Drug Resistance of Enteric Bacteria

Drug resistance of 3,000 Shigella strains isolated in 1965 were investigated. These strains originated from 10 City Hospitals and 4 Prefectural Health Centers, which are located in different parts of Japan. One hundred and seventy strains which were resistant to 4 drugs, chloramphenicol (CM), tetracycline (TC), dihydrostreptomycin (SM), and sulfanilamide (SA), were selected at random from these stock cultures in this laboratory and the distribution of R factors in these isolates was examined. It was found that the strains all harbored R factors which were capable of transferring drug resistance by usual conjugal process. Among the strains carrying R factors, 85 per cent harbored a single type of R factor and 15 per cent carried two types of R factor in a cell. The latter is called the hetero-R state. Among the strains in the hetero-R state, isolation of strains harboring both R (SM.SA) and R (TC.CM.SM.SA) factors was most frequent. It was found that 25 R (SM.SA) factors isolated from strains in hetero-R had the genetic determinant iR^?, while most of the R (TC.CM.SM.SA) factors isolated from natural sources were iR⁺. When two types of R factor, R (SM.SA) and R (TC.CM.SM.SA) derived from the same host cells, were brought together in a host cell by superinfection with both factors, they were found to exist stably in a host bacterium. These results confirmed the stable existence of both factors in Shigella strains isolated from dysenteric patients.     

Drug Resistance of Enteric Bacteria VIII. Chromosomal Location of Nontransferable R Factor in Escherichia coli

The R₂₁(TC) factor, obtained by transduction of the R₁₀(TC.CM.SM.SA) factor with phage ε to group E Salmonella, is not transferable by the normal conjugal process. However, when R₂₁(TC)⁺ transductants are infected with the F₁₃ factor, the nontransferable R₂₁(TC) factor acquires transmissibility by conjugation. R₂₁(TC)⁺ conjugants of Escherichia coli K-12, to which only the R₂₁(TC) factor was transmitted by cell-to-cell contact from an F′ R⁺ donor, were still unable to transfer their R₂₁(TC) factor by conjugation. In crosses between Hfr and F⁻E. coli K-12 strains containing R₂₁(TC), the gene responsible for tetracycline resistance was located on the E. coli K-12 chromosome between lac and pro, near lac.     

Drug Resistance of Staphylococci

It was reported that resistance to tetracycline (TC) in some staphylococcal strains was lost irreversibly without loss of resistance to other drugs when cultured at high temperature, and that the determinant for TC resistance exists on a plasmid. According to the transductional analysis of TC resistance in Staphylococcus aureus E169 it was found that the genes which govern resistance to tetracycline and streptomycin are located close together on a single genetic element. When TC resistance in MS146, one of our stock cultures, was transduced to E169S which had lost TC resistance, TC resistance in transductants was found to be unstable at elevated temperatures. By contrast, TC resistance in transductants MS353 TC^r, to which TC resistance was transduced from E169, was indicated to be stable even when cultured at high temperature. From these results, it is strongly suggested that instability of TC resistance in E169 is not accounted for by the genetic properties of the genes which govern TC resistance but those of host cell (E169) itself.     

Drug Resistance of Enteric Bacteria

A nontransferable R₂₁ (TC) factor was obtained by transduction of R₁₀ (TC.CM.SM.SA) with phage epsilon in group E Salmonella. The R₂₁ (TC) factor acquired transmissibility by the normal conjugal process when group E Salmonella strains harboring R₂₁ (TC) factor were infected with wild-type F or R₁₆ (CM) factor. This transmissibility at high frequency was accounted for by the formation of the recombinant F TC and R₁₀ (CM) TC factors. The F TC and R₁₆ (CM) TC factors were genetically the same as the original F and R₁₆ (CM) factors, except for the ability to confer TC resistance. In the transduction of F TC factor with phage P1, a dF TC (d: defective) factor was obtained that was defective in many F properties, such as the ability to introduce host chromosome and produce male substance, but was capable of transducing TC resistance (dF TC-infection) at low frequency.     

Unstable Mutants of R Factor

Thirty mutants sensitive to tetracycline were obtained from an R100 factor capable of conferring resistance to tetracycline (TC), chloramphenicol (CM), streptomycin (SM) and sulfanilamide (SA). Among the TC sensitive mutants, three showed a high frequency of spontaneous loss from host strains. The genetic loci governing the stability of R factor in host bacteria were denoted as stb. The stb^– R factors have lost many of the properties of a wild type R factor, such as, the capability to sexually transfer drug resistance and host chromosome, to confer superinfection immunity and to inhibit F function. All of these properties did not revert to a wild type phenotype, suggesting that these mutations are deletions including genetic determinants governing both TC resistance and stability of R factor. Recombinational analysis between stb^– and stb⁺ R factors indicated that crossovers between the stb loci and those governing CM (or SM.SA) resistance took place at high frequency. No crossovers were detected between stb loci and those governing TC resistance, indicating that the stb loci are linked closely to the loci governing TC resistance.     

Transduction of Methicillin Resistance in Staphylococcus aureus Dependent on an Unusual Specificity of the Recipient Strain

Resistance to methicillin was transduced by phage 80 or 53 from two naturally occurring methicillin-resistant strains of Staphylococcus aureus to methicillin-susceptible recipient strains at frequencies of 10⁻⁷ to 10⁻⁹. Ultraviolet irradiation of transducing phage and posttransductional incubation at 30 C were essential for useful frequencies of transduction. Effectiveness as a recipient for this transduction was highly specific. Strain NCTC 8325 (PS47) in its native state was an ineffective recipient but became effective after it had received by transduction one of several penicillinase plasmids. This acquired effectiveness was retained in most cases after elimination of the plasmid by ethidium bromide treatment. Like the donor strain, the progeny were heterogeneous in the degree of their resistance to methicillin, which was expressed by a higher proportion of cells as the temperature of incubation was lowered from 37 to 30 C. Separate transductants varied widely in the degree of resistance acquired by transduction. Methicillin resistance was stable in the donor and transductant strains. We favored the interpretation that methicillin resistance in our strains was determined by a single chromosomal gene, although the possibility that it was determined by two or more closely linked genes could not be excluded.     

Drug resistance and conjugative R plasmids in fecal Escherichia coli strains isolated from healthy younger animals (chickens, piglets, calves) and children

A total of 11,777 Escherichia coli strains were isolated from 90 chickens, 103 piglets, 96 calves, and 104 children in 1979 in Gunma Prefecture and tested for drug resistance and the presence of conjugative R plasmids. The percentages of individuals that excreted drug-resistant strains were: chickens, 100%; piglets, 99%; calves, 100%; and children, 64%. The frequency of isolation of drug-resistant strains among the total isolates was: chickens, 98%; piglets, 93%; calves, 94%; and children, 41%. Frequency of isolation of R plasmids among the strains tested was: chickens, 48%; piglets, 33%; calves, 38%; and children, 10%. Resistance patterns of the strains isolated most frequently among the four groups were tetracycline (TC), sulfonamides (SA) in single resistance, TC.SA in double resistance, TC.streptomycin (SM).SA in triple resistance and TC.SM.SA. kanamycin (KM) in quadruple resistance. R plasmids were isolated frequently from animals (over 33%) but infrequently from children (about 10%). The high frequency of isolation of drug-resistant strains and R plasmids from animals was caused by the heavy use of chemicals in the period of growth of younger animals.     

R Factor-Mediated Resistance to Aminoglycoside Antibiotics in Pseudomonas aeruginosa

Conjugal transferability of drug resistance was examined, in eleven Pseudomonas aeruginosa strains which were isolated in Frankfurt. Four R factors were demonstrated from three strains using P. aeruginosa as recipients but they were nontransferable to Escherichia coli K12. Two R factors, i.e., R_ms146 and R_ms147, mediated resistances to tetracycline (TC), streptomycin (SM), sulfanilamide (SA), kanamycin (KM), lividomycin (LV), gentamicin C complex (GM) and 3′,4′-dideoxykanamycin B (DKB). They mediated the formation of aminoglycoside-inactivating enzymes, i.e., SM phosphotransferase, SM adenylyltransferase, KM and LV phosphotransferase 1, and GM and DKB 6′-N-acetyltransferase. TC resistance conferred by these R factors was due to impermeability of the drug. P. aeruginosa Ps 142 carried two kinds of R factor in one cell, R_ms148 (SM) and R_ms149 (SM·SA·GM·CPC) (CPC, carbenicillin). R_ms148 (SM) was transferable at a high frequency of 10^–1 and mediated the formation of SM phosphotransferase. R_ms149 mediated the formation of drug-inactivating enzymes, i.e., GM 3-N-acetyltransferase and β-lactamase, but did not inactivate SM. SM resistance was probably due to impermeability of the drug.     

Recombination Between a Thermosensitive Kanamycin Resistance Factor and a Nonthermosensitive Multiple-Drug Resistance Factor

The thermosensitive kanamycin (KM) resistance factor, R(KM)(t), and a nonthermosensitive multiple-drug resistance factor, R(100), were simultaneously introduced into Escherichia coli and Salmonella typhimurium. The temperature sensitivity of both R factors remained unchanged as long as they replicated independently. Under certain conditions, however, a new thermosensitive R factor harboring resistance markers for kanamycin, streptomycin (SM), and sulfanilamide (SA) was obtained by recombination between the R(KM)(t) and R(100) factors. R factors carrying resistance markers for KM and SA, or for SM and SA, were obtained from the recombinant R(KM SA SM)(t) by spontaneous segregation. Though the R(100) factor has been known as an fi(+) (positive for F-mediated fertility inhibition of its host) type and it does not restrict any coexisting phages, the thermosensitive recombinants of R(100) with R(KM)(t) and their segregants were found to be fi(-) and to restrict the replication of all T-even phages, as does the R(KM)(t) factor. Double infection immunity was not observed between the R(KM)(t) and R(100) factors.     

Drug resistance of enteric bacteria. V. High frequency of transduction of R factors with bacteriophage epsilon

Kameda, Mitsuo (Gunma University, Maebashi, Japan), Kenji Harada, Mitsue Suzuki, and Susumu Mitsuhashi. Drug resistance of enteric bacteria. V. High frequency of transduction of R factors with bacteriophage epsilon. J. Bacteriol. 90:1174-1181. 1965.-In the transduction of R factors with phage epsilon(15), a lysate capable of transducing the markers for (TC) or (CM.SM.SA) resistance at high frequency was obtained. The transducing agent is a defective element called epsilon(15)dR(23) which lacks certain functions of phage epsilon(15). After lysogenization with normal epsilon(15) phage and ultraviolet (UV) induction, strains carrying the epsilon(15)dR(23) element produce lysates which have a high frequency of transduction (HFT) on group E(1)Salmonella. Lytic lysates prepared on phage epsilon(15) sensitive strain with the epsilon(15)dR(23) element have a low frequency of transduction (LFT). Lytic growth of phage epsilon(34) on an epsilon(15)dR(23) strain or UV induction of an epsilon(34) lysogenic strain containing epsilon(15)dR(23) results in LFT lysates on group E(2)Salmonella. On UV induction, group E(2)Salmonella (epsilon(15) lysogens) with the epsilon(15)dR(23) element give lysates which are HFT on group E(1)Salmonella but are LFT when tested on group E(2)Salmonella. In all instances, the production of drug-resistant transductants requires infection of the cell with only a single epsilon(15)dR(23) element. It appears that the resistance region of the R factor has replaced that portion of phage genome which is essential for vegetative replication and superinfection immunity. The epsilon(15)dR(23) element does not contain the genetic determinants of the R factor responsible for transmissibility, inhibition of F mating, and interference between two R factors.     

Recent advances in systemic acquired resistance research — a review

Little is known about the signal transduction events that lead to the establishment of the broad-spectrum, inducible plant immunity called systemic acquired resistance (SAR). Salicylic acid (SA) accumulation has been shown to be essential for the expression of SAR and plays a key role in SAR signaling. Hydrogen peroxide has been proposed to serve as a second messenger of SA. However, our results do not support such a role in the establishment of SAR. Further elucidation of SAR signal transduction has been facilitated by the identification and characterization of mutants. The lesions simulating disease (lsd) resistance response mutant class exhibits spontaneous lesions similar to those that occur during the hypersensitive response. Interestingly, some lsd mutants lose their lesioned phenotype when SA accumulation is prevented by expression of the nahG gene (encoding salicylate hydroxylase), thereby providing evidence for a feedback loop in SAR signal transduction. Characterization of a mutant non-responsive to SAR activator treatments has provided additional evidence for common signaling components between SAR and gene-for-gene resistance.     

Drug resistance and R plasmids in Escherichia coli strains isolated from broilers

In 1978, 1,021 Escherichia coli strains were isolated from 105 field broilers (F) and 1,058 strains from 106 broilers in a zootechnical experiment station (Z), and their drug-resistance patterns and the presence of conjugative R plasmids were compared. The resistance markers examined were tetracycline (TC), chloramphenicol (CM), streptomycin (SM), sulfonamides (SA), kanamycin (KM), and ampicillin (APC). The populations of individuals that excreted resistant strains were 100% in F and 58% in Z. Frequencies of isolation of drug-resistant strains among the total isolates were 93% in F and 36% in Z, indicating that the resistant strains are a rather high proportion of the intestinal flora in F but are slightly less prevalent in Z. The resistance pattern to (TC.SM.SA.KM) was seen at the highest frequency in both groups. Conjugative R plasmids were demonstrated more frequently in field broilers (F). The results reflect the wide use of antibiotics in the livestock industry, resulting in the appearance of drug-resistant strains mostly due to the presence of R plasmids.     

Interspecies transduction of plasmids among Bacillus anthracis, B. cereus, and B. thuringiensis

Bacteriophage CP-51, a generalized transducing phage for Bacillus anthracis, B. cereus, and B. thuringiensis, mediates transduction of plasmid DNA. B. cereus GP7 harbors the 2.8-megadalton multicopy tetracycline resistance plasmid, pBC16. B. thuringiensis 4D11A carries pC194, the 1.8-megadalton multicopy chloramphenicol resistance plasmid. When phage CP-51 was propagated on these strains, it transferred the plasmid-encoded antibiotic resistances to the nonvirulent Weybridge (Sterne) strain of B. anthracis, to B. cereus 569, and to strains of several B. thuringiensis subspecies. The frequency of transfer was as high as 10(-5) transductants per PFU. Tetracycline-resistant and chloramphenicol-resistant transductants contained newly acquired plasmid DNA having the same molecular weight as that contained in the donor strain. Antibiotic-resistant transductants derived from any of the three species were effective donors of plasmids to recipients from all three species.     

Gene Transfer by Transduction in the Marine Environment

To determine the potential for bacteriophage-mediated gene transfer in the marine environment, we established transduction systems by using marine phage host isolates. Plasmid pQSR50, which contains transposon Tn5 and encodes kanamycin and streptomycin resistance, was used in plasmid transduction assays. Both marine bacterial isolates and concentrated natural bacterial communities were used as recipients in transduction studies. Transductants were detected by a gene probe complementary to the neomycin phosphotransferase (nptII) gene in Tn5. The transduction frequencies ranged from 1.33 × 10⁻⁷ to 5.13 × 10⁻⁹ transductants/PFU in studies performed with the bacterial isolates. With the mixed bacterial communities, putative transductants were detected in two of the six experiments performed. These putative transductants were confirmed and separated from indigenous antibiotic-resistant bacteria by colony hybridization probed with the nptII probe and by PCR amplification performed with two sets of primers specific for pQSR50. The frequencies of plasmid transduction in the mixed bacterial communities ranged from 1.58 × 10⁻⁸ to 3.7 × 10⁻⁸ transductants/PFU. Estimates of the transduction rate obtained by using a numerical model suggested that up to 1.3 × 10¹⁴ transduction events per year could occur in the Tampa Bay Estuary. The results of this study suggest that transduction could be an important mechanism for horizontal gene transfer in the marine environment.     

Tandem duplications of the histidine operon observed following generalized transduction in Salmonella typhimurium

Unstable merodiploid transductants may be observed among the progeny of certain generalized transductional crosses between complementing mutations in the histidine operon of Salmonella typhimurium. In the presence of a functional recombination system, these transductants are unstable and they segregate His^? clones of both parental genotypes. The properties of these His⁺ transductants suggest that they contain tandem duplications of a region of DNA which includes the histidine operon, such that each copy of the duplication contains one of the two complementing mutations involved in the transduction. Transductional duplications have been observed from 14 pairs of his mutations, but only with complementing pairs of parental mutations. The length of duplicated material may be quite large: two duplications were found to include genetic markers ten minutes removed from the histidine operon on the Salmonella chromosomal map.These transductants appear to arise in a subpopulation of recipient cells which contain pre-existing tandem duplications of the histidine operon. As much as 0.01 to 0.1% of the cell population appears to be tandemly duplicated for a chromosomal region which includes the histidine operon.     

Studies of Drug Resistance and R Factors in Bacteria from Pond-Cultured Salmonids

Considerable fractions of gram-negative bacilli, Aeromonas liquefaciens, A. salmonicida, Pseudomonas, Hafnia and unidentified Enterobacteriaceae, isolated from the intestinal tracts of cultured Amago (Oncorhynchus rhodurus macrostomus) from 23 Amago-ponds and of Yamame (O. masou ishikawae) from one pond as well as the water of 3 ponds in Shiga, Gifu and Nagano Prefectures and Tokyo Metropolis in Japan were found to be multiple-drug-resistant. Of these drug-resistant strains, A. salmonicida and A. liquefaciens carried R factors at high frequencies and to be prevalent in many Amago ponds throughout Japan. These R factors had markers of resistance to SA, SA.TC, SA.SM.CM. All the R factors belonged to fi^– type.     

Salicylic Acid Interferes with Tobacco Mosaic Virus Replication via a Novel Salicylhydroxamic Acid-Sensitive Mechanism

Salicylic acid (SA) induces resistance to all plant pathogens, including bacteria, fungi, and viruses, but the mechanism by which SA engenders resistance to viruses is not known. Pretreatment of tobacco mosaic virus (TMV)-susceptible (nn genotype) tobacco tissue with SA reduced the levels of viral RNAs and viral coat protein accumulating after inoculation with TMV. Viral RNAs were not affected equally, suggesting that SA treatment interferes with TMV replication. Salicylhydroxamic acid (SHAM), an inhibitor of the mitochondrial alternative oxidase, antagonized both SA-induced resistance to TMV in nn genotype plants and SA-induced acquired resistance in resistant (NN genotype) tobacco. SHAM did not inhibit induction of the PR-1 pathogenesis-related protein or induction of resistance to Erwinia carotovora or Botrytis cinerea by SA. This indicates that SA induces resistance to TMV via a novel SHAM-sensitive signal transduction pathway (potentially involving alternative oxidase), which is distinct from that leading to resistance to bacteria and fungi.     

Detection of R+ Bacteria in Cultured Marine Fish,Yellowtails (Seriola quinqueradiata)

Many drug-resistant gram-negative bacilli were isolated from the intestinal tracts of yellowtails (Seriola quinqueradiata) cultured on farms in various parts of Kochi and Ehime Prefectures, Shikoku Island. They were Vibrio, Pseudomonas, Proteus, Citrobacter and some unidentified Enterobacteriaceae. Of these drug-resistant strains, Vibrio and Pseudomonas were found to carry R factors in high frequencies. These R factors had four types of resistance markers, SA, SA. CM, SM. CM. ABP. and SA. SM. CM. TC. All R factors were found to belong to the fi^– type. In contrast, only one drug-resistant gram-negative bacillus was detected in a cultured yellowtail on farms near Numazu City, Shizuoka Prefecture.     

Negative Regulation of Systemic Acquired Resistance by Replication Factor C Subunit3 in Arabidopsis

Systemic acquired resistance (SAR) is a plant immune response induced by local necrotizing pathogen infections. Expression of SAR in Arabidopsis (Arabidopsis thaliana) plants correlates with accumulation of salicylic acid (SA) and up-regulation of Pathogenesis-Related (PR) genes. SA is an essential and sufficient signal for SAR. In a genetic screen to search for negative regulators of PR gene expression and SAR, we found a new mutant that is hypersensitive to SA and exhibits enhanced induction of PR genes and resistance against the virulent oomycete Hyaloperonospora arabidopsidis Noco2. The enhanced pathogen resistance in the mutant is Nonexpressor of PR genes1 independent. The mutant gene was identified by map-based cloning, and it encodes a protein with high homology to Replication Factor C Subunit3 (RFC3) of yeast and other eukaryotes; thus, the mutant was named rfc3-1. rfc3-1 mutant plants are smaller than wild-type plants and have narrower leaves and petals. On the epidermis of true leaves, there are fewer cells in rfc3-1 compared with the wild type. Cell production rate is reduced in rfc3-1 mutant roots, indicating that the mutated RFC3 slows down cell proliferation. As Replication Factor C is involved in replication-coupled chromatin assembly, our data suggest that chromatin assembly and remodeling may play important roles in the negative control of PR gene expression and SAR.     

Central Role of Salicylic Acid in Resistance of Wheat Against <Emphasis Type="Italic">Fusarium graminearum</Emphasis>

Head blight caused by Fusarium graminearum (F. graminearum) is one of the major threats to wheat and barley around the world. The importance of this disease is due to a reduction in both grain yield and quality in infected plants. Currently, there is limited knowledge about the physiological mechanisms involved in plant resistance against this pathogen. To reveal the physiological mechanisms underlying the resistance to F. graminearum, spikes of resistant (Sumai3) and susceptible (Falat) wheat cultivars were analyzed 4 days after inoculation, as the first symptoms of pathogen infection appeared. F. graminearum inoculation resulted in a greater induction level and activity of salicylic acid (SA), callose, phenolic compounds, peroxidase, phenylalanine ammonia lyase (PAL), and polyphenol oxidase in resistant versus susceptible cultivars. Soil drench application to spikes of SA, 24 h before inoculation with F. graminearum alleviated Fusarium head blight symptoms in both resistant and susceptible cultivars. SA treated plants showed a significant increment in hydrogen peroxide (H₂O₂) production, lipid peroxidation, SA, and callose content. SA-induced H₂O₂ level seems to be related to increased superoxide dismutase and decreased catalase activities. In addition, real-time quantitative PCR analysis showed that SA pretreatment induced expression of PAL genes in both infected and non-infected head tissues of the susceptible and resistant cultivars. Our data showed that soil drench application of SA activates antioxidant defense responses and may subsequently induce systemic acquired resistance, which may contribute to the resistance against F. graminearum. These results provide novel insights about the physiological and molecular role of SA in plant resistance against hemi-biotrophic pathogen infection.