Condensation of the forespore nucleoid early in sporulation of Bacillus species.

Fluorescence microscopic examination coupled with digital videoimage analysis of 4',6-diamidino-2-phenylindole-stained sporulating cells of Bacillus megaterium or Bacillus subtilis revealed a striking condensation of the forespore nucleoid. While both mother cell and forespore compartments had equal amounts of DNA, the forespore nucleoid became greater than 2-fold more condensed than the mother cell nucleoid. The condensation of the forespore nucleoid began after only the first hour of sporulation, 2 to 3 h before expression of most forespore-specific genes including those for small, acid-soluble spore proteins, and was abolished in spo0 mutants but not in spoII or spoIII mutants. It is possible that this striking condensation of forespore DNA plays some role in modulating gene expression during sporulation.     

Viability of rep recA mutants depends on their capacity to cope with spontaneous oxidative damage and on the DnaK chaperone protein

Replication arrests due to the lack or the inhibition of replicative helicases are processed by recombination proteins. Consequently, cells deficient in the Rep helicase, in which replication pauses are frequent, require the RecBCD recombination complex for growth. rep recA mutants are viable and display no growth defect at 37 or 42 degrees C. The putative role of chaperone proteins in rep and rep recA mutants was investigated by testing the effects of dnaK mutations. dnaK756 and dnaK306 mutations, which allow growth of otherwise wild-type Escherichia coli cells at 40 degrees C, are lethal in rep recA mutants at this temperature. Furthermore, they affect the growth of rep mutants, and to a lesser extent, that of recA mutants. We conclude that both rep and recA mutants require DnaK for optimal growth, leading to low viability of the triple (rep recA dnaK) mutant. rep recA mutant cells form colonies at low efficiency when grown to exponential phase at 30 degrees C. Although the plating defect is not observed at a high temperature, it is not suppressed by overexpression of heat shock proteins at 30 degrees C. The plating defect of rep recA mutant cells is suppressed by the presence of catalase in the plates. The cryosensitivity of rep recA mutants therefore results from an increased sensitivity to oxidative damage upon propagation at low temperatures.     

Inactivation of the Spirochete recA Gene Results in a Mutant with Low Viability and Irregular Nucleoid Morphology

Recently, we have shown the first evidence for allelic exchange in Leptospira spp. By using the same methodology, the cloned recA of Leptospira biflexa was interrupted by a kanamycin resistance cassette, and the mutated allele was then introduced into the L. biflexa chromosome by homologous recombination. The recA double-crossover mutant showed poor growth in liquid media and was considerably more sensitive to DNA-damaging agents such as mitomycin C and UV light than the wild-type strain. The efficiency of plating of the recA mutant was about 10% of that of the parent strain. In addition, microscopic observation of the L. biflexa recA mutant showed cells that are more elongated than those of the wild-type strain. Fluorescent microscopy of stained cells of the L. biflexa wild-type strain revealed that chromosomal DNA is distributed throughout most of the length of the cell. In contrast, the recA mutant showed aberrant nucleoid morphologies, i.e., DNA is condensed at the midcell. Our data indicate that L. biflexa RecA plays a major role in ensuring cell viability via mechanisms such as DNA repair and, indirectly, active chromosome partitioning.     

Delayed nucleoid segregation in Escherichia coli

To study the role of cell division in the process of nucleoid segregation, we measured the DNA content of individual nucleoids in isogenic Escherichia coli cell division mutants by image cytometry. In pbpB(Ts) and ftsZ strains growing as filaments at 42 degrees C, nucleoids contained, on average, more than two chromosome equivalents compared with 1.6 in wild-type cells. Because similar results were obtained with a pbpB recA strain, the increased DNA content cannot be ascribed to the occurrence of chromosome dimers. From the determination of the amount of DNA per cell and per individual nucleoid after rifampicin inhibition, we estimated the C and D periods (duration of a round of replication and time between termination and cell division respectively), as well as the D' period (time between termination and nucleoid separation). Compared with the parent strain and in contrast to ftsQ, ftsA and ftsZ mutants, pbpB(Ts) cells growing at the permissive temperature (28 degrees C) showed a long D' period (42 min versus 18 min in the parent) indicative of an extended segregation time. The results indicate that a defective cell division protein such as PbpB not only affects the division process but also plays a role in the last stage of DNA segregation. We propose that PbpB is involved in the assembly of the divisome and that this structure enhances nucleoid segregation.     

Synthetic Lethal Phenotypes Caused by Mutations Affecting Chromosome Partitioning in Bacillus subtilis

We investigated the genetic interactions between mutations affecting chromosome structure and partitioning in Bacillus subtilis. Loss-of-function mutations in spoIIIE (encoding a putative DNA translocase) and smc (involved in chromosome structure and partitioning) caused a synthetic lethal phenotype. We constructed a conditional mutation in smc and found that many of the spoIIIE smc double-mutant cells had a chromosome bisected by a division septum. The growth defect of the double mutant was exacerbated by a null mutation in the chromosome partitioning gene spo0J. These results suggest that mutants defective in nucleoid structure are unable to move chromosomes out of the way of the invaginating septum and that SpoIIIE is involved in repositioning these bisected chromosomes during vegetative growth.     

Association of the histone-like protein HBsu with the nucleoid of Bacillus subtilis.

To investigate the physiological role of the essential histone-like protein of Bacillus subtilis (HBsu) in the nucleoid structure, a fusion to the green fluorescent protein (GFP) of Aequorea victoria was constructed. This purified fusion protein, HBsuGFP, showed a threefold-reduced affinity to DNA compared to unmodified HBsu; however, in gel mobility shift experiments HBsuGFP DNA-binding was greatly enhanced in the presence of low HBsu concentrations. Additional production of HBsu also had a positive effect on the retarded growth of a B. subtilis strain, PK9C8, which expresses only hbs-gfp (encoding HBsuGFP). HBsu seemed to influence not only growth but also nucleoid structure, as monitored by DNA staining and fluorescence microscopy. Without HBsu production, strain PK9C8 showed a relaxed nucleoid structure associated with HBsuGFP. However, a highly compact nucleoid structure that coincides with the fluorescence of the fusion protein was visualized when HBsu synthesis was induced. This provides the first evidence for in vivo association of HBsu in DNA packaging and its consequence on cell growth.     

DNA-dependent ATPases in Bacillus subtilis mutants and in competent cells

Three DNA-dependent ATPases (gamma phosphohydrolases) can be isolated from Bacillus subtilis cells. We studied these enzymes in a number of mutants deficient in recombination or repair functions (rec, uvr) and in competent cells. The recA mutant studied had lower ATPase II activity, while competent cells had higher ATPase I activity, in comparison with the parental strain not brought to competence.     

The recE(A)+ gene of B subtilis and its gene product: further characterization of this universal protein

Although the SOS system of E coli and the SOB system of B subtilis share many similarities, there are distinct differences with respect to the regulation and specificity of the phenomena that constitute these global regulons. One of these differences resides in the regulation of the respective RecA and RecA-like proteins. In B subtilis the RecA-like protein, the RecE protein, shares 60% amino acid homology with its E coli counterpart. The E coli recA gene can complement most, but not all, of the functions that are lost in strains of B subtilis that do not produce a functional RecE protein. The DNA sequence of the recE+ gene as well as the sequence of the recE4 allele and the recA73 allele of B subtilis has demonstrated that mutants of the recE and recA loci of this bacterium actually represent alleles of the same complex gene. Accordingly, the major recombination protein of B subtilis should be referred to as RecA and the gene that encodes this protein as recA+.     

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.     

The Mechanism of Reca Pola Lethality: Suppression by Reca-Independent Recombination Repair Activated by the Lexa(def) Mutation in Escherichia Coli

The mechanism of recA polA lethality in Escherichia coli has been studied. Complementation tests have indicated that both the 5' -> 3' exonuclease and the polymerization activities of DNA polymerase I are essential for viability in the absence of RecA protein, whereas the viability and DNA replication of DNA polymerase I-defective cells depend on the recombinase activity of RecA. An alkaline sucrose gradient sedimentation analysis has indicated that RecA has only a minor role in Okazaki fragment processing. Double-strand break repair is proposed for the major role of RecA in the absence of DNA polymerase I. The lexA(Def)::Tn5 mutation has previously been shown to suppress the temperature-sensitive growth of recA200(Ts) polA25::spc mutants. The lexA(Def) mutation can alleviate impaired DNA synthesis in the recA200(Ts) polA25::spc mutant cells at the restrictive temperature. recF(+) is essential for this suppression pathway. recJ and recQ mutations have minor but significant adverse effects on the suppression. The recA200(Ts) allele in the recA200(Ts) polA25::spc lexA(Def) mutant can be replaced by δrecA, indicating that the lexA(Def)-induced suppression is RecA independent. lexA(Def) reduces the sensitivity of δrecA polA25::spc cells to UV damage by ~10(4)-fold. lexA(Def) also restores P1 transduction proficiency to the δrecA polA25::spc mutant to a level that is 7.3% of the recA(+) wild type. These results suggest that lexA(Def) activates a RecA-independent, RecF-dependent recombination repair pathway that suppresses the defect in DNA replication in recA polA double mutants.     

Role of DNA repair by nonhomologous-end joining in Bacillus subtilis spore resistance to extreme dryness, mono- and polychromatic UV, and ionizing radiation

The role of DNA repair by nonhomologous-end joining (NHEJ) in spore resistance to UV, ionizing radiation, and ultrahigh vacuum was studied in wild-type and DNA repair mutants (recA, splB, ykoU, ykoV, and ykoU ykoV mutants) of Bacillus subtilis. NHEJ-defective spores with mutations in ykoU, ykoV, and ykoU ykoV were significantly more sensitive to UV, ionizing radiation, and ultrahigh vacuum than wild-type spores, indicating that NHEJ provides an important pathway during spore germination for repair of DNA double-strand breaks.     

A recA null mutation may be generated in Streptomyces coelicolor

The recombinase RecA plays a crucial role in homologous recombination and the SOS response in bacteria. Although recA mutants usually are defective in homologous recombination and grow poorly, they nevertheless can be isolated in almost all bacteria. Previously, considerable difficulties were experienced by several laboratories in generating recA null mutations in Streptomyces, and the only recA null mutants isolated (from Streptomyces lividans) appeared to be accompanied by a suppressing mutation. Using gene replacement mediated by Escherichia coli-Streptomyces conjugation, we generated recA null mutations in a series of Streptomyces coelicolor A3(2) strains. These recA mutants were very sensitive to mitomycin C but only moderately sensitive to UV irradiation, and the UV survival curves showed wide shoulders, reflecting the presence of a recA-independent repair pathway. The mutants segregated minute colonies with low viability during growth and produced more anucleate spores than the wild type. Some crosses between pairs of recA null mutants generated no detectable recombinants, showing for the first time that conjugal recombination in S. coelicolor is recA mediated, but other mutants retained the ability to undergo recombination. The nature of this novel recombination activity is unknown.     

Cell division in Escherichia coli minB mutants

In Escherichia coli minB mutants, cell division can take place at the cell poles as well as non-polarly in the cell. We have examined growth, division patterns, and nucleoid distribution in individual cells of a minC point mutant and a minB deletion mutant, and compared them to the corresponding wild-type strain and an intR1 strain in which the chromosome is over-replicated. The main findings were as follows. In the minB mutants, polar and non-polar divisions appeared to occur independently of each other. Furthermore, the timing of cell division in the cell cycle was found to be severely affected. In addition, nucleoid conformation and distribution were considerably disturbed. The results obtained call for a re-evaluation of the role of the MinB system in the E. coli cell cycle, and of the concept that limiting quanta of cell division factors are regularly produced during the cell cycle.     

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.     

The Bacillus subtilis SftA (YtpS) and SpoIIIE DNA translocases play distinct roles in growing cells to ensure faithful chromosome partitioning

In several bacterial species, the faithful completion of chromosome partitioning is known to be promoted by a conserved family of DNA translocases that includes Escherichia coli FtsK and Bacillus subtilis SpoIIIE. FtsK localizes at nascent division sites during every cell cycle and stimulates chromosome decatenation and the resolution of chromosome dimers formed by recA -dependent homologous recombination. In contrast, SpoIIIE localizes at sites where cells have divided and trapped chromosomal DNA in the membrane, which happens during spore development and under some conditions when DNA replication is perturbed. SpoIIIE completes chromosome segregation post-septationally by translocating trapped DNA across the membrane. Unlike E. coli , B. subtilis contains a second uncharacterized FtsK/SpoIIIE-like protein, SftA (formerly YtpS). We report that SftA plays a role similar to FtsK during each cell cycle but cannot substitute for SpoIIIE in rescuing trapped chromosomes. SftA colocalizes with FtsZ at nascent division sites but not with SpoIIIE at sites of chromosome trapping. SftA mutants divide over unsegregated chromosomes more frequently than wild-type unless recA is inactivated, suggesting that SftA, like FtsK, stimulates chromosome dimer resolution. Having two FtsK/SpoIIIE paralogues is not conserved among endospore-forming bacteria, but is highly conserved within several groups of soil- and plant-associated bacteria.     

Biocrystalline structures in the nucleoids of the stationary and dormant prokaryotic cells

Compaction and biocrystallization of the nucleoid are presently considered as a necessary and important stage in the transformation of the cell ultrastructure during change of microbial cultures strategies from growth to survival. Nucleoid biocrystallization in the stationary phase cells is achieved due to structural regularity of the DNA complexes with the histone-like Dps protein. Our experiments with Escherichia coli mutants, overproducers of the Dps protein, confirmed nucleoid biocrystallization in the late stationary phase cells. Since nucleoid biocrystallization was revealed in E. сoli cells without Dps overproduction at late stages of starvation, it is constitutive in the cycle of development of microbial populations. The present work concentrated on detection of the nucleoid biocrystalline structure in (1) long-starved (21 day in the chemostat mode) bacterial cells (genera Arthrobacter and Pseudomonas), (2) dormant ametabolic (anabiotic) cells of such prokaryotes as archaea and non-spore-forming bacteria, (3) endospores of bacilli, (4) streptomycete exospores, and (5) in the cells surviving in permafrost for (2?3 Ma). The topics discussed include nucleoid biocrystallization as a necessary stage of maturation of the dormant microbial cells providing for survival and preservation of the species, dynamics of nucleoid biocrystallization during maturation of the dormant cells, and its possible role for the preservation of genetic information in the case of autolysis of most of the cells in a developing culture.     

The ripX Locus of Bacillus subtilis Encodes a Site-Specific Recombinase Involved in Proper Chromosome Partitioning

The Bacillus subtilis ripX gene encodes a protein that has 37 and 44% identity with the XerC and XerD site-specific recombinases of Escherichia coli. XerC and XerD are hypothesized to act in concert at the dif site to resolve dimeric chromosomes formed by recombination during replication. Cultures of ripX mutants contained a subpopulation of unequal-size cells held together in long chains. The chains included anucleate cells and cells with aberrantly dense or diffuse nucleoids, indicating a chromosome partitioning failure. This result is consistent with RipX having a role in the resolution of chromosome dimers in B. subtilis. Spores contain a single uninitiated chromosome, and analysis of germinated, outgrowing spores showed that the placement of FtsZ rings and septa is affected in ripX strains by the first division after the initiation of germination. The introduction of a recA mutation into ripX strains resulted in only slight modifications of the ripX phenotype, suggesting that chromosome dimers can form in a RecA-independent manner in B. subtilis. In addition to RipX, the CodV protein of B. subtilis shows extensive similarity to XerC and XerD. The RipX and CodV proteins were shown to bind in vitro to DNA containing the E. coli dif site. Together they functioned efficiently in vitro to catalyze site-specific cleavage of an artificial Holliday junction containing a dif site. Inactivation of codV alone did not cause a discernible change in phenotype, and it is speculated that RipX can substitute for CodV in vivo.     

Cloning and expression of the Escherichia coli recA gene in Bacillus subtilis

By means of homopolymer dG-dC tailing, using PstI linearized pBR327 as vector, we constructed small plasmids containing the entire Escherichia coli recA gene. The 1.8-kb inserts were recloned in the Bacillus subtilis expression vector pPL608 in a B. subtilis recE4 strain. Analysis of plasmid-coded proteins showed expression of the E. coli recA gene both in minicells and whole cells of B. subtilis. Expression was under control of the bacteriophage SP02 promoter, which is part of pPL608. A recA-expressing plasmid completely abolished the transformation deficiency of the recE4 mutant as well as its sensitivity to mitomycin C (MC). The expressed recA gene also restored recombination in other B. subtilis strains lacking the recE gene product. These results indicate a high similarity between the functions of the E. coli RecA and B. subtilis RecE proteins.