Molecular Specificities of R Factor-Determined Beta-Lactamases: Correlation with Plasmid Compatibility

Beta (beta)-lactamases determined by 29 ampicillin resistance plasmids could be divided into two types. One, TEM-type, was very uniform with respect to substrate specificity but heterogeneous in absolute levels of beta-lactamase activity. The TEM-type beta-lactamase was determined by R factors of compatibility groups FII, Ialpha, Iepsilon, N, C, A, T, W, P, L, and X, and by prophage phi Amp. The other type, characterized by the ability to hydrolyze oxacillin, was less common, showed lower absolute levels of activity, and was heterogeneous as regards substrate specificities. Oxacillin-hydrolyzing beta-lactamases were determined by R factors of compatibility groups FI, Ialpha, N, C, and O.     

Molecular Structure of an R Factor, Its Component Drug-Resistance Determinants and Transfer Factor

Plasmid DNA from Escherichia coli strains harboring drug resistance either of the infectious or noninfectious kind has been separated by CsCl centrifugation of crude cell lysates in the presence of ethidium bromide and examined by electron microscopy. Plasmid deoxyribonucleic acid (DNA) from an S(+) strain (which has the property of noninfectious streptomycin-sulfonamide resistance) consists of a monomolecular covalently closed circular species of 2.7 mum in contour length (5.6 x 10(6) atomic mass units; amu). DNA from a strain carrying a transfer factor, termed Delta, but no determinant for drug resistance, is a monomolecular covalently closed circular species of 29.3 mum in contour length (61 x 10(6) amu). DNA from either Delta(+)A(+) or Delta(+)S(+) strains, (which are respectively ampicillin or streptomycin-sulfonamide resistant, and can transfer this drug resistance), shows a bimodal distribution of molecules of contour lengths 2.7 mum and 29.3 mum, whereas DNA from a (Delta-T)(+) strain (showing infectious tetracycline resistance) contains only one species of molecule measuring 32.3 mum (67 x 10(6) amu). We conclude that ampicillin resistance is carried by a DNA molecule (the A determinant) of 2.7 mum, and streptomycin-sulfonamide resistance is carried by an independent molecule (the S determinant) of similar size. These molecules are not able to effect their own transfer, but can be transmitted to other cells due to the simultaneous presence of the transfer factor, Delta, which also constitutes an independent molecule, of size 29.3 mum. In general, there appears to be little recombination or integration of the A or S molecules into that of Delta, although a small proportion (5-10%) of recombinant molecules cannot be excluded. In contrast, the third drug-resistance determinant, that for tetracycline resistance (denoted as T), is integrated in the Delta molecule to form the composite structure Delta-T of size 32.3 mum, which determines infectious tetracycline resistance. The Delta(+)A(+) and Delta(+)S(+) strains are defined as harboring plasmid aggregates, and the (Delta-T)(+) strain is defined as carrying a plasmid cointegrate; the properties of all three strains are characteristic of strains harboring R factors. These results are compatible with the previously published genetic data. The number of Delta molecules per cell appears to be equal to the chromosomal number irrespective of growth phase, and this plasmid can thus be defined as stringently regulated in DNA replication. In contrast, S and A exist as multiple copies, probably in at least a 10-fold excess of chromosomal copy number. S and A can thus be defined as relaxed in the regulation of their DNA replication.     

Facilitation of the Transfer of R Factor by the Resident R Factor

Transfer of some R factors were shown to be facilitated by resident R factors. The sex factor itself may be responsible for this phenomenon.     

Molecular Nature of the Deoxyribonucleic Acid of a Thermosensitive R Factor, Rts1

The deoxyribonucleic acid of the thermosensitive R factor, Rts1, has been examined by the technique of sedimentation in alkaline sucrose, electron microscopy, and radiation target size. All these methods yielded a molecular weight of approximately 120 million for Rts1 deoxyribonucleic acid in Escherichia coli. Sedimentation analysis revealed that Rts1 deoxyribonucleic acid in Proteus mirabilis was also 120 million daltons. Rts1 did not segregate into E. coli minicells under the conditions where another smaller non-thermosensitive R factor could.     

Naturally Occurring R Factor, Derepressed for Pilus Synthesis, Belonging to the Same Compatibility Group as the Sex Factor F of Escherichia coli K-12

A naturally occurring R factor with constitutive pilus synthesis is described which resembles the sex factor F in compatibility and in restricting coliphage T7. Unlike F, it is not cured during growth with acridine orange. Results suggest that the R factor produces repressor of pilus synthesis, to which the operator is insensitive (i(+)o(c)). In this respect it differs from both the F factor (i(-)o(+)) and wild-type F-like R factors (i(+)o(+)).     

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.     

Nitrate Nonutilizing Mutants and Vegetative Compatibility Groups in Fusarium poae

Nitrate nonutilizing (nit) mutants were recovered from 24 isolates of Fusarium poae and used to force heterokaryons between these isolates and to determine vegetative compatibility. Between 30 and 90% of the mycelial blocks, cultured on medium containing chlorate, produced nit mutants. The amount of chlorate in the medium altered the frequency and spectrum of nit mutants recovered. Most of the mutants (63%) had lesions at a nitrate reductase structural locus (nit1). Another 30% were mutants at one or more loci that control the production of a molybdenum-containing cofactor necessary for nitrate reductase activity (NitM). A few (6%) of the mutations occurred in a regulatory gene specific for the nitrate reduction pathway (nit3). Pairings between nit1 and NitM mutants were made on minimal medium containing nitrate as the sole nitrogen source. A mutant grows thinly unless it forms a complementary heterokaryon upon contact with another mutant. Heterokaryon formation was indicated by dense growth where the two mutant colonies touched. The 24 isolates could be divided into 13 nonoverlapping vegetative compatibility groups, suggesting that asexual exchange of genetic information within F. poae is subject to significant limitations.     

R Factor Proteins Synthesized in Escherichia coli Minicells: Membrane-Associated R Factor Proteins

R factor proteins are synthesized in R factor-containing Escherichia coli minicells. Half of this protein remained associated with the minicell membrane upon lysis of the minicells. Over 90% of the membrane-associated protein was extracted by sodium lauryl sarcosinate, suggesting a location of these proteins in the inner membrane. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis of these membrane preparations demonstrated the presence of multiple peptides, including a prominent band with a molecular weight of 28,000 to 30,000. A polypeptide of similar size was seen in membrane preparations from minicells harboring R factors from five different compatibility types. This major R factor membrane peptide was seen with R factors repressed or derepressed for pilus synthesis, with and without antibiotic resistances. It was associated with R factor deoxyribonucleic acid in membrane-deoxyribonucleic acid complexes. Its possible role in R factor replication and/or transfer is being investigated.     

Genetic and Molecular Properties of an Infectious Antibiotic Resistance (R) Factor Isolated from Klebsiella

A Klebsiella strain of human origin that was resistant to ampicillin, chloramphenicol, kanamycin, neomycin, streptomycin, and tetracycline was found to have all of these resistances associated with a R factor and a satellite molecular species of deoxyribonucleic acid (DNA) with an average buoyant density of 1.710 in cesium chloride gradients. There was no evidence of the existence of DNA with other buoyant densities. The strain bears two separable mutations for chloramphenicol resistance, both of which are associated with the R factor (KR9). Exposure of the Klebsiella strain to acridine derivatives or to ethidium bromide (which was more efficient) resulted in partial losses of resistance accompanied by the disappearance of the satellite DNA peak or shifts in its density. The R factor and its component genes were conjugally transmitted across generic boundaries and maintained in new hosts with different efficiencies. The basis of this difference lies not only in the efficiency of conjugal transfer but also in the stability of the components after transfer. All of the resistance genes and the resistance transfer factor were cotransducible by phage Plkc from Escherichia coli. Partially resistant strains could be reconstituted to full resistance or to a recombined pattern of partial resistance by conjugation with donors having complementary resistance patterns. This recombination serves as an efficient mechanism for rescuing superinfecting genes that are otherwise intracellularly excluded. KR9 is an fi⁺ type of R factor which in the natural state does not appear to be as repressed in conjugal transfer as other R factors.     

R Factor Transmission In Vivo

Experimental infections were induced in weanling pigs orally both with nalidixic acid (NA)-sensitive and -resistant strains of Salmonella choleraesuis var. kunzendorf, designated RC221 and RC221NA, respectively. Prior to the time of infection, cultures of normal bacterial flora were isolated from swine fecal matter and screened for the presence of R factors. A majority of these bacterial isolates harbored transferable resistances. Both strains RC221 and RC221NA have been shown to be competent recipients in vitro of the R factors present in the normal intestinal flora. The property of NA resistance greatly facilitated recovery of the infecting organism. After infection, salmonellae from liver, lung, spleen, lymph node, intestine, and feces were screened for the presence of R factors. Transfer of drug resistance in vivo was a rare occurrence; however, if infected specimens, particularly intestinal, were incubated in nutrient broth prior to plating, R factor transfer occurred, presumably in the test tube. Changes in recipient cultures were frequently observed after introduction of R factors from organisms of pig origin into the S. choleraesuis var. kunzendorf test organisms. Alterations include changes in typing reaction, granular growth in broth, differences in colony form, and reduction of virulence.     

R Factor Proteins Synthesized in Escherichia coli Minicells: Incorporation Studies with Different R Factors and Detection of Deoxyribonucleic Acid-Binding Proteins

Analysis of the protein synthesized by Escherichia coli minicells containing R factors demonstrated a variety of low- and high-molecular-weight polypeptides in sodium dodecyl sulfate (SDS)-polyacrylamide gels. Only half of this protein was released into a soluble fraction on lysis of these minicells. The other half remained associated with the minicell envelope. The efficiency of precursor incorporation into protein and the kinds of proteins synthesized changed with the age of the minicells at the time of harvest. About 1 to 2% of the soluble R factor-coded protein bound to calf thymus, E. coli, or R factor DNA-cellulose. Although most of these proteins were excluded from Sephadex G-100 columns, they migrated chiefly as low-molecular-weight-polypeptides (13,000 to 15,000) in SDS-polyacrylamide gels. Additional DNA-binding proteins that appeared to be higher-molecular-weight peptides were noted in extracts from younger minicells. At least one protein, identified as an SDS band, appeared to bind selectively to R factor DNA-cellulose. Minicells with R factors also contained DNA-binding proteins of cell origin, including the core RNA polymerase. No such binding proteins were found in R(-) minicells. These studies suggest that: (i) R factors code for proteins that may be involved in their own DNA metabolism; (ii) R factor DNA-binding proteins may be associated with larger host cell DNA-binding proteins or subunits of larger R factor proteins; and (iii) the age of the minicell influences the extent of protein synthesis and the kinds of proteins synthesized by R factors in minicells.     

Transition of the R Factor R12 in Proteus mirabilis

When Proteus mirabilis harboring the R factor R12 (a round of replication mutant of the R factor NR1) is cultured in medium containing streptomycin there can be an amplification in the number of copies of r-determinants per cell and the formation of enlarged polygenic R factors containing repeated sequences of r-determinants as well as polygenic molecules consisting of repeated sequences of r-determinants. This phenomenon has been referred to as the "transition." When transitioned cells are then cultured in drug-free medium, within a few generations two distinct density species of R factor deoxyribonucleic acid (DNA) are observed in a CsCl density gradient: a 1.712 g/ml band of covalently closed circular R factor DNA consisting of one transfer factor (RTF-TC) plus one r-determinant and a 1.718 g/ml band consisting of repeated sequences of r-determinants. The RTF-TC component of the R factor appears to control the replication of all the R factor DNA which is attached to it. In the autonomous state, however, polygenic sequences of r-determinants do not appear to replicate under the same control mechanism as when they are attached to an RTF-TC.     

An Improved Growth Medium to Assess Mycelial Compatibility Groups in Sclerotium rolfsii

Mycelial compatibility is assayed mainly by pairing mycelial plugs of field isolates on Petri dishes with agar media. Although methodologically simple, mycelial compatibility testing requires an artificial growth medium that permits the identification of compatible and incompatible interactions. In this work, several growth media were studied to assess consistently mycelial interactions between Sclerotium rolfsii isolates. A modification of Patterson’s medium with an increment of 25% glucose from the original concentration at a rate of 23.4 g/l and amended with 180 μl/l of red food colouring was the most effective combination for enhancing the size, density and distinctiveness of the aversion zone between incompatible isolates. This medium allowed the unequivocal identification of compatible and incompatible reactions of a set of five S. rolfsii isolates, which could be determined quickly after 5 days of incubation in the dark at 25°C. This new formulation improved significantly and consistently the assessment of the aversion zone reaction that was visible as a red line on the colony reverse as compared to that assessed using previous media formulations, for which the visualization of aversion zones was scarcely discernible. The utility of the improved growth medium was validated by microscopic observations of the contact area of hyphal pairings between isolates of S. rolfsii in microscope slide cultures.     

Analysis of Vegetative Compatibility Groups of Fusarium oxysporum from Eruca vesicaria and Diplotaxis tenuifolia

From 2002 to 2004, wilted plants of different species of rocket (Eruca vesicaria and Diplotaxis spp.) were found for the first time in Europe, in greenhouse cultivations in Piedmont and Lombardy, northern Italy. The causal agent of the disease was found to be Fusarium oxysporum. Vegetative compatibility analysis was carried out on 46 isolates of the fungus, 41 of them obtained from wilted rocket (E. vesicaria and D. tenuifolia) and five reference strains, in order to increase the knowledge on the causal agent of recent epidemics of Fusarium wilt on rocket in Italy. The analysis showed the presence of two vegetative compatibility groups (VCGs) (VCG 0101 and VCG 0220) pathogenic on both kinds of rocket. The two VCG populations, which were classified as formae specialesconglutinans and raphani, respectively, are spread in the area of epidemics but are not related to the host species from which they were isolated (D. tenuifolia or E. vesicaria). This finding shows the heterogeneity of the causal agent of Fusarium wilt on rocket in Italy.     

Host Specialization among Vegetative Compatibility Groups of Verticillium dahliae in Relation to Verticillium longisporum

A collection of 24 isolates of Verticillium dahliae and 10 isolates of Verticillium longisporum originating from nine different host plants and from several geographic regions was tested for host specificity on 11 economically important crops such as potato, tomato, strawberry, linseed, three legumes and four Brassica species. In order to reveal host specificity the potential of each isolate to induce disease and affect plant yield was recorded for all isolate–host combinations. The collected data were statistically processed by means of a cluster analysis. As a result, the host range of individual isolates was found to be more dependent on the vegetative compatibility group (VCG) of the isolate than on its original host plant provenance. Twenty‐two out of 24 V. dahliae isolates belonged to either VCG 2B or 4B. VCG 2B isolates showed specificity for legumes, strawberry, potato and linseed, whereas VCG 4B was specifically virulent on potato, strawberry and linseed. Subgroups within VCG 2B and 4B almost lacking any host preference were designated 2B* and 4B*. Three isolates from VCG 2B*, however, severely attacked tomato which is a host outside the authentic host range of VCG 2B. The pathogenicity of V. longisporum isolates was restricted to cruciferous hosts. Conversely, cruciferous plants were not affected by isolates from VCGs 2B and 4B of V. dahliae. This lack of cross‐infectivity of certain subpopulations of V. dahliae and of V. longisporum may be useful in the management of this soil‐borne wilt disease.     

Protecting Groups as a Factor of Stereocontrol in Glycosylation Reactions

Russian Journal of Bioorganic Chemistry - Synthetic oligosaccharides are objects of interest as model compounds in studies on the biological activity of natural compounds, but also as components...     

Host Range and Properties of the Pseudomonas aeruginosa R Factor R1822

R1822, a plasmid specifying multiple drug resistances, has been transferred to a variety of species representative of related and unrelated genera. The host range of the plasmid includes Enterobacteriaceae, soil saprophytes, Neisseria perflava, and photosynthetic bacteria. With the acquisition of drug resistance(s), these strains became sensitive to a small, ribonuclease-sensitive bacteriophage, designated PRR1, isolated by enrichment from sewage.     

Properties of an R Factor from Pseudomonas aeruginosa

An R factor from Pseudomonas aeruginosa, which confers resistance to penicillins, kanamycin, and tetracycline, was studied in Escherichia coli K-12. The R factor could coexist with F-like or I-like plasmids and therefore constituted a novel compatibility group. The R factor was transferable from E. coli to bacterial genera outside the Enterobacteriaceae (Pseudomonas and members of the Rhizobiaceae) to which transfer of F-like and I-like plasmids could not be demonstrated.     

Evolutionary Relationships among the Fusarium oxysporum f. sp. cubense Vegetative Compatibility Groups

Fusarium oxysporum f. sp. cubense, the causal agent of fusarium wilt of banana (Musa spp.), is one of the most destructive strains of the vascular wilt fungus F. oxysporum. Genetic relatedness among and within vegetative compatibility groups (VCGs) of F. oxysporum f. sp. cubense was studied by sequencing two nuclear and two mitochondrial DNA regions in a collection of 70 F. oxysporum isolates that include representatives of 20 VCGs of F. oxysporum f. sp. cubense, other formae speciales, and nonpathogens. To determine the ability of F. oxysporum f. sp. cubense to sexually recombine, crosses were made between isolates of opposite mating types. Phylogenetic analysis separated the F. oxysporum isolates into two clades and eight lineages. Phylogenetic relationships between F. oxysporum f. sp. cubense and other formae speciales of F. oxysporum and the relationships among VCGs and races of F. oxysporum f. sp. cubense clearly showed that F. oxysporum f. sp. cubense''s ability to cause disease on banana has emerged multiple times, independently, and that the ability to cause disease to a specific banana cultivar is also a polyphyletic trait. These analyses further suggest that both coevolution with the host and horizontal gene transfer may have played important roles in the evolutionary history of the pathogen. All examined isolates harbored one of the two mating-type idiomorphs, but never both, which suggests a heterothallic mating system should sexual reproduction occur. Although, no sexual structures were observed, some lineages of F. oxysporum f. sp. cubense harbored MAT-1 and MAT-2 isolates, suggesting a potential that these lineages have a sexual origin that might be more recent than initially anticipated.Fusarium oxysporum Schlechtendahl emend. Snyder and Hansen is a cosmopolitan species (9) comprised of both pathogenic and nonpathogenic isolates (20). The pathogenic isolates of F. oxysporum cause fusarium wilt of several agricultural crops, and are accordingly subdivided into formae speciales (3, 26, 55). One of the economically more important and destructive formae speciales is the causal agent of fusarium wilt (Panama disease) of banana (Musa spp.), F. oxysporum f. sp. cubense (E. F. Smith) Snyder et Hansen. This disease has been reported in all banana production regions of the world, except those bordering the Mediterranean, Melanesia, Somalia, and some islands in the South Pacific (66, 77).A range of approaches are typically employed for the characterization of F. oxysporum f. sp. cubense isolates. Based on virulence to specific banana cultivars (66, 67), the pathogen may be classified into one of three races (i.e., races 1, 2, and 4), although this designation may be contingent on environmental conditions. For instance, genetically identical isolates of F. oxysporum f. sp. cubense are classified as race 4 isolates in the subtropics and as race 1 isolates in the tropics because they cause disease to Cavendish bananas under subtropical conditions only (67, 86). Based on vegetative compatibility, F. oxysporum f. sp. cubense isolates have been separated into 24 so-called vegetative compatibility groups (VCGs) (5, 29, 47, 68). Finally, various DNA-based tools have been used to separate F. oxysporum f. sp. cubense into a number of clonal lineages that more or less correspond to their grouping based on VCGs (6, 22, 38, 59).The evolutionary history of F. oxysporum f. sp. cubense is complex. Based on the results of phylogenetic studies (4-7, 22, 38, 57, 59). F. oxysporum f. sp. cubense represent multiple unrelated lineages, some of which are more closely related to other formae speciales of F. oxysporum than to other F. oxysporum f. sp. cubense lineages (3, 57, 59). This has lead to speculations that new pathogenic forms of F. oxysporum may be derived from other pathogenic and nonpathogenic members of this species (21). Factors such as coevolution with the plant host and the spread of virulence determinants via processes such as parasexuality, heterokaryosis, and sexual recombination also have been implicated in the evolution of this pathogen (11, 36, 37, 39, 64, 65, 69). Although parasexuality and heterokaryosis are known to occur in F. oxysporum (11, 39), sexual fruiting structures have never been observed in the species and only indirect evidence for sexual recombination has been detected (82). Indeed, the organization of the F. oxysporum f. sp. cubense mating type locus (MAT) is similar to those found in the closely related Gibberella fujikuroi (Sawada) Ito in Ito et K. Kimura complex and other heterothallic ascomycetes (2, 90).Development of appropriate disease management strategies and the selection of F. oxysporum f. sp. cubense-resistant banana cultivars may benefit from a better understanding of the diversity and evolutionary history of the pathogen. Although most previous DNA-based studies provided knowledge regarding the diversity of F. oxysporum f. sp. cubense, the genetic relatedness among the lineages identified in these studies remains uncertain (22). It is also not clear how the different races and VCGs of F. oxysporum f. sp. cubense are related to one another and to other isolates of F. oxysporum. Therefore, the main objective of this study was to resolve the relationships among the F. oxysporum f. sp. cubense VCGs and determine their relationships with other formae speciales and nonpathogenic members of F. oxysporum by using a multigene phylogenetic approach (8, 32, 52, 53, 62, 75, 91). To facilitate the rapid differentiation of the various F. oxysporum f. sp. cubense lineages, we also aimed to develop a diagnostic PCR-restriction fragment length polymorphism (RFLP) procedure. To evaluate the potential of F. oxysporum f. sp. cubense to reproduce sexually, sexual crosses among isolates of opposite mating types were attempted after PCR-based detection of the MAT-1 and MAT-2 idiomorphs (34).