Transformability of Streptomycin-resistant Group H Streptococci

Several resistant mutants of a transformable group H streptococcus, strain Challis, were isolated from media containing high concentrations of streptomycin. Mutants SR5a and SR5 exhibited high and low transformability, respectively, when exposed to deoxyribonucleic acid (DNA) from a novobiocin-resistant Challis strain. With similar exposure, mutant SR30 exhibited loss of transformability. The mutants further differed from the parent strain in time of appearance of optimal competence, and, in the case of SR5 and SR30, total growth was somewhat less than that of the parent. The rapidity with which transformants appeared upon initial exposure to DNA was approximately the same in the mutants and the parent strain. The decrease or loss of transformability of mutants SR5 and SR30 was found to be due to an alteration in capacity to take up DNA. Mutant SR5a (highly transformable) was further differentiated from mutants SR5 and SR30 in that it was somewhat more sensitive to high concentrations of streptomycin. Transformants obtained by treating strain Challis with the three types of mutant DNA, on the other hand, exhibited similar degrees of resistance to increasing concentrations of streptomycin. The additional decrease in transforming ability of mutant SR5a and the loss of transforming ability of mutant SR5 after a second exposure to streptomycin may indicate a stepwise process in the change from transformability to nontransformability. Although streptomycin resistance may not be directly related to inability to transform, results indicate that streptomycin greatly increases the chances of selecting these mutants and also can be of value in serving as a marker in studies of this nature.     

Cellular Sites for the Competence-provoking Factor of Streptococci

Immune globulins against competent cells of group H streptococci, strains Challis and Wicky, inhibited genetic transformation to streptomycin resistance when added to competent cultures. Antibodies against noncompetent cells did not inhibit transformation of competent cells. Strain Challis is spontaneously highly transformable. Strain Wicky is very poorly transformable but can be converted to high transformability with the exocellular competence-provoking factor (CPF) produced by strain Challis. Globulins against noncompetent cells of strain Challis and Wicky also inhibited transformation when added to noncompetent cultures prior to conversion to competence. Antibodies against cells of the related strain Blackburn, however, did not inhibit transformation under any circumstances. It is concluded that, although globulins prepared against competent cells block the deoxyribonucleic acid receptor sites present in these cells, the globulins prepared against noncompetent cells prevent conversion to competence by blocking the access of CPF to specific cellular sites for this factor. Strain Blackburn seems not to contain CPF-receptive sites and is, therefore, nontransformable.     

Antibiotic Resistant Group A Streptococci

A series of Streptococcus pyogenes strains, including strains isolated from patients, mutants which had acquired in vitro resistance to penicillin (Pc), mitomycin C (MC), tetracycline (TC) and chloramphenicol (CM), ultraviolet light induced α hemolytic mutants, as well as β hemolytic mutants (β mutants) derived from α hemolytic mutants (α mutants) were compared as to their antibiotic sensitivity, and physiological, biochemical and serological properties. To obtain β mutants from α mutants the following procedures were employed: (1) serial mouse passage, (2) serial serum-broth transfers, (3) cultivation in heat-killed cultures of parent strains, and (4) cultivation in broth containing bacterial DNA extracted from parent streptococcus cells. From the results obtained these strains could be divided into two major groups, each with two subgroups. Group 1 strains produce soluble hemolysins and are sensitive to Pc. Subgroup 1–1 strains are sensitive to other antibiotics too; subgroup 1–2 are resistant to certain antibiotics other than Pc, bacitracin and MC. Group 2 strains do not produce soluble hemolysins and resistant to Pc. Subgroup 2-1 strains are α hemolytic on horse blood agar and subgroup 2–2 are β hemolytic on the same medium. Pc resistance in group 2 strains was more than 100-fold higher than that of sensitive strains, and was accompanied by MC resistance, but to a lesser degree. Pc resistance in group 2 mutants could be induced by antibiotics other than Pc and also by ultraviolet irradiation. Although group 1 cells retained the characteristics of typical S. pyogenes, group 2 cells, both α and β hemolytic, lost most of the physiological, biochemical and serological properties of this species. The similarity of group 2 strains to group D or group N streptococcal strains in their general properties is discussed.     

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.     

Transformation of type polysaccharide antigen synthesis and hemolysin synthesis in streptococci

Transformation of the ability to synthesize type polysaccharide antigen and beta-hemolysin has been obtained in group F streptococci. Colonies possessing cells transformed to antigen synthesis were detected on the agar surface with fluorescein-labeled anti-type serum. This selection method, in contrast to those with antibiotics, allowed both transformed and nontransformed cells to grow, resulting in sectored colonies. These colonies could be subcultured to further establish the synthesis of antigen. Group F, group A, and group-like z deoxyribonucleic acid (DNA) labeled with type II antigen and hemolysin, and streptomycin resistance transferred each marker to a group F strain lacking a type antigen. DNA from group F and z3 strains labeled with type III antigen, and streptomycin resistance transferred both markers to group F and z3 strains lacking type antigen. A second F strain without type antigen was not transformed with any of these markers. A group H strain was transformed to streptomycin resistance only by the same types of DNA. Transformation to type II antigen synthesis always resulted in the formation of beta-hemolysin. All strains isolated from natural sources contained both markers. A mutant, obtained by nitrosoguanidine treatment of an FII(sr) strain, did not synthesize either the hemolysin or the antigen. This mutant still possessed the group antigen and streptomycin resistance. A close linkage of type II antigen and beta-hemolysin is indicated. The fluorescent-antibody staining of cells containing both group and type antigens showed a more intense ultraviolet adsorption for type than group antigen. A surface location (microcapsular) for the type antigen appeared likely. These results are of interest for studies on antigen biosynthesis, genetics, and classification of the streptococci.     

Gene recombination and segregation of resistance factor R in Escherichia coli

Hashimoto, Hajime (Osaka University, Osaka, Japan), and Yukinori Hirota. Gene recombination and segregation of resistance factor R in Escherichia coli. J. Bacteriol. 91:51-62. 1966.-Independent chloramphenicol-sensitive (CM(s)) mutants of the drug-resistance factor R were isolated. Introduction of two different R factor CM(s) mutants into a single bacterium, by conjugation or transduction, gave chloramphenicol-resistant (CM(r)) colonies when such strains were plated on a medium containing chloramphenicol (Cm). These CM(r) colonies resulted from recombination between two R factors contained within the same cell. Most of the CM(r) colonies were heterogeneous, and segregation of drug-resistance markers was observed among the progeny. Segregated bacteria which still carried the recombinant R factor were stable for resistance to Cm as well as for other markers of R. All the markers of recombinant R factors were cotransducible with high coincidence and at the same frequency as wild-type R. Sensitive mutants of R which had lost all the resistance markers of the R factor were found also. A mutation of R, referred to as SMA, which was sensitive to streptomycin and sulfanilamide, was capable of reverting to resistance to both of these drugs simultaneously. The sensitive alleles for SMA, CM, and TC were shown to be recessive to the resistance alleles. Mutants of R having multisite mutations or deletions in the CM gene were isolated and used to analyze the pattern of linked segregation of unselected markers of the recombinant R factor. The drug resistance factor R was shown to have two linkage groups, CM-SMA and TC-m.     

Mutagenic effects of streptomycin in chlamydomonas

Summary Growth of a green streptomycin-resistant strain of Chlamydomonas reinhardi on a sub-lethal concentration of streptomycin on agar led to the appearance of yellow mutant cells in almost every colony. The time of appearance of the mutants varied greatly among the 9 isolates studied, each of which was selected as a single colony after repeated cloning of the parental strain. 2 isolates gave rise to colonies which responded rapidly to streptomycin (class I), 2 isolates produced yellow sub-clones as papillae only after formation of normal green colonies (class II), and 2 isolates produced stable yellow sub-clones only after a second subculture on streptomycin-agar (class III). 3 isolates were mixtures of classes II and III.The evidence that these yellow mutants arose under the mutagenic action of streptomycin is discussed in relation to the alternative possibility of their selection by the drug from a pool of pre-existing mutants. The physiological and genetic effects of streptomycin upon chlorophyll formation in Chlamydomonas are compared with reported effects of the drug upon the green flagellate, Euglena gracilis.Dedicated with appreciation and affection to Professor Dr. E. G. Pringsheim on the occasion of his 80th birthday.     

The A-factor-binding protein of Streptomyces griseus negatively controls streptomycin production and sporulation.

A-factor, 2-(6'-methylheptanoyl)-3R-hydroxymethyl-4-butanolide, is an autoregulator essential for streptomycin production and sporulation in Streptomyces griseus. S. griseus 2247 that requires no A-factor for streptomycin production or sporulation was found to have a defect in the A-factor-binding protein. This observation implied that the A-factor-binding protein in the absence of A-factor repressed the expression of both phenotypes in the wild-type strain. Screening among mutagenized S. griseus colonies for strains producing streptomycin and sporulating in the absence of A-factor yielded three mutants that were also deficient in the A-factor-binding protein. Reversal of the defect in the A-factor-binding protein of these mutants led to the simultaneous loss of streptomycin production and sporulation. These data suggested that the A-factor-binding protein played a role in repressing both streptomycin production and sporulation and that the binding of A-factor to the protein released its repression. Mutants deficient in the A-factor-binding protein began to produce streptomycin and sporulate at an earlier stage of growth than did the wild-type strain. These mutants produced approximately 10 times more streptomycin than did the parental strain. These findings are consistent with the idea that the intracellular concentration of A-factor determines the timing of derepression of the gene(s) whose expression is repressed by the A-factor-binding protein.     

Mutants of Ustilago maydis defective in production of one of two polypeptides of KP6 toxin from the preprotoxin

Double-stranded RNA viruses of Ustilago maydis encode secreted killer toxins to which other cells of the same species and closely related species are sensitive. KP6 toxin consists of two polypeptides, α and β, produced from a single precursor preprotoxin. In this work, we cloned complementary DNA for the toxin-encoding segment of two of the KP6 nonkiller mutants NK3 and NK13 that secrete the β and α polypeptides, respectively. Both sequence analysis of the cDNA clones and in vitro translation of the toxin-encoding double-stranded RNAs showed that both mutants can produce full-length preprotoxins. Cys⁵¹ in α is converted to Arg in NK3 and Thr²⁵ and Lys⁴² in β are changed to Pro and Arg, respectively, in NK13. Although α and β are encoded in a single prepropolypeptide, only the β polypeptide is secreted by NK3 and only the α polypeptide is secreted by NK 13. This differential expression of peptides from one precursor is a unique phenomenon. Neither of the nonsecreted polypeptides accumulated in the cytosol. The possible effects of these mutations on pre-protoxin folding and their consequences for toxin secretion are discussed.     

微波诱变结合抗性突变筛选放线菌素D高产菌株

采用微波结合链霉素抗性筛选法选育放线菌素D的高产菌株。通过考察链霉素对Streptomyces rubiginosohelvolus FIM-N31菌株孢子生长情况的影响确定链霉素致死浓度,出发菌株FIM-N31的孢子经微波辐照处理后,涂布在含链霉素致死浓度（50 μg/mL）的培养基平板上培养,获得了大量的链霉素抗性基因突变株。摇瓶发酵筛选突变株,结果获得一株遗传性状稳定的放线菌素D高产菌Str186,其产放线菌素D的能力比出发菌株提高了8倍以上。     

Phospholipase A-deficient mutants of Escherichia coli B

Phospholipase A-deficient mutants were isolated from Escherichia coli B/SM as follows. Replica plates were incubated to allow formation of colonies and then overlayed with soft agar containing washed sheep erythrocytes, lecithin Ca++, colistin, lysozyme and streptomycin. The mutant colonies were detected as colonies without hemolytic zones. Two or three cycles of treatment with mutagen and selection were necessary for their isolation. The mutants obtained could grow in a synthetic medium with glucose as the sole carbon source, and their phospholipid compositions were similar to that of the parent. They also gave the same agglutination titer as the parent with rabbit antiserum against the parent strain. They supported the growth of all members of the T-series of bacteriophages as effectively as the parent. Some hemolytic substance was produced from either lecithin or bacterial constituents when the mutants were infected with T even phages, but not with T odd phages. When the parent strain was infected with either T1 or T4, free fatty acids (FFA) were produced in the cell debris. Only a trace of FFA was formed in the debris of one of these mutants on infection with T4 and no FFA was formed on infection with T1.     

Transduction of penicillinase production and other antibiotic-resistance markers in Staphylococcus epidermidis.

Transduction of resistance from a multiply antibiotic-resistant strain of Staphylococcus epidermidis sub-group II was studied using the typing phage 108. The effect of increasing doses of ultraviolet radiation on the transducing phage was used to indicate the chromosomal or plasmid nature of the genes. Tetracycline and chloramphenicol resistance behaved as plasmid genes and streptomycin resistance as a chromosomal marker. It was also possible to transduce penicillin resistance (Pc) due to penicillinase production (bla+) using a low level of benzylpenicillin (0.03 microgram ml-1) for recovery. Approximately 10(-5) transductant colonies per phage input were obtained and ultraviolet kinetics indicated that Pc was plasmid carried. Pc transductants fell into two categories. In one group PC was stable as in the donor strain and transductants had the same phage sensitivity as the recipient. In the other, Pc was unstable at 37 degrees C and the instability was enhanced by growth at approximately 43.5 degrees C; these transductants also gained genes for restriction and modification of certain phages. Transductants that subsequently lost bla+ also lost the restriction and modification characters.     

Detection of streptococcal mutants presumed to be defective in sugar catabolism

The tetrazolium method for detection of bacterial mutants defective in sugar catabolism was modified for use with streptococci. The critical factors were (i) the concentration of tetrazolium, which must be titrated to determine the optimum concentration for each species or even strain, and (ii) anaerobic incubation of tetrazolium-containing agar plates. When used with standard mutagenesis protocols, this method yielded lactose-negative mutants of nine streptococcal strains representing six species. A collection of lactose-negative mutants of streptococcus, sanguis Challis was characterized and contained phospho-beta-galactosidase, lactose phosphotransferase, and general phosphotransferase mutants.     

Detection of streptococcal mutants presumed to be defective in sugar catabolism.

The tetrazolium method for detection of bacterial mutants defective in sugar catabolism was modified for use with streptococci. The critical factors were (i) the concentration of tetrazolium, which must be titrated to determine the optimum concentration for each species or even strain, and (ii) anaerobic incubation of tetrazolium-containing agar plates. When used with standard mutagenesis protocols, this method yielded lactose-negative mutants of nine streptococcal strains representing six species. A collection of lactose-negative mutants of streptococcus, sanguis Challis was characterized and contained phospho-beta-galactosidase, lactose phosphotransferase, and general phosphotransferase mutants.     

Inhibition of Transformation in Group H Streptococci by Lysogeny

Group H streptococcal strains Challis and WE4 were lysogenized with a bacteriophage isolated from strain Channon, after which their capacity for transformation to streptomycin and rifampin resistance was reduced by three orders of magnitude. The probable reason is the inability of the lysogenized strains to bind deoxyribonucleic acid irreversibly, even though they exhibit earlier stages of competence development during a competence regimen.     

Masking of antibiotic-resistance upon recovery of endophytic bacteria

During studies on internal plant colonization by rhizosphere bacteria and endophytic bacteria over several years, we frequently observed lack of growth of rifampicin-resistant mutants (rif+) on tryptic soy agar amended with rifampicin (RTSA). Following seed treatment of cucumber with 6 species of rif+ rhizosphere bacteria in one experiment, all strains were recoverable on RTSA when external root colonization was monitored. Following trituration of surface-disinfested roots, only one strain grew directly on RTSA; however colonies isolated on tryptic soy agar (TSA) grew within 18 h after transfer to RTSA. We term this temporary loss of the antibiotic-resistant phenotype ‘antibiotic masking’. Antibiotic masking was also observed with isolation of 7 rif+ endophytic bacterial strains from inside stems of cotton and with isolation of mutants of bacterial endophytes resistant to polymyxin B sulfate from cotton plants. Rifampicin-masking was not accounted for in vitro by inhibitory compounds from cotton plant extracts, by bacterial growth on low nutrient agar, or by competition with other bacteria. Collectively, these results suggest that expression of antibiotic-resistance may be altered in planta, although causes for this antibiotic-masking remain to be elucidated, methods for quantifying internal plant colonization by rif+ bacteria should account for this possibility. ei]Section editor: R O D Dixon     

Casein kinase II α subunits affect multiple developmental and stress-responsive pathways in Arabidopsis

Casein kinase II (formerly known as CK2), a ubiquitous Ser/Thr kinase, plays critical roles in all higher organisms including plants. The CK2 holoenzyme consists of two catalytic α subunits and two regulatory β subunits. The Arabidopsis genome has four α subunit and four β subunit genes, and members of both the α and β subunit families have been shown to be localized in the cytoplasm, nucleus and also in chloroplasts. However, the biological roles of CK2 subunits have not been fully characterized yet. Here we identified T-DNA insertion mutants in three α subunit genes (α1, α2 and α3) and made double and triple mutants. The CK2 α1α2α3 triple mutants displayed reduced CK2 activity compared with wild-type seedlings. Phenotypic characterization showed that CK2 α1α2α3 triple mutants are late flowering under both long- and short-day conditions. Genes encoding floral integrators are differentially regulated in the triple mutant compared with the wild-type plants. CK2 α1α2α3 triple mutants also displayed reduced hypocotyl growth, smaller cotyledon size and a reduced number of lateral roots compared with wild-type seedlings under light. Abscisic acid-induced blockage of seed germination and cotyledon greening is reduced in CK2 α subunit mutants in an additive manner. Moreover, CK2 α subunit mutants are also hyposensitive to a NaCl-induced blockage of seed germination. Taken together, these data suggest that CK2 α subunits affect diverse developmental and stress responsive pathways in Arabidopsis.     

Mechanism of Resistance to Antibiotic Synergism in Enterococci

Enterococci exhibit two types of resistance to streptomycin. Moderately high-level resistance is observed in most naturally occurring strains and can be overcome by simultaneous exposure to penicillin. In addition, very high-level resistance is found in those strains against which penicillin plus streptomycin fail to produce synergism in vitro. To study the mechanism of streptomycin resistance in enterococci, ribosomes from a wild-type strain and from a highly streptomycin-resistant mutant were isolated, characterized, and studied in an in vitro amino acid incorporation system. The ribosomes from the organism with moderately high-level streptomycin resistance were sensitive to streptomycin in vitro, suggesting that this type of resistance is caused by failure of streptomycin to reach the ribosomes. Very high-level resistance (and lack of penicillin-streptomycin synergism), on the other hand, appears to be due to ribosomally mediated streptomycin resistance.     

The growth advantage in stationary-phase (GASP) phenomenon in mixed cultures of enterobacteria

Growth advantage in stationary phase (GASP) is the term used to describe the ability of mutants with an increased fitness from 10-day-old enterobacteria culture to out-compete 1-day-old cells of the same initial strain during a prolonged stationary phase, although the aged cells are introduced as a minority. We studied this bacterial trait in mixed cultures of two enterobacterial species, Escherichia coli and Salmonella enterica, wild type in addition to derived mutants from both strains that contain chromosomal-encoded resistance to either nalidixic acid or streptomycin. The strong GASP phenotype was obtained in mixed cultures with the aged mutant strains, but not when the isogenic antibiotic-sensitive strains were used. This phenomenon was associated with chromosomal rearrangements in 10-day-old bacterial antibiotic-resistant mutated cells.     

Sucrose-dependent cell adherence and cariogenicity of serotype c Streptococcus mutans

Four strains of serotype c Streptococcus mutans differing in glucosyltransferase (GTase) and fructosyltransferase (FTase) activities were examined. These strains had been made resistant to streptomycin. FTase activity of an S. mutans clinical variant, MT6801R, which forms large mucoid colonies on sucrose-containing agar, was considerably higher than that of a typical serotype c strain, MT8148R, which forms small, rough colonies on the same agar. Two mutants, NG14 and NG7183, were induced from strain MT6801R by N-methyl-N'-nitro-N-nitrosoguanidine, and were found to be streptomycin-resistant. GTase and FTase activities of mutant NG14 were similar to those of the typical serotype c strain, while in mutant NG7183 the two enzyme activities were very low. Growing cells of these strains (except NG7183) adhered firmly to a glass surface in sucrose broth. Resting cells of all strains attached in small numbers to saliva-coated hydroxyapatite in the absence of sucrose. On the other hand, the presence of sucrose markedly enhanced the attachment of cells of strains MT8148R, MT6801R and NG14, but not NG7183. Cell-surface hydrophobicity and acid production of all strains were similar. Both strain MT8148R and NG14 colonized tooth surfaces and produced significant dental caries in specific-pathogen-free rats. Strain MT6801R had lower colonization ability and cariogenicity when compared with strains MT8148R and NG14. Furthermore, mutant NG7183 was able to colonize the tooth surfaces in small numbers, but failed to cause dental caries. These results indicate that sucrose-dependent cell adherence mediated by de novo glucan synthesis is necessary for the accumulation of serotype c S. mutans cells on the tooth surface and the induction of dental caries.