Genetic characterization of the metK locus in Escherichia coli K-12.

Three independently isolated metK mutants have been shown to have leisions lying between speB and glc near 57 min on the Escherichia coli chromosome. Two deletions result in a lack of the metC gene product but neither extends into the metK glc region. The three metK mutations are recessive to the wild-type allele carried on the KLF16 episome.     

Identification of the purI locus in Escherichia coli K-12

A genetic locus has been identified in Escherichia coli that is analogous to the purI locus in Salmonella.     

Regulation of Escherichia coli K-12 hexuronate system genes: exu regulon.

Two types of Escherichia coli K-12 regulatory mutants, partially or totally negative for the induction of the five catabolic enzymes (uronic isomerase, uxaC; altronate oxidized nicotinamide adenine dinucleotide: uxaB; mannonate hydrolyase, uxuA) and the transport system (exuT) of the hexuronate-inducible pathway, were isolated and analyzed enzymatically. Hexuronate-catabolizing revertants of the negative mutants showed a constitutive synthesis for some or all of these enzymes. Negative and constitutive mutations were localized in the same genetic locus, called exuR, and the following order for the markers situated between the min 65 and 68 was determined: argG--exuR--exuT--uxaC--uxaA--tolC. The enzymatic characterization of the pleiotropic negative and constitutive mutants of the exuR gene suggests that the exuR regulatory gene product exerts a specific and total control on the three exuT, uszB, and uxaC-uxaA operons of the galacturonate pathway and a partial control on the uxuA-uxuB operon of the glucuronate pathway. The analysis of diploid strains conatining both the wild type and a negative or constitutive allele of the exuR gene, as well as the analysis of thermosensitive mutants of the exuR gene, was in agreement with a negative regulatory mechanism for the control of the hexuronate system.     

New locus for exopolysaccharide overproduction in Escherichia coli K-12.

A new locus for exopolysaccharide overproduction in Escherichia coli K-12 was mapped by insertion mutagenesis. A 66% linkage to serA, which is located at 62 min on the E. coli K-12 linkage map, was shown by P1 transduction. The polysaccharide produced by the mutant was isolated and was shown to be similar to colanic acid.     

Molecular cloning of the N-acetylneuraminate lyase gene in Escherichia coli K-12

Summary The gene for N-acetylneuraminate lyase [N-acetylneuraminate pyruvate-lyase; NPL] of Escherichia coli C600 was cloned onto pBR322 as a 9.8 kilobase HindIII fragment of chromosomal DNA and the hybrid plasmid was designated pMK2. The gene in the hybrid plasmid was subcloned in pBR322 as a 1.2 kilobase HindIII-EcoRI fragment and the resultant hybrid plasmid was designated pMK6. NPL activity level was increased more than 5-fold in the pMK6-bearing strain compared with that of the wild type, when the cells were grown on a medium containing inducer (N-acetylneuraminate: NANA). The transformants harbouring pMK6 also showed higher activity even in the absence of inducer. The NPL produced by pMK6-bearing cells was structurally and immunologically the same as that purified from E. coli C600.     

Cloning and characterization of the dcm locus of Escherichia coli K-12.

The dcm locus of Escherichia coli K-12 has been shown to code for a methylase that methylates the second cytosine within the sequence 5'-CC(A/T)GG-3'. This sequence is also recognized by the EcoRII restriction-modification system coded by the E. coli plasmid N3. The methylase within the EcoRII system methylates the same cytosine as the dcm protein. We have isolated, from a library of E. coli K-12 DNA, two overlapping clones that carry the dcm locus. We show that the two clones carry overlapping sequences that are present in a dcm+ strain, but are absent in a delta dcm strain. We also show that the cloned gene codes for a methylase, that it complements mutations in the EcoRII methylase, and that it protects EcoRII recognition sites from cleavage by the EcoRII endonuclease. We found no phage restriction activity associated with the dcm clones.     

Overlapping and separate controls on the phosphate regulon in Escherichia coli K12

The physiological and genetic controls operating on phosphate-regulated promoters were studied in greater detail. This was done by defining the control for three phosphate-regulated genes: phoA, psiE, and psiO. Each is highly inducible by phosphate starvation. Individually, these phosphate-starvation-inducible, psi, genes at the same time show common and differing features in their molecular control. The phoA gene, encoding alkaline phosphatase, is specifically induced by phosphate starvation. It is negatively controlled by phoR as well as by the phosphate-specific transport (PST) system in Escherichia coli. phoA induction is positively controlled by the phoB, M, and R products; it is unaffected by the cAMP and CAP system. The psiE and psiO genes were studied by using strains with lacZ fused to their respective promoters. psiE-lacZ is induced by phosphate-, carbon- or nitrogen-limited growth. Genetically, psiE-lacZ induction is partially phoB and phoR-dependent. However, its expression is phoM-independent. This implies that phoB/phoR coupled control differs from phoB/phoM coupled control. Repression of psiE-lacZ is substantially altered in only some PST mutants, such as phoT. In addition, psiE-lacZ is negatively controlled by the cAMP and CAP system. psiO-lacZ is induced by phosphate-, carbon- or nitrogen-limited growth or by anaerobiosis. Its expression is unaffected by any pho mutation that has been previously described. A cell density-dependent induction of psiO-lacZ is observed in lon mutants. Also, psiO-lacZ is negatively controlled by the cAMP-CAP system. In summary, these results demonstrate that co-ordinately regulated promoters can have some common regulatory elements while, at the same time, not sharing other controlling factors.     

Genetic and sequence organization of the mcrBC locus of Escherichia coli K-12.

The mcrB (rglB) locus of Escherichia coli K-12 mediates sequence-specific restriction of cytosine-modified DNA. Genetic and sequence analysis shows that the locus actually comprises two genes, mcrB and mcrC. We show here that in vivo, McrC modifies the specificity of McrB restriction by expanding the range of modified sequences restricted. That is, the sequences sensitive to McrB(+)-dependent restriction can be divided into two sets: some modified sequences containing 5-methylcytosine are restricted by McrB+ cells even when McrC-, but most such sequences are restricted in vivo only by McrB+ McrC+ cells. The sequences restricted only by McrB+C+ include T-even bacteriophage containing 5-hydroxymethylcytosine (restriction of this phage is the RglB+ phenotype), some sequences containing N4-methylcytosine, and some sequences containing 5-methylcytosine. The sequence codes for two polypeptides of 54 (McrB) and 42 (McrC) kilodaltons, whereas in vitro translation yields four products, of approximately 29 and approximately 49 (McrB) and of approximately 38 and approximately 40 (McrC) kilodaltons. The McrB polypeptide sequence contains a potential GTP-binding motif, so this protein presumably binds the nucleotide cofactor. The deduced McrC polypeptide is somewhat basic and may bind to DNA, consistent with its genetic activity as a modulator of the specificity of McrB. At the nucleotide sequence level, the G+C content of mcrBC is very low for E. coli, suggesting that the genes may have been acquired recently during the evolution of the species.     

Selenocysteine lyase activity in a cysteine-requiring mutant ofEscherichia coli K-12

Selenocysteine lyase activity was detected in crude extracts from a cysteine-requiring mutant ofEscherichia coli K-12. The level of activity was the same whether cells had been grown aerobically or anaerobically, with or without selenocysteine. Selenocysteine lyase catalyzes the conversion of selenocysteine to alanine and elemental Se, a reaction that is followed by a nonenzymatic reduction of the Se to hydrogen selenide. Both of these end products were identified in this study. With cysteine as the substrate, alanine and H₂S were formed, but only at levels 50% less than the products formed from selenocysteine. Selenocysteine lyase has been identified in a number of mammals and bacteria; its presence in a cysK mutant ofE. coli K-12 suggests a common route whereby hydrogen selenide, derived from selenocysteine, can then be assimilated into selenoproteins.     

Transport properties of merodiploids covering the dagA locus in Escherichia coli K-12.

A membrane componenet of the dag transport system which serves for glycine, D-alanine, and D-serine is coded for by the dagA gene at minute 83 of the Escherichia coli chromosome. Merodiploid strains (dagA+/dagA+) show two to three times the transport activity for only those amino acids that are substrates of the dag transport system. The increased transport activity is a result of a two-to threefold increase in Vmax for amino acid uptake with little or no change in the Km value. The two- to threefold gene dose effect of the merodiploid strains is maintained even during carbon starvation, eliminating the possibility that a greater energy supply for transport activity may account for the effect. Since merodiploids which carry more than one copy of the dagA allele show a gene dose response for transport activity, we conclude that the membrane componenet of the dag transport system which is coded for by the dagA allele is present in limiting amounts.     

Regulation of the phosphate regulon in Escherichia coli K-12: regulation of the negative regulatory gene phoU and identification of the gene product.

The phoU gene is one of the negative regulatory genes of the pho regulon of Escherichia coli. The DNA fragment carrying phoU has been cloned on pBR322 (Amemura et al., J. Bacteriol. 152:692-701, 1982). Further subcloning, Tn1000 insertion inactivation, and complementation tests localized the phoU gene within a 1.1-kilobase region on the cloned DNA fragment. The gene product of phoU was identified by the maxicell method as a protein with an approximate molecular weight of 27,000. A hybrid plasmid that contains a phoU'-lac'Z fused gene was constructed in vitro. This plasmid enabled us to study phoU gene expression by measuring the beta-galactosidase level in the cells. The plasmid was introduced into various regulatory mutants related to the pho regulon, and phoU gene expression in these strains was studied under limited and excess phosphate conditions. It was found that phoU is expressed at a higher level when the cells are cultured under the excess phosphate condition. The higher phoU expression was observed in a phoB mutant and a phoR-phoM double mutant. The implications of these findings for the regulation of pho genes are discussed.     

The DNA sequence of the sulfate activation locus from Escherichia coli K-12.

The DNA sequence of the sulfate activation locus from Escherichia coli K-12 has been determined. The sequence includes the structural genes encoding the enzymes ATP sulfurylase (cysD and cysN) and APS kinase (cysC) which catalyze the synthesis of activated sulfate. These are the only genes known to reside in the sulfate activation operon. Consensus elements of the operon promoter were identified, and the start codons and open reading frames of the Cys polypeptides were determined. During this work, another gene, iap, was partially sequenced and mapped. The activity of ATP sulfurylase is stimulated by an intrinsic GTPase. Comparison of the primary sequences of CysN and Ef-Tu revealed that CysN has conserved many of the residues integral to the three-dimensional structure important for guanine nucleotide binding in Ef-Tu and RAS. nodP and nodQ, from Rhizobium meliloti, are essential for nodulation in leguminous plants. The Cys and Nod proteins are remarkably similar. NodP appears to be the smaller subunit of ATP sulfurylase. NodQ encodes homologues of both CysN and CysC; thus, these enzymes may be covalently associated in R. meliloti. The consensus GTP-binding sequences of NodQ and CysN are identical suggesting that NodQ encodes a regulatory GTPase.