The catalytic domain of Escherichia coli K-12 adenylate cyclase as revealed by deletion analysis of the cya gene

In Escherichia coli, adenylate cyclase activity is regulated by phosphorylated EnzymeIIA^Glc, a component of the phosphotransferase system for glucose transport. In strains deficient in EnzymeIIA^Glc, CAMP levels are very low. Adenylate cyclase containing the D414N substitution produces a low level of cAMP and it has been proposed that D414 may be involved in the process leading to activation by EnzymeIIA^Glc. In this work, spontaneous secondary mutants producing large amounts of cAMP in strains deficient in EnzymeIIA^Glc were obtained. The secondary mutations were all deletions located in the cya gene around the D414N mutation, generating adenylate cyclases truncated at the carboxyl end. Among them, a 48 kDa protein (half the size of wild-type adenylate cyclase) was shown to produce ten times more cAMP than wild-type adenylate cyclase in strains deficient in EnzymeIIA^Glc. In addition, this protein was not regulated in strains grown on glucose and diauxic growth was abolished. This allowed the definition of a catalytic domain that is not regulated by the phosphotransferase system and produces levels of cAMP similar to that of regulated wild-type adenylate cyclase in wild-type strains grown in the absence of glucose. Further analysis allowed the characterization of the COOH-terminal regulatory domain, which is proposed to be inhibitory to the activity of the catalytic domain.     

Identification of the Escherichia coli cya gene product as authentic adenylate cyclase

The Escherichia coli cya gene has been fused in the same register with the lacZ gene. The corresponding hybrid cya-lacZ gene is expressed as a bifunctional protein that exhibits both adenylate cyclase and beta-galactosidase activities, thus proving that cya is the structural gene for adenylate cyclase. The hybrid protein was purified to homogeneity and has been used to raise antibodies that recognize wild-type adenylate cyclase. Finally, the protein has been submitted to amino acid sequence analysis. It has been found that the first ten amino acids fit the predicted sequence obtained from DNA sequence analysis, thus substantiating the prediction that the cya translation initiation codon is UUG .     

Cloning of the adenylate cyclase gene of Escherichia coli K-12

The adenylate cyclase gene of Escherichia coli has been cloned on the plasmid vector pBR325. The hybrid plasmid pTH4 obtained has a molecular weight of 6,4 megadalton and represents pBR325 plasmid with the insertion of 2,8 megadalton in the Pst1 site. The cya mutant bacteria carrying pTH4 recover their ability to utilize mannitol, lactose and other carbohydrates as carbon sources, and lose this ability again in the case of rare spontaneous excision of the DNA insert from the Pst1 site. The phenotypical effect of pTH4 in cya mutants can be only seen in the crp+ genome. The strains carrying pTH4 are also characterized by the ability of beta-galactosidase induction under conditions of catabolite repression. Besides, the bacteria containing cya+ allele on the plasmid do not grow on glycerol, which seems to be caused by toxic concentrations of methylglyoxal formed as a result of the increased intracellular level of cyclic adenosine monophosphate.     

Cell filamentation in an Escherichia coli K-12 fic mutant caused by theophylline or an adenylate cyclase gene (cya)-containing plasmid

Abstract The bioconversion of 17α-ethynyl steroids was effected with 11α-hydroxylase of Rhizopus nigricans . 7β-Hydroxyethisterone was found after the bioconversion of ethisterone, and 10β- and 6β-hydroxy derivatives after the bioconversion of norethisterone. It seems that the ethynyl group prevents steroid-enzyme binding in the normal mode and thus inhibits the formation of an 11α-hydroxylated product.     

Isolation and expression of the Bradyrhizobium japonicum adenylate cyclase gene (cya) in Escherichia coli

A 5.0-kilobase-pair HindIII fragment of Bradyrhizobium japonicum DNA containing the cya gene which encodes adenylate cyclase was isolated as an insert in pBR322, using marker rescue of the maltose-negative phenotype of an Escherichia coli cya mutant for identification. The isolated B. japonicum DNA fragment was capable of reversing the pleiotropic phenotype of cya mutations when inserted in either orientation in the HindIII site of pBR322. The complemented E. coli strains produced high levels of cyclic AMP. No sequence homology between the B. japonicum cya gene and that of E. coli was detected by hybridization analysis.     

luxS-dependent gene regulation in Escherichia coli K-12 revealed by genomic expression profiling

The bacterial quorum-sensing autoinducer 2 (AI-2) has received intense interest because the gene for its synthase, luxS, is common among a large number of bacterial species. We have identified luxS-controlled genes in Escherichia coli under two different growth conditions using DNA microarrays. Twenty-three genes were affected by luxS deletion in the presence of glucose, and 63 genes were influenced by luxS deletion in the absence of glucose. Minimal overlap among these gene sets suggests the role of luxS is condition dependent. Under the latter condition, the metE gene, the lsrACDBFG operon, and the flanking genes of the lsr operon (lsrR, lsrK, tam, and yneE) were among the most significantly induced genes by luxS. The E. coli lsr operon includes an additional gene, tam, encoding an S-adenosyl-l-methionine-dependent methyltransferase. Also, lsrR and lsrK belong to the same operon, lsrRK, which is positively regulated by the cyclic AMP receptor protein and negatively regulated by LsrR. lsrK is additionally transcribed by a promoter between lsrR and lsrK. Deletion of luxS was also shown to affect genes involved in methionine biosynthesis, methyl transfer reactions, iron uptake, and utilization of carbon. It was surprising, however, that so few genes were affected by luxS deletion in this E. coli K-12 strain under these conditions. Most of the highly induced genes are related to AI-2 production and transport. These data are consistent with the function of LuxS as an important metabolic enzyme but appear not to support the role of AI-2 as a true signal molecule for E. coli W3110 under the investigated conditions.     

Escherichia coli cells with mutations in the gene for adenylate cyclase (cya) exhibit a heat shock response

Abstract Adenylate cyclase mutants of Escherichia coli showed the heat-shock response. The heat-shock response was studied in two different mutants and in different growth media, including rich and minimal media. These results are in disagreement with the proposal that the cya gene regulates the expression of the heat-shock genes.     

Characterization and generation of Escherichia coli adenylate cyclase deletion mutants.

Escherichia coli delta cya-283 is a 75-bp in-frame deletion overlapping the 5' end of delta cya-854; delta cya-201 is a 41-bp frameshift deletion overlapping the 3' end of delta cya-854. Sequence repeats were found at the boundaries of delta cya-283 and delta cya-201, suggesting a mechanism for deletion formation. Recombinant DNA procedures were used to construct a strain in which the total cya structural gene in the chromosome was replaced by the kanamycin resistance gene.     

The complete nucleotide sequence of the adenylate cyclase gene of Escherichia coli

The complete nucleotide sequence of the cya gene from E. coli was determined. The gene encodes a polypeptide consisting of 848 amino acid residues with a calculated molecular weight of 97,542. The deduced protein structure reveals that cyclase is comprised of two domains, an amino-terminal region exhibiting catalytic activity and a carboxy-terminal region possibly carrying regulatory function. The frequent appearance of rare codons in the beginning of the gene as well as the sequence duplication in the promoter-initiator region suggest possible regulation(s) at the translational level. An unknown gene (cyaX) which seems to code for a very hydrophobic protein was found following the cya gene. Sequence analysis suggests that the cyax is a part of the cya operon.     

Amplification of the adenylate cyclase gene in Escherichia coli cells

Amplification of the cya gene of E. coli on the plasmid pBR325 leads to an increase of adenylate cyclase activity proportional to the gene dosage. In strains harboring hybrid plasmids with cya gene the intracellular level of cAMP and the rate of nucleotide secretion are also elevated. The adenylate cyclase activity in cells with truncated cya gene cloned on pBR322 remains sensitive to glucose inhibition. Amplification of the cya gene leads to considerable resistance of beta-galactosidase synthesis to transient repression by alpha-methylglucoside, but does not influence the permanent repression caused by glucose.     

Isolation and characterization of a small catalytic domain released from the adenylate cyclase from Escherichia coli by digestion with trypsin

An expression plasmid containing a hybrid gene encoding a protein having the primary amino acid sequence of the adenylate cyclase from Escherichia coli was constructed. When the gene was induced, the adenylate cyclase could be expressed at high levels in a cya- strain of E. coli. The majority of the enzymatic activity and protein (having a molecular weight of 95,000) induced was insoluble. However, treatment of the insoluble fraction of cell lysates with trypsin resulted in both an increase in and solubilization of the total amount of adenylate cyclase activity. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis of the soluble protein produced by treatment with trypsin revealed a polypeptide having a molecular weight of 30,000. This soluble, catalytically active fragment of adenylate cyclase was purified and subjected to amino-terminal sequence analyses; two amino-terminal sequences were identified beginning at residue 82 and at residue 342 of the intact enzyme. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis analysis of the purified fragment followed by either silver or Coomassie Blue staining revealed the presence of only a single polypeptide having a molecular weight of 30,000; a short oligopeptide associated with the amino terminus at residue 342 could not be detected. Site-directed mutagenesis was used to place a stop codon at residue 341; the truncated enzyme was catalytically active, so the short oligopeptide is not necessary for catalysis. The Km for ATP, the Ka for Mg2+, and the Vmax determined for the product containing the 30,000-dalton fragment were similar to the values reported for the intact enzyme from E. coli.     

Physical analysis of deletion mutations in the ilvGEDA operon of Escherichia coli K-12.

DNA-DNA hybridization of cloned segments of the Escherichia coli K-12 ilvGEDA operon to genomic blots was used to determine the physical dimensions of a series of deletion mutations of the ilvGEDA operon. The smallest mutation resulted from the deletion of approximately 200 base pairs from within ilvD, whereas the largest mutation resulted from the deletion of 17 kilobases including the rep gene. The structure of three of these mutants indicates that formation of the deletions was mediated by Tn5 (or Tn5-131) that is retained in the chromosome. This is the first observation of this type of Tn5-mediated event. Our analysis of the total acetohydroxy acid synthase activity of strains containing deletions of ilvG indicates that the truncated ilvG polypeptide of wild-type E. coli K-12 lacks enzyme activity. The small 200-base-pair deletion of ilvD confirms the presence of a strong polar site 5' to ilvA. The detailed structure of these deletions should prove useful for the investigation of other genes in this region. This genomic analysis demonstrates that the ilv restriction site map that was established previously by the analysis of recombinant bacteriophage and plasmids is identical to that on the genome.     

Purification and characterization of adenylate cyclase from Escherichia coli K12

Adenylate cyclase of Escherichia coli K12 has been purified 17,000-fold to near homogeneity from a 5-fold overproducing strain. One major band of Mr = 92,000 and several minor bands are seen on sodium dodecyl sulfate-polyacrylamide electrophoresis of the purest fractions. Identification of the enzyme with the 92,000-Da protein is based on the correlation of this band with activity when highly purified enzyme is eluted from ADP-sepharose columns. The native enzyme has a molecular weight of 95,000 determined by gel filtration, showing that the enzyme is active as a monomer. The purest enzyme has a specific activity of 700 nmol min-1 mg-1, indicating a turnover number of about 100 min-1. Our data indicate that there are only about 15 molecules of the enzyme in wild type cells of E. coli. In crude extracts, over 80% of the activity is soluble after centrifugation at 100,000 x g, indicating the enzyme is soluble or, at most, loosely membrane bound. The enzyme is only moderately stable in crude extracts and becomes more unstable as purification proceeds. Activity is stabilized by ATP, or at -20 degrees C as an ammonium sulfate precipitate or in 50% glycerol. The enzyme has an absolute requirement for divalent cations. Maximum activity with Mg2+ is reached at 30 mM. Mn2+ is a good substitute; Co2+ activates well at low concentrations but becomes inhibitory at high concentrations; and Ca2+ is a potent inhibitor in the presence of Mg2+. The isoelectric point of the enzyme is 6.1, and its pH optimum is 8.5. The enzyme is inhibited by its substrate, with a Km of about 1 mM and a Ki of about 1.5 mM, and is noncompetitively inhibited by PPi, ADP, GTP, and a number of other compounds. The data suggest that dissociation of PPi from the first enzyme-product complex is the rate-limiting step in the reaction. Activation of the enzyme, inferred to occur in vivo, could be produced by a postulated regulatory effector which speeds release of PPi from the enzyme-product complex.     

The Escherichia coli adenylate cyclase complex: Activation by phosphoenolpyruvate

A model for the regulation of the activity of Escherichia coli adenylate cyclase is presented. It is proposed that Enzyme I of the phosphoenolpyruvate:sugar phosphotransferase system (PTS) interacts in a regulatory sense with the catalytic unit of adenylate cyclase. The phosphoenolpyruvate (PEP)-dependent phosphorylation of Enzyme I is assumed to be associated with a high activity state of adenylate cyclase. The pyruvate or sugar-dependent dephosphorylation of Enzyme I is correlated with a low activity state of adenylate cyclase. Evidence in support of the proposed model involves the observation that Enzyme I mutants have low cAMP levels and that PEP increases cellular cAMP levels and, under certain conditions, activates adenylate cyclase, Kinetic studies indicate that various ligands have opposing effects on adenylate cyclase. While PEP activates the enzyme, either glucose or pyruvate inhibit it. The unique relationships of PEP and Enzyme I to adenylate cyclase activity are discussed.