Integrative suppression of dnaA(Ts) mutations mediated by plasmid F in Escherichia coli is a DnaA-dependent process

Summary The thermosensitivity of dnaA(Ts) mutations can be suppressed by integration of plasmid F (integrative suppression). In the light of the recent finding that F requires DnaA protein for both establishment and maintenance, integrative suppression of 11 dnaA(Ts) mutations by a mini-F, pML31, integrated near oriC was examined. The plating efficiency of integratively suppressed strains was dnaA(Ts) allele-dependent and medium-dependent. The initiation capability of suppressed dnaA(Ts) strains lacking the oriC site and their F^- counterparts was determined at various temperatures between 30°C and 42°C. The degree of integrative suppression measured by the initiation capability varied in a dnaA(Ts) allele-dependent manner. F-directed DNA replication was most affected by the dnaA(Ts) mutations mapping in the middle of the gene whereas oriC-dependent replication was most thermosensitive in strains carrying mutations mapping in the carboxy-terminal half of the gene. The results indicated that the integrative suppression by F plasmid is a DnaA-dependent process and suggested that the requirements for DnaA protein in the oriC-dependent replication and F replication processes are qualitatively different.     

Fine structure genetic map and complementation analysis of mutations in the dnaA gene of Escherichia coli

Summary A fine structure genetic map of several mutations in the dnaA gene of Escherichia coli was constructed by the use of recombinant and M13 phages. The dnaA508 mutation was found to be the mutation most proximal to the promoter, while the dnaA203 mutation was found to be the most distal one. The order of mutations established in this analysis was: dnaA508, dnaA167, (dnaA5, dnaA46, dnaA211), dnaA205, dnaA204, dnaA203. The mutations dnaA601, dnaA602, dnaA603, dnaA604 and dnaA606 were found to map very close to each other and close to dnaA205 in the middle third of the dnaA gene. In analysing the dominance relationship all 13 dnaA mutations were found to be recessive to the wild type. Characteristic phenotypes of the dnaA(Ts) mutants, like reversibility of the temperature inactivation of the dnaA protein, cold sensivity of haploid or of merodiploid strains and suppressibility by rpoB mutations, are found to correlate with clusters of mutations within the gene.     

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).     

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.     

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.     

Genetic studies on the beta subunit of Escherichia coli RNA polymerase. II. Evidence that large N-terminal amber fragments of the beta subunit interfere with RNA polymerase function

Summary A collection of 95 independent, spontaneously-occurring mutants carrying amber lesions that affect expression of the gene, rpoB, has been isolated (see accompanying paper (Nene and Glass 1982)). Certain rpoB amber mutations act in trans, preventing a functional allele present on an F plasmid from acting at high temperature. Two such temperature-sensitive rpoB(Am) strains are shown to produce large, N-terminal amber fragments. The possibility that these truncated polypeptides are the cause of this trans-dominant conditional-lethal phenotype is supported by analysis of fragment levels in thermoresistant survivors: the nonsense fragments are degraded at a significantly faster rate (half-lives 1.4- to 2.6-fold reduced) in Ts⁺ derivatives likely to carry second-site mutations within rpoB. We suggest that the fragments interfere with RNA polymerase function by interacting with one or more of the polymerase subunits.     

Three rpoBC mutations that suppress the termination defects of rho mutants also affect the functions of nusA mutants

Summary We have mapped three Escherichia coli RNA polymerase mutations selected by Guarente (1979) to suppress the termination defects of rho201. We find that two of the mutations are located in the 3 half of the rpoB gene encoding the subunit. The third mutation is in the rpoC gene, encoding the subunit. All three RNA polymerase mutations affect termination efficiency, even in rho ⁺ strains, suggesting that the C-terminal end of the as well as the subunit participates in termination. In addition we find that all three rpoBC alleles inhibit N-mediated antitermination at 30° C in a strain containing the nusA1 allele. It may be significant that the three other RNA polymerase mutations known to revert the termination defect of mutant rho alleles also affect N-mediated antitermination in nusA1 strains. The correlation of these two phenotypes suggests that both phenotypes may arise from the same functional defect in RNA polymerase.     

Temperature-sensitive mutations affecting the replication of F-prime factors in Escherichia coli K 12

Summary More temperature-sensitive mutants affecting the replication of the F-gal⁺ episome of Escherichia coli K12 have been isolated. Eight of the mutations were located on F itself and three were located on the chromosome.The temperature sensitive F-gal⁺'s have been integrated into the chromosome to produce Hfr strains. These Hfr strains have transfer origins similar to Hfr Cavalli, and all show aberrant excision and transfer of elongated segments of the chromosome including the integrated F-gal to generate long merodiploids.The chromosomal mutations that govern the replication of F have been termed seg (for segregation). Wild-type F-gal⁺ can be integrated into seg cells at 42° C to give Hfrs, in a process analogous to integrative suppression in the formation of Hfrs from cells carrying mutations that are temperature-sensitive for chromosomal DNA replication (dnaA). A curious feature of an Hfr derived from a seg strain is that it also shows F-genote enlargement as well as normal transfer of chromosomal genetic marker. Preliminary transductional mapping data show that the mutation seg-2 is linked to the threonine locus (minute 0).     

Genetic inactivation of topoisomerase I suppresses a defect in initiation of chromosome replication in Escherichia coli

Summary A strain of Escherichia coli K12 harboring simultaneously the temperature-sensitive dnaA46 mutation and a deletion of the trp-topA-cysB region plates with the same full efficiency at 30° C and 42° C. We have analyzed the possible involvement of the gene coding for topoisomerase I, topA, in this suppression phenomenon. The Ts phenotype was retrieved upon introduction of a plasmid-borne DNA fragment including an active topA gene into this strain, but not upon introduction of the same fragment harboring a topA::Tn1000 insertion. Replication seems to remain DnaA-dependent in the (topA) strain, however, since we have been unable to introduce a dnaA::Tn10 allele. We propose either that the dnaA46 gene product is overproduced and compensates for its thermal inactivation, or that initiation at oriC demands less DnaA protein in the absence of topoisomerase I.Abbreviations Ap^r ampicillin resistance - Cm^r chloramphenicol resistance - Km^r Kanamycin resistance - St^r streptomycin resistance - Tc^r tetracycline resistance     

Suppression of a thermosensitive dnaA mutation of Escherichia coli by bacteriophage P1 and P7.

Like other plasmids, the P1 and P7 prophages suppress E. coli dnaA(Ts) mutations by integrating into the host chromosome. This conclusion is supported by three lines of evidence: (1) Alkaline sucrose gradients reveal the absence of plasmid DNA in suppressed lysogens; (2) the prophage is linked to host chromosomal markers in conjugation; and (3) auxotrophs whose defect is linked to the prophage are found among suppressed colonies. No phage or bacterial mutation is required for suppression. Integrative suppression by P1 and P7, unlike suppression by F, does not require the host recA⁺ function. Among suppressed P7 lysogens are some that do not produce phage; these contain defective prophages. The genetic extent of the deletions contained by these defective prophages delineates the prophage regions which are not necessary for suppression of dnaA(Ts). The possible mechanisms of integration and deletion formation are discussed.     

A temperature-sensitive Escherichia coli mutant defective in DNA replication: dnaA, a new gene adjacent to the dnA, gene

Summary An Escherichia coli mutant defective in replication of the chromosome has been isolated from temperature-sensitive mutants that cannot support colicin E1 plasmid DNA synthesis in the presence of chloramphenicol. Cellular DNA synthesis of the mutant ceases almost immediately after transfer to the nonpermissive temperature. The defect is due to a single mutation, dna-59, which is located close to the sites of dnaA mutations and a cou ^R mutation conferring DNA gyrase with resistance to coumermycin. The dna-59 mutant is not able to support DNA synthesis of phage at the high temperature. The mutant also restricts growth of X174 phage at the high temperature, but permits formation of supercoiled closedcircular duplex replicative intermediates. T7 phage can grow on the mutant even at the high temperature.A specialized transducing phage imm ²¹[tna dnaA]#2 (Miki et al., 1978) supports growth of dna-59, dnaA46 and dna-167 cells at the high temperature. Some of the EDTA-resistant derivatives of the phage have lost part or all of the dnaA gene, but carry gene function complementing the defect of dna-59 cells, as judged by conversion of the above dna strains to wild type cells by phage infection, and by suppression of the loss of viability of dna-59 cells at the high temperature by phage infection. The gene containing the dna-59 mutation site is thus distinct from the dnaA gene. Since the dna-59 mutation does not affect expression of the cou ^r gene of DNA gyrase, which is another known gene involved in DNA synthesis near the dnaA gene, this mutation is probably in a new gene, dnaN. From analysis of the suppression activities of imm ²¹[tna dnaA]#2 phage and its deletion derivatives against dnaN59 cells, it is suggested that the expression of the dnaN gene function is reduced by deletion in the dnaA region.     

Cloning and nucleotide sequence determination of twelve mutant dnaA genes of Escherichia coli

Summary Plasmids carrying different regions of the wild-type dnaA gene were used for marker rescue analysis of the temperature sensitivity of twelve strains carrying dnaA mutations. The different dnaA(Ts) mutations could be unambiguously located within specific regions of the dnaA gene. The mutant dnaA genes were cloned on pBR322-derived plasmids and on nucleotide sequencing by dideoxy chain termination the respective mutations were determined using M13 clones carrying the relevant parts of the mutant dnaA gene. Several of the mutant dnaA genes were found to have two mutations. The dnaA5, dnaA46, dnaA601, dnaA602, dnaA604, and dnaA606 genes all had identical mutations corresponding to an amino acid change from alanine to valine at amino acid 184 in the DnaA protein, close to the proposed ATP binding site, but all carried one further mutation giving rise to an amino acid substitution. The dnaA508 gene also had two mutations, whereas dnaA167, dnaA203, dnaA204, dnaA205, and dnaA211 each had only one. The pairs dnaA601/602, dnaA604/606, and dnaA203/204 were each found to have identical mutations. Plasmids carrying the different dnaA mutant genes intact were introduced into the respective dnaA mutant strains. Surprisingly, these homopolyploid mutant strains were found to be temperature resistant in most cases, indicating that a high intracellular concentration of the mutant DnaA protein can compensate for the decreased activity of the protein.     

RifR mutations in the beginning of the Escherichia coli rpoB gene

In Escherichia coli, mutations conferring rifampicin (Rif) resistance map to the rpoB gene, which encodes the 1342-amino acid subunit of RNA polymerase. Almost all sequenced RifR mutations occur within the Rif region, encompassing rpoB codons 500–575. A strong Rif^R mutation lying outside the Rif region, which changed Val¹⁴⁶ to Phe was previously reported, but was not recovered in subsequent studies. Here, we used site-directed mutagenesis followed by selection on Rif to search for Rif^R mutations in the evolutionarily conserved segment of rpoB around codon 146. Strong Rif^R mutations were obtained when Val¹⁴⁶ was mutated, and several weak Rif^R mutations were also isolated near position 146. The results define a new, N-terminal cluster of Rif^R mutations, in addition to the classical central Rif region.     

Identification of an amber fragment of the beta subunit of Escherichia coli RNA polymerase: a yardstick for measuring controls on RNA polymerase subunit synthesis.

Summary An amber fragment of the subunit of Escherichia coli RNA polymerase has been recovered from strains carrying the rpoB12 amber mutation, indicating that the B12 mutation resides in the structural gene for the subunit. The fragment is readily assayed and can be used to determine the degree of expression of a single rpoB cistron in strains haploid or diploid for this region. These studies confirm that the bacterial mechanism, which can compensate for reduced translation of the message, operates by the co-ordinate induction of rpoB and rpoC. Furthermore, I show that rpo control depends upon cistron(s) located on the F factor, KLF10, whose product(s) can act negatively in trans on rpoBC expression.     

dnaA suppressor (dasF) mutants of Escherichia coli are stable DNA replication (sdrA/rnh) mutants

Summary The possible allelic relationship between dasF (dnaA suppressor) and sdrA/rnh (stable DNA replication/RNase H) mutations was examined. dasF mutations could not only suppress various dnaA(ts) mutations, but also the insertional inactivation of the dnaA gene or deletion of the oriC sequence, as could sdrA mutations. dasF mutants were found to exhibit the stable DNA replication phenotype, and the sensitivity to rich media, of sdrA mutants. The dasF and sdrA mutations were mapped very closely between metD and proA on the E. coli genetic map. The mutations were recessive to the wild-type allele for all the above phenotypes. It was concluded that dasF is allelic to sdrA/mh.     

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     

Unique sequences for two HLA-DRB1 genes expressed on distinct DRw6 haplotypes

We have used restriction fragment length polymorphism (RFLP) analysis and DNA sequencing to characterize two distinct DRB1 alleles expressed on DRw52 and DQw7-associated haplotypes but not readily defined by conventional DR serology. These two haplotypes, designated HLA-D HAG and PEV, react variably with DRw13(w6), DRw14(w6), and the more broad DR 3+6 antisera. Analysis of RFLP revealed that HLA-D HAG and PEV are associated with different DRw52 variants, and that HAG is indistinguishable from DRw18(3) haplotypes. Sequencing of the HAG and PEV DRB1 genes showed each to represent novel alleles. Nevertheless, these sequences show similarities with the other alleles of the DR5, w6, and w8 family. HAG (DRB1*1303) appears to have arisen either from two recombinational events involving at least three DRB1 sequences (DRB1*1101, DRB1*0803, DRB1*0401) or from a single recombinational event together with multiple point mutational events. PEV appears to represent a DRB1*1301-1302/DRB1*1101 recombinant allele, with recombination having occured in the region of bases 175 – 198. The results of this study suggest that the DRw52 family haplotypes is derived from a relatively restricted number of ancestral sequences, with diversity among DRB1 alleles within this family arising through gene conversion or recombination events.