Transposon Mutagenesis and Excision of R' Plasmids by Conjugative, Chimeric Plasmid pUW942 in Extra-Slow-Growing Rhizobium japonicum Strains

Transposons Tn501 (specifying mercury resistance) and Tn7 (specifying resistance to trimethoprim and streptomycin) were introduced into extra-slow-growing Rhizobium japonicum by conjugal transfer of the 82 kilobase chimeric plasmid pUW942. Mercury-resistant transconjugants were obtained at a frequency of 10 to 10. The transfer frequency of streptomycin resistance was lower than that of mercury resistance, and Tn7 was relatively unstable. pUW942 was not maintained as an autonomously replicating plasmid in R. japonicum strains. However, some of the Hg transconjugants from the RJ19FY, RJ17W, and RJ12S strains acquired antibiotic markers of the vector plasmid pUW942. Southern hybridization of plasmid and chromosomal DNA of R. japonicum strains with P-labeled pUW942 and pAS8Rep-1, the same plasmid as pUW942 except that it does not contain Tn501, revealed the formation of cointegrates between pUW942 and the chromosome of R. japonicum. More transconjugants with only Tn501 insertions in plasmids or the chromosome were obtained in crosses with strains RJ19FY and RJ17W than with RJ12S. These retained stable Hg both in plant nodules and under nonselective in vitro growth conditions. One of the RJ19FY and two of the RJ12S Hg transconjugants with vector plasmid-chromosome cointegrates conjugally transferred plasmids of 82, 84 or 86, and 90 kilobases, respectively, into plasmidless Escherichia coli C. These plasmids strongly hybridized to pUW942 and EcoRI digests of total DNA of each respective R. japonicum strain but not to indigenous plasmid DNA of the R. japonicum strains. These R' plasmids consisted of pUW942-specific EcoRI fragments and an additional one or two new fragments derived from the R. japonicum chromosome.     

Excision of the Conjugative Transposon Tn916 in Lactococcus lactis

In Lactococcus lactis excision of Tn916 is limited by the concentration of integrase and is increased by providing more excisionase. However, even with increased excision of Tn916 in L. lactis, no conjugative transfer is detectable. This suggests that L. lactis is deficient in a host factor(s) required for conjugative transposition.     

Evolution of Plasmid Mobility: Origin and Fate of Conjugative and Nonconjugative Plasmids

Conjugation drives the horizontal transfer of adaptive traits across prokaryotes. One-fourth of the plasmids encode the functions necessary to conjugate autonomously, the others being eventually mobilizable by conjugation. To understand the evolution of plasmid mobility, we studied plasmid size, gene repertoires, and conjugation-related genes. Plasmid gene repertoires were found to vary rapidly in relation to the evolutionary rate of relaxases, for example, most pairs of plasmids with 95% identical relaxases have fewer than 50% of homologs. Among 249 recent transitions of mobility type, we observed a clear excess of plasmids losing the capacity to conjugate. These transitions are associated with even greater changes in gene repertoires, possibly mediated by transposable elements, including pseudogenization of the conjugation locus, exchange of replicases reducing the problem of incompatibility, and extensive loss of other genes. At the microevolutionary scale of plasmid taxonomy, transitions of mobility type sometimes result in the creation of novel taxonomic units. Interestingly, most transitions from conjugative to mobilizable plasmids seem to be lost in the long term. This suggests a source-sink dynamic, where conjugative plasmids generate nonconjugative plasmids that tend to be poorly adapted and are frequently lost. Still, in some cases, these relaxases seem to have evolved to become efficient at plasmid mobilization in trans, possibly by hijacking multiple conjugative systems. This resulted in specialized relaxases of mobilizable plasmids. In conclusion, the evolution of plasmid mobility is frequent, shapes the patterns of gene flow in bacteria, the dynamics of gene repertoires, and the ecology of plasmids.     

Induction of Symbiotically Defective Auxotrophic Mutants of Rhizobium fredii HH303 by Transposon Mutagenesis

Symbiotically defective auxotrophic mutants were isolated by transposon Tn5 mutagenesis of Rhizobium fredii HH303, a fast-growing microsymbiont of North American commercial soybean cultivars such as Glycine max cv. Williams. Three different Tn5-carrying suicide vectors, pBLK1-2, pSUP1011, and pGS9, were used for mutagenesis with transposition frequencies of 4 x 10, 3 x 10, and 1 x 10, respectively, while the frequency of background mutation resistant to 500 mug of kanamycin per ml was 1 x 10. From 2,600 Tn5-induced mutants, 14 auxotrophic mutants were isolated and classified in seven groups including adenosine (four), aspartate (two), cysteine or methionine (two), isoleucine and valine (two), nicotinic acid (one), pantothenic acid (one), and uracil (two). All the auxotrophs induced nodulation on soybean, but the symbiotic effectiveness of each mutant was different. Three auxotrophs (two cysteine or methionine and one pantothenic acid) formed effective nodules similar to those of the wild type. Three auxotrophs (one nicotinic acid and two aspartate) produced mature nodules like those of the wild type, but the nodules lacked the characteristic pink color inside and were unable to fix nitrogen. Four auxotrophs (two adenosine and two uracil) induced pseudonodules unable to fix nitrogen. The other four auxotrophs repeatedly induced both effective and ineffective nodules, but bacteroids isolated from the effective nodules were prototrophic revertants. The symbiotic phenotype and the degree of effectiveness of the auxotrophic mutants varied with the type of mutation.     

Characteristics of Effective and Host Specific Ineffective Strains of Rhizobium japonicum

The formation of dimers in the initial stage of methyl linoleate (ML) autoxidation was demonstrated. The oxidation profile of freshly prepared ML was followed by TLC during autoxidation by aeration at 30°C for 192 hr. After 24 hr of autoxidation, the peroxide value of ML was still 0.6, and two unknown polar spots appeared besides intact ML and methyl linoleate hydroperoxides (MLHPO). These two spots were identified as dimers by successive gel and high performance liquid Chromatographic separations and by molecular weight determination. The ratio of dimers/MLHPO reached a maximum (0.74) after 96 hr of autoxidation. This result indicates that the formation of dimers in the initial stage of autoxidation was slightly less than that of MLHPO. The dimers were linked through ?C?O?O?C? bonds and contained hydroperoxy and/or carbonyl groups and conjugated dienes.     

Isolation of Hfr Strains from R+ and ColV2+ Strains of Escherichia coli and Derivation of an R′lac Factor by Transduction

Temperature-resistant revertants were isolated from Escherichia coli strains carrying a temperature-sensitive dnaA mutation (initiation of chromosome replication) and either a repressed or a derepressed F-like R factor or a ColV2 factor. Many of the revertants had all the properties of Hfr strains, with a variety of directions and origins of transfer. From one such revertant, episomes carrying the R factor and part of the lac region (R'lac) could be isolated by transduction. This system offers a good selection for Hfr strains produced by integration of various episomes and for the isolation of R' factors.     

Growth of Rhizobium japonicum Strains at Temperatures Above 27°C

A study was conducted to examine the growth responses of different Rhizobium japonicum strains to increasing temperatures, determine the degree of variability among strains in those responses, and identify temperature-related growth characteristics that could be used to select temperature-tolerant strains. Each of 42 strains was grown in liquid culture for 96 h at 19 incubation temperatures ranging from 27.4 to 54.1°C in a temperature gradient apparatus. Growth was estimated by measuring the change in optical density over time. Strains differed in their responses to increasing temperatures. Three characteristic temperatures were determined for each strain: the temperature giving the maximum optical density at 96 h (optimum temperature), the maximum temperature allowing a continuous increase in optical density during the 96-h period (maximum permissive temperature), and the maximum temperature allowing growth of the cultures after they were transferred to a uniform incubation temperature of 28°C (maximum survival temperature). The three characteristic temperatures varied among strains and had the following ranges: optimum temperature, from 27.4 to 35.2°C; maximum permissive temperature, from 29.8 to 38.0°C; and maximum survival temperature, from 33.7 to 48.7°C. Significant positive correlations were found between maximum permissive temperature and optimum temperature and between maximum permissive temperature and maximum survival temperature. Eight strains which had the highest maximum permissive temperature, optimum temperature, and maximum survival temperature were considered tolerant of high temperatures and were able to grow at temperatures higher than those previously reported for the most tolerant R. japonicum strains. The strains were of diverse geographical origin, but the response to high temperatures was not related to their origin. Evaluation of the temperature responses in pure culture may be useful in the search for R. japonicum strains better suited to environments in which high soil temperature is a limiting factor.     

Plasmid transfer within and between serologically distinct strains of Rhizobium japonicum, using antibiotic resistance mutants and auxotrophs.

Methionine-requiring and pantothenic acid-requiring auxotrophs of Rhizobium japanicum USDA 31, as well as highly antibiotic-resistant mutants of R. japonicum strains USDA 31, USDA 110, USDA 138, and Webster 48, were isolated. These mutants were used to transfer the P-1 group plasmids R68.45 and RP4 within and between strains USDA 31, USDA 110, and Webster 48. Attempts to demonstrate transfer of either plasmid to strain USDA 138 were unsuccessful.     

Discrimination of Rhizobium japonicum,Rhizobium lupini,Rhizobium trifolii,Rhizobium leguminosarum and of bacteriods by uptake of 2-ketoglutaric acid,glutamic acid and phosphate

Rhizobium strains (one each of Rh.japonicum, Rh. lupini, Rh. leguminosarum) take up 2-ketoglutaric acid in general much faster and from lower concentrations in the medium than strains of Escherichia coli, Bacillus subtilis and Chromobacterium violaceum. A strain of Enterobacter aerogenes, however, is more similar to some Rhizobium strains. The same strains of Rhizobium take up also phosphate much faster and from lower concentrations than the other bacteria tested. 4 strains of Rh. lupini proved to be significantly different from 4 strains of Rh. trifolii in taking up l-glutamic acid from three to ten times lower concentration within 5 h. A similar difference was noticed between 5 strains of Rh. leguminosarum and 2 strains of Rh. japonicum for the uptake of 2-ketoglutaric acid and of l-glutamic acid. Isolated bacteriods from nodules of Glycine max var. Chippeway have a reduced uptake capacity for glutamic acid and for 2-ketoglutaric acid during the first 10–12 h, but reach the same value after 24 h as free living Rh. japonicum cells. The differences in the uptake kinetics are independent of cell concentration. The group II Rhizobium strains (Rh. japonicum and Rh. lupini, slow growing Rhizobium) are characterized by a rapid uptake of glutamic acid to a lowremaining concentration of 1–3×10^-7 M and an uptake of 2-ketoglutaric acid to a remaining concentration of 2–5×10^-7 M. The group I Rhizobium strains (Rh. trifolii and Rh. leguminosarum, fast growing Rhizobium), can be characterized by a much slower uptake of both substances with a more than ten times higher concentration of both metabolites remaining in the medium after the same time.     

Identification of Flagellar Motility Genes in Yersinia ruckeri by Transposon Mutagenesis

Here we demonstrate that flagellar secretion is required for production of secreted lipase activity in the fish pathogen Yersinia ruckeri and that neither of these activities is necessary for virulence in rainbow trout. Our results suggest a possible mechanism for the emergence of nonmotile biotype 2 Y. ruckeri through the mutational loss of flagellar secretion.Yersinia ruckeri is the etiologic agent of enteric redmouth disease, a disease of salmonid fish species that is found worldwide in areas where salmonid fish species are farmed (3, 6, 18, 20). Vaccines for enteric redmouth disease have been used successfully for nearly 3 decades and consist of immersion-applied, killed whole-cell preparations of motile serovar 1 Y. ruckeri strains (22). Recently though, outbreaks have been reported in vaccinated fish at trout farms in the United Kingdom (2), Spain (9), and the United States (1). The Y. ruckeri strains isolated from these outbreaks are uniformly atypical serovar 1 isolates lacking both flagellar motility and secreted lipase activity. These variants have been classified as Y. ruckeri biotype 2 (BT2) and are believed to have a reduced sensitivity to immersion vaccination (2). The objective of this study was to obtain a better understanding of the emergence of BT2 Y. ruckeri by identifying genetic elements necessary for expression of the Y. ruckeri flagellum and determining the role that the flagellum plays in virulence by using a rainbow trout infection model.     

Conjugative Transfer of the Large Plasmid p19 in Various <Emphasis Type="Italic">Bacillus subtilis</Emphasis> Strains

Cryptic conjugative plasmid p19 from the environmental Bacillus subtilis strain 19 was labeled with the cat gene conferring resistance to chloramphenicol. The resulting plasmid, p19cat, was used to estimate the transfer frequency, to study the dynamics of plasmid transfer, and to detect some specific features of conjugation between various B. subtilis strains.__________Translated from Genetika, Vol. 41, No. 5, 2005, pp. 601–606.Original Russian Text Copyright © 2005 by Poluektova, Fedorina, Prozorov.     

Efficient Allelic Exchange and Transposon Mutagenesis in Mycobacterium avium by Specialized Transduction

Mycobacterium tuberculosis and Mycobacterium avium are pathogenic slow-growing mycobacteria that cause distinct human diseases. In contrast to recent advances in M. tuberculosis genetics and pathogenesis investigation, M. avium has remained genetically intractable and, consequently, its pathogenic strategies remain poorly understood. Here we report the successful development of efficient allelic exchange and transposon mutagenesis in an opaque clinical strain of M. avium by specialized transduction. Efforts to disrupt the leuD gene of M. avium by specialized transduction were successful but were complicated by inefficient isolation of recombinants secondary to high spontaneous antibiotic resistance. However, by using this leucine auxotroph as a genetic host and the Streptomyces coelicolor leuD gene as a selectable marker, we achieved efficient allelic exchange at the M. avium pcaA locus. A leuD-marked transposon delivered by specialized transduction mutagenized M. avium with efficiencies similar to M. tuberculosis. These results establish a system for random and directed mutagenesis of M. avium. In combination with the forthcoming M. avium genome sequence, these tools will allow the distinct physiologic and pathogenic properties of M. avium to be dissected in molecular detail.     

Organic acids and prolonged nitrogenase activity by non-growing,free-living Rhizobium japonicum

Rhizobium japonicum 61-A-101 grew and fixed nitrogen more effectively on media containing an organic acid and a pentose sugar than on media containing only one of these carbon sources. Peak specific activities in the range 10–15 nmol C₂H₄ · h^-1 · mg protein^-1 were found for these organisms in a spot of growth about 1 cm diameter on agar surfaces exposed to air. Increasing concentrations of the organic acids (succinate or malonate) in a medium containing arabinose resulted in longer lasting activity. The inclusion of a third carbon source, glycerol, gave activity which remained at the maximum from about the 8 to the 18 day after inoculation although no growth of the bacteria occurs during the last 8 or 10 days. At low concentration of organic acid l-arabinose was a much better carbon source for supporting nitrogenase activity of these organisms that the d-form. Both organic acids affected the morphology of the bacteria. Higher concentrations, especially of malonate, gave swollen and distorted cells. When bacteria growing on organic acid-containing agar plates were suspended and plated after appropriate dilution on yeast extract — mannitolglycerol agar there was heterogeneity of colony form, with up to 90% microcolonies after growth on high malonate concentrations. The effects of malonate may be correlated with characteristics of the bacteroid form inside the nodule which contains relatively high concentrations of organic acids, especially malonate.     

Evaluation of Plasmid Content and Tetracycline Resistance Conjugative Transfer in <Emphasis Type="Italic">Enterococcus italicus</Emphasis> Strains of Dairy Origin

Five Enterococcus italicus strains harbouring tet genes responsible for the tetracycline resistance were subjected to plasmid profile determination studies. For four strains tested the profiles showed between three and six plasmid bands, the size of which ranged between 1.6 and 18.5 kb. Southern hybridization experiments associated tetS and tetK genes with chromosomal DNA in all strains and tetM gene with plasmids of around the same size (18.5 kb) in two of the tested strains. The ability of the new species to transfer tetM gene was studied by transfer experiments with the tetracycline-susceptible recipient strains E. faecalis JH2-2 and OG1RF; mobilization experiments were performed with E. faecalis JH 2-2 harbouring the conjugative plasmid pIP501as helper plasmid. The results obtained show that the new enterococcal species was able to acquire antibiotic resistance by conjugation, but not to transfer its plasmids to other bacteria. Further PCR and hybridization experiments carried out to assess the presence of mobilization sequences also suggest that the tetM plasmid from E. italicus is a non-mobilizable plasmid.     

Variations in Ability of Rhizobium japonicum Strains To Nodulate Soybeans and Maintain Fixation in the Presence of Nitrate

This study investigated differences in sensitivity to nitrate of soybean (Glycine max cv. Davis) symbioses with 16 different Rhizobium japonicum strains. When nitrate (20 mM) was added to established symbioses, there were no significant differences in the degree of inhibition of acetylene reduction for any of the 16 strains. When nitrate was present during the establishment of nodules, high levels of nitrate (10 mM) were equally inhibitory on all symbioses, whereas specific strain effects appeared at low (0.5 mM) to medium (2.0 mM) levels of nitrate. At 1.5 mM nitrate in solution culture, the days to emergence of nodules varied from less than 10 (CB:1809, Nit61A118) to more than 16 (11 of 16 strains). In a clay-pot trial maintained at the low nitrate level (0.5 mM), symbioses with CB:1809 increased total nodule mass by 30% relative to nitrate-free controls. In the presence of 2.0 mM nitrate, CB:1809 maintained total nodule mass. For the remaining 6 strains tested, total nodule mass decreased to below the levels of the nitrate-free controls. In a separate clay pot trial, CB:1809 increased its competitive ability relative to USDA:110 when nitrate was added. If no nitrate was added, CB:1809 occupied 0.97 times as many nodules as USDA:110; when 10 mM nitrate was added, CB:1809 occupied 1.75 times as many nodules as USDA:110. Attempts to select nitrogen-adapted substrains of R. japonicum through sequential isolation and infection of plants grown on nitrate were not successful.     

两株高效相思根瘤菌的抗药性研究及其质粒组成分析

目的:研究相思根瘤菌质粒与其抗药性之间的关系。方法:研究了相思根瘤菌MZ和AJ018在含不同浓度的抗生素的固体培养基和液体培养基的生长情况,并用碱裂解方法对其质粒组成进行检测。结果:两菌株对链霉素和卡那霉素均无抗性,而对其它抗生素都有不同程度的抗性。MZ菌株对实验中的氯霉素、氨苄青霉素、四环素三种抗生素的耐受范围与最大耐受值都比AJ018强,当平板培养基中氨苄青霉素、四环素、氯霉素的终浓度分别为250μg/ml、75μg/ml、150μg/ml时,AJ018在平板上无菌落生长,当三种抗生素终浓度分别为800μg/ml1、50μg/ml、400μg/ml时无菌落生长。两菌株都含有一个大约50kb的质粒。     

Isolation of Rhodospirillum centenum Mutants Defective in Phototactic Colony Motility by Transposon Mutagenesis

The purple photosynthetic bacterium Rhodospirillum centenum is capable of forming swarm colonies that rapidly migrate toward or away from light, depending on the wavelength of excitation. To identify components specific for photoperception, we conducted mini-Tn5-mediated mutagenesis and screened approximately 23,000 transposition events for mutants that failed to respond to either continuous illumination or to a step down in light intensity. A majority of the ca. 250 mutants identified lost the ability to form motile swarm cells on an agar surface. These cells appeared to contain defects in the synthesis or assembly of surface-induced lateral flagella. Another large fraction of mutants that were unresponsive to light were shown to be defective in the formation of a functional photosynthetic apparatus. Several photosensory mutants also were obtained with defects in the perception and transmission of light signals. Twelve mutants in this class were shown to contain disruptions in a chemotaxis operon, and five mutants contained disruptions of components unique to photoperception. It was shown that screening for photosensory defective R. centenum swarm colonies is an effective method for genetic dissection of the mechanism of light sensing in eubacteria.Behavioral change in response to alterations in the quality and quantity of light in the environment is a ubiquitous trait among motile photosynthetic bacteria. Three distinct types of responses to light have been described in the literature (14, 19, 36, 37). The scotophobic response (fear of darkness) is characterized by a tumbling, stop, or reversal that occurs when a swimming bacterium experiences a temporal, or spatial, step down in light intensity. Photokinesis describes an alteration in the rate of motility caused by differences in light intensity. A phototactic response, which has been studied most extensively in algae and cyanobacteria, involves an oriented movement of a cell toward or away from a light source (19). An important distinction is that the direction of irradiation is not relevant to scotophobic or photokinetic responses, whereas it is a critical determinant in phototaxis. Thus, phototactic organisms are uniquely capable of migrating towards a light source, irrespective of whether they are going up or down a gradient of light intensity (37).The various photosensory behaviors exhibited by anoxygenic photosynthetic bacteria have been studied mainly by physiological and biochemical tests, with little supporting genetic data (3, 4, 8, 9, 13, 16, 27, 38). The few genetic tests that have been undertaken have demonstrated that mutations which functionally impair the photosystem also disrupt the ability of cells to respond to light (3, 20). This indicates that a product of photosynthesis, such as the generation of proton motive force or photosynthesis-driven electron transfer, is most likely the signal that controls photosensory behavior, rather than direct absorption of light by a chromophore-containing receptor. This conclusion is supported by recent physiological studies which have shown that specific inhibitors of cyclic photosynthesis-driven electron transport inhibit photosensory behavior in Rhodobacter sphaeroides (13, 16) and Rhodospirillum centenum (38). By using a site-directed mutational approach, we have shown that the scotophobic and phototactic responses of the purple nonsulfur photosynthetic bacterium R. centenum involve components of the chemotaxis phosphorylation cascade (25, 26). This suggests that a sensor of photosynthetic activity may have features similar to that of chemoreceptors. However, which component of the photosynthesis electron transfer chain is being sensed and what is actually sensing alterations in electron transfer are unknown.To identify components responsible for prokaryotic behavioral responses to light, it is essential that techniques be developed for the isolation of mutants that are specifically defective in photosensory behavior. One of the reasons why screens for photosensory mutants have not been developed is the inherent difficulty of assaying for photosensory behavior. Until recently, screening for such mutants involved the onerous task of microscopically assaying individual cells from liquid-grown cultures for a response to a step up or down in light intensity. Since statistically meaningful results require that multiple cells be assayed, this “brute force” approach is infeasible. A significant advance in the isolation of prokaryotic photosensory mutants was recently provided by our observation that colonies of the purple photosynthetic bacterium R. centenum are capable of macroscopic phototactic motility (36, 37). Cells of R. centenum are dimorphic, existing in liquid medium as swim cells bearing a single polar flagellum or as hyperflagellated swarm cells on solid surfaces (36, 37). A unique feature of R. centenum swarming colonies is that they are capable of migrating rapidly (up to 75 mm/h) toward an infrared light source or away from a visible light source (36, 37). This behavior allows us to rapidly screen for mutants that are deficient in photosensory responses by simply assaying colonies for aberrant light-directed migration. In this study, we have utilized mini-Tn5-mediated mutagenesis to isolate numerous mutants that exhibit defects in light-directed motility. The phenotypes of specific classes of mutants provide some unique observations on photosensory behavior, as well as on the mechanism of swim cell to swarm cell differentiation.     

Comparison of colony morphology, salt tolerance, and effectiveness in Rhizobium japonicum

Four strains of Rhizobium japonicum, two of which produce slimy and non-slimy colony types and two others which produce large and small colony types, were isolated and cloned. All were infective and nodulated Lee soybean host plants. Each colony type was characterized as to its salt sensitivity to Na+ and K+ ions, relative level of symbiotic nitrogen fixation, and relative level of free-living nitrogen fixation. Growth studies performed in the presence of salts demonstrated that the non-slimy or small colony types were sensitive to salt with significantly depressed growth rates and cell yields. Growth rates and cell yields of slimy, large, colony types were relatively unaffected by salt. Both symbiotic and free-living (non-associative) nitrogen fixation analyses (by acetylene reduction) revealed that the non-slimy, small colonies were significantly more effective than slimy, large colonies.