Inhibition of bacterial DNA replication by 6-(p-hydroxyphenylazo)-uracil: differential effect on repair and semi-conservative synthesis in Bacillus subtilis

Geometric principles underlying the proliferation of a model cell system

Many bacteria can form wall-deficient variants, or L-forms, that divide by a simple mechanism that does not require the FtsZ-based cell division machinery. Here, we use microfluidic systems to probe the growth, chromosome cycle and division mechanism of Bacillus subtilis L-forms. We find that forcing cells into a narrow linear configuration greatly improves the efficiency of cell growth and chromosome segregation. This reinforces the view that L-form division is driven by an excess accumulation of surface area over volume. Cell geometry also plays a dominant role in controlling the relative positions and movement of segregating chromosomes. Furthermore, the presence of the nucleoid appears to influence division both via a cell volume effect and by nucleoid occlusion, even in the absence of FtsZ. Our results emphasise the importance of geometric effects for a range of crucial cell functions, and are of relevance for efforts to develop artificial or minimal cell systems.

ComGA-RelA interaction and persistence in the Bacillus subtilis K-state

The bistably expressed K-state of Bacillus subtilis is characterized by two distinct features; transformability and arrested growth when K-state cells are exposed to fresh medium. The arrest is manifested by a failure to assemble replisomes and by decreased rates of cell growth and rRNA synthesis. These phenotypes are all partially explained by the presence of the AAA(+) protein ComGA, which is also required for the binding of transforming DNA to the cell surface and for the assembly of the transformation pilus that mediates DNA transport. We have discovered that ComGA interacts with RelA and that the ComGA-dependent inhibition of rRNA synthesis is largely bypassed in strains that cannot synthesize the alarmone (p)ppGpp. We propose that the interaction of ComGA with RelA prevents the hydrolysis of (p)ppGpp in K-state cells, which are thus trapped in a non-growing state until ComGA is degraded. We show that some K-state cells exhibit tolerance to antibiotics, a form of type 1 persistence, and we propose that the bistable expression of both transformability and the growth arrest are bet-hedging adaptations that improve fitness in the face of varying environments, such as those presumably encountered by B. subtilis in the soil.

Mechanism of the Heat Sensitization of Bacillus subtilis Spores by Ethidium Bromide

Pretreatment with ethidium bromide (5 mug/ml) followed by a water wash had no effect on unheated Bacillus subtilis spores, but the viability of these spores after heating was much lower than that of similarly heated spores exposed to water alone. The fate of water- or ethidium bromide-treated spores, unheated or heated, was followed by allowing them to germinate and outgrow in a minimal or a complex liquid medium. Spores exposed to ethidium bromide and then heated (85 degrees C, 10 min) exhibited a developmental block during germination and outgrowth. Many of them were blocked at the stage when the bacterium emerged from the germinated spore. When 0.35 mug of ethidium bromide per ml was added to heated spores in the germination-growth medium, the outgrowth of heated spores was inhibited to the same extent as were pretreated spores. Ethidium bromide acted in the first hour of germination of heated spores since addition after this time was ineffective in inhibiting recovery events. Repair of heat-damaged spore DNA was detected during the first 2 h of germination. The addition of ethidium bromide (final concentration, 0.35 mug/ml) inhibited DNA repair during early outgrowth. Increased sensitivity of spores to heat after pretreatment with sublethal concentrations of ethidium bromide was due to the inhibition of the repair of heat-damaged DNA.

Coordination of cell division and chromosome segregation by a nucleoid occlusion protein in Bacillus subtilis

A range of genetical and physiological experiments have established that diverse bacterial cells possess a function called nucleoid occlusion, which acts to prevent cell division in the vicinity of the nucleoid. We have identified a specific effector of nucleoid occlusion in Bacillus subtilis, Noc (YyaA), as an inhibitor of division that is also a nonspecific DNA binding protein. Under various conditions in which the cell cycle is perturbed, Noc prevents the division machinery from assembling in the vicinity of the nucleoid. Unexpectedly, cells lacking both Noc and the Min system (which prevents division close to the cell poles) are blocked for division, apparently because they establish multiple nonproductive accumulations of division proteins. The results help to explain how B. subtilis specifies the division site under a range of conditions and how it avoids catastrophic breakage of the chromosome by division through the nucleoid.

Hpr (ScoC) and the phosphorelay couple cell cycle and sporulation inBacillus subtilis

Bacillus subtilis sporulation is a developmental process that culminates in the formation of a highly resistant and persistent endospore. Inhibiting DNA synthesis prior to the completion of the final round of DNA replication blocks sporulation at an early stage. Conditions that prevent compartmentalization of gene expression, i.e. inhibition of asymmetric septum formation or chromosome partitioning, also block sporulation at an early stage. Multiple mechanisms including a RecA-dependent, a RecA-independent, and the soj-spo0J operon have been implicated in signal transduction, connecting DNA replication and chromosome partitioning to the onset of sporulation in B. subtilis. We suggest that a single mechanism involving Hpr (ScoC) and Sda couple cell cycle signaling to sporulation initiation. We show that transcription of phosphorelay sensory chain genes is adversely affected by post-exponential perturbation of the cell cycle. DNA replication arrest by chemical treatments, such as hydroxyphenylazouracil, hydroxyurea, nalidixic acid, and through genetic means using dnaA1ts and dnaB19ts temperature-sensitive mutants caused substantial down-regulation of spo0F and kinA expression and elevated the expression of spo0A and spo0H (sigH). Despite the elevation in spo0A expression, Spo0A approximately P-dependent sinI expression was substantially down-regulated indicating that in vivo Spo0A approximately P levels may be diminished. Similar alterations in gene expression patterns were observed in an ftsA279ts mutant background, indicating that cytokinesis and sporulation may also be coupled by a similar mechanism. Loss of function mutation in hpr (scoC) restored sporulation in a dnaA1ts mutant, blocked the DNA replication arrest induction of spo0A expression and restored expression of spo0F, kinA and sinI. Moreover, hpr expression was up-regulated in response to DNA replication arrest. The increase in hpr expression required Sda. These results suggest a role for Hpr (ScoC) in mediating the coupling of cell cycle events to the onset of sporulation.

Structures and Chemical Equilibria of Some N-Heterocycles Containing Amide Linkages

Structures and chemical equilibria of 5-carboxy-2-thiouracil (1), 5,6-diphenyl-3-hydroxy-1,2,4-triazine (2),  1-phenyl-3-methyl-5-pyrazolone (3) and 2-mercapto-4,6-dimethylpyrimidine hydrochloride (4) are reported. Their electronic transitions are assigned and pK values are evaluated and discussed.

Postexponential regulation of sin operon expression in Bacillus subtilis

The expression of many gene products required during the early stages of Bacillus subtilis sporulation is regulated by sinIR operon proteins. Transcription of sinIR from the P1 promoter is induced at the end of exponential growth. In vivo transcription studies suggest that P1 induction is repressed by the transition-state regulatory protein Hpr and is induced by the phosphorylated form of Spo0A. In vitro DNase I footprinting studies confirmed that Hpr, AbrB, and Spo0A are trans-acting transcriptional factors that bind to the P1 promoter region of sinIR. We have also determined that the P1 promoter is transcribed in vitro by the major vegetative sigma factor, final sigma(A), form of RNA polymerase.

Visualization of mismatch repair in bacterial cells

We determined the localizations of mismatch repair proteins in living Bacillus subtilis cells. MutS-GFP colocalized with the chromosome in all cells and formed foci in a subset of cells. MutL-GFP formed foci in a subset of cells, and its localization was MutS dependent. The introduction of mismatches by growth in 2-aminopurine caused a replication-dependent increase in the number of cells with MutS and MutL foci. Approximately half of the MutS foci colocalized with DNA polymerase foci. We conclude that MutS is associated with the entire chromosome, poised to detect mismatches. After detection, it appears that mismatch repair foci assemble at mismatches as they emerge from the DNA polymerase and are then carried away from the replisome by continuing replication.

Transfection enhancement in Bacillus subtilis displays features of a novel DNA repair pathway. II: Host constitutive expression, repair DNA synthesis, and in vitro activity

In the Bacillus subtilis genetic system, transfection refers to uptake of isolated bacteriophage DNA by competent host cells, sometimes followed by productive cell infection. Previous studies have shown that ultraviolet (UV)-irradiation of the competent host cells, or cotransfection of UV-irradiated heterologous DNA, can increase the efficiency of transfection in some cases; these latter two phenomena have been called transfection enhancement (TE). In an accompanying paper, we show that TE is apparently confined to the B. subtilis phages that contain hydroxymethyluracil (HMU) in their DNA, and that the photoproduct in UV-irradiated DNA that mediates TE is specific, and different than the pyrimidine dimer, thymine glycol, uracil, or HMU. We also show that TE is due to reduced intracellular endonucleolytic attack of transfecting DNA. Based on this DNA base and nucleolytic specificity, we hypothesized that TE reflects the incidental action of a host DNA repair system on transfecting HMU phage DNA. In continuing these studies, we show here that duplex infecting HMU phage DNA is apparently inactivated by this same putative repair system when phage protein synthesis is blocked. We find, too, that this inactivation of infecting HMU phage DNA can be inhibited by UV-irradiated DNA, and that this process has a similar DNA base specificity as for TE. The survival of infecting HMU phage DNA is dependent on host DNA polymerase activity. We can detect specific DNA synthesis consistent with formation of repair patches when inactivation of infecting HMU phage DNA is ongoing, but not when it is inhibited by the presence of UV DNA or by allowing phage gene expression. Each of these results is consistent with the hypothesis that TE reflects the action of a novel DNA repair pathway. We show that a candidate TE-associated enzymatic activity can be detected in cell free extracts of uninfected, but not HMU phage-infected, B. subtilis cells. Correspondingly, the extracts of phage-infected cells appear to contain a diffusible factor that acts as an inhibitor of this host enzyme.

Hyperrecombination in pneumococcus: A/G to C.G repair and requirement for DNA polymerase I

During pneumococcal transformation, we had previously described that the ami36 mutation, which results from a C.G to A.T transversion, induces a large excess of wild-type recombinants in two point crosses. Upon donor-recipient DNA recombination, two heteroduplexes are generated by this mutation: A36/G+ and C+/T36. In two point crosses, hyperrecombination is observed only when transformation leads to the A/G mismatch. Here, we have studied the separate evolution of A36/G+ and C+/T36 heterozygotes created upon transformation of an ami36 mutant strain with artificial heteroduplex DNAs. We found that the A36/G+ mismatch leads to a preferential generation of wild-type progeny as compared with the complementary C+/T36 mismatch. This result suggests that A/G carrying transformants partly behave as wild-type homozygotes. The only way to account for such behavior is an excision repair correcting some A/G mispairs created upon transformation into C.G pairs. Moreover, we show that hyperrecombination triggered by ami36 is strongly reduced in a DNA polymerase I deficient strain. This strengthens the fact of DNA repair synthesis, which should be therefore prominently due to DNA polymerase I.

Analysis of the SOS inducing signal in Bacillus subtilis using Escherichia coli LexA as a probe

We analyzed the Bacillus subtilis SOS response using Escherichia coli LexA protein as a probe to measure the kinetics of SOS activation and DNA repair in wild-type and DNA repair-deficient strains. By examining the effects of DNA-damaging agents that produce the SOS inducing signal in E. coli by three distinct pathways, we obtained evidence that the nature of the SOS inducing signal has been conserved in B. subtilis. In particular, we used the B. subtilis DNA polymerase III inhibitor, 6-(p-hydroxyphenylazo)-uracil, to show that DNA replication is required to generate the SOS inducing signal following UV irradiation. We also present evidence that single-stranded gaps, generated by excision repair, serve as part of the UV inducing signal. By assaying the SOS response in B. subtilis dinA, dinB, and dinC mutants, we identified distinct deficiencies in SOS activation and DNA repair that suggest roles for the corresponding gene products in the SOS response.

Complementation assay of primer protein: gene expression systems of plasmid vectors support the infection of suppressor sensitive mutant phages M2 and phi 29

Two different expression systems of genes of primer proteins (pE for phage M2, and p3 for phi 29) were constructed to study the protein primed DNA replication of Bacillus phages M2 and phi 29. In one system, expression of the genes was under the control of the inducible spac promoter, whereas in the other system, the expression was under the control of the constitutive promoter in plasmid pUB110. Complementation tests in vivo were performed between the primer proteins expressed by these systems and mutant phages having suppressor sensitive mutations in the genes of the primer proteins. The phages M2 susE and phi 29 sus3 were complemented by pE and p3 expressed by the systems, respectively. However, the complementation and apparent phage DNA synthesis were not detected in the combinations between susE of phage M2 and p3 of phage phi 29, and vice versa. Although pE and p3 proteins exhibited structurally and functionally similar characteristics, these proteins showed species specificity in the protein primed DNA replication of bacteriophages M2 and phi 29.

Axial filament formation in Bacillus subtilis: induction of nucleoids of increasing length after addition of chloramphenicol to exponential-phase cultures approaching stationary phase

When chloramphenicol was added to a culture of Bacillus subtilis in early exponential growth, microscopic observation of cells stained by 4',6-diamidino-2-phenylindole showed nucleoids that had changed in appearance from irregular spheres and dumbbells to large, brightly stained spheres and ovals. In contrast, the addition of chloramphenicol to cultures in mid- and late exponential growth showed cells with elongated nucleoids whose frequency and length increased as the culture approached stationary phase. The kinetics of nucleoid elongation after the addition of chloramphenicol to exponential-phase cultures was complex. Immediately after treatment, the rate of nucleoid elongation was very rapid. The nucleoid then elongated steadily for about 4 min, after which the rate of elongation decreased considerably. Nucleoids of cells treated with 6-(p-hydroxyphenylazo)-uracil (an inhibitor of DNA synthesis) exhibited the immediate rapid elongation upon chloramphenicol treatment but not the subsequent changes. These observations suggest that axial filament formation during stationary phase (stage I of sporulation) in the absence of chloramphenicol results from changes in nucleoid structure that are initiated earlier, during exponential growth.

Coupling between gene expression and DNA synthesis early during development in Bacillus subtilis

Endospore formation in the bacterium Bacillus subtilis involves generation of two cell types, each with different developmental fates. Each cell type contains an active chromosome, and treatments that inhibit DNA synthesis at the beginning of development inhibit spore formation. We describe experiments demonstrating that gene expression early during sporulation is coupled to DNA synthesis. Expression of several genes that are induced early during sporulation, before the formation of two cell types, is inhibited when DNA synthesis is inhibited. Genes that are affected require the transcription factor encoded by spo0A for normal induction. Spo0A protein is normally activated early in development by a multicomponent phosphorylation pathway, or phospho-relay. Altered function mutations in spo0A that bypass the need for the phospho-relay allow early sporulation gene expression, even when DNA synthesis is inhibited. These results indicate that inhibition of DNA synthesis prevents activation of the Spo0A transcription factor by inhibiting a step in the phospho-relay. It seems likely that coupling early developmental gene expression to DNA synthesis is a general mechanism to prevent inappropriate or unnecessary gene expression.

Action of 6-(p-hydroxyphenylazo)-uracil on bacteriophage IG 1

IG 1, a temperate phage of Bacillus subtilis, is strongly induced from its lysogens by 6-(p-hydroxyphenylazo)-uracil, an azopyrimidine known as selectively inhibiting the B. subtilis DNA polymerase III. IG 1 phages originated either by induction or infection multiply, abundantly, in the presence of that azopyrimidine, in spite of the drastic decline of cell viability. Chloramphenicol completely suppresses the induction effect and also blocks the formation of spontaneously induced phage particles.

Effect of ultraviolet radiation on the Bacillus subtilis phages SPO2, SPP1 and phi 29 and their DNAs

A comparative study of the effects of ultraviolet radiation on three Bacillus subtilis phages is presented. Phages phi 29, SPP1 and SPO2c12 or their DNAs were irradiated by UVC (254 nm) and quantum yields for inactivation were calculated. For each phage, the purified DNA was found to be more sensitive than the intact virus when assayed in a uvr+ host. The data imply that this is because transfecting DNA is repaired less efficiently than DNA of the intact phage; rather than because of differences in sensitivity to lesion production. Even though phi 29 has the smallest target size of the three phages, phi 29 and its DNA are the most sensitive. Phages SPO2 and SPP1 code for gene products which complement the repair system of the host. The transfecting DNA of phage SPP1 is extremely sensitive to UV damage when assayed in a uvr-host. This is attributed to the fact that in transfection SPP1 DNA must undergo recombination for productive infection to occur. The recombination process strongly interferes with the repair of damaged DNA.

DNA replication by a DNA-membrane complex extracted from Bacillus subtilis: site of initiation in vitro and initiation potential of subcomplexes

A DNA-membrane complex extracted from Bacillus subtilis was studied further as a model system for initiation of bacterial DNA replication in vitro. Of three subcomplexes purified from the crude complex by a combination of CsCl and sucrose gradient centrifugation, the synthetic capability of only one was inhibited significantly by streptovaricin, a known inhibitor of RNA primer formation. A selective enrichment in the level of this subcomplex was obtained by manipulating a thymine-requiring mutant. The synthetic capabilities of an enriched and nonenriched DNA-membrane complex were compared in the presence and absence of streptovaricin. Although the rate and extent of DNA synthesis per unit of protein were approximately the same in the absence of the antibiotic, there was a much greater inhibition of synthesis shown by the enriched complex in the presence of streptovaricin. Although the amount of DNA present in the putative initiation subcomplex was less than 0.3 to 0.4% of the total DNA present in the crude complex, such DNA, except for a few quantitative differences, was still representative of genomic DNA. Newly synthesized DNA hybridized to specific origin- and non-origin-derived restriction fragments of the B. subtilis genome. However, when an elongation inhibitor (ddCTP) was added, hybridization of such DNA to almost all of the nonorigin fragments disappeared or was reduced drastically, whereas origin region hybridization patterns remained strong. The highest level of hybridization in the origin region occurred with a BamHI (B7) restriction fragment of 5.6 kilobases that has been implicated by others as one site initiation in vivo (N. Ogasawara, M. Seiki, and H. Yoshikawa, Nature (London) 281:702-704, 1979; S. J. Seror-Laurent and G. Henckes, Proc. Natl. Acad. Sci. USA 82:3586-3590, 1985).

Plasmid marker rescue transformation proceeds by breakage-reunion in Bacillus subtilis

Bacillus subtilis carrying a plasmid which replicates with a copy number of about 1 was transformed with linearized homologous plasmid DNA labeled with the heavy isotopes 2H and 15N, in the presence of 32Pi and 6-(p-hydroxyphenylazo)-uracil to inhibit DNA replication. Plasmid DNA was isolated from the transformed culture and fractionated in cesium chloride density gradients. The distribution of total and donor plasmid DNA was examined, using specific hybridization probes. The synthesis of new DNA, associated with the integration of donor moiety, was also monitored. Donor-specific sequences were present at a density intermediate between that of light and hybrid DNA. This recombinant DNA represented 1.4% of total plasmid DNA. The latter value corresponded well with the transforming activity (1.7%) obtained for the donor marker. Newly synthesized material associated with plasmid DNA at the recombinant density amounted to a minor portion of the recombinant plasmid DNA. These data suggest that, like chromosomal transformation, plasmid marker rescue transformation does not require replication for the integration of donor markers and, also like chromosomal transformation, proceeds by a breakage-reunion mechanism. The extent of donor DNA replacement of recipient DNA per plasmid molecule of 54 kilobases (27 kilobase pairs) was estimated as 16 kilobases.

Use of a cloned DNA fragment to analyze the fate of donor DNA in transformation of Streptococcus pneumoniae

The integration of donor label into the recipient fragment is followed during transformation of Streptococcus pneumoniae. The method used involves gel analysis of restriction endonuclease-treated recipient DNA after recombination with a radioactively labeled homologous cloned fragment.

Postincision steps of photoproduct removal in a mutant of Bacillus cereus 569 that produces UV-sensitive spores

An excision-defective mutant of Bacillus cereus 569 is normal in incision and repair synthesis, but rejoining of incision breaks is defective, resulting in accumulation of low-molecular-weight DNA after UV irradiation. The defect in removal of photoproducts by exonuclease after incision renders both vegetative cells and dormant spores of the mutant sensitive to UV. A similarity is indicated to the uvrD mutation described recently in Escherichia coli.

Single-stranded fraction of deoxyribonucleic acid from Bacillus subtilis

About 13% of the deoxyribonucleic acid (DNA) of various strains of Bacillus subtilis, independent of the stage of growth or competence for transformation, was rendered acid soluble by endonuclease S1. In a pH 11.2 CsCl gradient, 4% of the untreated DNA banded at the density typical for single-stranded molecules, whereas 9% of the remaining DNA (main band) was sensitive to endonuclease S1. Selective inhibition of DNA polymerase III, or of DNA-dependent ribonucleic acid polymerase, did not increase or abolish single-strandedness. The DNA purification procedure did affect the level of single-stranded DNA, indicating its binding to cell constituents containing ribonucleic acid, protein, and membranous material. The molecular weight of the single-stranded fraction resembled that of total denatured DNA, and its buoyant density in an alkaline CsCl gradient was centered partially at a density of 1.772 g/cm3 and partially at a density of 7.759 g/cm3. Incubation of DNA under conditions leading to renaturation of its single-stranded fraction led to an increase in transforming activity for the purA16+ marker (close to the origin of replication) relative to leu-8+ and metC3+ markers (located in the middle of the chromosome), indicating this region is the main source of the single-stranded fraction.

Plasmid transformation in Bacillus subtilis: fate of plasmid DNA

Only multimeric, and not monomeric forms of B. subtilis plasmids can transform B. subtilis cells (Canosi et al. 1978). This finding prompted us to study the physico-chemical fate of plasmid DNA in transformation. Competent cells of B. subtilis were exposed to either unfractionated preparations or to preparations of multimeric plasmid DNA. Plasmid DNA was re-extracted from such cells and then analyzed by sedimentation and isopycnic centrifugation and also defined by its sensitivity to nuclease S1 degradation. No double-stranded plasmid DNA could be recovered from cells transformed with unfractionated plasmid preparations which contained predominantly monomeric covalently closed circular (CCC) DNA. Re-extracted plasmid DNA was single-stranded, had a molecular weight considerably smaller than monomer length DNA and had been subject to degradation to acid soluble products. However, when transformations were performed with multimeric DNA (constructed by in vitro ligation of linearized pC194 DNA), both double-stranded and partially double-stranded DNA could be recovered in addition to single-stranded DNA. We assume that plasmid DNA is converted to a single-stranded form in transformation, irrespective of its molecular structure. Double-stranded and partially double-stranded DNAs found in transformation with multimeric DNA would be the products of intramolecular annealing.

Enrichment of DNA polymerase III activity in a DNA membrane complex purified from Pneumococcus: the possible existence of subcomplexes

Three DNA polymerase activities, one related to DNA pol III, have been extracted from a DNA membrane complex purified from Streptococcus pneumoniae. DNA pol III was purified 3300-fold, DNA pol II 2800-fold and DNA pol I 1800-fold. Based on inhibition analysis with a drug known to inhibit DNA pol III activity in Gram positive organisms. 6(p-hydroxyphenyl azo) uracil (HpU), 55% of the total DNA polymerase activity is represented by pol III. In contrast, only 3-5% of the total DNA polymerase activity is inhibited by HpU in crude extracts. The purification of the DNA membrane complex from pneumococcus is modified from an earlier procedure (Firshein 1972). The modified procedure results in the separation of three distinct DNA-protein-phospholipid subcomplexes of which the one described above contains most of the radioactivity derived from cells pulsed for a short time with (3H)-thymidine. Proteins are involved in binding DNA in each complex and the conformation of DNA in each complex may be different. All of the subcomplexes contain DNA polymerase activity partially sensitive to HpU. These results provide direct evidence for the structural integrity of a complex that may be involved in DNA replication in vivo.

Capacity for postreplication repair correlated with transducibility in Rec- mutants of Bacillus subtilis

Bacillus subtilis strains deficient in transduction, transformation, or both were examined for the ability to remove pyrimidine dimers and to convert deoxyribonucleic acid newly synthesized after ultraviolet irradiation to high molecular weight. In one strain deficient in both recombination processes, short pieces of deoxyribonucleic acid synthesized after irradiation were not converted to high molecular weight. Two transformable strains deficient in transduction were also deficient in postreplication repair (i.e., joining of newly synthesized DNA fragments), whereas a nontransformable strain that was normal in transduction was proficient in postreplication repair. None of the transformable strains showed deficiencies in repair resynthesis or ligase activity. Our results suggest that some recombinational events may be common to transduction and postreplication repair but not to transformation, emphasizing the difference between these two pathways for genetic exchange.

Chromosome replication in sporulating cells of Bacillus subtilis

A method of specifically labeling the chromosomal terminus of Bacillus subtilis is described. When sporulating cultures were pulse-labeled with [(3)H]thymidine and then treated with 6-(p-hydroxyphenylazo)uracil, a drug which inhibits deoxyribonucleic acid (DNA) synthesis rapidly and completely, the only labeled spores formed were those that had completed replication during the pulse period. DNA-mediated transformation was used to show that the DNA of spores formed in the presence of 6-(p-hydroxyphenylazo)uracil had the same ratio of origin to terminus markers as DNA from untreated spores. Furthermore, spores formed in the presence of 6-(p-hydroxyphenylazo)uracil had the same DNA content as untreated spores. These two observations indicated that spores formed in the presence of 6-(hydroxyphenylazo)uracil contained completed chromosomes. The rate of termination of chromosomes destined to be packaged into spores was determined by this method, using the Sterlini-Mandelstam replacement system and a single medium exhaustion system for inducing sporulation. With both systems the rate of termination reached a broad peak 2 h after the start of sporogenesis. This was measured from the time of resuspension by using the replacement system and from the point where exponential growth ceased in the exhaustion system. The amount of spore DNA synthesized in the Sterlini-Mandelstam sporulation-inducing medium was very close to one-half the amount of the DNA present in mature spores. This suggests that chromosomes destined to be packaged into spores were replicated from close to the origin and possibly initiated in the sporulation-inducing medium. A method was devised for estimating the time taken to complete replication of the chromosomes destined to be packaged into spores. This was probably no more than 50 min. Whereas starvation must have occurred almost simultaneously in most cells in the population, the chromosome replication that was essential for sporogenesis was distributed over a wide time span. Thus, in some cells, replication started within 10 min of the nutritional step-down, but the peak rate was not reached for 1 h; thereafter replication continued at a substantial rate.

Excision and repair of mismatched base pairs in transformation of Streptococcus pneumoniae

The use of heteroduplex DNA molecules as donors in pneumococcal transformation makes it possible to follow the fate of each DNA strand. The integration efficiency of each strand depends strongly upon the single base changes it carries. The function (hex) which reduces drastically the transformation yield of markers referred to as low efficiency (LE) tends to remove either donor strand without respect ot which one is introduced. In the case of high efficiency (HE) markers the reduction in the transformation yield involves the elimination of only one donor strand. For a given locus it can be either one depending upon the mutation. The reduction in transformation yield can be less drastic for HE markers than for both strands of the LE markers. These data are discussed in terms of differences in the affinity for mismatched base pairs. We have studied the transfer of information from each donor DNA strand to the recipient genome, on the basis of differences in the rates of phenotypic expression of a given marker introduced on opposite strands. Results show that, as in the case of LE markers, the information from HE markers, when introduced on the strand recognized by the hex function, is transmitted to both strands of the recipient molecule. Correction of the recipient strand to homozygosis probably accounts for this information transfer. These results, together with earlier investigations, strongly suggest that the hex function is an excision-repair system acting on donor-recipient base pair mismatches.

Gap-filling repair synthesis induced by ultraviolet light in a Bacillus subtilis Uvr- mutant

Deoxyribonucleic acid repair synthesis was studied in one wild-type and two mutant strains of Bacillus subtilis that are defective in excision of pyrimidine dimers. The cells were irradiated with ultraviolet light, and 6-(p-hydroxyphenyl-azo)-uracil was used to block replicative synthesis, allowing only repair synthesis. One of the mutations (uvs-42) resulted in a severe inhibition of incision, dimer excision, and repair synthesis. In contrast, the other mutant (uvr-1) slowly incised and excised dimers and did repair synthesis in patches which appear to be several-fold longer than those in the wild-type strain, apparently because large gaps are produced at excision sites. The results indicate that the primary defect in uvs-42 cells is in initiation of dimer excision, whereas the uvr-1 mutation appears to be a defect in the exonuclease normally used to complete dimer excision.

Independence of Bacillus subtilis spore outgrowth from DNA synthesis

The outgrowth of spores of Bacillus subtilis 168 proceeded normally in temperature-sensitive DNA mutants under restrictive conditions and in the absence of DNA synthesis. Two inhibitors of DNA synthesis, nalidoxic acid and 6-(p-hydroxyphenylazo)-uracil, inhibited spore outgrowth under some nutritional conditions; this inhibition of outgrowth however, though not that of DNA synthesis, could be reversed by glucose. The sensitivity of the outgrowing spores to nalidixic acid and 6-(p-hydroxyphenylazo)-uracil inhbition decreased as a function of outgrowth time. The cells became completely resistant to the inhibitors after 90 min. The development of this resistance occurred also in the absence of DNA synthesis. It was concluded that DNA synthesis is not needed for spore outgrowth, and that outgrowing cells and vegetative cells differ in their sensitivity to these inhibitors.

Bacillus subtilis dnaF: a mutation of the gene specifying the structure of DNA polymerase III

The characteristics of Bacillus subtilis dnaF, a mutation specifying a temperature sensitive phenotype, were examined to determine its relationship to polC, the gene specifying the structure of DNA polymerase III (pol III). Exposure of growing cells bearing dnaF to non-permissive temperature inhibited replicative DNA synthesis and specifically depressed the expression of pol III activity in crude extracts. Highly purified pol III derived from cells bearing dnaF was temperature.sensitive in its polymerase activity, indicating that dnaF is a specific, polC mutation which specifies a structurally altered enzyme.

DNA synthesis in competent Bacillus subtilis cells

Competent cells of Bacillus subtilis incorporate degradation products from transfecting DNA into their chromosomal DNA. The sensitivity of this incorporation to inhibitors of bacterial DNA synthesis [phage infection or 6-(p-hydroxyphenylazo)-uracil] suggests that semiconservative DNA synthesis can occur in competent cells.

Repair and subsequent fragmentation of deoxyribonucleic acid in ultraviolet-irradiated Bacillus subtilis recA

Cells of Bacillus subtilis recA1 are sensitive to irradiation with ultraviolet light. Evidence is presented here that these cells are not defective in ultraviolet light-induced incision of deoxyribonucleic acid (DNA) or repair DNA synthesis. Ligation of DNA at repair sites appears to occur, but the DNA is subsequently fragmented, apparently at sites of previous repair synthesis. It is hypothesized that the defect in DNA repair leads to host-specific restriction at repaired sites because of a defect in either the structure of the repaired region or specificity of the restriction/modification system.

On the identity of dnaP and dnaF genes of Bacillus subtilis

The dnaP strains of Bacillus subtilis are altered in the initiation of DNA replication at high temperature (Riva et al., 1975). Fine mapping of the gene shows that it is located very close to the dnaF gene described by Karamata and Gross (1970) and mapped by Love et al. (1976) in the polC region. The phenotype of both mutants is indistinguishable: the DNA synthesis stops at non permissive temperature after synthesizing an amount of DNA equivalent to the completion of the rounds of replication already initiated; at permissive temperature they are abnormally sensitive to MMS and are reduced in the ability to be transformed. Both mutants are to be considered as belonging to the dnaF locus. The dnaF gene is very close to the polC gene, which specifies the DNA polymerase III of B. subtilis. The DNA polymerase III of the dnaF mutants is not temperature sensitive in vitro, however, the level of this enzyme is lower by a factor of 4 or 5 in the dnaF mutants, at the permissive temperature. Following shift of dnaF cultures to the non permissive temperature, the level of DNA polymerase III activity specifically decreases further by a factor of at least 10 in the mutant, whereas the DNA polymerase I level is unaffected. The possible roles of the dnaF gene in the control of the cellular level of the DNA polymerase III, and the possibility of a regulatory role of DNA polymerase III in the initiation of DNA replication in bacteria are discussed.

Changes in deoxyribonucleic acid polymerase activities in synthesis of deoxyribonucleic acid during sporulation of Bacillus subtilis

The deoxyribonucleic acid (DNA) polymerase activities in Bacillus subtilis strains Marburg 168 (thy-trp2) and D22, a DNA polymerase I-deficient mutant, were measured at various stages of sporulation. The DNA polymerase I activity, which had decreased after the exponential growth, began to increase at the early stage of sporulation, reached a maximum and then again decreased. The activity of neither DNA polymerase II nor III was observed to change so drastically as that of DNA polymerase I during sporulation. The incorporation of [3H]deoxythymidine 5'-triphosphate ([3H]dTTP) into Brij 58-treated permeable cells increased during sporulation. The stimulation of [3H]dTTP incorporation into the cells by irradiation with ultraviolet light was also observed to coincide with DNA polymerase I activity. In strain D22 the activities of DNA polymerase II and III were almost constant with time. Neither change of [3H]dTTP incorporation into Brij 58-treated cells nor stimulation of incorporation by irradiation with ultraviolet light was observed.

Postirradiation recovery dependent on the uvr-1 locus in Bacillus subtilis

A mutant (uvr-1) of Bacillus subtilis that is deficient in excision of ultraviolet (UV)-induced pyrimidine dimers from deoxyribonucleic acid (DNA) shows a marked increase in ability to survive UV irradiation when plated on amino acid-supplemented agar medium compared with its survival ability when plated on nutrient plating medium, the effect is considered to be one of growth-dependent lethality. Irradiated stationary phase uvr-1 cells, incubated in liquid medium lacking amino acids required for growth, recover from this sensitivity to rich medium within 3 to 4 h after irradiation. Recovery is greatly reduced in the absence of glucose oiminated. Exponentially growing cells have a limited ability to recover from sensitivity to rich medium. Growth-dependent lethality can also occur in liquid medium. In nutrient broth the ability of irradiated stationary-phase uvr-1 cells to form colonies on defined agar medium decreases during postirradiation incubation, but treatmeth with chloramphenicol inhibits the loss of colony-forming ability. Recovery from sensitivity to rich media is inhibited by caffeine but not by 6-(p-hydroxyphenylazo)-uracil, and inhibitor of DNA replication. Alkaline sucrose gradient profiles show that conditions allowing recovery also favor maintaining intact DNA strands, whereas DNA strand breakage or degradation is associated with loss of viability. Recovery from sensitivity to rich medium has not been observed in the Ur+ parent or in strains carrying the mutations uvs-42 (another deficiency in dimer excision), recA1, or polA59. A uvr-1 recA1 mutants shows a higher level of recovery than does the recA1 single mutant, but a much lower level than the uvr-1 single mutant. Apparently, both the uvr-1 defect and Rec+ and PoII+ functions are essential for recovery from sensitivity to rich medium. For optimal recovery, growth immediately after irradiation must be delayed. The process requires energy, apparently involves recombination, and probably results in rejoining of DNA strands in which incision but not excision has occurred.

Coumerimycin A1: A preferential inhibitor of replicative DNA synthesis in Escherichia coli. II. In vivo characterization

In vitro inhibitions by coumermycin A1 of DNA and RNA synthesis in toluenized cells were studied. In a sensitive strain, 50% inhibitions of replication and transcription were observed at 0.035 and 0.600 mug/ml, respectively. DNA synthesis in a toluenized-resistant mutant was 50% inhibited at 0.140 mug/ml of coumermycin A1, whereas RNA synthesis was unaffected at all concentrations tested. Studies with a mixture of toluenized-sensitive and -resistant bacteria ruled out the presence of a diffusable activator or inhibitor of coumermycin A1 action. Density label studies with toluenized pol A+ and pol A- strains indicated that replicative DNA synthesis was specifically inhibited, in agreement with the in vivo studies in the preceding paper of this issue (Ryan, M. J. (1976), Biochemistry 15). Highly purified Escherichia coli DNA polymerase III and RNA polymerase both were inhibited by this antibiotic. However, the high concentrations necessary for these inhibitions suggest that they are not biologically relevant. No interaction between DNA and coumermycin A1 was observed with the following analytical procedures: ultraviolet difference spectra, DNA absorbance-temperature transitions, equilibrium buoyant density centrifugation, and DNA cross-linking determinations.

Effect of deoxyribonucleic acid replication inhibitors on bacterial recombination

Two inhibitors of replicative deoxyribonucleic acid (DNA) synthesis, nalidixic acid (NAL) and 6-(p-hydroxyphenylazo)-uracil (HPUra), showed different effects on genetic recombination and DNA repair in Bacillus subtilis. Previous work (Pedrini et al., 1972) showed that NAL does not interfere with the transformation process of B. subtilis. The results reported in this work demonstrated that the drug was also without effect on the transfection by SPP1 or SPO-1 phage DNA (a process that requires a recombination event). The drug was also ineffective on the host cell reactivation of ultraviolet-irradiated SPP1 phage, as well as on transfection with ultraviolet-irradiated DNA of the same phage. HPUra instead markedly reduced the transformation process, as well as transfection, by SPO-1 DNA, but it did not affect the host cell reactivation of SPO-1 phage. In conclusion, whereas the NAL target seems to be specific for replicative DNA synthesis, the HPUra target (i.e., the DNA polymerase III of B. subtilis) seems to be involved also in recombination, but not in the excision repair process. The mutations conferring NAL and HPUra resistance used in this work were mapped by PBS-1 transduction.

Mapping of the gene specifying DNA polymerase III of Bacillus subtilis

polC, the gene specifying the structure of the replication-specific DNA polymerase III of B. subtilis, was mapped by exploiting azp-12, a mutation conferring resistance to azopyrimidine which determines a mutant, azopyrimidine-resistant enzyme. azp-12 was located in the area of the pyrA locus and is between spcB1 and recA1. azp-12 was linked by transformation to four other mutations which influence the in vitro behaviour of DNA polymerase III--polC25, polC26, mut-1(ts), and DNAF133; the close linkage of these five mutations strongly suggests that they are alleles of the same gene.

Gene expression of bacteriophage SPP1. II. Regulatory aspects

The expression of late SPP1 genes depends on preceding SPP1 DNA replication. This is shown in nonpermissive infection with a mutant defective in DNA replication and after inhibition of DNA synthesis by HPUra. The potential for host gene expression is not significantly influenced by SPP1 infection, as evidenced by the continuation of host protein synthesis and the inducibility of glycerolphosphate dehydrogenase after infection. The involvement of a positive control element in the regulation of SPP1 gene expression is deduced from the observation that chloramphenicol prevents the synthesis of the only class of mRNA which is transcribed from the L-strand.

Nucleic acid synthesis and ribonucleic acid polymerase specificity in germinating and outgrowing spores of Bacillus subtilis

Nucleic acid synthesis was studied during germination and outgrowth of normal spores of Bacillus subtilis, as well as of spores carrying the genome of phage phie. In a system in which development was restricted to the spore-darkening phase, synthesis of ribonucleic acid (RNA), but not deoxyribonucleic acid (DNA), was detected. The extent of RNA synthesis and turnover, during this phase was similar for the two types of spores. In a partially darkened population of spores of either type, there was little RNA degradation, whereas there was considerable turnover in a fully darkened population. The DNA-dependent RNA polymerase of dormant or dark spores was not active in vitro with phi DNA as template, although a sigma-like factor could be separated from the polymerizing activity by zone centrifugation. Within 40 min after resuspension of dark spores in a medium that allows outgrowth, the enzyme acquired the ability to transcribe the phage DNA efficiently. During outgrowth, both normal and carrier spores synthesized DNA, but in carrier spores this DNA was almost entirely phage specific. The pattern of RNA accumulation in normal spores was in two distinct phase (0 to 60 min and 90 to 180 min). The second phase was absent in outgrowing carrier spores. The burst of phage in carrier spores occurred at 160 to 180 min.