Analysis of genetic recombination between two partially deleted lactose operons of Escherichia coli K-12.

Genetic recombination between a nontandem duplication of two partially deleted lactose operons (lacMS286phi80dIIlacBK1) in Escherichia coli K-12 has been examined. Since the deletions were nonoverlapping, rare lactose-fermenting (Lac+) recombinants occurred and were detected qualitatively on lactose tetrazolium agar indicator plates as white papillae growing on the surface of red colonies or quantitively on lactose minimal agar plates. Formation of Lac+ recombinants required the recA, recB, and recC gene products. Indirect suppression of recB21 by sbcB15 led to an increase in the frequency of Lac+ recombinants over wild-type levels. recF143 did not appreciably alter the number of Lac+ progeny, whereas recL152 and sbcB15 strains yielded increased numbers of Lac+ recombinants. The nature and formation of Lac+ recombinants was also examined. Respreading analysis indicated that formation of recombinants occurred primarily as the cells entered early stationary phase on the surface of the minimal agar plates and that over 90% of the recombinants contained a phi80dIIlac+ prophage. Time-of-entry experiments suggested that the region of deoxyribonucleic acid between the two operons was not inverted as a result of the recombinational event.     

An Escherichia coli gene divergently transcribed from a promoter overlapping the metA promoter

The upstream region of the metA gene in Escherichia coli contains two promoters. We have identified by lacZ fusion an additional promoter in this region, and showed that it is transcribed in the opposite orientation from the metA gene. The putative translation product corresponds to a peptide of 147 amino acids – ORF19 by molecular mass. This peptide is probably not essential for growth, as an insertion mutant is viable.     

Resolution of glpA and glpT loci into separate operons in Escherichia coli K-12 strains.

The independent insertion of bacteriophage Mu into the gene coding for anaerobic sn-glycerol 3-phosphate dehydrogenase (glpA) or into the genes coding for sn-glycerol 3-phosphate transport (glpT) suggested that these two closely linked loci are in separate operons.     

Molecular analysis of the cryptic and functional phn operons for phosphonate use in Escherichia coli K-12.

We cloned the cryptic phn operon of a K-12 strain, phn(EcoK), and analyzed the nucleotide sequence of the phn region (11,672 bp). An mRNA start site upstream of the phnC gene was identified by S1 nuclease mapping. The pho regulon activator PhoB protects a pho box region near the mRNA start in DNase I footprinting and methylation protection experiments. The sequence of the cryptic phn(EcoK) operon was very similar to that of the functional phn operon of an Escherichia coli B strain, phn(EcoB) (C.-M. Chen, Q.-Z. Ye, Z. Zhu, B. L. Wanner, and C. T. Walsh, J. Biol. Chem. 265:4461-4471, 1990). The phnE(EcoK) gene has an 8-bp insertion, absent from the phnE(EcoB) gene, which causes a frameshift mutation. The spontaneous activation of the cryptic phn(EcoK) operon is accompanied by loss of this additional 8-bp insertion. Studies of the structure, regulation, and function of the phn region suggest that the phosphate starvation-inducible phn operon consists of 14 cistrons from phnC to phnP.     

Cross-resistance between bacteriophages and colicins in Escherichia coli K-12.

Cross-resistance between bacteriophages and colicins was studied using collections of bacteriophage- and colicin-resistant mutants of Escherichia coli K-12. No new examples were found of highly specific one-to-one cross-resistance of the type suggestive of common receptors. However, several groups of mutants showed tolerance to colicins and resistance to bacteriophages. Mutants known to be very defective in lipopolysaccharides composition were found to commonly show tolerance to certain colicins in addition to their bacteriophage resistance. Another group of mutants showed varying patterns of resistance to colicins E2, E3, K, L, A, S4, N, and X and bacteriophages E4, K2, K20, K21, K29, and H+. However, many bacteriophage-resistant mutants were fully colicin sensitive, and most colicin-resistant mutants were fully sensitive to bacteriophages.     

Uroporphyrin-accumulating mutant of Escherichia coli K-12.

An uroporphyrin III-accumulating mutant of Escherichia coli K-12 was isolated by neomycin. The mutant, designated SASQ85, was catalase deficient and formed dwarf colonies on usual media. Comparative extraction by cyclohexanone and ethyl acetate showed the superiority of the former for the extraction of the uroporphyrin accumulated by the mutant. Cell-free extracts of SASQ85 were able to convert 5-aminolevulinic acid and porphobilinogen to uroporphyrinogen, but not to copro- or protoporphyrinogen. Under the same conditions cell-free extracts of the parent strain converted 5-aminolevulinic to uroporphyringen, coproporphyrinogen, and protoporphyrinogen. The conversion of porphobilinogen to uroporphyrinogen by cell-free extracts of the mutant was inhibited 98 and 95%, respectively, by p-chloromercuribenzoate and p-chloromercuriphenyl-sulfonate, indicating the presence of uroporphyrinogen synthetase activity in the extracts. Spontaneous transformation of porphobilinogen to uroporphyrin was not detectable under the experimental conditions used [4 h at 37 C in tris(hydroxymethyl)aminomethane-potassium phosphate buffer, pH 8.2]. The results indicate a deficient uroporphyrinogen decarboxylase activity of SASQ85 which is thus the first uroporphyrinogen decarboxylase-deficient mutant isolated in E. coli K-12. Mapping of the corresponding locus by P1-mediated transduction revealed the frequent joint transduction of hemE and thiA markers (frequency of co-transduction, 41 to 44%). The results of the genetic analysis suggest the gene order rif, hemE, thiA, metA; however, they do not totally exclude the gene order rif, thiA, hemE, metA.