Coordinate expression of Escherichia coli dnaA and dnaN genes

Summary The defects of temperature-sensitive dnaA and dnaN mutants of Escherichia coli are complemented by a recombinant lambda phage, which carries the bacterial DNA segment composed of two EcoRI segments of 1.0 and 3.3 kilobases. Derivatives of the phage, which have an insertion segment of Tn3 in the dnaA gene, are much less active in expressing the dnaN gene function than the parent phage. The dnaN gene activity was determined as the efficiency of superinfecting phage to suppress loss of the viability of lysogenic dnaN59 cells at the nonpermissive temperature. Deletions that include the end of the dnaA gene distal to the dnaN gene also reduce the expression of the dnaN gene fuction. Deletion and insertion in the dnaN gene do not affect the expression of the dnaA gene function. The expression of the dnaN gene function by the dnaA ^- dnaN ⁺ phages remains weak upon simultaneous infection with dnaA ⁺ dnaN ^- phages. Thus the insertion and deletion in the dnaA gene influence in cis the expression of the dnaN gene. We propose that the dnaA and dnaN genes constitute an operon, where the former is upstream to the latter.     

Requirement of the Escherichia coli dnaA gene function for integrative suppression of dnaA mutations by plasmid R100-1

Summary The phenotype of Escherichia coli dnaA missense and nonsense mutations was integratively suppressed by plasmid R100-1. The suppressed strains, however, could not survive when the dnaA function was totally inactivated. This was demonstrated by the inability of replacing the dnaA allele in the suppressed strain by a dnaA::Tn10 insertion using phage P1-mediated transduction. When the intact dnaA ⁺ allele was additionally supplied by a specialized transducing phage, imm ²¹ dnaA ⁺, which integrated at the att site on the E. coli chromosome, then the dnaA::Tn10 insertion, together with a oriC deletion, were able to be introduced into the suppressed strain. Thus, the mechanisms of dnaA function for oriC and for the replication origin of R100-1 may not be quite the same.     

Identification of the dnaA and dnaN gene products of Escherichia coli

Summary A specialized transducing lambda phage carrying the dnaN and dnaA genes of Escherichia coli specifies two proteins of about 41 and 48 kilodaltons (kd). The temperature-sensitive mutations, dnaN59 and dnaA167, were found to result in altered isoelectric points of the 41 and 48 kd proteins, respectively. Thus the dnaN gene product was identified as a weakly acidic 41 kd protein, and the dnaA gene product as a weakly basic 48 kd protein. The synthesis of the dnaN gene product is greatly reduced by insertion of a transposon Tn3 in the dnaA gene and by deletion in the gene at the distal end to the dnaN gene. Temperature-sensitive dnaA mutations, on the other hand, do not affect the synthesis of the dnaN gene product. These results indicate that the synthesis of the dnaN gene product is dependent on the structural integrity of the dnaA gene.Abbreviations kd kilodaltons - SDS sodium dodecyl sulfate     

Analysis of a temperature sensitive mutation in gene cII of bacteriophage lambda

Summary The mutation cIIts612 was found to map outside the immunity region of phage imm21 hybrid. As expected of a cII mutation, cIIts612 is unable to stimulate either cI repressor or Int synthesis during the establishment of lysogeny. These results indicate that part of the cII gene of is homologous to that of imm21 phage.     

Characterization of the dnaA, gyrB and other genes in the dnaA region of the Escherichia coli chromosome on specialized transducing phages lambda tna.

Summary Specialized transducing phages tna (tryptophanase) harboring chromosomal DNA and genetic markers from the dnaA region of the Escherichia coli chromosome were isolated. Transductional analysis showed that some of these tnaA transducing phages carry two genes important in DNA replication, namely the dnaA gene (initiation of chromosome replication) and the gyrB gene (subunit B of DNA gyrase), formerly designated cou ^R. The following clockwise order of genetic markers was found: uhp, gyrB, dnaA, rimA, tnaA, bglB.The gene-protein relationship was established by the determination of the gene products encoded on the chromosomal DNA of the different tna. A 54 kD and a 91 kD polypeptide appear to be coded for by the dnaA and gyrB genes, respectively; the 91 kD protein is encoded on a region in which coumermycin sensitivity maps and is with respect to electrophoretic behavior identical to subunit B of DNA gyrase. The 54 kD protein is encoded on the region in which different independently isolated dnaA(Ts) mutations (dnaA5, dnaA46, dnaA167, dnaA203, dnaA204, dnaA205, dnaA211, dnaA508) are located. Additional genes which code for polypeptides with hitherto unknown functions were identified and mapped. The acriflavin sensitivity mutation acrB1 was found to be an allele of the gyrB gene (see Note Added in Proof).     

Identification of the E. coli dnaJ gene product

Summary We have previously shown that a mutation (groPC259) in the E. coli dnaJ gene renders the cell inviable at high temperatures and arrests bacteriophage DNA replication at all temperatures (Sunshine et al., 1977). We have isolated dnaJ ⁺⁺ transducing phages both by in vitro cloning and by abnormal excision of a dnaK transducing phage integrated near the dnaJ locus. The dnaJ gene product has been identified on SDS polacrylamide gels after infection of UV-irradiated E. coli cells by dnaJ ⁺⁺ derivative phages. It is a polypeptide chain with an apparent molecular weight of 37,000-daltons. This has been verified by the fact that a transducing phage carrying an amber mutation in the dnaJ gene fails to induce the synthesis of the 37,000-dalton polypeptide chain upon infection of sup ⁺⁺ bacteria, but does so upon infection of supF or supD bacteria.     

Characterization of dnaA gene carried by lambda transducing phage

Summary Specialized transducing phages dnaA were obtained by inducing lysogens in which tna was integrated at the tnaA region of the Escherichia coli chromosome; the tnA region is located in the vicinity of the dnaA gene. The dnaA ^- deletion derivatives of dnaA were isolated from the lysate of dnaA grown on bacteria carrying a transposon Tn3.The structures of various transducing phages thus obtained were determined by heteroduplex DNA mapping. From these results, the transducing fragment of 13.8-kb-long was divided into nine domains. Upon infection of UV-irradiated cells with the phage, production of polypeptides of 49 kD and 42 kD was specifically associated with infections by the dnaA and recF transducing phages. Polypeptides of 49 kD and 42 kD appeared to be coded for by dnaA and recF genes, respectively. The dnaA gene was assigned to the region of 2.8-kb-long which extends by 2.4 kb in the counterclockwise direction on the E. coli genetic map and 0.4 kb in the opposite direction, as measured from the nearest HindIII site close to the tnaA gene. The recF gene was also discovered to lie very close to dnaA in the order of tnaA-dnaA-recF.Merogenotes heterozygous for the dnaA gene were constructed by introducing F100-12 carrying dnaA into the recipients with different mutations at or near dnaA. For combinations, F(dnaA ⁺)/dnaA46 and F(dna ⁺)/dna-83, dnaA ⁺ was trans-dominant, whereas the dnaA ⁺ was recessive for F(dnaA ⁺)/dna-5. For F(dnaA ⁺)/dna-167, the result of the transdominance test was affected by the growth media employed; dnaA ⁺ was dominant on a -broth plate, and dna-167 was dominant on an M9-minimal plate. Thus, transdominance of dnaA ⁺ in heterozygotes is affected by difference in mutations and growth media.     

Establishment of Escherichia coli cells with an integrated high copy number plasmid

Summary The dnaA46 cells can grow at high temperature when a high copy number plasmid pKY31, a derivative of pBR322 carrying a segment of the E. coli chromosome, integrates into the bacterial chromosome. In contrast, the dnaA46 polA ^- cells with the integrated plasmid can not grow at high temperature. Therefore, integration of the plasmid can suppress the dnaA mutation and this suppression requires DNA polymerase I which has been known to be required for plasmid replication. Full reversion of polA or lysogenization of polA ⁺ is lethal for the dnaA46polA ^- bacteria that carry the plasmid only in integrated state. Partial reversion of polA allows these cells to grow at both low and high temperatures. Introduction of the plasmid pBR322 into cytoplasm of these bacteria suppresses the lethal effect caused by full reversion of polA or lysogenization of polA ⁺. This lethal effect expresses independent of the presence or absence of the dnaA mutation. In partial revertants of polA which have only integrated plasmid, the number of copies of a region near the replication origin of integrated plasmid increases. The number is reduced by the presence of extrachromosomal pBR322. It is suggested that the lethal effect of normal levels of DNA polymerase I in strains that carry only the integrated plasmid is due to excessive initiation of replication of the bacterial chromosome from the plasmid origin and high potential of initiation can be absorbed in many copies of cytoplasmic plasmid, probably, in their replication origins.Abbreviations Amp^r ampicillin resistant (resistance) - Tet^s tetracycline sensitive - Tet^r tetracycline resistant - MMS^r methyl methane sulfonate resistant (resistance) - ts temperature sensitive - Kb kilobase pairs     

Cloning and characterization of the alkaline phosphatase positive regulator gene (phoB) of Escherichia coli

Summary The positive regulator gene (phoB) for alkaline phosphatase of Escherichia coli was cloned into the EcoRI site of pBR322 from the E. coli chromosome by a shotgun method. phoB was then constructed in vitro by replacing the C fragment of gtC by the phoB chromosomal fragment obtained from the hybrid plasmid. When the phoB mutant was lysogenized by phoB, the lysogen became PhoB⁺. The integration site of the phage was identified by P1 phage transduction to be around phoB site on the chromosome. From these results, we conclude that the cloned gene is phoB and not a gene which suppresses phenotypically phoB mutation when it is in a multi-copy state. The restriction map was constructed. Based on this information, several PhoB deletion plasmids and smaller PhoB⁺ plasmids were constructed in vitro. By examining PhoB phenotype when these plasmids were introduced into phoB mutant, we could define the phoB gene locus in 2 kb on the restriction map of the cloned chromosomal fragment. Cells carrying the multi-copy phoB gene produced alkaline phosphatase qualitatively under normal phosphate regulation. The phoB gene product was identified by the maxicell method as a protein with a molecular weight of approximately 31,000 daltons.     

Purification and some properties of presumptive tof gene product of Coli phage 434.

Summary The presumptive tof gene product of Coli phage 434 has been purified from cells carrying imm–⁴³⁴ cIdv plasmid known to contain only some of the early genes of phage 434 and . It was detected and tentatively identified as tof protein primarily by its ability to specifically bind to phage 434 DNA. The protein has a molecular weight of about 11,000 and requires Mg²⁺ for specific DNA binding, unlike 434 cI-repressor.     

Reduced expression of a distal gene of the prn gene cluster in deletion mutants of Aspergillus nidulans: genetic evidence for a dicistronic messenger in an eukaryote.

Summary Temperature sensitive dnaAts46 mutants, in which initiation of chromosome replication is blocked at 42° C, are unable to maintain a dv plasmid at the permissive temperature unless the plasmid carries a mutation in gene P of the type permitting phage to grow in groP (dnaB) bacteria. The growth rate of dnaAts46 mutants seems to be impaired by the presence of the dvP mutant plasmid.Cold sensitive dnaAcos mutants which overinitiate replication at low temperature and grow normally only at 40° and above, can maintain efficiently dvP ⁺ plasmids as well as dvP mutants. Cold sensitivity of dnaAcos mutants is suppressed by the presence of the plasmid dvP ⁺ and by certain dvP mutants, but not by others.The gene P product seems to act by reducing the initiation potential of both types of dnaA mutants, aggravating the initiation defect in dnaAts46 and correcting the overinitiation of dnaAcos.     

Genetic and physical mapping of recF in Escherichia coli K-12

Summary Two factor transductional crosses place recF at approximately 82 min on the E. coli chromosome; recF is highly cotransducible with dnaA and gyrB (cou). Transductional analysis with a series of tna specialized transducing phages carrying chromosomal DNA from the tnaA region place recF between dnaA and gyrB. This analysis also indicates that a gene lying in the same region and producing an easily detectable protein (estimated MW of 45 kD) is dnaN and not recF.     

Effect of the dnaN mutation on the growth of small DNA phages

Summary The effect of the dnaN mutation on the growth of single-stranded DNA phages was studied by burst experiments. In HC138 dnaN cells exposed to 42.5° C at 5 min before infection, growth of spherical (microvirid or isometric) phages such as 3, Kh-1 and X174 was partially reduced at the nonpermissive temperature. When infection was performed at 30 min after temperature shift-up, viral replication was completely inhibited at 42.5° C in the dnaN strain but not in a dna ⁺ revertant. At 41° C, multiplication of filamentous (inovirid) phages M13 and fd was restricted specifically in HC138 F⁺ dnaN bacteria. When dnaN cells lysogenic for i²¹ were grown at 42.5° C for 60 min and then shifted down to 33° C, a burst of i²¹ occurred with concomitant cellular lysis, manifesting induction of the prophage development.     

Initiation of DNA replication in Escherichia coli

Summary When E. coli F⁺ cells carrying the dna-167 or dnaC2 mutation, which causes the temperature-sensitive initiation of DNA replication, are exposed to a non-permissive temperature to stop the replication of chromosome and F factor, and then transferred back to a permissive temperature with the addition of chloramphenicol, one round of the chromosomal replication occurs, but further replication is inhibited. Under these conditions, F DNA replicates coincidentally with the initiation of the chromosomal replication in both strains. When rifampicin is added to the cells upon lowering of the temperature, the chromosome can not replicate in the F⁺ dna-167 strain, but can do so in the F⁺ dnaC2 strain. F DNA can replicate in both of the mutant strains under these conditions.     

Influence of plasmids carrying the lexA gene on DNA repair and related processes in Escherichia coli K-12

Summary Plasmid pLC44-14 from the Clarke and Carbon collection has been shown to carry the lexA gene. The presence of lexA was demonstrated by complementation of tsl mutants which lie close to lexA on the E. coli K-12 linkage map and are probably in the lexA gene, and by crossing the dominant lexA mutation on to pLC44-14 to produce a recombinant plasmid, pSEl, which gave the host cell the properties of a lexA mutant. The lexA gene has been cloned on to pBR322 (Little, 1980). pJL21, which carries the lexA ⁺ gene, rendered the host cell moderately sensitive to UV light, greatly reduced the extent of Weigle reactivation and mutagenesis of UV-irradiated phage , and inhibited induction of protein X by either UV light or nalidixic acid. A similar plasmid carrying a mutant lexA3 allele produced extreme sensitivity to UV light, reduced recombinant production 10 to 50-fold following Hfr x F^– conjugation crosses, and otherwise mimicked the effects of pJL21. Introduction of an amber mutation into the lexA gene carried by the plasmid greatly reduced the UV-sensitivity of the host, thereby indicating that the extreme sensitivity was due to the mutant lexA gene product. These properties of strains with lexA plasmids are thought to originate from high levels of the lexA protein in the cell due to a large plasmid copy number. This protein, which appears from other studies to regulate negatively the recA gene, may inhibit expression of recA or other DNA repair genes when present in excess amounts in the cell.     

Identification of the protein products of the rrnC, ilv, rho region of the Escherichia coli K-12 chromosome

Summary Two methods have been used to identify the protein products of the Escherichia coli K-12 ilv region at 84 min and the flanking rrnC (counterclockwise) and rho (clockwise) loci. First, a set of dilv specialized transducing phages, including some phages that carry rho and others that carry part of rrnC, was used to infect UV irradiated cells. The proteins produced by the infecting dilv phage were selectively labelled with radioactive amino acids and identified by SDS gel electrophoresis and autoradiography. Second, restriction enzyme fragments were cloned from the dilv phage into pBR322 and the plasmid specific gene products produced in maxicells were similarly identified by SDS gel electrophoresis and autoradiography. The proteins produced were correlated with specific genes and restriction enzyme fragments present in the dilv phage and the pBR322 derivatives. Several ilv gene products that have previously been refractory to protein purification attempts have been identified for the first time by this technique. The presence of mutations at the ilvO site is shown to activate the cryptic ilvG gene and to result in the production of a 62,000 dalton protein. A 15,000 dalton protein of unknown function is synthesized from a DNA segment between ilv and rrnC. The rho gene was cloned from dilv phage into pBR322 and shown to be dominant to a rho mutation on the host cromosome. The rho gene product and four additional proteins coded by genes near or between rho and ilv have been detected.     

A new bacterial gene (groPC) which affects lambda DNA replication.

Summary A bacterial mutation affecting DNA replication, called groPC756, has been mapped between the thr and leu bacterial loci. Most of the parental DNA does not undergo even one round of replication in this host. Lambda mutants, called , which map in the P gene are able to overcome the inhibitory effect of the groPC756 mutation. It is shown that the mutation at the groPC locus also interferes with bacterial growth at 42°C. A -transducing phage, carrying the groPC⁺ allele, was isolated as a plaqueformer on groPC756 bacteria. Upon lysogenization, it restores both the gro ⁺ and temperature resistant phenotypes.     

The initiation of chromosome replication in a dnaAts46 and a dnaA+ strain at various temperatures

Summary The regulation of chromosome replication initiation was studied at various temperatures with an E. coli dnaA46 strain and its dnaA ⁺ parent. We find that, in both strains, the initiation mass varies depending upon growth temperature while the replication time remains constant relative to the cell doubling time. In the permissive temperature range, the initiation mass of the dnaA46 mutant strain is larger by a constant factor than that for a dnaA ⁺ strain. We conclude that, even at temperatures permissive for growth of the dnaA46 strain, the activity of the dnaA46 product is lower than that of the wild-type protein. The dnaA gene product, therefore, plays an important role in regulating initiation.