Synthesis of deoxythymidylate and the unusual deoxynucleotide in mature DNA of Bacillus subtilis bacteriophage SP10 occurs by postreplicational modification of 5-hydroxymethyldeoxyuridylate

Mature DNA of Bacillus subtilis W23 phage SP10 contains a hypermodified nucleotide (YdTMP) that replaces ca. 20% of the DTMP. SP10 DNA was pulse-labeled for 1 min at 20 degrees C with 32Pi. Among the oxopyrimidine nucleotides, virtually all of the radioactivity was recovered as 5-hydroxymethyldeoxyuridylate (HMdUMP). During the subsequent chase, radioactivity was lost from HMdUMP and recovered as YdTMP. At 37 degrees C, exogenous [6-3H]5-hydroxymethyldeoxyuridine (HMdUrd) was incorporated into SP10 DNA. Label administered as HMdUrd was phosphorylated to HMdUTP in the infected cells, but all radioactivity was recovered from SP10 DNA as YdTMP and dTMP. Two heat-sensitive mutants defective in hypermodification of SP10 DNA are described. In one mutant, HMdUMP replaces YdTMP in DNA. The other mutant generates a DNA containing a novel deoxynucleotide in place of YdTMP. The novel deoxynucleotide seems to consist of PPi esterified to the 5-hydroxymethyl function of HMdUMP (PP-HMdUMP). Both mutants make normal amounts of dTMP. The data are discussed in terms of the following conclusions. (i) Both oxopyrimidine nucleotides in mature SP10 DNA are derived by postreplicative modification of HMdUMP in nascent DNA. (ii) PP-HMdUMP is an intermediate that facilitate formation of a putative exocyclic methylene intermediate which receives the hypermodification. It is also argued that PP-HMdUMP and the same exocyclic methylene intermediate could serve as intermediates in reductive modification to dTMP. (iii) YdTMP is not an intermediate in the formation of dTMP, and reductive modification proceeds independently of hypermodification.     

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.     

An atypical deoxynucleoside triphosphate inBacillus subtilis infected with bacteriophage SP10c

In mature DNA ofBacillus subtilis phage SP10c, deoxythymidine monophosphate is partially replaced by a hypermodified nucleotide. During the interval of phage replication, infected cells contained greatly reduced levels of deoxythymidine triphosphate. However, an atypical mononucleotide, tentatively identified as 5-hydroxymethyldeoxyuridine triphosphate, was present during the interval of SP10c DNA synthesis. It is proposed that the atypical mononucleotide, and not deoxythymidine triphosphate, is a substrate for SP10c DNA replication.     

DNA synthesis in toluene-treated bacteriophage-infected minicells or Bacillus subtilis.

Bateriophage (phi29, SPP1, or SPO1)-infected, toluene-treated minicells of Bacillus subtilis are capable of limited amounts of non-replicative DNA synthesis as measured by incorporation of [3H]dTTP into a trichloroacetic acid-precipitable form. The [3H]dTTP is covalently incorporated into small DNA fragments which result from the degradation of a small percentage of the infecting phage genomes (molecular weights in the range of 2 . 10(5)). Short exposure of the DNA molecules containing the incorporated [3H]dTMP to Escherichia coli exonuclease III results in over 90% of the E13H]dTMP being converted to a trichloroacetic acid-soluble form. The synthesis is totally dependent on host-cell enzymes and is not inhibited by the addition of chloramphenicol, rifampicin, nalidixic acid and mitomycin C and only slightly (approx. 20%) inhibited by the addition of 6-(p-hydroxyphenylazo)-uracil.     

SP-10 bacteriophage-specific nucleic acid and enzyme synthesis in Bacillus subtilis W23.

Bacillus subtilis W23 was infected with a clear-plaque variant of SP-10 phage, namely, SP-10c. Exogenous thymidine was not incorporated into phage DNA (even in the presence of deoxyadenosine), nor was there any transfer of thymidine nucleotides from bacterial to viral DNA. The lytic program was unaffected by concentrations of 5-fluorodeoxyuridine sufficient to reduce bacterial DNA synthesis by greater than 95%. Although these data are consistent with the interpretation that thymidine nucleotides are excluded from phage DNA, formic acid digests of SP-10c DNA contained what appeared to be the four conventional bases; however, adenine and thymine were not recovered in equimolar yields. DNA-RNA hybridization and hybridization competition experiments were done. Synthesis of host RNA started to wane moments postinfection and stopped completely by 36 min. SP-10c coded for discrete classes of early and late RNA. The possibility of discrete subclasses of early RNA exists. Replication of the bacterial genome appeared to terminate 12 min postinfection. Degradation of the host DNA to acid-soluble material started at 36 min and, by the end of the latent period, greater than 90% of the host chromosome was hydrolyzed. Four apparent phage-coded enzymes have been identified. A di- and triphosphatase degraded dUTP, dUDP, dTTP, and dTDP (and, to a lesser extent, dCDP and d CTP) to the corresponding monophosphates; the enzyme had no apparent activity on dATP and dGTP. SP10c also coded for a DNA-dependent DNA polymerase, lysozyme, and a nuclease that degrades native bacterial DNA. Judging from the dependence of enzyme synthesis on the time of addition of rifampin (an inhibitor of the initiation of RNA synthesis), messengers for the di- and triphosphatase, as well as the nuclease, are transcribed from promoters that start to function 6 min postinfection. Promoters for polymerase and lysozyme did not become functional until 8 and 16 min postinfection, respectively.     

Polymer-level synthesis of oxopyrimidine deoxynucleotides by Bacillus subtilis phage SP10: characterization of modification-defective mutants.

Bacillus subtilis phage SP10 DNA has two oxopyrimidines, thymidine 5'-monophosphate (dTMP) and its hypermodified analog (YdTMP). Published data suggest that both are synthesized by postreplicational modification of 5-hydroxymethyldeoxyuridylate (HOMedUMP) in nascent DNA by the following pathway: HOMedUMP----PPOMedUMP----dTMP (85%) or YdTMP (15%); PPOMedUMP is 5-(hydroxymethyl-O-pyrophosphoryl)deoxyuridylate, the pyrophosphoric acid ester of the C5CH2OH function of HOMedUMP. This paper describes aberrant DNAs synthesized at nonpermissive temperatures by a complementary series of heat-sensitive, modification-defective (mod) mutants. Collectively, these mutants encompass the major steps in the complete modification of nascent SP10 DNA. DNA produced by modA phage retains HOMedUMP as its sole oxopyrimidine, implying that (i) this mutant is defective in the pyrophosphorylation step and (ii) formation of PPOMedUMP is required for any further modification. Furthermore, studies with double mutants indicated that modA is epistatic for all other mod mutants, which supports the hypothesis that modA controls the earliest step in the modification pathway. Since their DNAs contain no YdTMP, modC and modD are defective in hypermodification (i.e., PPOMedUMP----YdTMP). However, dTMP occupies the entire oxopyrimidine fraction of modC DNA, whereas modD DNA has a normal dTMP content, but the now-missing YdTMP is replaced by either PPOMedUMP or a byproduct of abortive hypermodification. It is proposed that the modD mutants are defective in the catalytic aspects of hypermodification and that modC are defective in some regulatory function that promotes hypermodification at the expense of reductive modification (i.e., PPOMedUMP----dTMP). Reductive modification is defective in modB phage, as evidenced by the absence of dTMP. In contrast to the others, modB DNA has a complex oxopyrimidine content: HOMedUMP, ca. 30%; PPOMedUMP, ca. 40%; and YdTMP, ca. 30%. The expanded level of YdTMP suggests that at certain sites, reductive modification and hypermodification are competing reactions. Interestingly, the PPOMedUMP content of modB DNA seemingly reflects the maximum degree to which phage DNA can be pyrophosphorylated, since the loss of YdTMP from modBmodC and modBmodD DNAs results in a unilateral increase in HOMedUMP content.     

Genome organization of Sp beta c2 bacteriophage carrying the thyP3 gene

Thymine auxotrophs of Bacillus subtilis strains lysogenic for temperate bacteriophage SP beta c2 were transformed to prototrophy by DNA from related phage phi 3T. During transformation, the phi 3T-encoded thymidylate synthetase gene, thyP3, became integrated into the extreme right end of the SP beta c2 prophage near the bacterial citK gene. Upon heat induction, the transformed B. subtilis cells released SP beta c2T phages that could lysogenize thymine auxotrophs and convert them to prototrophy. Comparison of restriction endonuclease fragments of DNAs from SP beta c2 and SP beta c2T phages revealed that the latter contained a large region of deletion and substitution near the center of the chromosome. This region included the phage attachment site on the SP beta c2 genome.     

DNA Synthesis and Gene Expression in Bacillus subtilis Infected with Wild-Type and Hypermodification-Defective Bacteriophage SP10

A hypermodified base (Y-Thy) replaces 20% of the thymine (Thy) in mature DNA of Bacillus subtilis phage SP10. Two noncomplementing hypermodification-defective (hmd) mutants are described. At 30°C, hmd phage carried out a normal program, but at temperatures of ≥37°C, the infection process was nonproductive. When cells were infected at 37°C with hmd phage, DNA synthesis started at its usual time (12 min), proceeded at about half the normal rate for 6 to 8 min, and then stopped or declined manyfold. All, or nearly all, of the DNA made under hmd conditions consisted of fully hypermodified parental DNA strands H-bonded to unhypermodified nascent strands. The reduced levels of DNA synthesis observed under hmd conditions were accompanied by weak expression of late genes. A sucrose gradient analysis of SP10 hmd⁺ replicating DNA intermediates was made. Two intermediates, called VG and F, were identified. VF consisted of condensed DNA complexed to protein; VF also contained negatively supercoiled domains covalently joined to relaxed regions. F was composed of linear concatenates from which mature DNA was cleaved. None of those intermediates was evident in cells infected at 37°C with hmd phage. Shiftup experiments were performed wherein cells infected with hmd phage at 30°C were shifted to 37°C at a time when replication was well under way. DNA synthesis stopped or declined manyfold 10 min after shiftup. The hmd DNA made after shiftup was conserved as a form sedimentationally equivalent to the F intermediate, but little mature DNA was evident. It is proposed that Y-Thy is required for replication and DNA maturation because certain key proteins involved with these processes interact preferentially with hypermodified DNA.     

Synthesis of 5-hydroxymethyldeoxyuridine triphosphate in extracts of SP10c phage-infectedBacillus subtilis W23

A hypermodified nucleotide partially replaced deoxythymidylate in mature DNA ofBacillus subtilis phage SP10c. Studies with crude extracts of SP10c-infected cells revealed that deoxythymidylate synthetase activity declined by 70% during the program and was replaced by deoxyuridylate hydroxymethyltransferase. In addition, extracts of infected cells were able to phosphorylate 5-hydroxymethyldeoxyuridylate to the corresponding triphosphate, but these same extracts could not phosphorylate the hypermodified deoxynucleoside monophosphate. It is suggested that deoxythymidylate and the hypermodified nucleotide in mature SP10c DNA are derived by postreplicational modification of 5-hydroxymethyldeoxyuridylate in newly replicated DNA.     

Cloning and expression of bacteriophage SP02 DNAZ polymerase gene L in Bacillus subtilis, using the Staphylococcus aureus plasmid pC194

HindIII restriction endonuclease fragments of DNA from temperate Bacillus subtilis bacteriophage SP02 were cloned in B. subtilis by using the plasmid pC194. Three hybrid plasmids which permit growth of the mutant SP02 susL244 in suppressor-negative bacteria were isolated. SP02 gene L is thought to code for a DNA polymerase essential for autonomous replication of SP02 DNA. Extracts of bacteria carrying one of these hybrid plasmids, pC194-96, had 10- to 30-fold increased DNA polymerase activity. The plasmid-induced DNA polymerase activity differed from that of the known B. subtilis DNA polymerases in several respects. The results of the experiments support the idea that phage SP02 codes for a new DNA polymerase.     

Transductional selection of cloned bacteriophage phi 105 and SP02 deoxyribonucleic acids in Bacillus subtilis.

The Bacillus subtilis temperate bacteriophages phi 105 and SP02 are incapable of transduction of the small, multicopy drug resistance plasmids pUB110 and pCM194. Cloning endonuclease-generated fragments of phi 105 or SP02 DNA into each of the plasmids renders the chimeric derivatives susceptible to transduction specifically by the phage whose deoxyribonucleic acid is present in the chimera. The majority of phage deoxyribonucleic acid fragments identified that render plasmids transducible by phi 105 or SP02 appear to be internal fragments, not fragments containing the cohesive ends. However, the highest overall transduction frequency was observed in SP02-mediated transduction of a derivative of pUB110 containing a 1.6-megadalton EcoRI fragment that likely contains the SP02 cohesive ends (plasmid pPL1010). The transducing activity present in a phi 105 transducing lysate had a buoyant density slightly greater than infectious particles, whereas the majority of transducing particles in an SP02(pPL1010) transducing lysate had a buoyant density slightly less than infectious particles. Although no detectable change in plasmid structure resulted from transduction by phi 105 or SP02, deoxyribonucleic acid isolated from a purified SP02(pPL1010) transducing lysate contained no detectable monomeric pPL1010, but did contain a form of pPL1010 of higher molecular weight than the monomer.     

Synthesis of thymine and alpha-putrescinylthymine in bacteriophage phi W-14-infected Pseudomonas acidovorans.

Host DNA synthesis stopped about 10 min after the infection of Pseudomonas acidovorans with bacteriophage phi W-14, but host DNA was not degraded to acid-soluble fragments. The synthesis of host but not of phage DNA was inhibited by 5-fluorodeoxyuridine. The nucleotide pools of infected cells did not contain dTTP, and infection resulted in the appearance of dTTPase activity. Although ornithine labeled the alpha-putrescinylthymine residues of phi W-14 DNA, ornithine-labeled nucleotides were not detected in infected cells. A new deoxynucleoside triphosphate did appear in infected cells, but it was not labeled by ornithine. It is concluded that the thymine and alpha-putrescinylthymine in phi W-14 DNA are synthesized at the polynucleotide level.     

Interference of plasmid pCM194 with lysogeny of bacteriophage SP02 in Bacillus subtilis.

Three observations indicated that the 2-megadalton chloramphenicol resistance plasmid pCM194 interferes with SP02 lysogeny of Bacillus subtilis. SP02 plaques formed on B. subtilis(pCM194) appeared almost clear, whereas plaques produced on plasmid-free or pUB110-containing cells contained large turbid centers. The number of phages spontaneously liberated by B. subtilis(SP02) was increased 10-fold or more when pCM194 was also present in the lysogens. Lastly, growth of B. subtilis(SP02, pCM194) for approximately 20 to 25 generations resulted in essentially complete loss of the prophage. This interference was not observed with pUB110 or pE194, and the pCM194 interference was not directed against B. subtilis temperate phage phi 105, which is unrelated to SP02. Lytic replication of SP02 appeared to be unaffected by pCM194. pCM194 interference with SP02 lysogeny was demonstrable in recombination-proficient strains and a recE mutant of B. subtilis. SP02 prophage which were noninducible due to the phage ind mutation were resistant to pCM194 interference. pCM194 interference was lost when the entire pCM194 molecule was joined at its unique HpaII site or at one of the two MboI sites to pUB110 or pUB110 derivatives. pBR322 joined to pCM194 at the same MboI site or at the HindIII site produced chimeras that retained the ability to interfere with SP02 lysogeny. A three-part plasmid constructed by joining pBR322 to pCM194 (at HindIII sites) and to pE194 (at PstI sites) was compatible with the SP02 prophage and showed a temperature-sensitive replication phenotype characteristic of the pE194 replicon. One explanation for the interference involves competition for a host component between an SP02 genome attempting to establish lysogeny and plasmids whose replication is directed by the pCM194 replicon.     

Biosynthesis of 5-(4''5''-dihydroxypentyl) uracil as a nucleoside triphosphate in bacteriophage SP15-infected Bacillus subtilis.

The nucleoside triphosphate of 5-(4',5'-dihydroxypentyl)uracil (DHPU) was detected in the acid-soluble extract from bacteriophage SP15-infected Bacillus subtilis W23. No uracil was found in the DNA of either replicating or mature phage. Labeled thymidine added during phage DNA synthesis was incorporated into phage DNA. The presence of DHPU as a nucleoside triphosphate in the acid-soluble pool and the incorporation of thymidine into phage DNA suggest that both DHPU and thymine are incorporated into SP15 DNA via their nucleoside triphosphates. 5-Fluorodeoxyuridine inhibited biosynthesis of SP15 DNA, and this inhibition was reversed by thymidine, resulting in the synthesis of a DNA containing reduced amounts of fully modified DHPU. It is proposed that 5-fluorodeoxyuridine, or its metabolic product, inhibits a step in the biosynthetic pathway to the nucleoside triphosphate of DHPU.     

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.     

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.