Leader region of the gene encoding DNA polymerase III of Bacillus subtilis.

Previously we cloned and sequenced the polC gene of Bacillus subtilis and identified regions corresponding to various catalytic domains of DNA polymerase III, the enzyme it encodes. In the present study, by using primer extension, we have identified the transcription start site and a 139 nucleotide leader region upstream of the first codon. This region contains a DnaA box in the non-transcribed DNA strand. An RNA transcript of the leader would contain a sequence that could form a 29 bp stem-loop secondary structure followed by a strong terminator sequence, rich in uracil, before the ribosome binding site. Plasmids were constructed containing either the intact leader region or deletion mutations of the leader, fused to the Escherichia coli lacZ gene in an expression vector. Single copies of the fusions were then integrated into the B. subtilis genome by transformation. Studies of the expression of beta-galactosidase by the transformed cells supported the idea that the leader region is important in regulating polC gene expression.

Genetic structure and domains of DNA polymerase III of Bacillus subtilis.

We have determined the nucleotide sequence of the polC gene of Bacillus subtilis which codes for DNA polymerase III. Our recent analysis has revealed that the gene comprises 4311 nucleotides, from the start to the stop codon, 306 nucleotides more than we reported earlier. The plasmid reported by us and by N.C. Brown's laboratory contained a sequence at the end of the gene which is not related to the polC region of B. subtilis. We have isolated the rest of the gene, the sequence of which is presented in this paper. The new stop codon is followed by a hyphenated palindromic sequence of 13 nucleotides. The C-terminus of the coding region contains the novel mutation, dnaF, which results in a defect in the initiation of replication due to a change in the codon TCC to TTC (serine to phenylalanine). The hypermutator mutation mut-1 is due to two point mutations in the 3' to 5' exonuclease domain, the proof reading function. The codon changes are GGA to GAA (glycine to glutamic acid) and AGC to AAC (serine to asparagine). The elongation defective mutation, polC26, affecting the catalytic site that adds nucleotides to the growing chain, is due to a change in the codon GTC to GAC (valine to aspartic acid). It is separated from the mutation reported earlier, azp-12, by 306 nucleotides. Knowing the locations of the mutational sites allowed us to deduce the domains of the gene and the enzyme it encodes, and permitted us to present a precise map of the gene at the molecular level.

DNA polymerase III gene of Bacillus subtilis.

The Bacillus subtilis dnaF (polC) gene that codes for the alpha subunit of the DNA polymerase III holoenzyme has been sequenced. It consists of 4005 base pairs coding for 1335 amino acids (from the start to the stop codon), giving a molecular weight of 151,273. A mutation (azp-12) that confers resistance to the antimicrobial drug 6-(p-hydroxyphenylazo)-uracil is due to a single base change at nucleotide 3523, from TCA to GCA, resulting in a change of the 1175th amino acid, serine, to alanine. It is in the active site and located at the C-terminal part of the enzyme. The amino acid composition in an N-terminal domain has 26% homology to the epsilon subunit coded by the dnaQ gene of Escherichia coli, which is a 3'----5' proofreading exonuclease, supporting an earlier observation that this function is an integral part of the polymerase molecule in B. subtilis.

Expression of the Bacillus subtilis polC gene in Escherichia coli.

We have cloned a 14 kb DNA segment containing the coding sequence (polC) for DNA polymerase III (PolIII) from the Bacillus subtilis chromosome. The plasmid carrying the sequence, pRO10, directs the synthesis of the 160 kDa PolIII protein and three additional polypeptides in Escherichia coli maxicells from strain CSR603. A set of deletion derivatives of pRO10 was constructed in vitro. The location of the PolIII coding sequence and the direction of transcription through the polC gene were determined by analysis of the truncated polypeptides observed in extracts of CSR603 transformants. Two HindIII segments subcloned from pRO10 were found to contain promoter sequences which function in E. coli and in vegetative phase B. subtilis cells. The location of the promoter sequence was determined with respect to the polC gene. The B. subtilis polC gene did not complement the temperature-sensitive defect of an E. coli PolIII mutant (dnaE486). The presence of the complete B. subtilis polC gene on a multicopy plasmid inhibited the growth of E. coli cells.

Cloning and characterization of the polC region of Bacillus subtilis.

The polC gene of Bacillus subtilis is defined by five temperature-sensitive mutations and the 6-(p-hydroxyphenylazo)-uracil (HPUra) resistance mutation azp-12. Biochemical evidence suggests that polC codes for the 160-kilodalton DNA polymerase III. A recombinant plasmid, p154t, was isolated and found to contain the azp-12 marker and one end of the polC gene (N. C. Brown and M. H. Barnes, J. Cell. Biochem. 78 [Suppl.]: 116, 1983). The azp-12 marker was localized to a 1-kilobase DNA segment which was used as a probe to isolate recombinant lambda phages containing polC region sequences. A complete polC gene was constructed by in vitro ligation of DNA segments derived from two of the recombinant phages. The resulting plasmid, pRO10, directed the synthesis of four proteins of 160, 76, 39, and 32 kilodaltons in Escherichia coli maxicells. Recombination-deficient (recE) B. subtilis PSL1 containing pRO10 produced an HPUra-resistant polymerase III activity which was lost when the strain was cured of pRO10. In vivo, the HPUra resistance of the plasmid-encoded polymerase III appeared to be recessive to the resident HPUra-sensitive polymerase III enzyme.

Procaryotic genomic DNA inhibits mammalian cell transformation.

Ltk- mouse cells were transformed to thymidine kinase prototrophy in the presence of carrier DNAs isolated from different organisms. Procaryotic genomic and phage DNA was consistently less effective as a carrier than was eucaryotic DNA. Mixing experiments indicate that DNA of procaryotic origin inhibits mammalian cell transformation.

Biological assay of prokaryotic genes in mouse cells following DNA mediated transformation.

Genes coding for leucine biosynthesis in Bacillus subtilis were introduced into mouse LTK- cells by co-transformation with thymidine kinase+ (tk) DNA. Genomic DNA from the tk+ transformants was used to transform competent cultures of different B. subtilis leucine auxotrophs. Each auxotroph was transformed to prototrophy at a similar frequency and the number of leucine gene sequences per transformant genome as deduced by the B. subtilis bioassay strongly correlated with the number estimated by hybridization methods. Tk- subclones were obtained by plating the transformants in 5'-bromodeoxyuridine. One subclone still contained the non-selected leucine gene sequences and could transform auxotrophs of B. subtilis. No deletions or rearrangements in the linkage relationships of the leucine genes occurred in the LTK- cells that inhibited transformation of B. subtilis.

The genome of B. subtilis phage SPP1: physical arrangement in phage genes.

41 genes of SPP1 have been delineated by using complementation analyses of 75 conditionally lethal (ts and sus) mutations. The physical locations of these genes on the SPP1 chromosome have been determined by transfection/marker rescue experiments in which restriction endonuclease generated fragments of SPP1 DNA were used as donor DNA. The physical order of these fragments has been previously established (Ratcliff et al., 1979).

Genetic recombination during transformation in Bacillus subtilis: appearance of a deoxyribonucleic acid methylase.

In Bacillus subtilis the ability to take up deoxyribonucleic acid (DNA) and undergo genetic transformation may coincide with the induction of defective phage(s) and the expression of possibly related cryptic genes. A restriction-modification enzyme system appears to be expressed. Targets of the restriction activity on the DNA can be blocked my methylation catalyzed by the methyl transferase. It is shown that cellular DNA becomes progressively methylated and reaches the maxium level during the peak of competency. Deoxycytidine residues of both incoming donor and resident DNA are methylated. The possible participation of these enzymes in recombination and the general role of cryptic genes in inducible functions are discussed.

The genome of B. subtilis phage SSP1: the topology of DNA molecules.

DNA molecules of B. subtilis phage SPP1 exhibit terminal redundancy and are partially circularly permuted. This was established by the hybridization of selected EcoRI restriction fragments to single strands of SPP1 DNA and by an analysis of the distribution of denaturation loops in partially denatured SPP1 DNA molecules. Deletions in SSP1 DNA are not compensated by an increase in terminally repetitious DNA. This finding, which is unique to SPP1, is discussed in terms of a modification of the Streisinger/Botstein model of phage maturation.

The genome of Bacillus subtilis phage SPP1: the arrangement of restriction endonuclease generated fragments.

SPP1 DNA was cleaved by the restriction endonucleases, BglI, BglII, EcoRI, KpnI, SmaI, and SalI. The molecular weights of the DNA fragments obtained by single enzyme digestion or by consecutive digestion with two enzymes were determined by electron microscopic measurements of contour length and by gel electrophoresis. The major fragments from the six digests could be ordered to give a consistent restriction map of SPP1. The electropherograms of several digests indicated that certain fragments occurred in less than stoichiometric amounts or were heterogeneous in size. Such bands carried a major part of radioactivity, when SPP1 DNA was terminally labelled with P32 prior to degradation by restriction enzymes. These results, and studies of the effect of exonuclease III treatment on restriction enzyme patterns define the terminal restriction fragments. All data obtained support the conclusion drawn in the preceding paper (Morelli et al., 1978 b) that the SPP1 genome is terminally redundant and partially circularly permuted.

Electron microscopic studies of bacteriophage M13 DNA replication.

Intracellular forms of M13 phage DNA isolated after infection of Escherichia coli with wild-type phage have been studied by electron microscopy and ultracentrifugation. The data indicate the involvement of rolling-circle intermediates in single-stranded DNA synthesis. In addition to single-stranded circular DNA, we observed covalently closed and nicked replicative-form (RF) DNAs, dimer RF DNAs, concatenated RF DNAs, RF DNAs with single-stranded tails (theta, rolling circles), and, occasionally, RF DNAs with theta structures. The tails in theta molecules are always single stranded and are never longer than the DNA from mature phage; the proportion of theta to other RF molecules does not change significantly with time after infection. The origin of single-stranded DNA synthesis has been mapped by electron microscopy at a unique location on RF DNA by use of partial denaturation mapping and restriction endonuclease digestion. This location is between gene IV and gene II, and synthesis proceeds in a counterclockwise direction on the conventional genetic map.

Control of chromosome replication in thymine-requiring strains of Bacillus subtilis 168.

Study of the replication pattern of a number of B. subtilis 168 strains under controlled physiological conditions revealed great interstrain variation in control of replication. Replication patterns were calculated from ratios of purA16/leu-8 and purA16/metB5 transformation frequency. The thymine-independent strains are under strict regulation with an average of one replication position per chromosome during log phase. After starvation for required amino acids or sporulation, the chromosome is in a completed state with no replication forks (class I). In contrast, several thymine-requiring strains (class III) have an average of three to four replication positions per chromosome during log phase (multiforked replication) of which one to two remain uncompleted after amino acid starvation or sporulation. The other thymine-requiring strains studied are intermediate (class II) in that they have an average of two replication positions per chromosome during log phase and one after amino acid starvation or sporulation. Pulse chase experiments indicate that the deoxyribonucleic acid which is close to the chromosomal origin on each branch of the multiforked chromosome is bound to a rapidly sedimenting cellular fraction, presumably membrane.

Temperature-sensitive deoxyribonucleic acid replication in a dnaC mutant of Bacillus subtilis.

A temperature-sensitive mutant of Bacillus subtilis is defective in deoxyribonucleic acid (DNA) synthesis, contains a lesion in the dnaC locus, and is not primarily an initiation mutant. The amount of DNA synthesized by this mutant at temperatures above 40 C decreases with increasing temperature. DNA synthesis resumes within 20 min after the temperature is lowered to 30 C. In the presence of chloramphenical, DNA synthesis begins at a reduced rate after the temperature is lowered to 30 C. Spores germinated at 46 C cannot initiate DNA replication. The capacity for residual DNA synthesis is stable at the restrictive temperature during inhibition of DNA synthesis. When the temperature is lowered to 30 C after a period of incubation at 43 C, DNA synthesis starts at the origin of the chromosome as well as at preexisting growing points. Similar DNA synthesis patterns are found in mutant cells in vivo and after toluene treatment.

DNA repair and its relation to recombination-deficient and other mutations in Bacillus subtilis.

DNA repair processes operating in Bacillus subtilis are similar to other transformable bacterial systems. Radiation-sensitive, recombination-deficient mutants are blocked in distinct steps leading to recombination. DNA polymerase I is essential for the repair of X-ray-induced damage to DNA but not for recombination.

Bacteriophage interference in Bacillus subtilis 168.

Strains of Bacillus subtilis lysogenic for temperate bacteriophage SPO2 inhibit the development of bacteriophage phi1. After infection by bacteriophage phi1, DNA and RNA synthesis in the lysogenic host terminates, culminating in cell death. Bacteriophage SPO2 also prevents the production of bacteriophage phi105. Mechanisms for these two types of bacteriophage interference are discussed.

In vitro repair of x-irradiated DNA extracted from Bacillus subtilis deficient in polymerase I.

DNA extracted from x-irradiated cells of a mutant of Bacillus subtilis deficient in DNA polymerase I has greatly reduced biological activity. This DNA, which has many single-strand nicks, can be repaired in vitro with purified DNA polymerase I and DNA ligase or with lysates of wild-type B. subtilis cells, which restore biological activity and increase the single-strand molecular weight. Lysates of polymerase I-deficient B. subtilis cells cannot repair such irradiated DNA until purified DNA polymerase I or lysate from wild-type cells is added to the deficient lysate.