Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts:   Target Concepts:
Query: EC:4.6.1.1 (adenylate cyclase)
 19,190 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Cyclic AMP (cAMP) is found in a variety of prokaryotes including both eubacteria and archaebacteria. cAMP plays a role in regulating gene expression, not only for the classic inducible catabolic operons, but also for other categories. In the enteric coliforms, the effects of cAMP on gene expression are mediated through its interaction with and allosteric modification of a cAMP-binding protein (CRP). The CRP-cAMP complex subsequently binds specific DNA sequences and either activates or inhibits transcription depending upon the positioning of the complex relative to the promoter. Enteric coliforms have provided a model to explore the mechanisms involved in controlling adenylate cyclase activity, in regulating adenylate cyclase synthesis, and in performing detailed examinations of CRP-cAMP complex-regulated gene expression. This review summarizes recent work focused on elucidating the molecular mechanisms of CRP-cAMP complex-mediated processes. For other bacteria, less detail is known. cAMP has been implicated in regulating antibiotic production, phototrophic growth, and pathogenesis. A role for cAMP has been suggested in nitrogen fixation. Often the only data that support cAMP involvement in these processes includes cAMP measurement, detection of the enzymes involved in cAMP metabolism, or observed effects of high concentrations of the nucleotide on cell growth.
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PMID:Cyclic AMP in prokaryotes. 131 22

The Escherichia coli rpoB636 mutant is defective in the transcription of lac and other catabolite-sensitive operons. The lac promoter variant, UV5, which is independent of cyclic AMP and the cyclic AMP receptor protein, CRP, was also defective in rpoB636 mutants. The activity of the lac UV5 promoter was restored to wild-type levels by deletion of cya (adenylate cyclase) or crp. Cyclic AMP and CRP apparently act as inhibitors of the rpoB636 RNA polymerase.
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PMID:An Escherichia coli rpoB mutation that inhibits transcription of catabolite-sensitive operons. 166 71

We have characterized crp mutations in E. coli that allow CRP to function without cAMP. crp* mutants carrying a deletion of the gene encoding adenylate cyclase (cya) show significant lac expression. Cyclic GMP, normally an ineffective activator of CRP+, can stimulate these mutant CRP*s to permit greater lac expression in vivo. Cyclic AMP binding to the amino-terminal domain of CRP+ induces an allosteric transition that changes the DNA-binding property of the carboxy domain. The CRP* phenotype is caused by substitution of amino acids with bulkier side chains in the D alpha-helix of the protein's carboxy domain, near the hinge connecting the two domains. These results are consistent with a model in which the mutant CRP*s assume, in part, a conformation normally evoked only by cAMP binding: one in which the relative orientation of the C, D, and F alpha-helices is altered. We define precisely the amino acids of these alpha-helices that interact to cause the allosteric shift.
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PMID:Sites of allosteric shift in the structure of the cyclic AMP receptor protein. 298 85

In previous experiments, we showed that the in vivo transcription of the colicin E1 gene was dependent on cyclic AMP in adenylate cyclase-defective mutant cells of Escherichia coli (Ebina, Y. and Nakazawa, A (1983) J. Biol. Chem. 258, 7072-7078). We now show that cyclic AMP and cyclic AMP receptor protein stimulated the in vitro transcription of the gene in the presence of spermidine. As determined in DNase I protection experiments, two binding sites for the complex of cyclic AMP and the receptor protein were identified about 60 base pairs (CRP-1) and 110 base pairs (CRP-2) upstream from the transcription initiation site of the colicin E1 gene. CRP-1 had a higher affinity for the complex than that of CRP-2. Substituting an unrelated DNA sequence for CRP-2 reduced the efficiency of in vitro stimulation of the gene by cyclic AMP and the receptor protein. These potential binding sites for the cyclic AMP-cyclic AMP receptor protein complex probably participate in the stimulation of the colicin E1 gene transcription.
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PMID:Positive regulation of the colicin E1 gene by cyclic AMP and cyclic AMP receptor protein. 299 44

Several strains of Escherichia coli K12 were compared for activity of the periplasmic "pH 2.5 acid phosphatase", an enzyme whose expression is regulated negatively by cyclic AMP. Two distinct enzyme levels differing by about four-fold were observed. This strain-dependent difference does not involve modifications in the structure of the enzyme, but results from a difference in its expression. We show that strains with a high- or a low level of enzyme differ in the gene locus appR located in the 59 min region of the chromosome, a site remote from the structural gene appA; the appR+ versus appR enzyme ratio is 3-4 in wild-type strains, adenylate cyclase-deficient strains (cya) or cyclic AMP receptor protein-deficient strains (crp) grown in rich medium or in glucose minimal medium, but is close to 1 in cya strains in the presence of 0.1 mM cyclic AMP and in wild-type strains grown with succinate as carbon source; in a crp genetic background, appR strains, contrary to appR+ strains, are able to grow on minimal medium with succinate as the sole carbon source. The selection, from an appR+ crp strain, of clones growing on succinate-minimal medium, yielded mutations in the same region of the chromosome and showing the same phenotype as "naturally-occurring" appR strains. All appR strains analysed so far showed other similar deficiencies. The possibility that mutated appR gene products might function as weak substitutes for a functional cAMP-CRP complex is discussed.
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PMID:Pleiotropic mutations in appR reduce pH 2.5 acid phosphatase expression and restore succinate utilisation in CRP-deficient strains of Escherichia coli. 351 93

The synthesis of the adenylate cyclase [ATP pyrophosphatelyase-(cyclizing), E.C. 4.6.1.1.] of Escherichia coli, appears to be regulated negatively by the cAMP receptor protein, CRP. This conclusion is based on a comparison of adenylate cyclase activities measured in vitro with the rates of cAMP synthesis by intact bacteria. The activity of adenylate cyclase, depending on conditions of growth, is also regulated by CRP; this effect, however, is indirect insofar as it is mediated by a protein or proteins under CRP control.
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PMID:Regulation of the synthesis of adenylate cyclase in Escherichia coli by the cAMP -- cAMP receptor protein complex. 626 21

A well-characterized set of pts deletion mutants of Salmonella typhimurium were used to re-evaluate the purported role of the PTS in the inducer exclusion process and in regulation cAMP synthesis. During the course of these studies a class of secondary mutations was isolated which suppress the inhibition of cAMP synthesis caused by pts mutations. These suppressor mutations were traced to the crp locus and tentatively designated as acr (adenylate cyclase regulation) mutations. A new model is proposed in which CRP rather than adenylate cyclase is believed to be the central regulatory element in the catabolite repression phenomenon.
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PMID:Regulatory interactions among the cya, crp and pts gene products in Salmonella typhimurium. 631 40

The gene for adenylate cyclase of E. coli has been cloned in the plasmid pBR322. The Cya- strain transformed with the isolated plasmids produces significant amounts of adenylate cyclase and cAMP. Some of the Cya+ plasmids were shown to direct the synthesis of a 85,000 dalton polypeptide in a cell-free system. The direction of transcription and the location of the cya promoter including the transcriptional start site were determined by an S1 digestion method. DNA sequence around the promoter region indicates that a putative coding region for adenylate cyclase begins at +233. The 233 bp leader region could encode a potential small polypeptide containing 30 amino acids. Two probable CRP binding sites were found in the leader region, suggesting a negative control at the transcriptional level by CRP-cAMP.
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PMID:Cloning and promoter analysis of the Escherichia coli adenylate cyclase gene. 634 11

CRP-cAMP-dependent operons of Escherichia coli can be expressed in cells lacking functional adenylate cyclase when they carry a second-site mutation in the crp gene (crp*). It is known that the expression of these operons is repressed by glucose, but the molecular mechanism underlying this cAMP-independent catabolite repression has been a long-standing mystery. Here we address the question of how glucose inhibits the expression of beta-galactosidase in the absence of cAMP. We have isolated several mutations in the crp gene that confer a CRP* phenotype. The expression of beta-galactosidase is reduced by glucose in cells carrying these mutations. Using Western blotting and/or SDS-PAGE analysis, we demonstrate that glucose lowers the cellular concentration of CRP* through a reduction in crp* mRNA levels. The level of CRP* protein correlates with beta-galactosidase activity. When the crp promoter is replaced with the bla promoter, the inhibitory effect of glucose on crp* expression is virtually abolished. These data strongly suggest that the lowered level of CRP* caused by glucose mediates catabolite repression in cya- crp* cells and that the autoregulatory circuit of the crp gene is involved in the down-regulation of CRP* expression by glucose.
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PMID:Glucose lowers CRP* levels resulting in repression of the lac operon in cells lacking cAMP. 749 74

Competence for transformation in Haemophilus influenzae is stimulated by cyclic AMP (cAMP) and requires the cAMP-dependent catabolite regulatory protein CRP. Thus, understanding the control of competence will require understanding how cAMP levels are regulated. As a first step, we have cloned the H. influenzae adenylate cyclase gene (cya) by complementing the Lac- phenotype of delta cya Escherichia coli. Its sequence specifies an 843-amino-acid protein which has significant identity to other known bacterial adenylate cyclases (41 to 43% and 61% identical to the cya genes of enteric bacteria and of Pasteurella multocida, respectively). As seen in other bacterial cya genes, there is evidence for regulation similar to that demonstrated for E. coli: the presence of a strong consensus CRP binding site within the promoter of the gene may provide feedback control of cAMP levels by repressing cya transcription, and translation may be limited by the weak ribosome binding site and by initiation of protein synthesis with GUG rather than AUG or the UUG used in other bacterial cya genes. We confirmed the essential role of cAMP in competence by constructing and characterizing H. influenzae cya mutants. This strain failed to develop competence either spontaneously or after transfer to a competence-inducing medium. However, it became as competent as its wild-type parent in the presence of exogenous cAMP. This result suggests that the failure of exogenously added cAMP to induce optimum competence in wild-type cells is not due to a limitation to the entry of cAMP into the cells. Rather, it strongly favors models in which competence induction requires both an increase in intracellular cAMP and a second as yet unidentified regulatory event. H. influenzae strains mutant in cya or crp were unable to ferment xylose or ribose. This confirms that influenzae, like E. coli, uses cAMP and CRP to regulate nutrient uptake and utilization and lends increasing support to the hypothesis that DNA uptake is mechanism of nutrient acquisition.
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PMID:The Haemophilus influenzae adenylate cyclase gene: cloning, sequence, and essential role in competence. 822 61


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