Involvement of a transmissible plasmid in heat-stable exotoxin and delta-endotoxin production inBacillus thuringiensis subspeciesdarmstadiensis

A strain ofBacillus thuringiensis subsp.darmstadiensis (serotype 10), which produces heat-stable exotoxin and delta-endotoxin (Exo⁺Cry⁺), was used for curing and conjugation-like transformation experiments. After treatment with sodium dodecyl sulfate, nine independent mutants that lacked exotoxin productivity (Exo^–) were obtained. Agarose gel electrophoresis showed that all Exo^– strains had lost a plasmid, whose size was 62 megadaltons (Mdal). WhenB. thuringiensis was mated with a streptomycin-resistant (Str^r)B. cereus strain, five Exo⁺Str^r transformants that had acquired the 62-Mdal plasmid were isolated. Furthermore, the Cry⁺ phenotype was consistently associated with the Exo⁺ phenotype. These results indicate that a transmissible plasmid is involved in production of both heat-stable exotoxin and delta-endotoxin.     

Stimulation of recombination between homologous sequences on carcinogen-treated plasmid DNA and chromosomal DNA by induction of the SOS response in Escherichia coli K12

Summary Previous studies have shown that transformation of Escherichia coli by plasmid DNA modified in vitro by carcinogens leads to RecA-dependant recombination between homologous plasmid and chromosomal DNA sequences. The mechanism of this recombination has now been studied using recombination-deficient mutants, and the influence of induction of the SOS response on the level of recombination investigated. Plasmid pNO1523, containing the str ⁺ operon (Sm^s), has been modified in vitro by either irradiation with UV light, or by reaction with (±) trans-benzo(a)pyrene-7,8-dihydrodiol-9,10-epoxide (BPDE) and used to transform streptomycin-resistant hosts. The formation of Amp^r transformants which also carry streptomycin resistance was used as a measure of the level of recombination between plasmid and chromosomal DNA. Transformation of recB and recC mutants produced no change in the level of recombination while in the recF mutant a significant decrease was observed compared to the wild type host. Thermal induction of the SOS response in tif-1 and tif-1 umuC mutants followed by transformation led to a four-fold increase in recombination in both cases. The results suggest that the streptomycin-resistant transformants arise exclusively via a recombinational pathway which is largely dependant on the recF gene product, and that this pathway is influenced by induction of the SOS response. These results are discussed in terms of the mechanism of this recombination.     

Ribosomal proteins. 33. Location of amino-acid replacements in protein S12 isolated from Escherichia coli mutants resistant to streptomycin

Ribosomal protein S12, the protein coded by the strA ciatron, was isolated from nine streptomycin-resistant mutants originating from various Escherichia coli strains. Analysis of the tryptic peptides revealed that each mutant had a single amino-acid replacement in one of two peptides: in mutants belonging to the allele types strA1, strA2 and strA60 the lysine residue in position 42 (peptide T6) of protein S12 is replaced by one of three ammo acids (asparagine, threonine or arginine) whereas the mutants belonging to allele type strA40 have a replacement of lysine by arginine in peptide T15. There is a good agreement between our protein-chemical data and earlier genetic data on streptomycin-resistant mutants.     

A Suitable Streptomycin-Resistant Mutant for Constructing Unmarked In-Frame Gene Deletions Using rpsL as a Counter-Selection Marker

The streptomycin counter-selection system is a useful tool for constructing unmarked in-frame gene deletions, which is a fundamental approach to study bacteria and their pathogenicity at the molecular level. A prerequisite for this system is acquiring a streptomycin-resistant strain due to rpsL mutations, which encodes the ribosomal protein S12. However, in this study no streptomycin resistance was found to be caused by rpsL mutations in all 127 clinical strains of Klebsiella pneumoniae isolated from liver abscess patients. By screening 107 spontaneous mutants of streptomycin resistance from a clinical strain of K. pneumoniae, nucleotide substitution or insertion located within the rpsL was detected in each of these strains. Thirteen different mutants with varied S12 proteins were obtained, including nine streptomycin-dependent mutants. The virulence of all four streptomycin-resistant mutants was further evaluated. Compared with the parental strain, the K42N, K42T and K87R mutants showed a reduction in growth rate, and the K42N and K42T mutants became susceptible to normal human serum. In the mice LD₅₀ (the bacterial dose that caused 50% death) assay, the K42N and K42T mutants were ∼1,000-fold less lethal (∼2×10⁵ CFU) and the K87R mutant was ∼50-fold less lethal (∼1×10⁴ CFU) than the parental strain (∼2×10² CFU). A K42R mutant showed non-observable effects on the above assays, while this mutant exhibited a small cost (P<0.01) in an in vitro growth competition experiment. In summary, most of the K. pneumoniae strains with streptomycin resistance caused by rpsL mutations are less virulent than their parental strain in the absence of streptomycin. The K42R mutant showed similar pathogenicity to its parental strain and should be one of the best choices when using rpsL as a counter-selection marker.     

Ribosomal Protein S12 and Aminoglycoside Antibiotics Modulate A-site mRNA Cleavage and Transfer-Messenger RNA Activity in Escherichia coli

Translational pausing in Escherichia coli can lead to mRNA cleavage within the ribosomal A-site. A-site mRNA cleavage is thought to facilitate transfer-messenger RNA (tmRNA)·SmpB- mediated recycling of stalled ribosome complexes. Here, we demonstrate that the aminoglycosides paromomycin and streptomycin inhibit A-site cleavage of stop codons during inefficient translation termination. Aminoglycosides also induced stop codon read-through, suggesting that these antibiotics alleviate ribosome pausing during termination. Streptomycin did not inhibit A-site cleavage in rpsL mutants, which express streptomycin-resistant variants of ribosomal protein S12. However, rpsL strains exhibited reduced A-site mRNA cleavage compared with rpsL⁺ cells. Additionally, tmRNA·SmpB-mediated SsrA peptide tagging was significantly reduced in several rpsL strains but could be fully restored in a subset of mutants when treated with streptomycin. The streptomycin-dependent rpsL(P90K) mutant also showed significantly lower levels of A-site cleavage and tmRNA·SmpB activity. Mutations in rpsD (encoding ribosomal protein S4), which suppressed streptomycin dependence, were able to partially restore A-site cleavage to rpsL(P90K) cells but failed to increase tmRNA·SmpB activity. Taken together, these results show that perturbations to A-site structure and function modulate A-site mRNA cleavage and tmRNA·SmpB activity. We propose that tmRNA·SmpB binds to streptomycin-resistant rpsL ribosomes less efficiently, leading to a partial loss of ribosome rescue function in these mutants.     

The rpsL gene and streptomycin resistance in single and multiple drug-resistant strains of Mycobacterium tuberculosis

The recent emergence of indolent and rapidly fatal drug-resistant strains of Mycobacterium tuberculosis has renewed interest in defining the molecular mechanisms of drug resistance in the tubercle bacilli. In this report, we have examined the mechanism of resistance to streptomycin (Sm) in M. tuberculosis through the cloning and nucleotide sequence analysis of the gene encoding the ribosomal S^R protein (rpsL gene) from streptomycin-resistant strains and their streptomycin-sensitive parental strains. We have demonstrated that five singly Sm^RM. tuberculosis strains and an Sm^R isolate that has reduced sensitivity to multiple antibiotics have identical point mutations at codon 43 of the rpsL gene. Mutations at this same site confer Sm^R in Escherichia coli. In contrast, two other multiple drug-resistant M. tuberculosis strains that are resistant to Sm have rpsL genes that have the same nucleotide sequence as their drug-sensitive parent strains, suggesting that different resistance mechanisms are involved in these strains.     

Expression of parasporal crystal protein (δ—endotoxin) gene(s) ofBacillus thuringiensis var.israelensis in sporogenic and asporogenic mutant strains ofBacillus cereus

The expression of parasporal crystal protein (δ-endotoxin) coding gene(s) ofBacillus thuringlensis var.israelensis and its association, if any, with sporulation was studied in sporogenicBacillus cereus and its asporogenic mutant strains. Five asporogenous mutants ofBacillus cereus blocked at different stages of sporulation, were isolated from a streptomycin-resistant strain, The transconjugants isolated from the plasmid transfer experiments betweenBacillus thuringiensis var.israelensis and streptomycin resistantBacillus cereus and its asporogenous mutants, showed larvicidal activity. The crystal protein gene(s) are, therefore, expressed both in sporulating and in non-sporulating mutant strains ofBacillus cereus suggesting that the expression of crystal protein gene(s), is independent of sporulation specific functions inBacillus cereus. Part of the work was carried out at Biotechnology Programme, Jadavpur University, Calcutta 700 032, India.     

Streptomycin resistance in Rhizobium japonicum

Mutants resistant to varying concentrations of streptomycin were recovered from two streptomycin-sensitive, effective nitrogen-fixing strains of Rhizobium japonicum. To determine if there were an upper limit of resistible antibiotic concentration, 3 mutants which were resistant to 10000 μg/ml were challenged by higher concentrations of streptomycin. Only one grew well at 25000 μg/ml, and none grew at 50000 μg/ml. All mutants maintained a smooth colonial morphology, and none exhibited streptomycin-dependence. Streptomycin-resistant mutants of both strains were examined for properties of infectivity and effectiveness. All mutants tested retained the symbiotic properties of the parental strains. The retention of these parental properties by the streptomycin-resistant mutants of R. japonicum is different from the properties described for phenotypically similar mutants in certain other rhizobial species.     

Improvement of milbemycin-producing <Emphasis Type="Italic">Streptomyces bingchenggensis</Emphasis> by rational screening of ultraviolet- and chemically induced mutants

Milbemycin antibiotics are produced by Streptomyces hygroscopicus subsp. aureolacrimosus and a newly isolated Streptomyces bingchenggensis, respectively. According to the biosynthetic pathway of milbemycins generated by S. hygroscopicus subsp. aureolacrimosus, a rational screening procedure with UV irradiation and N-methyl-N′-nitroso-N-nitrosoguanidine (NTG) mutation was performed to obtain high milbemycin-producing S. bingchenggensis. Aminoacetic acid (Glycine)-resistant mutants (AA^r), propionate-resistant mutants (PRP^r), streptomycin-resistant mutants (STR^r) and 2-deoxy-d-glucose-resistant mutants (DOG^r) were selected successively. A strain S. bingchenggensis BC-109-6 with AA^r, PRPr, STR^r and DOG^r was obtained and its production of milbemycin A3 and A4 reached 1,450 μg/ml, which was 80% higher than that of the ancestral strain S. bingchenggensis BC-101-4. The subculture experiments indicated that the hereditary characteristic of high productivity of S. bingchenggensis BC-109-6 was stable. The production of milbemycin A3 and A4 by S. bingchenggensis BC-109-6 in a 50-l fermentor could reach 1,380 μg/ml after 360 h batch fermentation.     

Phenotypic suppression by streptomycin of amber mutants in the ribonucleic Acid bacteriophage coat protein cistron

After mutagenesis with nitrosoguanidine or ultraviolet light, 298 streptomycin high-resistant and 98 streptomycin high-dependent mutants were isolated from HfrC Su⁻. They were tested for their ability to phenotypically suppress five different amber ribonucleic acid (RNA) bacteriophage mutants in the presence of streptomycin. The phage mutants are all in the coat protein, which is 129 amino acids long; the uracil-adenine-guanine codons were at the following positions: sus3 and amB2, 6; amB11, 50; amB21, 54; sus11, 70. Only sus3 and amB2 could be phenotypically suppressed by streptomycin; this was clearly demonstrated in nine mutant strains, seven str-HR and two str-HD. The suppression was always dependent upon added streptomycin and was dose-dependent in all cases. None of the mutants showed measurable suppression in absence of the drug. Among revertants to streptomycin independence from streptomycin-dependent strains that could show phenotypic suppression, most of those that were still resistant to streptomycin (10 μg or more) retained the capacity to show phenotypic suppression; whereas among those revertants sensitive to 10 μg of streptomycin or less, none retained the capacity. Eight different amber polar mutants (strong and weak) in gene 34 of phage T4 were also tested for pleiotypic suppression by streptomycin in all the streptomycin-resistant and -dependent strains isolated. No suppression was found in any of the 396 strains tested.     

Accumulation of 14C-Streptomycin by Streptomycin-sensitive and Streptomycin-resistant Group H Streptococci

Three streptomycin-resistant mutants of group H streptococcus, strain Challis, were examined for ability to accumulate ¹⁴C-streptomycin. Although the mutants exhibited different levels of transformation, only the streptomycin-sensitive parent Challis strain accumulated significant amounts of ¹⁴C-streptomycin. It appears that impermeability to streptomycin does not necessarily result in reduction or loss of transformability. The amount of label accumulated by strain Challis was correlated with a loss of viability. In addition, accumulation of label was influenced by the concentration of ¹⁴C-streptomycin, the time of exposure, and the type of medium employed.     

Nitrate and nitrite reductase negative mutants of N2-fixingAzospirillum spp.

Chlorate resistant spontaneous mutants ofAzospirillum spp. (syn.Spirillum lipoferum) were selected in oxygen limited, deep agar tubes with chlorate. Among 20 mutants fromA. brasilense and 13 fromA. lipoferum all retained their functional nitrogenase and 11 from each species were nitrate reductase negative (nr^–). Most of the mutants were also nitrite reductase negative (nir^–), only 3 remaining nir⁺. Two mutants from nr⁺ nir⁺ parent strains lost only nir and became like the nr⁺ nir^– parent strain ofA. brasilense. No parent strain or nr⁺ mutant showed any nitrogenase activity with 10 mM NO ₃ ^– . In all nr^– mutants, nitrogenase was unaffected by 10 mM NO ₃ ^– . Nitrite inhibited nitrogenase activity of all parent strains and mutants including those which were nir^–. It seems therefore, that inhibition of nitrogenase by nitrate is dependent on nitrate reduction. Under aerobic conditions, where nitrogenase activity is inhibited by oxygen, nitrate could be used as sole nitrogen source for growth of the parent strains and one mutant (nr^– nir^–) and nitritite of the parent strains and 10 mutants (all types). This indicates the loss of both assimilatory and dissimilatory nitrate reduction but only dissimilatory nitrite reduction in the mutants selected with chlorate.     

Bradyrhizobium japonicum mutants defective in root-nodule bacteroid development and nitrogen fixation

The genome of the slow-growing Bradyrhizobium japonicum (strain 110) was mutagenized with transposon Tn5. A total of 1623 kanamycin/streptomycin resistant derivatives were screened in soybean infection tests for nodulation (Nod) and symbiotic nitrogen fixation (Fix). In this report we describe 14 strains possessing a stable, reproducible Nod⁺Fix^- phenotype. These strains were also grown under microaerobic culture conditions to test them for free-living nitrogen fixation activity (Nif). In addition to strains having reduced Fix and Nif activities, there were also strains that had reduced symbiotic Fix activity but were Nif⁺ ex planta.Analysis of the genomic structure revealed that the majority of the strains had a single Tn5 insertion without any further apparent physical alteration. A few strains had additional insertions (by Tn5 or IS50), or a deletion, or had cointegrated part of the vector used for Tn5 mutagenesis. One of the insertions was found in a known nif gene (nifD) whereas all other mutations seem to affect different, hitherto unknown genes or operons.Several mutant strains had an altered nodulation phenotype, inducing numerous, small, widely distributed nodules. Light and electron microscopy revealed that most of these mutants were defective in different stages of bacteroid development and/or bacteroid persistence. The protein patterns of the mutants were inspected by two-dimensional gel electrophoresis after labelling microaerobic cultures with l-(³⁵S)methionine. Of particular interest were mutants lacking a group of proteins the synthesis of which was known to be under oxygen control. Such strains can be regarded as potential regulatory mutants.     

Assessing the microbial oxidative stress mechanism of ozone treatment through the responses of Escherichia coli mutants

Aims:  To investigate the effect of the oxidative stress of ozone on the microbial inactivation, cell membrane integrity and permeability and morphology changes of Escherichia coli. Methods and Results:  Escherichia coli BW 25113 and its isogenic mutants in soxR, soxS, oxyR, rpoS and dnaK genes were treated with ozone at a concentration of 6 μg ml^?1 for a period up to 240 s. A significant effect of ozone exposure on microbial inactivation was observed. After ozonation, minor effects on the cell membrane integrity and permeability were observed, while scanning electron microscopy analysis showed slightly altered cell surface structure. Conclusions:  The results of this study suggest that cell lysis was not the major mechanism of microbial inactivation. The deletion of oxidative stress–related genes resulted in increased susceptibility of E. coli cells to ozone treatment, implying that they play an important role for protection against the radicals produced by ozone. However, DnaK that has previously been shown to protect against oxidative stress did not protect against ozone treatment in this study. Furthermore, RpoS was important for the survival against ozone. Significance and Impact of the Study:  This study provides important information about the role of oxidative stress in the responses of E. coli during ozonation.     

Aflagellated mutants of Helicobacter pylori generated by genetic transformation of naturally competent strains using transposon shuttle mutagenesis

Three out of 10 Helicobacter pylori clinical isolates were found to be naturally competent for genetic transformation to streptomycin resistance by chromosomal DNA extracted from a spontaneous streptomycin-resistant H. pylori mutant. The frequency of transformation varied between 5 × 10^?4 and 4 × 10^?6, depending on the H. pylori isolate used. Transposon shuttle mutagenesis based on this natural competence was established using the flagellin gene flaA as the target. The cloned flaA gene was interrupted by insertion of TnMax1, a mini-Tn1721 transposon carrying a modified chloramphenicol-acetyltransferase gene, the cat_GC cassette. Natural transformation of competent H. pylori strains with plasmid constructs harbouring a cat_GC-inactivated flaA gene resulted in chloramphenicol-resistant transformants at an average frequency of 4 × 10^?5. Southern hybridization experiments confirmed the replacement of the chromosomal H. pylori flaA gene by the cat-inactivated cloned gene copy via homologous recombination resulting in allelic exchange. Phenotypic characterization of the mutants demonstrated the absence of flagella under the electron microscope and the loss of bacterial motility. Immunoblots of cell lysates of the H. pylori mutants with an antiserum raised against the C-terminal portion of recombinant H. pylori major flagellin (FlaA) confirmed the absence of the 54kDa FlaA protein. This efficient transposon shuttle mutagenesis procedure for H. pylori based on natural competence opens up new possibilities for the genetic assessment of putative H. pylori virulence determinants.     

Ozone response in wild type and radiation-sensitive mutants of Saccharomyces cerevisiae.

Summary The effect of ozone exposure on Saccharomyces cerevisiae was studied. Factors such as ozone concentration, treatment time, media, initial cell concentration and growth phase were shown to influence ozone response in this organism. Logarithmic phase cells were much more sensitive than stationary phase cells to the lethal effect of ozone.The radiation-sensitive mutants rad3, rad6, rad51 and rad52 of S. cerevisiae were exposed, in water, to 50 ppm of ozone for 30 min. On comparing their survival curves, the rad51 and the rad52 mutants showed a greater sensitivity to ozone exposure than the wild type.     

Impaired nitrogen fixation and glutamine synthesis in methionine sulfoximine sensitive (MSs) mutants of Rhizobium phaseoli

Summary Random Tn5 mutagenesis of antibiotic-resistant derivatives of Rhizobium phaseoli CFN42 yielded several independent mutants that were sensitive to methionine sulfoximine (MS^s), a specific inhibitor of glutamine synthetase (GS). These MS^s mutants were analyzed for GSI and GSII activities and for their symbiotic properties. Four classes of MS^s mutants have been distinguished. Class I strains are impaired in their synthesis of glutamine and in their symbiotic properties. Class II strains have wild type levels of GSI and GSII activities but have a reduced capacity to fix nitrogen. Class III strains have lost GSII activity, but their symbiotic properties are wild type. In class IV mutants neither glutamine synthesis nor symbiotic properties are affected. Mutants of classes I, III, and IV all have the Tn5 inserted into the chromosome, whereas in class II mutants the Tn5 is located in plasmid p42e, a plasmid different from the previously identified symbiotic plasmid p42d.     

Symbiotic mutants of USDA191, a fast-growing Rhizobium that nodulates soybeans

Summary Symbiotic and auxotrophic mutants of Rhizobium japonicum strain USDA191 were isolated using Tn5 mutagenesis and techniques that cause plasmid deletions and plasmid curing. Characterization of several mutants that are unable to nodulate (Nod^-) or unable to fix nitrogen (Fix^_) showed that nod and nif genes are located within one regions of a 200 MD plasmid (pSym191). Blot hybridization analysis of plasmids in other fast-growing R. japonicum strains showed that nod as well as nif sequences are located on plasmids in eight strains but are apparently carried in the chromosome in two strains.     

Dicarboxylic acid transport in Rhizobium meliloti: isolation of mutants and cloning of dicarboxylic acid transport genes

The role of the dicarboxylic acid transport (dct) system in the Rhizobium meliloti-Alfalfa symbiosis was investigated. Mutants of R. meliloti CM2 unable to grow on medium containing succinate as the sole carbon source were isolated following chemical and transposon mutagenesis. These mutants were also unable to utilize malate or fumarate as the sole source of carbon. Transport studies with ¹⁴C-labelled succinate showed that the mutants were specifically defective in succinate transport. Revertants of both chemical and transposon mutants were obtained at a frequency of 10^-5–10^-6. The R. meliloti dct mutants were able to nodulate Alfalfa plants but the nodules formed were unable to fix nitrogen. Revertants of the mutants were fully effective on plants. The mutants unable to transport succinate were used to isolate dct genes from a R. meliloti gene bank. Two plasmids containing a common 26.5 Mdal insert were found to complement some of the mutants. The presence of this DNA insert in the complementing mutant strains restored their effectivenss of plants. This DNA fragment encoding succinate transport function(s) was used to produce genetically engineered R. meliloti strains with an increased rate of succinate uptake.Abbreviation dct dicarboxylic acid transport     

The two megaplasmids of Rhizobium meliloti are involved in the effective nodulation of alfalfa

Summary We have shown by physical and genetic means that there are two megaplasmids in all strains of Rhizobium meliloti that we have studied. Megaplasmids from several strains of R. meliloti were mobilized to Agrobacterium tumefaciens and to other Rhizobium strains using the Tn5-Mob system. We were also able to resolve these two megaplasmids in agarose gels for most strains, and to show that only one of them hybridized to nif and nod genes. Transfer of this plasmid, the pSym, to Agrobacterium, R. leguminosarum, and R. trifolii strains conferred on these recipients the ability to nodulate alfalfa ineffectively. The second megaplasmid did not appear to have a direct role in nodule initiation. However, we were able to complement extracellular polysaccharide (EPS^-) mutants of R. meliloti by transferring this second megaplasmid into them. Furthermore, Tn5-induced EPS^- mutants of R. meliloti 2011, which produced ineffective (Fix^-) nodules of abnormal morphology, were shown by hybridization and complementation to carry mutations in this second megaplasmid. This demonstrates that both megaplasmids of R. meliloti are necessary for the effective nodulation of alfalfa.