Regulation of capsular polysaccharide synthesis in Escherichia coli K-12: characterization of three regulatory genes.

The synthesis of the Escherichia coli capsular polysaccharide varies with growth medium, temperature of growth, and genetic background. lac fusions to genes necessary for capsule synthesis (cps) demonstrated that these genes are regulated negatively in vivo by the lon gene product. We have now isolated, characterized, and mapped mutations in three new regulatory genes (rcs, for regulator of capsule synthesis) that control expression of these same fusions. rcsA and rcsB are positive regulators of capsule synthesis. rcsA is located at min 43 on the E. coli map, whereas rcsB lies at 47 min. rcsC, a negative regulator of capsule synthesis, is located at min 47, close to rcsB. All three regulatory mutations are unlinked to either the structural genes cpsA-F or lon. Mutations in all three rcs genes are recessive to the wild type. We postulate that lon may regulate capsule synthesis indirectly, by regulating the availability of one of the positive regulators.     

Evidence for two distinct pyruvate kinase genes in Escherichia coli K-12

A strain of Escherichia coli K-12 defective in pyruvate kinase F has been produced. The existence of this mutant, in conjunction with earlier results, strongly suggests that the two pyruvate kinases in this bacterium are distinct forms and not interconvertible. Either form of pyruvate kinase appeared to be equally effective in the glycolytic conversion of phosphoenolpyruvate to pyruvate. Genes specifying pyruvate kinase A and pyruvate kinase F were present on the small F-prime F506 and the locus for pyruvate kinase F was found to be at minute 36.5 on the E. coli genetic map.     

DNA synthesis in UV-irradiated Escherichia coli K-12 strains carrying dnaA mutations.

Summary In this article we describe some in vivo properties of a coldsensitive ribosomal mutant from Escherichia coli. The mutation affects the rplV gene which is the structural gene of ribosomal protein L22.Our work shows that at 22°C, the biosynthesis of both ribosomal subunits and the maturation processing of 16S and 23S ribosomal RNA are impaired. Integration of our results in a general model of in vivo ribosomal assembly in E. coli is presented.     

Expression of the tolQRA genes of Escherichia coli K-12 is controlled by the RcsC sensor protein involved in capsule synthesis

The tolQRABpal cluster of Escherichia coli K-12 encodes proteins involved in the maintenance of cell-envelope integrity. In addition, toi/pal mutations result in a mucoid colony phenotype at low temperature. The synthesis of capsular polysaccharides by the cps genes is controlled by the positive regulator RcsA and the two-component RcsC/RcsB system. It was shown that the mucoid phenotype of the tol/pal mutants was due to an rcsCB-dependent activation of the cps genes. Furthermore, we have identified a mutation in the rcsC gene that decreased the activity of a tolA-lac operon fusion independently of RcsA and partially independently of RcsB activators. The corresponding rcsC338 mutation resulted in a Glu to Lys substitution at residue 338 of RcsC. This mutation induced mucoidy even at high temperature. We propose that RcsC modulates the phosphorylated forms of RcsB and an uncharacterized regulatory protein involved in the control of the tolQRA genes in an opposite manner. Moreover, our findings strengthen the previous suggestion that RcsC senses some alterations in the cell surface such as those induced by tol, pal or rfa mutations, and activates capsule synthesis to protect the cell against deleterious agents.     

Dominant mutations of rifampicin resistance in Escherichia coli K-12

Significant portion (up to 20%) of dominant mutations (rifd mutations) was observed among spontaneous mutations of rifampicin resistance picked up in cells of haploid Escherichia coli strain. These mutations are similar to rifd mutations obtained earlier when selecting them in rif-s/rif-s merodiploids. On the basis of analysis of nucleotide substitutions taking place in formation of spontaneous and induced mutations, it is established that rifd mutations are caused by single nucleotide substitution. The majority of rifd mutations are localized in a small region of the central part of RNA polymerase beta-subunit gene covering less than 200 base pairs. A rifd mutant has been described which occurred as a result of micro-deletion in one of the "hot" spots of the central region of beta-subunit gene.     

Characterization of lexB mutations in Escherichia coli K-12.

Two mutations have been located at the recA locus and phenotypically characterized along with a third one, previously called rec-34. The three mutants behaved similarly to lexA mutants. They were sensitive to ultraviolet (UV) light and X rays, and lambdaFec- phages were able to plate on them. The three mutations were called lexB because they could be distinguished from recA mutations by the last property. lexB mutants were less sensitive to UV and X irradiations than were recA mutants and were, to various degrees, recombination proficient. UV light failed to induce prophage lambda in all three lexB lysogens. In contrast, thymine starvation induced lexB31 and lexB34 lysogens. In lexB34 mutants, but not in lexB30 and lexB31 mutants, UV reactivation occurred at a low level. In Escherichia coli K-12, the recA gene has basic functions in the repair of deoxyribonucleic acid lesions, deoxyribonucleic acid recombination, and prophage induction. The three lexB mutations alter unequally and independently the three functions. This suggests that the recA and lexB mutations affect the same gene.     

Small genes/gene-products in Escherichia coli K-12

Forty-two protein spots of observed M_r 6–15 kDa were resolved by two-dimensional gel electrophoresis, stained by Coomassie blue and subjected to Edman microsequencing. All of the proteins could be related back to their encoding open reading frames, thereby vindicating the bioinformatic tools currently utilised in their identification. However, only 14/42 gene-products were expressed as annotated. Translation was confirmed for 14 open reading frames with no attributed function (EcoGene Y-entries), while N-terminal sequence allowed the start codon to be accurately annotated for the genes yjgF, yccU, yqiC, ynfD, and yeeX. The methionine start codon was cleaved in 11 gene-products (AtpE, Hns, RpoZ, RplL, CspC, YccJ, YggX, YjgF, HimA, InfA, RpsQ) and a further five showed loss of a signal peptide (PspE, HdeB, HdeA, YnfD, YkfE). Internal (Tig, AtpA, TufA) and N-terminal fragmentation (CspD, RpsF, AtcU) of much larger proteins was also detected, which may have resulted from physiological or translational processes. M_r and pI isoforms were detected respectively for PtsH and GatB, each being phosphoproteins, as well as RplY which manifested differences with respect to predicted M_r and pI. In addition, YjgF was shown to belong to a small gene family of unknown function with ancient conserved regions across procaryotes and eucaryotes. YgiN was revealed to have a paralogue and orthologues in Bacillus subtilis, Synechocystis sp., Mycobacterium tuberculosis, Neisseria gonorrhoea, and Rhodococcus erythropolis. Orthologues are also reported for YihD, YccU and YeeX. Of the 14 Y-genes, only YkfE possessed no detectable orthologues. These results highlight the need to complement genomic analysis with detailed proteomics in order to gain a better understanding of cellular molecular biology, while the confirmation of the open reading frame start codon using Edman degradation protein microsequencing has yet to be superseded by recent advances in mass spectrometry.     

New maltose Blu mutations in Escherichia coli K-12.

Mutations in the genes pgi, pfkA, and ptsG resulted in a maltose Blu phenotype in Escherichia coli K-12, bringing the number of known Blu alleles to six. The Blu phenotype, as visualized by staining with iodine vapor, is a convenient mutant isolation technique.     

Outer membrane protein a and other polypeptides regulate capsular polysaccharide synthesis in E. coli K-12.

Summary capR (lon) mutants of Escherichia coli K-12 are mucoid on minimal agar because they produce large quantities of capsular polysaccharide. When such mutants are transformed to tetracycline resistance by plasmid pMC44, a hybrid plasmid that contains a 2 megadalton (Mdal) endonuclease EcoR1 fragment of E. coli K-12 DNA joined to the cloning vehicle-pSC101, capsular polysaccharide synthesis is inhibited and the transformed colonies exhibit a nonmucoid phenotype. Re-cloning of the 2 Mdal EcoR1 fragment onto plasmid pHA105, a min-colE1 plasmid, yielded plasmid pFM100 which also inhibited capsular polysaccharide synthesis in the capR mutants. A comparison of the polypeptides specified by both plasmids pFM100 and pMC44 in minicells demonstrated that seven polypeptide bands were specified by the 2 Mdal DNA, one of which was previously demonstrated to be outer membrane protein a; also known as 3b or M2 (40 kilodaltons, Kdal). Plasmid mutants no longer repressing capsular polysaccharide synthesis were either unable to specify the 40 K dal outer membrane protein a or were deficient in synthesis of 25 K dal and 14.5 K dal polypeptides specified by the 2 Mdal DNA fragment. Studies with a minicell-producing strain that also contained a capR mutation indicated that the capR gene product regulated processing of at least one normal protein, the precursor of outer membrane protein a.     

Insertion mutations in the dam gene of Escherichia coli K-12

The dam gene of E. coli can be inactivated by insertion of Tn9 or Mud phage. Strains bearing these mutations are viable indicating that the dam gene product is dispensable.     

Map location of arginyl-tRNA synthetase mutations in Escherichia coli K-12

Summary Mutants of Escherichia coli K-12 previously isolated in the authors' laboratory have reduced arginyl-tRNA synthetase activity. The mutants fall into two classes. All mutants grow slowly on arginine-free medium. On arginine-supplemented medium some mutants grow at a normal rate (Class I) while others still grow slowly (Class II). Matings were performed to located a Class I and a Class II mutation on the E. coli chromosome map, and on the basis of our results we have assigned both to one locus, argS.