Determination of the precise location and orientation of the Escherichia coli dnaE gene

Linkage map of Escherichia coli K-12, edition 10: the traditional map

This map is an update of the edition 9 map by Berlyn et al. (M. K. B. Berlyn, K. B. Low, and K. E. Rudd, p. 1715-1902, in F. C. Neidhardt et al., ed., Escherichia coli and Salmonella: cellular and molecular biology, 2nd ed., vol. 2, 1996). It uses coordinates established by the completed sequence, expressed as 100 minutes for the entire circular map, and adds new genes discovered and established since 1996 and eliminates those shown to correspond to other known genes. The latter are included as synonyms. An alphabetical list of genes showing map location, synonyms, the protein or RNA product of the gene, phenotypes of mutants, and reference citations is provided. In addition to genes known to correspond to gene sequences, other genes, often older, that are described by phenotype and older mapping techniques and that have not been correlated with sequences are included.

Isolation and characterization of suppressors of two Escherichia coli dnaG mutations, dnaG2903 and parB

The dnaG gene of Escherichia coli encodes the primase protein, which synthesizes a short pRNA that is essential for the initiation of both leading and lagging strand DNA synthesis. Two temperature-sensitive mutations in the 3' end of the dnaG gene, dnaG2903 and parB, cause a defect in chromosome partitioning at the nonpermissive temperature 42 degrees. We have characterized 24 cold-sensitive suppressor mutations of these two dnaG alleles. By genetic mapping and complementation, five different classes of suppressors have been assigned; sdgC, sdgD, sdgE, sdgG and sdgH. The genes responsible for suppression in four of the five classes have been determined. Four of the sdgC suppressor alleles are complemented by the dnaE gene, which encodes the enzymatic subunit of DNA polymerase III. The sdgE class are mutations in era, an essential GTPase of unknown function. The sdgG suppressor is likely a mutation in one of three genes: ubiC, ubiA or yjbI. The sdgH class affects rpsF, which encodes the ribosomal protein S6. Possible mechanisms of suppression by these different classes are discussed.

Interallelic complementation of dnaE(Ts) mutations

Some Escherichia coli dnaE(Ts) alleles will functionally complement in trans. The complementation is not due to copy number and is compatible with dimeric interaction.

Holoenzyme DNA polymerase III fixes mutations

DNA polymerase III is required for mutagenesis after damage to the chromosome. This effect is not modulated by the presence or absence of DNA polymerase II activity in the cell. In cells containing a temperature-sensitive dnaE mutation, the alpha-subunit of DNA polymerase III is inactivated at the restrictive temperature, resulting in lethality. Cells containing the pcbA1 mutation can continue replication if DNA polymerase I activity is present. When such cells are shifted from the permissive to the restrictive temperature, mutagenesis decreases rapidly after 10 min. These results are compatible with conversion of the replicative apparatus from one containing a functional DNA polymerase III synthetic subunit to one containing DNA polymerase I. We also find that DNA polymerase I dependent replication is markedly sensitive to coumermycin A1. We conclude that DNA polymerase III holoenzyme with the alpha-subunit is required for fixing mutations in the genome.

First committed step of lipid A biosynthesis in Escherichia coli: sequence of the lpxA gene

The min 4 region of the Escherichia coli genome contains genes (lpxA and lpxB) that encode proteins involved in lipid A biosynthesis. We have determined the sequence of 1,350 base pairs of DNA upstream of the lpxB gene. This fragment of DNA contains the complete coding sequence for the 28.0-kilodalton lpxA gene product and an upstream open reading frame capable of encoding a 17-kilodalton protein (ORF17). In addition there appears to be an additional open reading frame (ORF?) immediately upstream of ORF17. The initiation codon for lpxA is a GUG codon, and the start codon for ORF17 is apparently a UUG codon. The start and stop codons overlap between ORF? and ORF17, ORF17 and lpxA, and lpxA and lpxB. This overlap is suggestive of translational coupling and argues that the genes are cotranscribed. Crowell et al. (D.N. Crowell, W.S. Reznikoff, and C.R.H. Raetz, J. Bacteriol. 169:5727-5734, 1987) and Tomasiewicz and McHenry (H.G. Tomasiewicz and C.S. McHenry, J. Bacteriol. 169:5735-5744, 1987) have demonstrated that there are three similarly overlapping coding regions downstream of lpxB including dnaE, suggesting the existence of a complex operon of at least seven genes: 5'-ORF?-ORF17-lpxA-lpxB-ORF23-dnaE-ORF37-3 '.

Sequence analysis of the Escherichia coli dnaE gene

We have determined the sequence of a 4,350-nucleotide region of the Escherichia coli chromosome that contains dnaE, the structural gene for the alpha subunit of DNA polymerase III holoenzyme. The dnaE gene appeared to be part of an operon containing at least three other genes: 5'-lpxB-ORF23-dnaE-ORF37-3' (ORF, open reading frame). The lpxB gene encodes lipid A disaccharide synthase, an enzyme essential for cell growth and division (M. Nishijima, C.E. Bulawa, and C.R.H. Raetz, J. Bacteriol. 145:113-121, 1981). The termination codons of lpxB and ORF23 overlapped the initiation codons of ORF23 and dnaE, respectively, suggesting translational coupling. No rho-independent transcription termination sequences were observed. A potential internal transcriptional promoter was found preceding dnaE. Deletion of the -35 region of this promoter abolished dnaE expression in plasmids lacking additional upstream sequences. From the deduced amino acid sequence, alpha had a molecular weight of 129,920 and an isoelectric point of 4.93 for the denatured protein. ORF23 encoded a more basic protein (pI 7.11) with a molecular weight of 23,228. In the accompanying paper (D.N. Crowell, W.S. Reznikoff, and C.R.H. Raetz, J. Bacteriol. 169:5727-5734, 1987), the sequence of the upstream region that contains lpxA and lpxB is reported.

Nucleotide sequence of the Escherichia coli gene for lipid A disaccharide synthase

The lpxB gene of Escherichia coli, believed to be the structural gene for lipid A disaccharide synthase, is located in the min 4 region of the chromosome. It is adjacent to and clockwise of the lpxA gene, which is thought to encode UDP-N-acetylglucosamine acyltransferase. Preliminary evidence suggests that lpxA and lpxB are cotranscribed in the clockwise direction and thus constitute part of a previously unknown operon (D. N. Crowell, M. S. Anderson, and C. R. H. Raetz, J. Bacteriol. 168:152-159, 1986). We now report the complete nucleotide sequence of a 1,522-base-pair PvuII-HincII fragment known to carry the lpxB gene. This sequence contained an open reading frame of 1,149 base pairs, in agreement with the predicted size, location, and orientation of lpxB. There was a second open reading frame 5' to, and in the same orientation as, lpxB that corresponded to lpxA. The ochre codon terminating lpxA was shown to overlap the methionine codon identified as the initiation codon for lpxB, suggesting that these genes are cotranscribed and translationally coupled. A third open reading frame was also shown to begin at the 3' end of lpxB with analogous overlap between the opal codon terminating lpxB and the methionine codon that putatively initiates translation downstream of lpxB in the clockwise direction. These results argue that at least three genes constitute a translationally coupled operon in the min 4 region of the E. coli chromosome. The accompanying paper by Tomasiewicz and McHenry (J. Bacteriol. 169:5735-5744, 1987) presents 4.35 kilobases of DNA sequence, beginning at the 3' end of lpxB, and argues that dnaE and several other open reading frames may be members of this operon.

DNA polymerase III requirement for repair of DNA damage caused by methyl methanesulfonate and hydrogen peroxide

The pcbA1 mutation allows DNA replication dependent on DNA polymerase I at the restrictive temperature in polC(Ts) strains. Cells which carry pcbA1, a functional DNA polymerase I, and a temperature-sensitive DNA polymerase III gene were used to study the role of DNA polymerase III in DNA repair. At the restrictive temperature for DNA polymerase III, these strains were more sensitive to the alkylating agent methyl methanesulfonate (MMS) and hydrogen peroxide than normal cells. The same strains showed no increase in sensitivity to bleomycin, UV light, or psoralen at the restrictive temperature. The sensitivity of these strains to MMS and hydrogen peroxide was not due to the pcbAl allele, and normal sensitivity was restored by the introduction of a chromosomal or cloned DNA polymerase III gene, verifying that the sensitivity was due to loss of DNA polymerase III alpha-subunit activity. A functional DNA polymerase III is required for the reformation of high-molecular-weight DNA after treatment of cells with MMS or hydrogen peroxide, as demonstrated by alkaline sucrose sedimentation results. Thus, it appears that a functional DNA polymerase III is required for the optimal repair of DNA damage by MMS or hydrogen peroxide.

Isolation and characterization of a new globomycin-resistant dnaE mutant of Escherichia coli

We isolated a globomycin-resistant, temperature-sensitive mutant of Escherichia coli K-12 strain AB1157. The mutation mapped in dnaE, the structural gene for the alpha-subunit of DNA polymerase III. The in vivo processing of lipid-modified prolipoprotein was more resistant to globomycin in the mutant strain 307 than in its parent. The prolipoprotein signal peptidase activity was also increased twofold in the mutant, and there was a threefold increase in the activity of isoleucyl-tRNA synthetase. The results suggest that a mutation in dnaE may affect the expression of the ileS-lsp operon in E. coli. In addition, strain 307 showed a reduced level of streptomycin resistance compared with its parental strain AB1157 (rpsL31). Strain 307 was killed by streptomycin at a concentration of 200 micrograms/ml, which did not affect the rate of bulk protein synthesis in this mutant. A second mutation which was involved in the reduced streptomycin resistance in strain 307 was identified and found to be closely linked to or within the rpsD (ramA, ribosomal ambiguity) gene. Both dnaE and rpsD were required for the reduced streptomycin resistance in strain 307.

DNA polymerase III of Escherichia coli is required for UV and ethyl methanesulfonate mutagenesis

Strains of Escherichia coli possessing the pcbA1 mutation, a functional DNA polymerase I, and a temperature-sensitive mutation in DNA polymerase III can survive at the restrictive temperature (43 degrees C) for DNA polymerase III. The mutation rate of the bacterial genome of such strains after exposure to either UV light or ethyl methanesulfonate was measured by its rifampicin resistance or amino acid requirements. In addition, Weigle mutagenesis of preirradiated lambda phage was also measured. In all cases, no increase in mutagenesis was noted at the restrictive temperature for DNA polymerase III. Introduction of a cloned DNA polymerase III gene returned the mutation rate of the bacterial genome as well as the Weigle mutagenesis to normal at 43 degrees C. Using a recA-lacZ fusion, the SOS response after UV irradiation was measured and found to be normal at the restrictive and permissive temperature for DNA polymerase III, as was induction of lambda prophage. Recombination was also normal at either temperature. Our studies demonstrate that a functional DNA polymerase III is strictly required for mutagenesis at a step other than SOS induction.

Molecular cloning of the genes for lipid A disaccharide synthase and UDP-N-acetylglucosamine acyltransferase in Escherichia coli

Several enzymes have been discovered recently in crude extracts of Escherichia coli that appear to be involved in the biosynthesis of the lipid A component of lipopolysaccharide. Two of these are lipid A disaccharide synthase and UDP-N-acetylglucosamine acyltransferase. Lipid A disaccharide synthase activity is barely detectable in cells harboring a lesion in the lpxB (pgsB) gene. We subcloned the lpxB gene from plasmid pLC26-43 of the Clarke and Carbon collection (L. Clarke and J. Carbon, Cell 9:91-99, 1976) and localized it to a 1.7-kilobase-pair fragment of DNA counterclockwise of dnaE on the E. coli chromosome. Furthermore, we discovered a new gene (lpxA) located adjacent to and counterclockwise of lpxB that encodes or controls UDP-N-acetylglucosamine acyltransferase. Our data prove that lpxB and lpxA are transcribed in the clockwise direction and suggest that they may be cotranscribed.

DNA polymerase III holoenzyme of Escherichia coli: components and function of a true replicative complex

The DNA polymerase III holoenzyme is a complex, multisubunit enzyme that is responsible for the synthesis of most of the Escherichia coli chromosome. Through studies of the structure, function and regulation of this enzyme over the past decade, considerable progress has been made in the understanding of the features of a true replicative complex. The holoenzyme contains at least seven different subunits. Three of these, alpha, epsilon and theta, compose the catalytic core. Apparently alpha is the catalytic subunit and the product of the dnaE gene. Epsilon, encoded by dnaQ (mutD), is responsible for the proofreading 3'----5' activity of the polymerase. The function of the theta subunit remains to be established. The auxiliary subunits, beta, gamma and delta, encoded by dnaN, dnaZ and dnaX, respectively, are required for the functioning of the polymerase on natural chromosomes. All of the proteins participate in increasing the processivity of the polymerase and in the ATP-dependent formation of an initiation complex. Tau causes the polymerase to dimerize, perhaps forming a structure that can coordinate leading and lagging strand synthesis at the replication fork. This dimeric complex may be asymmetric with properties consistent with the distinct requirements for leading and lagging strand synthesis.