Restriction and modification of SP10 phage by BsuM of Bacillus subtilis Marburg

Bacillus subtilis Marburg has only one intrinsic restriction and modification system BsuM that recognizes the CTCGAG (XhoI site) sequence. It consists of two operons, BsuMM operon for two cytosine DNA methyltransferases, and BsuMR operon for a restriction nuclease and two associated proteins of unknown function. In this communication, we analyzed the BsuM system by utilizing phage SP10 that possesses more than twenty BsuM target sequences on the phage genome. SP10 phages grown in the restriction and modification-deficient strain could not make plaques on the restriction-proficient BsuMR(+) indicator strain. An enforced expression of the wild type BsuMM operon in the BsuMR(+) indicator strain, however, allowed more than thousand times more plaques. DNA extracted from SP10 phages, thus, propagated became more but not completely refractory to XhoI digestion in vitro. Thus, the SP10 phage genome DNA is able to be nearly full-methylated but some BsuM sites are considered to be unmethylated.     

Restriction and modification of bacteriophage SP10 DNA by Bacillus subtilis Marburg 168: stabilization of SP10 DNA in restricting hosts preinfected with a heterologous phage, SP18.

SP10 phage cannot propagate in Bacillus subtilis Marburg 168 containing the wild-type allele of either gene nonA or gene nonB. The latter gene codes for the intrinsic cellular restriction activity. SP10 DNA was degraded in nonB+ derivatives of Marburg 168. The degree of degradation depended upon the previous host in which SP10 was propagated. In the case of SP10 grown in B. subtilis W23 (a nonrestricting, nonmodifying bacterium), 90% of the phage DNA was hydrolyzed to acid solubles, and the residual acid-precipitable material was recovered as 0.5- to 1-megadalton fragments. In contrast, if SP10 was propagated in B. subtilis PS9W7 (a nonA nonB derivative of Marburg 168 that retains modifying activity), 40 to 50% of the input DNA was degraded to acid solubles, and most of the remainder was recovered as 15- to 20-megadalton fragments. In nonA+ nonB cells, SP10 DNA was conserved as unit-length molecules (ca. 80 megadalton). Prior infection of nonB+ cells with SP18 protected superinfecting SP10 DNA, even when rifampin or chloramphenicol was added before the primary infection. The data are discussed in terms of the following conclusions. (i) The nonB gene product of B. subtilis Marburg 168 is required for restriction of SP10 DNA. (ii) Some sites on SP10 DNA are sensitive to both the restricting and modifying activities, whereas other sites are nonmodifiable even though they are sensitive to the restriction enzyme. (iii) In some manner, SP18 antagonizes the action of the nonB gene product.     

Complementation and characterization of chemotaxis mutants of Bacillus subtilis.

A set of chemotaxis mutants of Bacillus subtilis was complemented by using SP beta c2 transducing bacteriophage either containing cloned segments of DNA or derived from abnormal excision of SP beta c2 dl2::Tn917 inserted into the chemotaxis region. Representative mutants were characterized in capillary assays for chemotaxis toward four amino acids and mannitol and in tethered-cell experiments for addition and removal of two attractants and two repellents. Twenty complementation groups were identified, in addition to the cheR previously characterized. All were found to be defective in chemotaxis toward all chemoeffectors. They were assigned the names cheA through cheU. The large number of general chemotaxis genes in B. subtilis, in contrast to the six in Escherichia coli, suggests fundamental differences in the mechanism of chemotaxis in the two species.     

Isolation and characterization of uncoupler-resistant mutants of Bacillus subtilis.

Three mutant strains of Bacillus subtilis were isolated on the basis of their ability to grow in the presence of 5 microM carbonyl cyanide m-chlorophenylhydrazone (CCCP). The mutants (AG2A, AG1A3, and AG3A) were also resistant to 2,4-dinitrophenol, and AG2A exhibited resistance to tributyltin and neomycin. The mutants all exhibited (i) elevated levels of membrane ATPase activity relative to the wild type; (ii) slightly elevated respiratory rates, with the cytochrome contents of the membranes being the same as or slightly lower than those of the wild type; (3) a passive membrane permeability to protons that was indistinguishable from that of the wild type in the absence of CCCP and that was increased by addition of CCCP to the same extent as observed with the wild type; and (4) an enhanced sensitivity to valinomycin with respect to the ability of the ionophore to reduce the transmembrane electrical potential. Finally and importantly, starved whole cells of all the mutants synthesized more ATP than the wild type did upon energization in the presence of any one of several agents that lowered the proton motive force. Studies of revertants indicated that the phenotype resulted from a single mutation. Since a mutation in the coupling membrane might produce such pleiotropic effects, an analysis of the membrane lipids was undertaken with preparations made from cells grown in the absence of CCCP. The membrane lipids of the uncoupler-resistant strains differed from those of the wild type in having reduced amounts of monounsaturated C16 fatty acids and increased ratios of iso/anteiso branches on the C15 fatty acids. Correlations between protonophore resistance and the membrane lipid compositions of the wild type, mutants, and revertants were most consistent with the hypothesis that a reduction in the content of monounsaturated C16 fatty acids in the membrane phospholipids is related, perhaps casually, to the ability to synthesize ATP at low bulk transmembrane electrochemical gradients of protons.     

Isolation and characterization of Bacillus subtilis mutants blocked in the synthesis of pantothenic acid.

We have produced and characterized by physiological and enzymatic analyses pantothenate (pan) auxotrophs of Bacillus subtilis. panB auxotrophs are deficient in ketopantoate hydroxymethyltransferase, whereas panE mutants lack ketopantoic acid reductase. The pan mutations were mapped by phage PBS1-mediated two-factor crosses and found to be located in the interval purE-tre of the genetic map of B. subtilis.     

Macromolecular synthesis in chromosome initiation mutants of Bacillus subtilis.

Summary Inactivation of the dna B or dna D gene product in Bacillus subtilis stimulates RNA and protein synthesis. Strains containing ts dna B and D mutations have been constructed by introducing the mutations by transformation into a thymine requiring strain which does not lyse during thymine starvation. The consequences of inactivation of these gene products have been assessed by comparing RNA and protein synthesis during thymine starvation at the restrictive temperature with the recipient strain. In the ts ⁺ strain, there is a doubling in rate of RNA synthesis during thymine starvation. In the ts dna B and D mutations at the restrictive temperature the rate of RNA synthesis increases four fold. By preincubating the mutants in the absence of thymine for one generation at the permissive temperature the two fold increase in rate of RNA synthesis associated with inactivation of the initiation complex can be demonstrated under conditions where the ts ⁺ strain shows a decrease in rate of RNA synthesis. The rate of protein synthesis observed largely reflects the rate of RNA synthesis in all strains. Completion of the chromosome at the restictive temperature has no significant effect on the rate of RNA synthesis. It is suggested that inactivation of the initiation complex after chromosome initiation could play an important role in control of RNA synthesis in relation to the cell cycle.     

SPP1 DNA replicative forms: growth of phage SPP1 in Bacillus subtilis mutants temperature-sensitive in DNA synthesis.

Summary The development of bacteriophages SPP1, and 29 has been studied in several B. subtilis mutants defective in host DNA replication, under non permissive conditions.Several gene products, involved in the synthesis of host DNA, are required for 29 replication, while SPP1 seems to require obly the host DNA polymerase III. In addition both phages are unable to grow in a dna A mutant (ribonucleotide reductase). Taking advantage of the fact that SPP1 DNA is actively replicated in several dna mutants at non-permissive temperature, we have studied the structure of the replicative intermediates of this phage in the absence of interfering host DNA synthesis.Fast sedimenting forms of SPP1 DNA can be isolated from phage infected cells and evidence of covalently joined concatemers has been obtained, suggesting the presence of terminally repeated sequences.     

Presence of a third sucrose hydrolyzing enzyme in Bacillus subtilis: constitutive levanase synthesis by mutants of Bacillus subtilis Marburg 168.

A beta-D-fructofuranosidase -- called levanase -- capable of the hydrolysis of sucrose, inulin and levans has been identified in Bacillus subtilis Marburg. This enzyme can not be detected in strain 168. However, sacL mutations -- mapped on the chromosome of strain 168 between the pheA and aroD reference markers -- lead to constitutive levanase synthesis. This synthesis is repressed by carbon sources such as glucose, glycerol or sucrose.     

Identification of the nonA and nonB loci of Bacillus subtilis Marburg permitting the growth of SP10 phage

Mutational inactivation of both nonA and nonB genes are required for the permissiveness of Bacillus subtilis Marburg cells to infection by phage SP10. By transformational analysis of the nonA strain with DNAs from gently lysed protoplasts carrying the integrative plasmid pMUTIN (em) insertions in every 20 kb along the whole chromosome, we have identified the nonA to be the cured state of endogenous prophage SPbeta. Direct DNA sequencing, on the other hand, revealed one nonsense mutation of nonB in ydiR, which is a component gene of the intrinsic restriction system BsuMR of B.subtilis Marburg. Introduction of the wild type ydiR into the nonB strain at aprE locus resulted in complementation of nonB. Furthermore, as the SP10 genome was found to possess multiple BsuM target sites, it is considered that SP10 can infect and multiply in B.subtilis cells, which are SPbeta free and possess a defective BsuMR restriction system.     

Bacillus subtilis RNAase III cleavage sites in phage SP82 early mRNA

We have determined the DNA sequence encoding three sites in Bacillus subtilis phage SP82 early mRNA that are cleaved by a B. subtilis processing endonuclease. The products generated by cleavage of the RNA were sequenced to determine the exact points of RNA strand scission. We propose that the RNA surrounding each processing site forms a stable stem-loop structure and that cleavage occurs at the 5- side of specific adenosine residues located on the loop. The model is consistent with our previous observations that the active site of the enzyme recognizes double-stranded RNA. S1 mapping experiments with RNA-DNA hybrids established that the same cleavage sites are used both in vivo and in vitro. Examination of the B. subtilis processing sites on SP82 mRNA reveals distinctive features of primary and secondary structure that are not present in any of the E. coli RNAase III processing sites previously studied.     

Isolation and characterization of Bacillus subtilis mutants altered in competence.

We isolated and characterized four Bacillus subtilis competence-deficient mutants. The mutants were obtained by nitrosoguanidine mutagenesis and by screening for mutants unable to be transformed both on solid and in liquid medium. Most of the mutants obtained in this way were tested for their sensitivity to the DNA-damaging agents methyl methanesulfonate, mitomycin C, and UV light. Among the mutants which did not show an increased sensitivity to these agents, four were chosen for further characterization. Data were obtained which indicate that the mutants are reduced in chromosomal and plasmid transformation and in transfection, whereas they are not altered in transduction and in protoplast transformation. Transformation experiments carried out by mixing a culture of a mutant with a culture of a wild-type strain gave some complementation for competence with one of the strains. The mutants were also characterized for their capacity to bind, take up, and break down transforming DNA; furthermore, the four competence mutations were mapped, and the results indicate that they belong to four different genes.     

Deoxyribonucleoside-requiring mutants of Bacillus subtilis.

A number of deoxyribonucleoside-requiring mutants (dns) of Bacillus subtilis were isolated and their growth characteristics and ribonucleotide reductase activities were compared with those of the wild type and of a dna mutant (tsA13). Both tsA13 and dns mutants required the presence of a mixture of deoxyribonucleosides for growth at 45 degrees C but not at 25 degrees C. All the mutant strains tested contained ribonucleotide reductase activity which showed heat sensitivity similar to that of the enzyme from a wild-type strain. The reductase in B. subtilis seemed to reduce ribonucleoside triphosphates in a similar manner to the enzyme in Lactobacillus leichmannii.     

Glutamine-requiring mutants of Bacillus subtilis.

Two glutamine-requiring (Gln^?) mutants of $\text{Bacillus subtilis}$ SMY were deficient in glutamine synthetase activity $\text{in vitro}$. The Gln^? mutants sporulated poorly unless glutamine was provided at high concentrations. The differential rate of histidase synthesis following induction was 4- to 6-fold higher in the Gln^? mutants than in wild-type cells. In addition, glucose repression of utilization of alternative carbohydrates appeared to be partially relieved in the Gln^? mutants.     

Recombination-deficient mutants of Bacillus subtilis.

Two mutant strains of Bacillus subtilis Marburg, NIG43 and NIG45, were isolated. They showed high sensitivities to gamma rays, ultraviolet light (UV), and chemicals. Deficiencies in genetic recombination of these two mutants were shown by the experiments on their capacity in transformation. SPO2 transfection, and PBS1 phage transduction, as well as on their radiation and drug sensitivities and their Hcr+ capacity for UV-exposed phage M2. Some of these characteristics were compared with those of the known strains possessing the recA1 or recB2 alleles. Mapping studies revealed that the mutation rec-43 of strain NIG43 lies in the region of chromosome replication origin. The order was purA dna-8132 rec-43. Another mutation, rec-45, of strain NIG45 was found to be tightly linked to recA1. The mutation rec-43 reduced mainly the frequency of PBS1 transduction. On the other hand, the mutation rec-45 reduced the frequency of recombination involved both in transformation and PBS1 transduction. The mutation rec-43 of strain NIG43 is conditional, but rec-45 of strain NIG45 is not. The UV impairment in cellular survival of strain NIG43 was gradually reverted at higher salt or sucrose concentrations, suggesting cellular possession of a mutated gene produce whose function is conditional. In contrast to several other recombination-deficient strains, SPO2 lysogens of strain NIG43 and NIG45 were not inducible, indicating involvement of rec-43+ or rec-45+ gene product in the development of SPO2 prophage to a vegetative form. The UV-induced deoxyribonucleic acid degradation in vegetative cells was higher in rec-43 and rec-45 strains.     

Kasugamycin-resistant mutants of Bacillus subtilis.

Kasugamycin-resistant mutants of Bacillus subtilis were isolated and classified into two groups, one of which had resistance to kasugamycin in in vitro protein synthesis and mapped in the ribosomal region. The other group had no resistance to kasugamycin in in vitro protein synthesis and had weak cross-resistance to gentamicin and kanamycin. Neither group could sporulate in the presence of kasugamycin.