Abortive Infection of Sporulating Bacillus subtilis 168 by φ2 Bacteriophage

Bacteriophage phi2 is unable to replicate in Bacillus subtilis 168. Although some phage deoxyribonucleic acid (DNA) synthesis can occur, the DNA made is not biologically active and sedimentation analysis reveals that it is smaller in size than that of mature DNA or DNA isolated from phi2-infected permissive hosts. Messenger ribonucleic acid hybridizable with phi2 DNA is also synthesized in phi2-infected cells of 168. Mutants of 168 which are permissive hosts for phi2 have been isolated. These mutants are defective in sporulation and possess the phenotype of "early sporulation mutants." The majority map in two locations, one near the lys locus opposite the trp locus (spoA locus) and the other tightly linked to a phe locus.     

Functional expression of two Bacillus subtilis chromosomal genes in Escherichia coli.

EcoRI-cleaved deoxyribonucleic acid segments carrying two genes from Bacillus subtilis, pyr and leu, have been cloned in Escherichia coli by insertion into a derivative of the E. coli bacteriophage lambda. Lysogenization of pyrimidine- and leucine-requiring auxotrophs of E. coli by the hybrid phages exhibited prototrophic phenotypes, suggesting the expression of B. subtilis genes in E. coli. Upon induction, these lysogens produced lysates capable of transducing E. coli pyr and leu auxotrophs to prototrophy with high frequency. Isolated DNAs of these bacteriophages have the ability to transform B. subtilis auxotrophs to pyr and leu independence and contain EcoRI-cleaved segments which hybridize to corresponding segments of B. subtilis.     

Cloning the gyrA gene of Bacillus subtilis.

We have isolated an eight kilobase fragment of Bacillus subtilis DNA by specific integration and excision of a plasmid containing a sequence adjacent to ribosomal operon rrn O. The genetic locus of the cloned fragment was verified by linkage of the integrated vector to nearby genetic markers using both transduction and transformation. Functional gyrA activity encoded by this fragment complements E. coli gyrA mutants. Recombination between the Bacillus sequences and the E. coli chromosome did not occur. The Bacillus wild type gyrA gene, which confers sensitivity to nalidixic acid, is dominant in E. coli as is the E. coli gene. The cloned DNA precisely defines the physical location of the gyrA mutation on the B. subtilis chromosome. Since an analogous fragment from a nalidixic acid resistant strain has also been isolated, and shown to transform B. subtilis to nalidixic acid resistance, both alleles have been cloned.     

Organization of transfer and ribosomal ribonucleic acid genes in Bacillus subtilis.

The structural relationship between the transfer ribonucleic acid (tRNA) and the ribosomal RNA (rRNA) genes of Bacillus subtilis has been studied by restriction endonuclease analysis of total chromosomal deoxyribonucleic acid (DNA) and characterization of DNA fragments cloned in Escherichia coli. The DNA sequences encoding rRNA and tRNA were assayed by hybridization to radioactive RNA. The results support the conclusion that the tRNA genes are interspersed between and closely linked to the rRNA genes of B. subtilis. They probably do not appear between the 16S and 23S rRNA genes as in E. coli.     

Pleiotropic, extragenic suppression of dna mutants in Bacillus subtilis.

Thermosensitive (dna) mutants of Bacillus subtilis defective in deoxyribonucleic acid replication can be divided into two groups on the basis of their ability to spontaneously yield secondary mutants with an HDS phenotype (thermoin-sensitivity and resistance to aryl-azo-pyrimidines) at frequencies higher than 10(-8). Such a phenotype is due to alleles at the hds locus (mapping close to cysA), which act as extragenic pleiotropic suppressors. HDS suppressibility has been used as a screening tool to identify new dna strains among uncharacterized temperature-sensitive mutants.     

Bacillus subtilis deoxyribonuclease activity specific for single-stranded deoxyribonucleic acid: cellular site and variations during germination and sporulation

The endonuclease of Bacillus subtilis specific for single-stranded deoxyribonucleic acid is absent in spores, appears during germination only after the start of deoxyribonucleic acid synthesis, and is located almost exclusively in the periplasm.     

Isolation of Bacillus subtilis genes from a charon 4A library.

A library of Bacillus subtilis chromosomal deoxyribonucleic acid (DNA) was constructed, using lambda charon 4A as a cloning vector. Partially cleaved Bacillus subtilis DNA was prepared by partial methylation with EcoRI methylase, followed by complete EcoRI endonuclease digestion. More than 95% of the phage particles carried B. subtilis DNA inserts. When this library was screened for transforming activity, using competent cells, 70% of the genetic markers tested were found in a sample of 1,710 plaques. Cloned genetic loci were found to be about 100-fold more efficient in transforming activity than chromosomal DNA. Intact phage particles containing the pheA locus were found to be able to transform competent recipients with approximately the same efficiency as phage DNA. Transformation by intact particles was insensitive to deoxyribonuclease.     

Insertional Inactivation of trpC in Cloned Bacillus trp Segments: Evidence for a Polar Effect on trpF

Plasmid pUB110 was previously used as a vector to clone fragments of deoxyribonucleic acid that complement the trpC2 mutation in Bacillus subtilis from endonuclease EcoRI digested B. licheniformis, B. pumilus, and B. subtilis cellular deoxyribonucleic acid. Each of several such trp plasmids was subsequently shown to contain a segment of the trp gene cluster on the basis of genetic complementing activity. In the present study, analysis of the Trp enzyme levels in B. subtilis harboring the constructed trp plasmids confirms the genetic constitution of the plasmids. Thus, plasmids that complement mutations in specific trp genes specify the corresponding enzyme activities. The levels of the plasmid-specified Trp enzymes in B. subtilis were generally above the repressed level of the chromosomally specified Trp enzymes and equal to or below the derepressed levels of the chromosomally specified Trp enzymes. Certain cloned trp segments contain a single HindIII-sensitive site. Insertion of HindIII-generated deoxyribonucleic acid fragments into these trp plasmids resulted in inactivation of trpC complementing activity, loss of the trpC-specified enzyme activity, and a 10-fold reduction in the specific activity of the plasmid-specified trpF product. The HindIII insertions had no detectable effect on the level of the trpD product, nor did the insertions detectably alter plasmid-specified complementing activity other than to abolish trpC complementation. Removal of the HindIII insertions was accompanied by recovery of trpC complementing activity and restoration of the trpC-and trpF-determined enzymes to the levels specified by the parent plasmids.     

Bacillus subtilis RNase III gene: cloning, function of the gene in Escherichia coli, and construction of Bacillus subtilis strains with altered rnc loci.

The rnc gene of Bacillus subtilis, which has 36% amino acid identity with the gene that encodes Escherichia coli RNase III endonuclease, was cloned in E. coli and shown by functional assays to encode B. subtilis RNase III (Bs-RNase III). The cloned B. subtilis rnc gene could complement an E. coli rnc strain that is deficient in rRNA processing, suggesting that Bs-RNase III is involved in rRNA processing in B. subtilis. Attempts to construct a B. subtilis rnc null mutant were unsuccessful, but a strain was constructed in which only a carboxy-terminal truncated version of Bs-RNase III was expressed. The truncated Bs-RNase III showed virtually no activity in vitro but was active in vivo. Analysis of expression of a copy of the rnc gene integrated at the amy locus and transcribed from a p(spac) promoter suggested that expression of the B. subtilis rnc is under regulatory control.     

Nuclear Fraction of Bacillus subtilis as a Template for Ribonucleic Acid Synthesis

A "nuclear fraction" prepared from Bacillus subtilis was a more efficient template than purified deoxyribonucleic acid for the synthesis of ribonucleic acid by exogenously added ribonucleic acid polymerase isolated from B. subtilis. The initial rate of synthesis with the nuclear fraction was higher and synthesis continued for several hours, yielding an amount of ribonucleic acid greater than the amount of deoxyribonucleic acid used as the template. The product was heterogenous in size, with a large portion exceeding 23S. When purified deoxyribonucleic acid was the template, a more limited synthesis was observed with a predominantly 7S product. However, the ribonucleic acids produced in vitro from these templates were very similar to each other and to in vivo synthesized ribonucleic acid as determined by the competition of ribonucleic acid from whole cells in the annealing of in vitro synthesized ribonucleic acids to deoxyribonucleic acid. Treatment of the nuclear fraction with heat (60 C for 15 min) or trypsin reduced the capacity of the nuclear fraction to synthesize ribonucleic acid to the level observed with purified deoxyribonucleic acid.     

Cloning and characterization of a Bacillus subtilis gene encoding a homolog of the 54-kilodalton subunit of mammalian signal recognition particle and Escherichia coli Ffh.

By using a DNA fragment of Escherichia coli ffh as a probe, the Bacillus subtilis ffh gene was cloned. The complete nucleotide sequence of the cloned DNA revealed that it contained three open reading frames (ORFs). Their order in the region, given by the gene product, was suggested to be ORF1-Ffh-S16, according to their similarity to the gene products of E. coli, although ORF1 exhibited no significant identity with any other known proteins. The orf1 and ffh genes are organized into an operon. Genetic mapping of the ffh locus showed that the B. subtilis ffh gene is located near the pyr locus on the chromosome. The gene product of B. subtilis ffh shared 53.9 and 32.6% amino acid identity with E. coli Ffh and the canine 54-kDa subunit of signal recognition particle, respectively. Although there was low amino acid identity with the 54-kDa subunit of mammalian signal recognition particle, three GTP-binding motifs in the NH2-terminal half and amphipathic helical cores in the COOH-terminus were conserved. The depletion of ffh in B. subtilis led to growth arrest and drastic morphological changes. Furthermore, the translocation of beta-lactamase and alpha-amylase under the depleted condition was also defective.     

Incorporation of Uridine into Bacillus subtilis and SPP1 Bacteriophage Deoxyribonucleic Acid

Tritiated uridine is incorporated into the deoxyribonucleic acid of Bacillus subtilis and bacteriophage SPP1; the tritium is recovered in the cytidine moiety of both deoxyribonucleic acids.     

Chromosomal location of genes regulating resistance to bacteriophage in Bacillus subtilis

Many of the viruses which infect Bacillus subtilis require glucosylated polyglycerol teichoic acid for adsorption. These mutants can be divided into three classes on the basis of enzymatic defects and growth on galactose-minimal medium. Transduction with phage PBS1 reveals that two of these, gtaA and gtaB, are linked to hisA1, whereas the gtaC locus is linked to argC. Analysis by deoxyribonucleic acid-mediated transformation indicates that these loci exist in a cluster between the hisA1 and argC4 loci. Anomalies in mapping in the group II region of the chromosome exist. The basis of these anomalies is discussed.     

Cloning of an early sporulation gene in Bacillus subtilis.

A 0.8-megadalton BglII restriction fragment of Bacillus licheniformis cloned into the BglII site of plasmid pBD64 can complement spo0H mutations of Bacillus subtilis. The clone was isolated by selecting for the Spo+ phenotype and antibiotic resistance, using the helper system described by Gryczan et al. (Mol. Gen. Genet. 177:459-467, 1980). The insert is functional in both orientations and thus presumably has its own promoter. A deletion generated within the 0.8-megadalton insert by HindIII restriction and subsequent religation eliminates the ability of the cloned fragment to complement spo0H mutations. The cloned B. licheniformis deoxyribonucleic acid segment specifies the synthesis, in minicells, of a polypeptide of approximately 27,000 daltons. This protein is observed with both orientations, but not when the HindIII deletion is present in the cloned B. licheniformis chromosomal fragment. We have also demonstrated that ribonucleic acid complementary to the cloned B. licheniformis sporulation gene is transcribed in B. licheniformis both during vegetative growth and sporulation.     

Relationship Between Transformation in Bacillus subtilis and Infection by Bacteriophage SP02

When bacteriophage SP02 infects a Bacillus subtilis culture during or shortly after transformation, the frequency of transformants among the resulting lysogens is greatly reduced relative to that in the uninfected culture. The effect can occur after the deoxyribonucleic acid has been taken up and covalently attached to recipient deoxyribonucleic acid.     

Involvement of deoxyribonucleic acid polymerase III in W-reactivation in Bacillus subtilis

6-(p-Hydroxyphenylazo)-uracil, a purine analog that is known to specifically inhibit deoxyribonucleic acid polymerase III in gram-positive organisms, inhibited W-reactivation in Bacillus subtilis. On the other hand, W-reactivation proceeded normally in the presence of 6-(p-hydroxyphenylazo)-uracil when a strain possessing a resistant deoxyribonucleic acid polymerase III was used as the host.     

Cell division of cycle of Bacillus subtilis: evidence of variability in period D

In Bacillus subtilis the deoxyribonucleic acid content and the extent of cell division during inhibition of chromosome replication increased as a function of the average cell mass, independent of the growth rate. At each growth rate, mass, deoxyribonucleic acid, and residual division varied in different cultures. The variation is consistent with a large variability in the D period. At growth rates higher than 1.5 doublings per h at 37 degrees C, the change in D accounts for the growth rate dependence of the mass and deoxyribonucleic acid content.     

Transport of Donor Deoxyribonucleic Acid into the Cell Interior of Thymine-starved Bacillus subtilis with Chromosomes Arrested at the Terminus

The chromosomes of a tryptophan(-), thymine(-) double auxotroph of Bacillus subtilis were uniformly aligned at the chromosome terminus by an amino acid starvation treatment. By subsequent incubations, the starved culture was rendered competent, while its state of synchronous chromosome arrest was maintained by thymine starvation. The competent, chromosome-arrested cells were transformed for three unlinked markers, located in two different chromosome regions. Shortly after addition of deoxyribonucleic acid, the cell walls were removed with lysozyme in a medium containing deoxyribonuclease and no thymine, and the protoplasted culture was assayed for single and double transformants. It was found that markers both near and distant from the terminus entered freely into the cell interior. There was no important difference in the relative frequency of entry of different markers between synchronously arrested cells and nonsynchronized control cultures. It is concluded that entry of a given marker into the cell interior can occur even if the replication site of the chromosome is stationary at a location distant from the locus of the resident homolog of the entering marker. A mechanism of donor deoxyribonucleic acid entry involving homology at the replication fork is excluded.     

Absence in Bacillus subtilis and Staphylococcus aureus of the sequence-specific deoxyribonucleic acid methylation that is conferred in Escherichia coli K-12 by the dam and dcm enzymes

Restriction analysis of plasmid pHV14 deoxyribonucleic acid isolated from Escherichia coli K-12, Bacillus subtilis, and staphylococcus aureus with restriction endonucleases MboI, Sau3AI, and EcoRII was used to study the methylation of those nucleotide sequences which in E. coli contain the major portions of N6-methyladenine and 5-methylcytosine. The results showed that neither B. subtilis nor S. aureus methylates deoxyribonucleic acid at the same sites and nucleotides which are recognized and methylated by dam and dcm enzymes in E. coli K-12.