Effect of nalidixic acid on sporulation of catabolite-resistant mutants ofBacillus subtilis

A number ofBacillus subtilis mutants that are able to sporulate in the presence of relatively high concentrations of carbon sources have been isolated in our laboratory. The present study shows that some of the mutants are also able to sporulate in the presence of nalidixic acid (Nal) under the condition where sporulation of wild-type strains is inhibited. Furthermore, it has been found that a Nal-resistant mutant is unable to sporulate normally when Nal (40 μg/ml) or glucose (55 mM) is present. Since the adverse effect of Nal on inducible enzymes is eliminated when bacterial strains carry a Nal-resistance marker, the above result suggests that the effect of this drug on sporulation might be mediated by a unique mechanism.     

Erythromycin resistant mutations in Bacillus subtilis cause temperature sensitive sporulation.

Summary All of several hundred erythromycin resistant (ery^R) single site mutants ofBacillus subtilis W168 are temperature sensitive for sporulation (spo^ts). The mutants and wild type cells grow vegetatively at essentially the same rates at both permissive (30° C) and nonpermissive (47° C) temperatures. In addition, cellular protein synthesis, cell mass increases and cell viabilities are similar in mutant and wild type strains for several hours after the end of vegetative growth (47° C). In the mutants examined, the temperature sensitive periods begin when the sporulation process is approximately 40% completed, and end when the process is 90% complete. At nonpermissive temperatures, the mutants produce serine and metal proteases at 50% of the wild type rate, accumulate serine esterase at 16% of the wild type rate, and do not demonstrate a sporulation related increase in alkaline phosphatase activity.The ery^R and spo^ts phenotypes cotransform 100%, and cotransduce 100% using phage PBS1. Revertants selected for ability to sporulate normally at 47° C (spo⁺), simultaneously regain parental sensitivity to erythromycin. No second site revertants are found.Ribosomes from ery^R spo^ts strains bind erythromycin at less than 1% of the wild type rate. A single 50S protein (L17) from mutant ribosomes shows an altered electrophoretic mobility. Ribosomes from spo⁺ revertants bind erythromycin like parental ribosomes and their proteins are electrophoretically identical to wild type. These data indicate that the L17 protein of the 50S ribosomal subunit fromBacillus subtilis may participate specifically in the sporulation process.     

A spectinomycin dependent mutant of Escherichia coli.

Summary A mutant of Escherichia coli B has been isolated which shows a novel phenotype of spectinomycin dependence. The mutant, termed RD, needs spectinomycin to grow at temperatures of 37° or below; it is unable to grow at 42° in either the presence or absence of spectinomycin. Secondary mutants which grow well in the absence of spectinomycin can be isolated spontaneously at a frequency of about 10^-6. Two-dimensional gel electrophoresis of ribosomal proteins from 25 of these revertants showed that two revertants had an alteration in S4; one other showed an alteration in L5, and one showed an apparent absence of L1. Mutant RD itself had an altered less basic S5, which was maintained in all the revertants that were checked.Genetic analysis indicated that RD was a double mutant: one mutation, which alone conferred a spectinomycin resistant phenotype on the strain, was located in the strA region of the E. coli chromosome and was represented by the mutation in S5. The other mutation, which conferred the dependence on spectinomycin, mapped close to the rif locus.     

Macrolide and aminoglycoside antibiotic resistance mutations in the Bacillus subtilis ribosome resulting in temperature-sensitive sporulation

Summary Mutants of Bacillus subtilis resistant to various macrolide antibiotics have been isolated and characterized with respect to their sporulation phenotype and the electrophoretic mobility of their ribosomal proteins (r-proteins). Two types of major alterations of r-protein L17, one probably due to a small deletion, are found among mutants exhibiting high-level macrolide resistance. These mutants are all temperature-sensitive for sporulation (Spo^ts). Low-level resistance to some macrolides is found to be associated with minor alterations in r-protein L17. These mutations do not cause a defective sporulation phenotype. All of the macrolide resistance mutations map at the same locus within the Str-Spc region of the B. subtilis chromosome. Hence, changes in a single ribosomal protein can result in different sporulation phenotypes.Mutants resistant to the aminoglycoside antibiotics neomycin and kanamycin have been isolated. Approximately 5% of these are Spo^ts. Representative mutations, neo 162 and kan25, cause concomitant drug resistance and sporulation temperature-sensitivity and map as single-site lesions in the Str-Spc region of the chromosome. Strains bearing neo162 or kan25 are equally cross-resistant to several aminoglycoside antibiotics but show no resistance to streptomycin or spectinomycin. These mutations define a new B. subtilis drug resistance locus at which mutation can cause defective sporulation.     

Isolation and Characterization of a Temperature-sensitive Sporulation Mutant of Bacillus subtilis

Temperature-sensitive sporulation mutants were isolated spontaneously from Bacillus subtilis 168 TT by a sequential transfer method. A representative mutant strain, ts32, was characterized in detail. The mutant grew normally at 30°C and 42°C, but did not sporulate at 42°C. Electron microscopic observation and physiological analysis showed that the mutant was blocked at stage 0-1 of sporulation. Genetic analysis suggested that the mutation was located at the spo0B locus on the B. subtilis chromosome. Temperature-shift experiments clearly showed that the spo0B gene product functions only at the beginning of sporulation.     

Conditional lethal mutants of Bacillus subtilis dependent on kasugamycin for growth

Summary Mutants of Bacillus subtilis dependent on the antibiotic kasugamycin have been isolated and characterised. The mutant phenotype was the result of a kasugamycin resistance mutation mapping near leu, together with a mutation conferring dependence which mapped elsewhere on the chromosome. In some cases, the latter mutation caused spectinomycin dependence in a spectinomycin resistant strain. Four mutants had detectable alterations in ribosomal proteins, which were not, however, responsible for the phenotype. These alterations were in proteins BS3, BS7, BS9, and BL15. Some mutants had defects in ribosomal subunit assembly, or altered cell morphology associated with the mutant phenotype.     

An easy method for screening and isolating rod mutants of<Emphasis Type="Italic"> Bacillus subtilis</Emphasis>

A convenient and rapid method for screening and identifying rod mutants of Bacillus subtilis is described. At the restrictive temperature (45 °C), all rod mutants of B. subtilis screened lost their ability to sporulate. The morphology and colour of mutant colonies grown on sporulation agar plates differed from those of rod⁺ cells, which were able to sporulate even at elevated temperature. These characteristics provide an alternative approach for the identification of rod mutants in B. subtilis culture by streaking the cells onto a minimal glucose agar plate and incubating at the restrictive temperature. After 30 h of incubation at this temperature, rod mutants are easily identified. This method will facilitate the screening and isolation of rod mutants of B. subtilis.     

Changes in regulation of ribosome synthesis during different stages of the life cycle of Saccharomyces cerevisiae.

Summary Diploid strains of Saccharomyces cerevisiae, each homozygous for one of the temperature sensitive mutations rna2, rna4, rna6 or rna8, are temperature sensitive for ribosome synthesis during vegetative growth, but are not inhibited for ribosomal synthesis at the restrictive temperature under sporulation conditions. The continued ribosome biosynthesis at the restrictive temperature (34° C) during sporulation includes de novo synthesis of both ribosomal RNA and ribosomal proteins. This lack of inhibition of ribosome biosynthesis is found even when cells committed to complete sporulation are returned to vegetative growth medium. The ribosomes synthesized at 34° C are apparently functional, as they are found in polyribosomes. Although the rna mutants do not regulate ribosome synthesis during sporulation, all of these diploid strains fail to complete sporulation at 34° C. The cells are arrested after the second meiotic nuclear division but before ascus formation. The failure to complete sporulation at the restrictive temperature and the inhibition of ribosome biosynthesis during growth are caused by the same mutation, because revertants selected for temperature independent growth were also able to sporulate at 34° C.     

Mutants of Schizosaccharomyces pombe which sporulate in the haploid state

Summary Suppressor mutants of mei1–102, a mutation in one of the mating type cassette genes (mat2-P) which blocks the progression into meiosis, were isolated and characterized in Schizosaccharomyces pombe. These suppressor mutations conferred either temperature-sensitivity or cold-sensitivity. The growth of these strains is halted and sporulation initiated at the restrictive temperatures, regardless of other conditions usually required for the initiation of meiosis i.e. they sporulate in the presence of a nitrogen source and mating type homozygosity. Their most striking feature is that they can sporulate from the haploid state. The haploidy of these mutants was confirmed by genetical analysis and by measurement of the DNA content of the cells. The mutants are all recessive and define a single gene pat1. The pat1 gene maps very close to the centromere of chromosome II. A meiosis defective mutation in mei5 can suppress the temperature-sensitivity caused by pat1, indicating some interaction between them. Spores produced from a haploid cell have poor viability and appear to contain only 1/2C DNA on average.     

Phenotypic reversion in some early blocked sporulation mutants of Bacillus subtilis. Genetic study of polymyxin resistant partial revertants

Summary A class of suppressor mutations restores, in pleiotropic sporulation mutants of B. subtilis (SPO mutants), the wild type level of resistance to Polymyxin, and, most often, other properties of the wild strain as well, but never the ability to sporulate. These suppressors, extracistronic, are active on mutations occurring in any one of the 5 genes in which SPO mutations have been found. The phenotype of the suppressed strains is dependent on both the suppressed (SPO) and the suppressive mutations. All these suppressors are located in a single locus and some of them are thermosensitive. The evidence suggests that a physiological compensation is at work in the partial revertants, so that the locus at which the suppressors are located was called cps X. Two hypotheses are discussed that might account for these observations.     

Properties of a Bacillus subtilis mutant able to sporulate continually during growth in synthetic medium

Several mutants of Bacillus subtilis were isolated which sporulate continually during exponential growth in glucose medium. The spdA1 mutation, responsible for the continual sporulation of one of the mutants, mapped near thr. When an exponentially growing culture of a strain containing spdA1 was maintained at essentially constant turbidity, 5% of the viable cells contained heat-resistant spores. The continual sporulation depended on the stringent response since it was absent in spdA relA double mutants. Genetic and biochemical analysis indicated that the continual sporulation of spdA1 strains was associated with a lower specific activity of pyruvate carboxylase, which limited the rate of oxaloacetate synthesis from glucose via pyruvate and thereby the supply of compounds depending on the citrate cycle, especially aspartate. Therefore, the mild stringent response caused by the spdA1 mutation seems to result from a partial deficiency of aspartyl-tRNA which may exert its sporulation-initiating effect during a limited time interval in each growth cycle. A mutant blocked in fumarase activity (citG) behaved similarly. It grew only slowly in glucose medium because much of the limiting oxaloacetate was wasted for the excretion of fumarate. The mutant produced little aspartate and sporulated at a high frequency in glucose medium, even in the presence of glutamate; the sporulation was again prevented by aspartate or malate or by introduction of the relA marker into the strain.     

Increase of translational fidelity blocks sporulation in the fungus Podospora anserina

Summary AS7-1 and AS7-2 are antisuppressor mutations reducing the miscoding capacity of ribosomes. Strains carrying and AS7 mutation do not sporulate. We have investigated whether the sporulation deficiency is due to the decrease of translational ambiguity. Two major findings argue in favour of this assumption. First, a significant sporulation level is restored in the presence of paromomycin. Second, three mutations which restore the sporulation of AS7-2 increase the ribosomal misreading in vitro. They define two new loci for ribosomal suppressors, su11 and su12. The two ribosomal proteins altered by su11-1 and su12-1 have been identified by electrophoresis. The results are discussed in the context of a more general hypothesis proposed by Picard-Bennoun (1982).     

Ribosomal Resistance to Streptomycin and Spectinomycin in Neisseria gonorrhoeae

A cell-free protein synthesizing system was used to study the mechanism of resistance to streptomycin (Str) and spectinomycin (Spc) in laboratory mutants and clinical isolates of Neisseria gonorrhoeae. The 70S ribosomes from sensitive strains were sensitive to the effects of Str and Spc on synthesis directed by several synthetic polynucleotide messengers, whereas 70S ribosomes from resistant strains were resistant to these same effects. In each case, the alteration was localized to the 30S ribosomal subunit by studying antibiotic sensitivities of hybrid 70S ribosomes formed by combining subunits from sensitive and resistant strains. No evidence was found for streptomycin- or spectinomycin-inactivating enzymes.     

Mating Type and Sporulation in Yeast I. Mutations Which Alter Mating-Type Control over Sporulation

In Saccharomyces cerevisiae, meiosis and spore formation as well as mating are controlled by mating-type genes. Diploids heterozygous for mating type (aα) can sporulate but cannot mate; homozygous aa and αα diploids can mate, but cannot sporulate. From an αα diploid parental strain, we have isolated mutants which have gained the ability to sporulate. Those mutants which continue to mate as αα cells have been designated CSP (control of sporulation). Upon sporulation, CSP mutants yield asci containing 4α spores. The mutant gene which allows αα cells to sporulate is unlinked to the mating-type locus and also acts to permit sporulation in aa diploid cells. Segregation data from crosses between mutant αα and wild-type aa diploids and vice versa indicate (for all but one mutant) that the mutation which allows constitutive sporulation (CSP) is dominant over the wild-type allele. Some of the CSP mutants are temperature-sensitive, sporulating at 32°, but not at 23°. In addition to CSP mutants, our mutagenesis and screening procedure led to the isolation of mutants which sporulate by virtue of a change in the mating-type locus itself, resulting in loss of ability to mate.     

Cyclic nucleotides and development ofMyxococcus xanthus: Analysis of mutants

Approximately 60 developmental mutants ofMyxococcus xanthus M300 were obtained through nitrosoguanidine mutagenesis and placed into three operationally defined categories. Type-I strains exhibited no aggregation or sporulation. Type-II strains were able to aggregate but did not sporulate. A strain classed as a type-III strain was a low-capacity fruiter. Each category displayed defects in cyclic nucleotide behavior that could be predicted from the current model. Most significantly, several aggregationless (type I) mutants lacking cGMP phosphodiesterase aggregated in the presence of externally applied phosphodiesterase. A requirement for cell-cell contact in sporulation has been confirmed. Evidence is presented that suggests the involvement of cAMP phosphodiesterase in sporulation and that sporulation may be a developmental pathway independent of aggregation. These results support a previously published hypothesis of the role of cyclic nucleotides in the development ofM. xanthus.     

Mannitol is required for asexual sporulation in the wheat pathogen Stagonospora nodorum (glume blotch)

The physiological role of the mannitol cycle in the wheat pathogen Stagonospora nodorum (glume blotch) has been investigated by reverse genetics and metabolite profiling. A putative mannitol 2-dehydrogenase gene (Mdh1) was cloned by degenerate PCR and disrupted. The resulting mutated mdh1 strains lacked all detectable NADPH-dependent mannitol dehydrogenase activity. The mdh1 strains were unaffected for mannitol production but, surprisingly, were still able to utilize mannitol as a sole carbon source, suggesting a hitherto unknown mechanism for mannitol catabolism. The mutant strains were not compromised in their ability to cause disease or sporulate. To further our understanding of mannitol metabolism, a previously developed mannitol-1-phosphate dehydrogenase (gene mpd1) disruption construct [Solomon, Tan and Oliver (2005) Mol. Plant-Microbe Interact. 18, 110-115] was introduced into the mutated mdh1 background, resulting in a strain lacking both enzyme activities. The mpd1mdh1 strains were unable to grow on mannitol and produced only trace levels of mannitol. The double-mutant strains were unable to sporulate in vitro when grown on minimal medium for extended periods. Deficiency in sporulation was correlated with the depletion of intracellular mannitol pools. Significantly sporulation could be restored with the addition of mannitol. Pathogenicity of the double mutant was not compromised, although, like the previously characterized mpd1 mutants, the strains were unable to sporulate in planta. These findings not only question the currently hypothesized pathways of mannitol metabolism, but also identify for the first time that mannitol is required for sporulation of a filamentous fungus.     

Sporulation of auxotrophic mutants ofBacillus subtilis in suboptimal concentrations of essential amino acids

The effect of the amino acid concentration on sporulation of five mutants ofBacillus subtilis requiring histidine, isoleucine, leucine, lysine and methionine for growth was studied. Low amino acid concentrations, permitting about 10–20% of maximum growth, inhibit the ability of the bacteria to sporulate on completing vegetative growth. In medium concentrations (from 25% of maximum growth), leucine, isoleucine, histidine and methionine induce sporulation, while the concentration of the other nutrients in the medium is still adequate for further vegetative growth. The percentage of sporulation depends on the amino acid concentration and is characteristic for each amino acid. The lysine mutant strain 1399 was not capable of sporulation unless cultivated in the presence of the lysine concentration optimal for growth. The effect of amino acid deficiency depends on the cultivation method.     

Catabolite repression-resistant mutants of Bacillus subtilis.

Mutants of Bacillus subtilis that are able to sporulate under the condition of catabolite repression were isolated by a simple selection technique. The mutants used in the present study were able to grow normally on minimal medium with ammonium sulphate as the nitrogen source and glucose as the carbon source. Studies carried out with these mutants show that there is no close relation between catabolite repression of an inducible enzyme, acetoin dehydrogenase, and that of sporulation. Certain mutants are able to sporulate in the presence of all the carbon sources tested but some mutants are resistant only to the carbon source used in isolation. It is suggested that several metabolic steps may be affected in catabolite repression of sporulation.     

A Suppressor of Mating-Type Locus Mutations in SACCHAROMYCES CEREVISIAE: Evidence for and Identification of Cryptic Mating-Type Loci

A mutation has been identified that suppresses the mating and sporulation defects of all mutations in the mating-type loci of S. cerevisiae. This suppressor, sir1-1, restores mating ability to mat alpha 1 and mat alpha 2 mutants and restores sporulation ability to mat alpha 2 and mata1 mutants. MATa sir1-1 strains exhibit a polar budding pattern and have reduced sensitivity to alpha-factor, both properties of a/alpha diploids. Furthermore, sir1-1 allows MATa/MATa, mat alpha 1/mat alpha/, and MAT alpha/MAT alpha strains to sporulate efficiently. All actions of sir1-1 are recessive to SIR1. The ability of sir1-1 to supply all functions necessary for mating and sporulation and its effects in a cells are explained by proposing that sir1-1 allows expression of mating type loci which are ordinarily not expressed. The ability of sir1-1 to suppress the mat alpha 1-5 mutation is dependent on the HMa gene, previously identified as required for switching of mating types from a to alpha. Thus, as predicted by the cassette model, HMa is functionally equivalent to MAT alpha since it supplies functions of MAT alpha. We propose that sir1-1 is defective in a function. Sir ("Silent-information regulator"), whose role may be to regulate expression of HMa and HM alpha.     

Analysis of Tn916-induced mutants ofClostridium acetobutylicum altered in solventogenesis and sporulation

Summary The conjugative transposon Tn916 was used for mutagenesis ofClostridium acetobutylicum ATCC 824. Tetracycline-resistant mutants were screened for loss of granulose synthesis and five classes of granulose mutants, that contained single transposon insertions, were identified on the basis of altered solvent production. Class 1 mutants did not make acetone or butanol, lacked activity of enzymes induced during solventogenesis, and did not sporulate, indicating that they are regulatory mutants. The class 2 mutant strains also did not produce acetone but did form small amounts of butanol and ethanol while the class 3 mutants produced low amounts of all solvents. Class 4 and 5 mutants produced essentially the same or higher amounts of solvents than the parent strain. Transposon insertions in the class 1 mutants were used as markers for in vitro synthesis of flanking chromosomal DNA using Tn916-specific primers. The DNA fragments were labeled to produce specific probes. Transposon insertion sites in the chromosomes of 13 different class 1 regulatory mutants were compared by hybridization of the specific probes to Southern blots of restriction endonuclease-digested parental chromosomal DNA. Insertions in two mutants appeared to be, in the same region of the chromosome. These results predict, that multiple regulatory elements are required to induce solvent production and sporulation.