Genetic and chemical studies of ribosomes from spectinomycin resistant mutants of Bacillus subtilis

Summary Spectinomycin resistant mutants were isolated fromBacillus subtilis ATCC 6633. Some of these mutants had an altered specific 30s ribosomal protein on CMC chromatography, the site of alteration residing in a different tryptic peptide fragment from one mutant to another on Dowex 50×8 chromatography.This work was supported by a grant from the Mitsubishi Foundation and grants from the Ministry of Education of Japan.     

Altered sporulation and respiratory patterns in mutants of Bacillus subtilis induced by acridine orange

Bott, K. F. (The University of Chicago, Chicago, Ill.), and R. Davidoff-Abelson. Altered sporulation and respiratory patterns in mutants of Bacillus subtilis induced by acridine orange. J. Bacteriol. 92:229-240. 1966.-The addition of acridine orange to vegetative cultures of Bacillus subtilis induces the formation of sporulation mutants at a frequency of 20% or greater. These mutants are grouped into seven categories which reflect their different morphological properties. They are altered in their vegetative metabolism, as indicated by abnormal growth on synthetic media. Sporulation of these mutants is impaired at several levels, all of which are stable upon repeated subculturing. The initial stages of sporulation which require no increased metabolic activity (proteolytic enzyme activity and antibiotic production) are functional in all strains, but glucose dehydrogenase activity, an enzyme associated with early synthetic functions in spore synthesis, is significantly reduced. Reduced nicotinamide adenine dinucleotide oxidase is slightly depressed. It is suggested that acridine orange interacts with a cellular constituent controlling respiration and consequently prevents an increased metabolic activity that may be associated with normal spore synthesis.     

Biofilm-defective mutants of Bacillus subtilis

Many bacteria can adopt organized, sessile, communal lifestyles. The gram-positive bacterium, Bacillus subtilis,forms biofilms on solid surfaces and at air-liquid interfaces, and biofilm development is dependent on environmental conditions. We demonstrate that biofilm formation by B. subtilis strain JH642 can be either activated or repressed by glucose, depending on the growth medium used, and that these glucose effects are at least in part mediated by the catabolite control protein, CcpA. Starting with a chromosomal Tn917-LTV3 insertional library, we isolated mutants that are defective for biofilm formation. The biofilm defects of these mutants were observable in both rich and minimal media, and both on polyvinylchloride abiotic surfaces and in borosilicate tubes. Two mutants were defective in flagellar synthesis. Chemotaxis was shown to be less important for biofilm formation than was flagellar-driven motility. Although motility is known to be required for biofilm formation in other bacteria, this had not previously been demonstrated for B. subtilis. In addition, our study suggests roles for glutamate synthase, GltAB, and an aminopeptidase, AmpS. The loss of these enzymes did not decrease growth or cellular motility but had dramatic effects on biofilm formation under all conditions assayed. The effect of the gltAB defect on biofilm formation could not be due to a decrease in poly-gamma-glutamate synthesis since this polymer proved to be nonessential for robust biofilm formation. High exogenous concentrations of glutamate, aspartate, glutamine or proline did not override the glutamate synthase requirement. This is the first report showing that glutamate synthase and a cytoplasmic aminopeptidase play roles in bacterial biofilm formation. Possible mechanistic implications and potential roles of biofilm formation in other developmental processes are discussed.     

Deoxyribonucleoside-requiring mutants of Bacillus subtilis.

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

Erythromycin resistant mutants of Bacillus subtilis

Summary Erythromycin resistant (ery ^r) mutants were isolated from Bacillus subtilis ATCC 6633. The composition of ribosomal proteins were analyzed for thirteen such ery ^r-mutants with chromatography on a carboxymethyl cellulose (CMC) column. The 50s subunit from all of the ery ^r-mutants was found to contain the altered 50d protein. The ribosomes prepared from the ery ^r-mutants did not show in vitro alteration of the ability to combine with erythromycin.     

5-Bromouracil-tolerant mutants of Bacillus subtilis

5-Bromouracil (BU)-tolerant mutants of Bacillus subtilis 23 (thy his) have been isolated. Several classes of tolerant mutants were obtained by a sequential selection procedure. The classes can be distinguished by their relative BU tolerance as well as several other phenotypic characteristics. The mutants can grow for an extended period of time in minimal medium supplemented with amino acids and BU, in which the sensitive parental strain (Bu(+)) undergoes rapid cell death. Both mutants But-1 and But-1310 have a greater rate of deoxyribonucleic acid (DNA) synthesis by a factor of two in the presence of BU than Bu(+), But-1 being somewhat faster than But-1310. The preferential incorporation of thymine to BU of But-1 is about half that of the Bu(+) strain during DNA replication in minimal medium supplemented with 10 mug of BU/ml and 1 mug of thymine/ml. It is not known at what step or steps this reduction in selectivity occurs.     

Recombination-deficient mutants of Bacillus subtilis.

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

Kasugamycin-resistant mutants of Bacillus subtilis.

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

Electron-dense particles resembling ribosomes in mesosomes of Bacillus subtilis

Thin-sectioning of Bacillus subtilis ATCC 6633 protoplasts and cells has revealed electron-dense particles resembling cytoplasmic ribosomes in mesosomal tubules and vesicles.     

Chloramphenicol resistant mutants of Bacillus subtilis

Summary Telve chloramphenicol resistant (CM ^r)-mutants were isolated from B. subtilis ATCC 6633 and were classified into the following six groups. Group I. No 50s ribosomal protein change was detectable. Ribosomes did not show alteration of the binding ability to CM or to erythromycin in vitro. Group II. A 50s protein, 50a, was altered. Ribosomes did not show alteration of the binding ability to CM or to erythromycin in vitro. The genes specifying the 50a protein was in the cysA-str region on B. subtilis chromosome. Group III. A 50s protein, 50b, was altered. Biological properties of the ribosomes were the same as Group I or II so fas as examined. The genes for 50b protein was in the cysA-str region. Group IV. A 50s protein, 50c, was altered. Ribosomes showed a definite decrease in ability to bind to CM in vitro. The binding of erythromycin to the ribosomes was not impaired. The chromosomal locus of the CM ^r (and for 50c protein) was in the cysA-str region. Group V. A 50s protein, 50e, was changed. The ability of the ribosomes to bind in vitro both to CM and to erythromycin was greatly reduced. The genetic locus of the CM ^r (and for 50e protein) was in the cysA-str region. Group VI. A 50s protein, 50f, was altered. Ribosomes showed a decrease in ability to bind in vitro both to CM and to erythromycin. The genes for 50f protein was in the cysA-str region.The results suggest that the ribosomal resistance to CM may be caused by an independent change of at least several 50s ribosomal protein species. The genetic data shown here and those reported previously show that at least two 30s and seven 50s ribosomal protein genes are situated in the cysA-str region on B. subtilis chromosome.     

Glutamine-requiring mutants of Bacillus subtilis.

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

Competence proteins in Bacillus subtilis com mutants

The synthesis of nucleases and proteins specific for competence development have been studied in four different Bacillus subtilis competence-deficient mutants. The nuclease analysis showed that two DNA-binding-deficient mutants were impaired in three nuclease activities involved in binding and entry of donor DNA. The other two strains did not show any reduction in nuclease activities. Two-dimensional gel electrophoresis of the proteins, synthesized during competence development, revealed that all four mutants are lacking several competence-specific polypeptides. Our data show that these com mutations have a strong pleiotropic effect, which could be due to a block in the metabolic pathway leading to competence development.     

Plasmid maintenance in Bacillus subtilis recombination-deficient mutants

Summary An isogenic set of 11 recombination-deficient mutant strains of Bacillus subtilis has been constructed. Whereas plasmid pUB110 is stably maintained in such Rec^- cells, the high copy number plasmid pC194 is unstable. Instability in Rec^- strains could be mostly attributed to the deleterious effect of the presence of the plasmid on the Rec^- cells' growth capability. In part, instability of pC194 derivatives could also be correlated with the presence of an unusually high amount of multimeric DNA molecules.     

Characterization of recombination-deficient mutants of Bacillus subtilis

An isogenic set of "prophage-free," DNA repair-proficient and -deficient strains of Bacillus subtilis were characterized phenotypically. The mutant strains were provisionally classified into four categories on the basis of their sensitivity to DNA-damaging agents, their ability to release phage after lysogenization followed by damage to chromosomal DNA, and their impairment in genetic exchange. The properties of double Rec- mutants showed that recF and addA belong to different epistatic groups, whereas recF, recL, and recH fall into the same group. More than one pathway for genetic exchange might be operative in B. subtilis.     

Mapping of rod mutants of Bacillus subtilis

Nine class A salt-dependent rod mutants were mapped on the Bacillus subtilis genome by PBS1-mediated transduction. They are distributed into two small linkage groups designated rod B and rod C; mutations in rod B are over 80% cotransducible with pheA and different mutations in rod C are 12 to 21% cotransducible with hisA. It is established that neither rod B nor rod C is linked by transformation to the other identified rod mutations present in 168-ts-200B and 8332 glu(-). It is hypothesized that salt-dependent mutations are due to enzyme alterations which are corrected by high salt concentrations.     

Properties of regeneration mutants of Bacillus subtilis

Abstract Higher regeneration mutants were isolated from Bacillus subtilis . Protoplasts from two out of four mutants regenerated at a 100% frequency on a semi-synthetic hypertonic medium. They conferred less autolytic productivity, and a revertant regained the parental levels of regeneration frequency and autolytic activities. This mutation ( rgn -1) expressed the other pleiotropic properties, i.e., nonmotility, phage PBS1 resistance and different cell morphology.