demonstrated that the complementing DNA was M. leprae DNA. Sodium dodecyl sulfate/polyacrylamide gel analysis of polypeptides produced by minicells containing the citrate synthase-complementing recombinant molecules demonstrated the production of a 46-kDa polypeptide. When the citrate synthase-complementing fragment was cloned in pYA626 in the reverse orientation, the recombinant molecule was no longer able to complement the mutation in the citrate synthase gene and no longer produced the 46-kDa polypeptide. When the DNA fragment was cloned in the Pst I site of pHC79, so as to allow expression from the beta-lactamase promoter, the resulting recombinant failed to complement the mutation in the E. coli citrate synthase gene yet still produced the 46-kDa polypeptide, but in one-fourth the amount than when expressed from the S. mutans asd promoters. This demonstrates that M. leprae translational sequences can be recognized by E. coli translational machinery. Promoter expression vectors can be used to obtain expression of protein antigens to be used for early diagnosis of leprosy or components of a vaccine and proteins that are targets of potential antileprosy drugs.
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PMID:Expression of Mycobacterium leprae genes from a Streptococcus mutans promoter in Escherichia coli K-12. 286 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.
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PMID:Chaperonins and protein folding: unity and disunity of mechanisms. 809 34

Six single point mutants of yeast citrate synthase were analyzed for binding to the molecular chaperone GroEL. In contrast to the wild-type and G276S, all other G276-mutants were able to displace pre-beta-lactamase from GroEL. The off-rate constant for pre-beta-lactamase must be at least partially rate-limiting, leading to an equilibrium dissociation constant between 10(-10) M and 10(-12)M. Direct evidence for binding of citrate synthase was obtained from gel filtration experiments. The results suggest that thermodynamic rather than structural features of the mutants determine the degree of binding to the chaperone.
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PMID:Effect of single point mutations in citrate synthase on binding to GroEL. 860 26

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.
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PMID:Atomic force microscopy detects changes in the interaction forces between GroEL and substrate proteins. 963 79