Plasmid instability in an industrial strain ofBacillus subtilis grown in chemostat culture

Summary A pUB110-derived plasmid/Bacillus subtilis host combination was segregationally unstable when grown in chemostat culture with complex or minimal medium and under starch, glucose or magnesium limitation. The kinetics of plasmid loss were described in terms of the difference in growth rates between plasmid-containing and plasmid-free cells (d) and the rate at which plasmid-free cells were generated from plasmid-containing cells (R). Loss of plasmid-containing cells from the population was d dominated. Changes in medium composition and the nature of growth limitation caused variations in both d and R. The plasmid was most stable in glucose-limited chemostat cultures with minimal medium and least stable under starch limitation with complex complex medium. R and d were smaller for cultures in complex media than those in minimal media. Limitation by starch induced expression of the plasmid-encoded HT amylase gene and was associated with increased values of R and d. Magnesium limitation in minimal medium caused a significant increase in d and a decrease in R.Abbreviations Cm chloramphenicol - Kan kanamycin - Cm^r cells resistant to chloramphenicol (5 mg L^–1) - Kan^r cells resistant to kanamycin (5 mg L^–1) - Cm^sKan^s cells sensitive to chloramphenicol and kanamycin     

Mechanisms of antibiotic resistance determined by resistance-transfer factors

Unowsky, Joel (Northwestern University Medical School, Chicago, Ill.), and Martin Rachmeler. Mechanisms of antibiotic resistance determined by resistance-transfer factors. J. Bacteriol. 92:358-365. 1966.-This study was concerned with the mechanism of expression of drug resistance carried by resistance-transfer (R) factors of two types: fi(-) (negative fertility inhibition) and fi(+) (positive fertility inhibition). The levels of drug resistance determined by R factors used in this study were similar to those reported by other investigators. A new finding was that Escherichia coli carrying the fi(-) episome was resistant to 150 to 200 mug/ml of streptomycin. The growth kinetics of R factor-containing cells were similar in the presence or absence of streptomycin, chloramphenicol, and tetracycline, but a period of adaptation was necessary before cells began exponential growth in the presence of tetracycline. By use of radioactive antibiotics, it was shown that cells containing the fi(-) episome were impermeable to tetracycline and streptomycin, whereas cells containing the fi(+) episome were impermeable only to chloramphenicol. Cell-free extracts from fi(+) and fi(-) cells were sensitive to the antibiotics tested in the polyuridylic acid-stimulated incorporation of phenylalanine into protein.     

Episome-mediated transfer of drug resistance in Enterobacteriaceae. IX. Recombination of an R factor with F

Watanabe, Tsutomu (Keio University, Tokyo, Japan), and Chizuko Ogata. Episome-mediated transfer of drug resistance in Enterobacteriaceae. IX. Recombination of an R factor with F. J. Bacteriol. 91:43-50. 1966.-R factors can be transduced in Salmonella typhimurium with phage P-22, and a majority of the drug-resistant transductants are unable to transfer their drug resistance by cell-to-cell contact, as we have previously reported. Several exceptional types of transductants of S. typhimurium, with the markers of resistance to sulfonamide, streptomycin, and chloramphenicol, were recently obtained by transduction with phage P-22 of a four-drug-resistance R factor carrying the markers of resistance to sulfonamide, streptomycin, chloramphenicol, and tetracycline. They were exceptional in that they had low conjugal transferability of their drug resistance. When one of these exceptional transductants (38R) was transferred to an F(+) strain of Escherichia coli K-12, 38R acquired high transferability in its further transfer. This high transferability was found to be due to the recombination of 38R with F. Transductant 38R was of the fi(+) (fi = fertility inhibition) type, and did not show superinfection immunity against fi(+) and fi(-) R factors. The recombinant 38R.F was genetically very stable and resistant to elimination with acridines. It did not show superinfection immunity against fi(+) and fi(-) R factors, but did show superinfection immunity against F. Further, 38R.F did not restrict a female-specific phage (W-31), unlike wild-type F. F(-) and R(-) segregants were isolated from this recombinant 38R.F, and these segregants exhibited genetic characteristics different from the original R, its transductant 38R, and wild-type F.     

Impaired Transduction of R213 and Its Recovery by a Homologous Resident R Factor

Transduction by Plkc of drug-resistance markers of the factor R213 was shown to occur at an exceptionally low frequency (at less than 10(-8) of the input phage), and they could not be transduced by P22. When the recipient cells carried a homologous R factor derived from R213, markers were transduced by Plkc at a normal frequency (at about 10(-5) to 10(-6) of the input phage). Derivative R factors, transducible by Plkc at a normal frequency but being transferred by conjugation at a frequency lower than that of the original R213, were obtained. This type of transductant often segregated R(-) cells. In addition, several transductants contained R factors which were transferred normally by conjugation but were transduced by Plkc at as low a frequency as the original R213. This type of transductant was an effective recipient for transduction by Plkc of R213 when apparently "cured" by acridine treatment. No such effective "cured" recipients were obtained from the transductants with derivatives of R213 transducible at a normal frequency. Two possible interpretations are presented: (i) R213 produces a bacteriocin-like substance upon transduction, or (ii) the genome size of R213 is too large for all of its determinants to be transduced.     

Physiological Modifications in the Production and Repair of Methyl Methane Sulfonate-Induced Breaks in the Deoxyribonucleic Acid of Escherichia coli K-12

The medium in which Rec(+) strains of Escherichia coli K-12 are grown affected their sensitivity to treatment with methyl methane sulfonate (MMS). Rec(+) cells grown to the stationary phase in glucose-enriched nutrient broth (GNB) were more resistant to MMS than cells grown in nutrient broth (NB). The repair of MMS-induced breaks (or alkali-labile bonds) in the deoxyribonucleic acid (DNA) from E. coli K-12 strains AB1157, AB1886 uvrA6, and SR111 recA13 recB21 grown in GNB and NB media was examined by means of alkaline sucrose gradient centrifugation. It appeared that essentially all of the repair of breaks that occurred, as evidenced by an increase in "molecular weight," took place within 10 min after treatment with MMS under our conditions. Cell survival was highest in cells for which the size of the DNA after the post-treatment incubation was the largest. The largest DNA after post-treatment incubation was found in Rec(+) cells grown in GNB medium. The results suggest that these cells may have an enhanced capacity for repairing breaks in DNA.     

Comparisons of F Factors and R Factors: Existence of Independent Regulation Groups in F Factors

The similarity of sex pili mediated by F factors and R(fi(+)) factors and the ability of R(fi(+)) factors to control by repression the functioning of pilus genes encoded by the F factor suggested that F factors and R(fi(+)) factors are closely related. Further comparisons of the episomal properties of F factors and R(fi(+)) factors, however, indicated many differences. F factors contain information for a restriction system for phages phiII and T7. Cells containing R factors are sensitive to these phages. Furthermore, R(fi(+)) factors do not repress the F factor phiII restriction system in cells containing both an R(fi(+)) factor and an F factor. R factors and F factors are heteroimmune episomes. In addition, an R(fi(+)) factor in cells containing both an R factor and an F factor does not fully repress the expression of F-factor immunity to an incoming second F factor. R-factor and F-factor replication systems are not identical. Wild-type F-factor replication genes will complement the mutant F(ts114)lac(+) replication genes in cells containing two F factors. The F(ts114)lac(+) episome is retained when these cells are grown at 42 C; however, cells containing an R(fi(+)) factor and F(ts114)lac(+) lose the F(ts114)lac(+) when grown at 42 C, at the same rate as cells containing only the F(ts114)lac(+). The replication system of the R(fi(+)) factor will not complement the mutant F(ts114)lac(+) replication system.     

Physiological Streptomycin Resistance in a Multiauxotroph of Escherichia coli Strain 15 T

Escherichia coli strain WWU was found to be moderately resistant to streptomycin when grown in a minimal medium, although the strain was sensitive if grown in nutrient broth. Transfer experiments showed that cells grown in minimal medium retain the resistant state for a period of time after dilution into nutrient broth; and conversely, sensitive cells grown in nutrient broth were sensitive after dilution into minimal medium for a period of time. The kinetics of transition from resistant to sensitive and from sensitive to resistant were observed, and kinetics of ³H-dihydrostreptomycin accumulation by resistant and sensitive cells were compared. The data suggested that cells grown in minimal medium were physiologically resistant because they accumulated streptomycin poorly. Inactivation per incorporated antibiotic molecule was the same in resistant and sensitive cells.     

Acriflavine Uptake and Resistance in Serratia marcescens Cells and Spheroplasts

Acriflavine uptake and resistance were investigated in red, sensitive Serratia marcescens cells and in orange, resistant mutant cells and their respective spheroplasts. Acriflavine-sensitive cells bound more acriflavine than acriflavine-resistant cells. Spheroplasts from sensitive and resistant cells were both resistant to and bound similar amounts of acriflavine. Sensitive cells were resistant to acriflavine in medium supplemented with 0.01 M MgSO(4) and 0.5 M sucrose. In the presence of 0.01 M MgSO(4) and 0.5 M sucrose, acriflavine binding by sensitive cells was reduced to the level of binding by resistant cells. Inhibition of metabolism by carbon starvation, chloramphenicol, As(2)O(3), nitrosoguanidine, and bromouracil did not affect the uptake of acriflavine by sensitive and resistant cells. Rapid temperature changes did not alter the acriflavine-binding capacity of the cells, and no temperature dependence of acriflavine uptake or release was observed at 0 and 30 C. Acriflavine uptake by both sensitive and resistant cells increased with increase in pH from 5.7 to 8.0. The logarithm of acriflavine uptake was a linear function of the logarithm of the acriflavine concentration in the binding medium.     

Cell fusion between L-forms and protoplasts of Staphylococcus aureus

Mixtures of various combinations of Lysostaphin protoplasts and stable L-forms of Staphylococcus aureus, which have different markers for drug resistance, were treated with polyethylene glycol (PEG) to examine the development of doubly resistant fusion products (fusants). To recover doubly resistant colonies as L-forms, they were incubated in 4.5% NaCl-brain heart infusion (BHI) broth containing penicillin G (PCG) for enrichment culture and cultured in PCG-4.5% NaCl-BHI agar medium (method 1), while to recover doubly resistant fusants as L-forms and coccal forms, they were grown on reversion medium (R medium) which causes reversion of protoplasts or fusants to parent type cells, and then cultured on assay media, i.e., R medium, BHI agar medium or PCG-4.5% NaCl-BHI agar medium (method 2). Under both experimental conditions, doubly resistant fusants developed as L-form cells by PEG treatment of pairs of protoplasts carrying the chloramphenicol (CP)-resistance plasmid and L-forms having chromosomal resistance to streptomycin (SM). In the reverse combinations, i.e., protoplasts showing chromosomal SM-resistance and L-form cells carrying the CP-resistance plasmid, the first method gave no doubly resistant colonies. By the second method, without enrichment culture on R medium, the latter combination gave doubly resistant fusants as L-form, coccal-type and mixed-type colonial forms, while when the PEG-treated mixture was enriched on R medium, fusants were obtained exclusively as the coccal type on either R medium or BHI agar assay medium. Neither of the methods yielded colonies of doubly resistant fusants on PEG-treatment of pairs of protoplasts and L-forms both of which were chromosomal, but with different drug resistances. These results show that PEG-induced cell fusion between protoplasts and L-forms of S. aureus, unlike the fusion between protoplasts or between L-forms, resulted in transfer of the drug resistance controlled by the plasmid to the fusion products. The fusants obtained were L-forms in method 1, and coccal type in the method 2.     

New Type of R Factors Incapable of Inactivating Chloramphenicol

Four R factors conferring chloramphenicol (CM) resistance were isolated from Escherichia coli strains of clinical origin. Strains carrying the factors were found to be incapable of inactivating the drug in the presence of acetyl coenzyme A. E. coli W3630 carrying R(70), one of these factors, became sensitive to CM after treatment with glycine, indicating that the spheroplasts of W3630 R(70) (+) were sensitive to the drug and suggesting that the cell membrane is important for CM resistance. The observation that cell-free protein synthesis in W3630 R(70) (+) was inhibited by CM is also compatible with a decrease in permeability. CM resistance in W3630 R(70) (+) appeared to be inducible, because (i) preincubation with subinhibitory concentrations of CM prevented the prolonged lag noted for growth in the presence of 25 mug of CM per ml, and (ii) the preincubation effect was lost after overnight growth in CM-free medium. By contrast, E. coli W3630 cml(+), in which the resistance determinant is integrated into the chromosome, was capable of rapid inactivation of CM. E. coli W3630 cml(+) R(70) (+), which contains the proposed permeability determinant (episomal) as well as levels of the inactivating enzyme (chromosomal) that are comparable with W3630 cml(+), was capable of brief inactivation of CM when inoculated into drug-containing medium. The absence of continued inactivation on more prolonged incubation favors the hypothesis that the R(70) factor inhibited further penetration of CM and that this property possesses the characteristics of induction.     

Sensitivity of Escherichia coli cells to seawater closely depends on their growth stage.

Sensitivity of Escherichia coli cells in seawater, considered in terms of culturability loss, was examined after different growth periods in a mineral medium supplemented with glucose (M9) at 37 degrees C under aerobic or anaerobic conditions. Their sensitivity varied considerably during the different growth phases and differed when cells were grown under aerobic or anaerobic conditions. Sensitivity of aerobic cells rapidly increased during the lag phase, then decreased during the exponential phase and became minimal during the stationary phase. Coliforms isolated from human faeces showed a similar sensitivity after incubation in wastewater at 37 degrees C for 3 h. The sensitivity phase was completely eliminated when cells were incubated with chloramphenicol. Variation of sensitivity in anaerobic cells according to their growth phase was comparable with that found for aerobic cells which had been left in seawater for a long period (6 d). However, for shorter periods in this medium (1-2 d), cells grown until the mid-exponential phase remained resistant to seawater. During the second half of the growth phase, they were as sensitive as aerobic cells at lag phase. Escherichia coli cells grown under anaerobic conditions, such as found in the intestine, progressively adapt to aerobic conditions after their transfer into aerated seawater and their sensitivity to seawater increases. On a practical level, these observations show that it is necessary to control accurately the age of cells before inoculation in seawater microcosms to conserve a comparative value in results. The importance of this factor is vital as all variations in sensitivity of cells to seawater according to their prior growth phase proved to be logarithmic functions of time.     

Occurrence of Chloramphenicol-acetylating Enzymes in Various Gram-negative Bacilli

The occurrence of a chloramphenicol-acetylating enzyme, similar to that found in Escherichia coli, carrying an R factor was investigated in various gram-negative bacilli. The acetylated products of chloramphenicol were identified by chromatography and quantitatively assayed after benzene extraction. The investigated strains were of the Salmonella-Arizona group, the Klebsiella-Aerobacter group, Serratia marcescens, the Proteus group, and Pseudomonas aeruginosa, most of which were isolated from 1947 to 1957. Both chloramphenicol-sensitive and -resistant strains were included, but none of them was able to transfer chloramphenicol resistance by conjugation. In the Proteus group, a significant level of a chloramphenicol-acetylating enzyme was found in most strains, whether they were sensitive or resistant to chloramphenicol; the resistant strains showed higher levels of the enzyme. Some chloramphenicol-sensitive strains lacked this enzyme. Only the sensitive strains containing the enzyme could easily produce chloramphenicol-resistant mutants with higher enzyme activity. Thus, the chloramphenicol resistance of this group can be reasonably explained on the basis of the chloramphenicol-acetylating enzyme. All of the Pseudomonas aeruginosa strains were resistant to chloramphenicol, and most strains showed low levels of the enzyme (which, however, did not appear sufficient to explain their resistance). All of the strains of the other groups (except one strain of Enterobacter cloacae) lacked the enzyme, although most strains of the Klebsiella-Aerobacter group and of S. marcescens were resistant to chloramphenicol. With respect to the origin of the resistance gene of the R factor, it is noteworthy that the strains of Proteus mirabilis isolated in 1947 possessed this enzyme before the discovery of chloramphenicol.     

Environmentally induced differential amplification of mitochondrial populations.

Resistance to the drug rutamycin, an inhibitor of mitochondrial ATPase, has been shown to be cytoplasmically inherited in a mouse fibroblast line (TL) on fusion of the cytoplast (enTL) with a nucleated recipient A9 [Lichtor & Getz (1978) Proc. Natl. Acad. Sci. U.S.A. 75, 324-328]. The cytoplasmic hybrid (cybrid) so formed may be readily grown in the presence [CY(+)] or absence [CY(-)] of rutamycin. The ATPase of TL mitochondria is similarly resistant to rutamycin whether grown in the presence or absence of antibiotic. The ATPase of CY(+) mitochondria is resistant to rutamycin, but CY(-) mitochondrial ATPase is sensitive to rutamycin. Nevertheless, CY(-) can be readily grown in rutamycin after a brief lag. The pH optima of mitochondrial ATPase are 8.0 for A9 and CY(-) cells and 7.5 for TL cells, whereas the pH optimum for CY(+) spans the optima of A9 and TL. The TL mitochondrial NADH-cytochrome c reductase is resistant to rotenone, whereas that of A9 mitochondria is sensitive to this agent. CY(-) and CY(+) mitochondria are sensitive and resistant respectively to rotenone. Growth of cybrids in rutamycin for 2 weeks results in a 2-3-fold increase in mitochondrial mass, measured on the basis of electron microscopic morphometry, mitochondrial membrane enzyme assays, mass of cardiolipin, and quantification of mitochondrial DNA. These data suggest that the cybrid harbours two populations of mitochondria and that the proportions of the two populations dramatically influence morphology, growth and mitochondrial phenotype in the cybrid. Selective pressure appears to induce these changes through the differential amplification of mitochondria.     

Prevention of the emergence of drug resistance in bacteria by acridines, phenothiazines, and dibenzocycloheptenes

It has been found that, like Atabrine, the phenothiazine tranquilizers promazine, chlorpromazine, promethazine, levopromethazine, and Stelazine; the antidepressants (dibenz-azepine and dibenzocycloheptene derivatives) Tofranil, Pertofrane, cyclobenzaprine, Elavil, protriptyline, and 3-chlorodibenzocycloheptene; and the acridine derivatives acridine orange, acriflavin, SKF no. 16214-A2, SKF no. 13231-A2, SKF no. 9200, and SKF no. 9836 are all to a greater or lesser extent than Atabrine, effective in preventing the emergence of resistant strains of Staphylococcus aureus and Escherichia coli in the presence of streptomycin, sulfathiazole, or chloramphenicol. The antimalarials chloroquine and hydroxychloroquine were also studied and found to be ineffective. The medical significance of these findings is discussed, as well as the effect of the structural variations of these compounds on their relative activities.     

Microcyst Germination in Myxococcus xanthus

Germination of glycerol-prepared microcysts of Myxococcus xanthus was studied. The sequence of morphological events during germination resembled that of germinating fruiting body-microcysts. The turbidity drop of a culture of germinating microcysts could be described by McCormick's formula derived for germinating Bacillus spores. The rate of uptake of labeled glycine and acetate did not change during germination. Temperature, aeration, and pH optima for germination were the same as for vegetative cell growth. Germination was induced by protein hydrolysates and the individual amino acids glycine, alanine, valine, aspartic acid, and glutamic acid. A number of organic compounds, including sugars, alcohols, aldehydes, ketones, organic acids, and chelating agents, did not induce germination. The inorganic ions HPO(4) (2-), Mg(++), Ca(++), and NH(4) (+) induced germination, although ionic strength was not a factor. Microcysts incubated in distilled water at concentrations greater than about 10(9) cells/ml germinated; supernatant fluid from such suspensions (germination factor) induced germination of less concentrated suspensions. The activity of germination factor was resistant to boiling, but was lost on charring and dialysis. Germination of microcysts and growth of vegetative cells was equally sensitive to a variety of metabolic inhibitors, including penicillin and chloramphenicol. Germination was more resistant than vegetative growth to inhibition by antibiotics of the streptomycin family and by actinomycin D.     

R Factor Elimination During Thymine Starvation: Effects of Inhibition of Protein Synthesis and Readdition of Thymine

R factor 1818 is shown to be eliminated from a thymineless strain of Escherichia coli J6-2 (R-1818) during thymine starvation. Readdition of thymine to the starved cultures produces a partial recovery in viable count but does not affect the proportion of R(-) cells. The R factor is not cured from exponential- or stationary-phase cultures which are starved of required amino acids as well as thymine, nor from cells which are deprived of thymine in the presence of chloramphenicol. However, in both of these cases, the extent of thymineless death is reduced. It is suggested that protein synthesis is a requirement for R-1818 elimination, and the possible nature of this protein is discussed.     

Expression of sodium-linked nucleoside transport activity in monolayer cultures of IEC-6 intestinal epithelial cells

Mature, confluent monolayer cultures of IEC-6 rat intestinal epithelial cells in conventional growth media express both Na(+)-linked, concentrative nucleoside transport (NT) activity and equilibrative, inhibitor-sensitive NT activity, but do not show morphologic differentiation. Na(+)-dependent fluxes of Ado and formycin B were minor in early subconfluent IEC-6 monolayers, but increased severalfold to become the major component of influx of these agents in confluent monolayers grown in medium containing Nu-Serum, a commercial medium supplement with a low serum content. In monolayers cultured in medium with fetal bovine serum, cell proliferation rates were similar to those in medium supplemented with Nu-Serum, but expression of Na(+)-linked NT activity was 6-8-fold lower than in monolayers grown in the latter medium. Inclusion of hydrocortisone in growth medium with Nu-Serum caused a 2-fold increase in the expression of Na(+)-linked NT activity. Experiments in which components of medium supplementation were withheld showed that insulin and epidermal growth factor were important in expression of the Na(+)-linked NT activity. Because the Na(+)-linked NT system has a brush border location in fresh intestinal epithelium, it is concluded that the regulated expression of this activity in the IEC-6 monolayers is a differentiative change.     

Transferable Drug Resistance Among Enterobacteriaceae Isolated from Cases of Neonatal Diarrhea in Calves and Piglets

Fecal specimens were collected on 22 different Nebraska ranches and at the Department of Veterinary Science from young calves and pigs with neonatal diarrhea. Enterobacteriaceae isolated from these fecal specimens were screened for resistance to tetracycline, streptomycin, sulfamethizole, kanamycin, chloramphenicol, colistin, nitrofurantoin, and nalidixic acid. Of the 92 strains studied, 57 were resistant to one or more of these antimicrobial agents. Resistant strains were obtained from all herds involved in the study. The two most common resistance patterns were tetracycline streptomycin sulfamethizole (22 of 57) and tetracycline (13 of 57). None of the strains were resistant to chloramphenicol, colistin, nitrofurantoin, or nalidixic acid. The 57 resistant strains were studied to determine whether the resistance was transferable. Forty-three of the 57 resistant strains could transfer part or all of their resistance pattern to a drug-sensitive recipient. The 43 R(+) strains were obtained from 17 of the 23 herds studied. Considerable variation was observed between different R(+) strains in the frequency of transfer of resistance to a particular drug. In addition, variation in the frequency of transfer of different resistance determinants in individual R(+) strains was noted.