Aromatic amino acid biosynthesis: regulation of shikimate kinase in Escherichia coli K-12.

Starvation of cells of Escherichia coli K-12 for the aromatic amino acids results in an increased rate of synthesis of shikimate kinase activity. The two controlling amino acids are tyrosine and tryptophan, and starvation for both results in derepression. The product of the regulator gene tyrR also participates in this control, and shikimate kinase synthesis was depressed in tyrR mutants. Chromatography of cell extracts on diethylaminoethyl-Sephadex allowed partial separation of two shikimate kinase enzymes and demonstrated that only one of these subject to specific repression control involving tyrR. By contrast, chromatography of cell extracts with G-75 or G-200 columns revealed a singl-molecular-weight species of shikimate kinase activity with an apparent molecular weight of 20,000. The levels of shikimate kinase in a series of partial diploid strains indicated that aroL, the structural gene for the tyrR-controlled shikimate kinase enzyme, is located on the E. coli chromosome between the structural genes proC and purE. By means of localized mutagenesis, an aroL mutant of E. coli was isolated. The mutant was an aromatic prototroph and, by the criterion of column chromatography, appeared to have only a single functional species of shikimate kinase enzyme.     

Genetic analysis of the Escherichia coli K-12 srl region.

Specialized transducing lambda derivatives, deletion mapping, and Plkc transductional crosses have been used to analyze the genetic organization and regulation of the srl genes. Transducing phages obtained from a secondary site lambda insertion in srlA are of two types: lambdapsrlC1 and lambdaprecA are substituted in the b2 region of the lambda chromosome (galtype) and carry the srlC gene but not srlD; lambdapsrlD is substituted in the early region of the phage deoxyribonucleic acid (biotype) and carries the srlD gene but not srlC. The lambdapsrlC1 phage, which lysogenizes at attlambda, complements srlC mutants in trans, indicating that this gene codes for a diffusable positive regulatory element. The srl genes have been ordered relative to the cysC, recA, and alaS genes by two- and three-factor P1kc crosses. The order, cysC...srlD-srlA-srlC-recA-alaS, has been obtained. The srlA and srlD genes comprise an operon with srlD operator distal. From the secondary site lysogen, it has been possible to obtain deletion mutants of this region that are sensitive to ultraviolet light and are recombination deficient. Genetic evidence suggests that these deletions extend from srl into the recA gene.     

Regulation of aroL expression by TyrR protein and Trp repressor in Escherichia coli K-12.

The promoter-operator region of the aroL gene of Escherichia coli K-12 contains three TYR R boxes and one TrpR binding site. Mutational analysis showed that TYR R boxes 1 and 3 are essential for TyrR-mediated regulation of aroL expression, while a fully functional TYR R box 2 does not appear to be essential for regulation. Regulation mediated by the TrpR protein required the TYR R boxes and TrpR site to be functional and was observed in vivo only with a tyrR+ strain. Under conditions favoring the formation of TyrR hexamers, DNase I protection experiments revealed the presence of phased hypersensitive sites, indicative of DNA backbone strain. This suggests that TyrR-mediated repression involves DNA looping. Purified TrpR protein protected the putative TrpR binding site in the presence of tryptophan, and this protection was slightly enhanced in the presence of TyrR protein. This result along with the in vivo findings implies that TyrR and TrpR are able to interact in some way. Inserting 4 bp between TYR R box 1 and the TrpR binding site results in increased tyrosine repression and the abolition of the tryptophan effect. Identification of a potential integration host factor binding site and repression studies of a himA mutant support the notion that integration host factor binding normally exerts a negative effect on tyrosine-mediated repression.     

Genetic mapping of xthA, the structural gene for exonuclease III in Escherichia coli K-12.

The genes xthA, pncA, and pabB were ordered relative to others by two- and three-factor transductional crosses with bacteriophage P1. The genes studied span 2 min (2%) of the genetic map of Escherichia coli K-12 in the clockwise sequence pheS-pfkB-xthA-pncA-gap-pabB-fadD. Eleven independently derived xth mutations were examined; all were known to affect exonuclease III and its associated endonuclease II activity, and all were mapped in the xthA region. pncA mutations were found to confer resistance to 6-aminonicotinamide, whereas some pheS mutations are known to specify resistance to p-fluorphenylalanine. xth mutations were readily transferred into other strains by selecting for these co-transducible drug resistance markers.     

nfi, the gene for endonuclease V in Escherichia coli K-12.

Endonuclease V is specific for single-stranded DNA or for duplex DNA that contains uracil or that is damaged by a variety of agents (B. Demple and S. Linn, J. Biol. Chem. 257:2848-2855, 1982). Thus, it may be a versatile DNA repair enzyme. The protein was purified to apparent homogeneity, and from its N-terminal sequence, its gene, nfi, was identified. nfi is immediately downstream of hemE, at kb 4208 (90.4 min) on the current chromosomal map of Escherichia coli K-12. This region was cloned, and plasmid insertion and deletion mutants were used to study its molecular organization. Although nfi is the third of four closely spaced, codirectional genes, it is expressed independently.     

Genetic analysis of the 5-azacytidine sensitivity of Escherichia coli K-12.

DNA containing 5-azacytidine (5-azaC) has been shown to form stable detergent-resistant complexes with cytosine methylases. We reasoned that if 5-azaC treatment causes protein-DNA cross-links in vivo, then mutations in DNA repair and recombination genes may increase the sensitivity of a cell to 5-azaC. We found that although recA (defective) and lexA (induction-negative) mutants of Escherichia coli were very sensitive to the drug, mutations in uvrA and ung genes had little effect on cell lethality. The sensitivity of recA strains to 5-azaC was dose dependent and was enhanced by the overproduction of a DNA cytosine methylase in the cell. Unexpectedly, a strain of E. coli carrying a recA mutation and a deletion of the DNA cytosine methylase gene (dcm) was found to be significantly sensitive to 5-azaC. Study of mutations in the pyrimidine salvage pathway of E. coli suggests that direct phosphorylation of 5-azaC, rather than phosphorylation of its degradation products, is largely responsible for the lethal effects of the drug. The addition of uracil to the growth medium has little effect on cell lethality of recA mutants, but it partially reversed the inhibition of cell growth caused by 5-azaC. This reversal of the bacteriostatic effects of the drug could not be achieved by adding cytosine or orotic acid to the growth medium and required the presence of functional UMP-pyrophosphorylase (gene upp) in the cell.     

Genetic and physical analysis of the thioredoxin (trxA) gene of Escherichia coli K-12

The trxA gene of Escherichia coli K-12 has been cloned into multicopy plasmids on DNA fragments of varying sizes. The smallest of these was a 1-kb fragment resulting from partial digestion with Sau3A (pBHK10). The complete nucleotide sequence of the trxA gene and its promoter was determined. Comparison of the DNA sequence with the published amino acid sequence revealed the inversion of two amino acid pairs and the possibility of a leader peptide 18 amino acids in length. Three-factor P1 transductional crosses and physical mapping experiments have determined a map order of ilv-trxA-uvrD-corA-metE.     

Cloning of the Escherichia coli K-12 hemB gene.

An Escherichia coli heme-requiring, heme-permeable mutant had no detectable 5-aminolevulinate dehydratase or porphobilinogen deaminase activities. The gene which complemented this mutation was cloned to a high-copy-number plasmid, and porphobilinogen deaminase activity was restored to normal levels, but the synthesis of 5-aminolevulinate dehydratase increased 20- to 30-fold. A maxicell procedure confirmed that the gene cloned was hemB.     

rhs gene family of Escherichia coli K-12.

Two additional members of a novel Escherichia coli gene family, the rhs genes, have been cloned and characterized. The structures of these loci, rhsC and rhsD, have been compared with those of rhsA and rhsB. All four loci contain a homologous 3.7-kilobase-pair core. Sequence comparison of the first 300 nucleotides of the cores showed that rhsA, rhsB, and rhsC are closely related, with only 1 to 2% sequence divergence, whereas rhsD is 18% divergent from the others. The beginning of the core coincides with the initiation of an open reading frame that extends beyond the 300 nucleotides compared. Whether a protein product is produced from this open reading frame has not been established. However, nucleotide substitutions which differentiate the cores have highly conservative effects on the predicted protein products; this suggests that products are made from the open reading frame and are under severe selection. The four rhs loci have been placed on both the genetic and restriction maps of E. coli K-12. A fifth rhs locus remains to be characterized. In terms of size, number, and sequence conservation, the rhs genes make up one of the most significant repetitions in E. coli, comparable to the rRNA operons.     

Mutational analysis of nitrate regulatory gene narL in Escherichia coli K-12.

The narL gene product, NarL, is the nitrate-responsive regulator of anaerobic respiratory gene expression. We used genetic analysis of narL mutants to better understand the mechanism of NarL-mediated gene regulation. We selected and analyzed seven nitrate-independent narL mutants. Each of three independent, strongly constitutive mutants had changes of Val-88 to Ala. The other four mutants were weakly constitutive. The narL505(V88A) allele was largely dominant to narL+, while narX+ had a negative influence on its constitutive phenotype, suggesting that NarX may play a negative role in nitrate regulation. We also constructed two narL mutations that are analogous to previously characterized constitutive degU alleles. The first, narL503(H15L), was a recessive null allele. The second, narL504(D110K), functioned essentially as wild type but was dependent on narX+ for full activity. We changed Asp-59 of NarL, which corresponds to the site of phosphorylation of other response regulators, to Asn. This change, narL502(D59N), was a recessive null allele, which is consistent with the hypothesis that NarL requires phosphorylation for activation. Finally, we tested the requirement for molybdate on regulation in a narL505(V88A) strain. Although narL505(V88A) conferred some nitrate-independent expression of fdnGHI (encoding formate dehydrogenase-N) in limiting molybdate, it required excess molybdate for full induction both in the absence and in the presence of nitrate. This finding suggests that narL505(V88A) did not confer molybdate-independent expression of fdnGHI.     

Genetic analysis of the RecE pathway of genetic recombination in Escherichia coli K-12.

The RecE pathway of genetic recombination in Escherichia coli K-12 was defined to be the pathway that is utilized in deoxyribonucleic acid exonuclease V (ExoV)-defective cells which express constitutively recE+, the structural gene for deoxyribonucleic acid exonuclease VIII. Dependence on ExoVIII was shown by the occurrence in a recB21 sbcA23 strain of recombination deficiency mutations in recE, the structural gene for ExoVIII. Point mutations in recE were found as well as deletion mutations in which the entire Rac prophage, carrying recE, was lost. In addition, strain construction and mutagenesis revealed the dependence of the RecE pathway on recA+ and on recF+. Dependence on a fourth gene was shown by a mutation (rec-77) which does not map near the other genes. The problem of distinguishing the RecE pathway from that previously called RecF is discussed.     

Genetic and biochemical analysis of the biotin loci of Escherichia coli K-12

Some 60 biotin auxotrophs of Escherichia coli K-12 were isolated and classified into four groups according to their cross-feeding patterns, excertion products, and their ability to show a growth response to various biotin vitamers. Since all the mutants could be transduced with lambdadbio phages known to carry the entire bioA locus, it was concluded that all of the mutation sites were located in this locus. It was also possible to derive a gene order for the different mutant groups on the basis of transduction studies with various lambdadbio phages that carry portions of the bioA locus. A possible biochemical pathway for the biosynthesis of biotin in E. coli K-12 is discussed.     

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.