Split-Root Assays Using Trifolium subterraneum Show that Rhizobium Infection Induces a Systemic Response That Can Inhibit Nodulation of Another Invasive Rhizobium Strain

Subterranean clover plants possessing two equally infectible and robust lateral root systems (“split roots”) were used in conjunction with several specific mutant strains (derived from Rhizobium trifolii ANU843) to investigate a systemic plant response induced by infective Rhizobium strains. This plant response controls and inhibits subsequent nodulation on the plant. When strain ANU843 was inoculated onto both root systems simultaneously or 24, 48, 72, or 96 h apart, an inhibitory response occurred which retarded nodulation on the root exposed to the delayed inoculum but only when the delay period between inocula was greater than 24 h. Equal numbers of nodules were generated on both roots when ANU843 was inoculated simultaneously or 24 h apart. The ability to infect subterranean clover plants was required to initiate the plant inhibitory response since preexposure of one root system to non-nodulating strains did not retard the ability of the wild-type strain to nodulate the opposing root system (even when the delay period was 96 h). Moreover, the use of specific Tn5-induced mutants subtly impaired in their ability to nodulate demonstrated that the plant could effectively and rapidly discriminate between infections initiated by either the parent or the mutant strains. When inoculated alone onto clover plants, these mutant strains were able to infect the most susceptible plant cells at the time of inoculation and induce nitrogen-fixing nodules. However, the separate but simultaneous inoculation on opposing root systems of the parent and the mutant strains resulted in the almost complete inhibition of the nodulation ability of the mutant strains. We concluded that the mutants were affected in their competitive ability, and this finding was reflected by poor nodule occupancy when the mutants were coinoculated with the parent strain onto a single root system. Thus the split-root system may form the basis of a simple screening method for the ranking of competitiveness of various rhizobia on small seeded legumes.     

Effect of the fungicide captafol on the survival and symbiotic properties of Rhizobium trifolii

The fungicide captafol is toxic to Rhizobium trifolii at concentrations greater than 75 μg/ml, and at lower concentrations it affects growth adversely. Captafol-resistant mutants were isolated and all were found to have lost the same plasmid and the ability to nodulate clovers. Nodulation plasmids transferred from a R. leguminosarum or R. trifolii donor to the resistant mutants conferred the ability to nodulate peas and clover plants, respectively. The rhizobia remained resistant to captafol indicating that the genetic alteration leading to captafol resistance was not necessarily detrimental to the ability of the bacteria to form nitrogen fixing nodules. These results indicate that captafol may act as a plasmid-curing agent in R. trifolii.     

Phages for the gliding bacteriumCytophaga johnsonae that infect only motile cells

Twenty-eight phages active againstCytophaga johnsonae have been isolated and placed into 16 groups based on phage size and morphology and on host range studies using a variety of mutants derived fromC. johnsonae. Several lines of evidence support the idea that these phages infect only actively motile cells: (i) many mutants selected for resistance to one phage are nonmotile and are resistant to all phages, (ii) nonmotile mutants, selected for their inability to spread on plates, are resistant to all phages, (iii) when nonmotile mutants revert to the motile condition, they regain sensitivity to some or all phages, and (iv) carbony-cyanidem-chlorophenylhydrazone inhibits motility and prevents adsorption of a test phage.     

GldI is a lipoprotein that is required for Flavobacterium johnsoniae gliding motility and chitin utilization

Cells of Flavobacterium johnsoniae glide rapidly over surfaces by an unknown mechanism. Seven genes (gldA, gldB, gldD, gldF, gldG, gldH, and ftsX) that are required for gliding motility have been described. Complementation of the nonmotile mutants UW102-41, UW102-85, and UW102-92 identified another gene, gldI, that is required for gliding motility. gldI mutants formed nonspreading colonies, and individual cells were completely nonmotile. They were also resistant to bacteriophages that infect wild-type cells, and they failed to digest chitin. Introduction of wild-type gldI on a plasmid restored colony spreading, cell motility, phage sensitivity, and the ability to digest chitin to the gldI mutants. gldI encodes a predicted 199-amino-acid protein that localized to the membrane fraction. Labeling studies with [(3)H]palmitate indicated that GldI is a lipoprotein. GldI is similar to peptidyl-prolyl cis/trans-isomerases of the FK506-binding protein family and may be involved in folding cell envelope protein components of the motility machinery.     

Flavobacterium johnsoniae gliding motility genes identified by mariner mutagenesis

Cells of Flavobacterium johnsoniae glide rapidly over surfaces. The mechanism of F. johnsoniae gliding motility is not known. Eight gld genes required for gliding motility have been described. Disruption of any of these genes results in complete loss of gliding motility, deficiency in chitin utilization, and resistance to bacteriophages that infect wild-type cells. Two modified mariner transposons, HimarEm1 and HimarEm2, were constructed to allow the identification of additional motility genes. HimarEm1 and HimarEm2 each transposed in F. johnsoniae, and nonmotile mutants were identified and analyzed. Four novel motility genes, gldK, gldL, gldM, and gldN, were identified. GldK is similar in sequence to the lipoprotein GldJ, which is required for gliding. GldL, GldM, and GldN are not similar in sequence to proteins of known function. Cells with mutations in gldK, gldL, gldM, and gldN were defective in motility and chitin utilization and were resistant to bacteriophages that infect wild-type cells. Introduction of gldA, gldB, gldD, gldFG, gldH, gldI, and gldJ and the region spanning gldK, gldL, gldM, and gldN individually into 50 spontaneous and chemically induced nonmotile mutants restored motility to each of them, suggesting that few additional F. johnsoniae gld genes remain to be identified.     

Biochemical and symbiotic properties of histidine-requiring mutants of Rhizobium leguminosarum biovar trifolii

A perturbation of the histidine biosynthetic pathway in legume microsymbionts can abolish their symbiotic competence. Twenty-one histidine-requiring (His⁻) mutants were isolated from berseem clover-nodulating, symbiotically-competent (Nod⁺, Fix⁺) Rhizobium leguminosarum bv. ' trifolii ' strain RTH 48 Sm^r by N-methyl-N'-nitro-N-nitrosoguanidine (MNNG) mutagenesis followed by enrichment. These mutants were analysed for their biochemical defect and the corresponding effect, if any, on their symbiotic abilities. Cross-feeding, supplementation and enzymatic studies identified three types of mutants. Group 1 mutants, His-2 and His-12, grew with histidine supplementation but not with the addition of either L -histidinol or L -histidinol phosphate to the medium ; they lacked histidinol dehydrogenase (EC 1.1.1.23) activity and consequently formed only ineffective, or 'non-fixing' nodules. Group 2 mutant, His-17, grew when supplemented with either L -histidinol or L -histidine, had low histidinol phosphate phosphatase (EC 3.1.3.15) activity (37% of wild-type), and consequently failed to nodulate berseem clover. Group 3, the remaining 18 mutants, grew when supplemented with L -histidinol phosphate, L -histidinol or histidine, and did not nodulate. Typically, reversion rates were between 10⁻⁷ and 10⁻⁸. Defects in early steps of the pathway abolished nodulating ability, whereas lesions in the last step did not. The last step, however, was required for symbiotic nitrogen fixation. It is hypothesized that histidine may be supplied by the host in sufficient quantity for nodulation by histidinol dehydrogenase mutants to occur, whereas the amount provided in the nodule may be insufficient to support bacteroid development and nitrogen fixation.     

Host range ofFrankia endophytes

Summary Cross-inoculation experiments with 10 pure cultured strains and 17 host species were carried out. The 10 strains were isolated from the root nodules on actinorhizal trees ranging in 9 species, 5 genera and 4 families. The host species belong to 5 genera. The pure cultured strains fromAlnus are of strong ability to infect different species of the same genus. The seedlings inoculated with these strains are able to nodulate normally. These strains can also infect and nodulate the seedlings ofMyrica californica, but not the seedlings of Elaeagnus, Casuarina andMyrica rubra. The pure cultured strains from Elaeagnus can infect and nodulate the host species in the same genus and family with an exception ofE. viridis vardelavayi, which can be only poorly nodulated by a few strains from Elaeagnus. The strains from Elaeagnus cannot infect the seedlings of Alnus andMyrica rubra. The results presented here suggest thatFrankia endophytes can be divided into two groups: Alnus group and Elaeagnus group.     

Trifolitoxin Production and Nodulation Are Necessary for the Expression of Superior Nodulation Competitiveness by Rhizobium leguminosarum bv. trifolii Strain T24 on Clover

Rhizobium leguminosarum bv. trifolii T24 is ineffective in symbiotic nitrogen fixation, produces a potent antibiotic (referred to here as trifolitoxin) that is bacteriostatic to certain Rhizobium strains, and is very competitive for clover root nodulation (EA Schwinghamer, RP Belkengren 1968 Arch Mikrobiol 64: 130-145). The primary objective of this work was to demonstrate the roles of nodulation and trifolitoxin production in the expression of nodulation competitiveness by T24. Unlike wildtype T24, transposon mutants of T24 lacking trifolitoxin production were unable to decrease clover nodulation by an effective, trifolitoxin-sensitive strain of R. leguminosarum bv. trifolii. A non-nodulating transposon mutant of T24 prevented clover nodulation by a trifolitoxin-sensitive R. leguminosarum bv. trifolii when co-inoculated with a T24 mutant lacking trifolitoxin production. Neither mutant alone prevented nodulation by the trifolitoxin-sensitive strain. These results demonstrate that trifolitoxin production and nodulation are required for the expression of nodulation competitiveness by strain T24. A trifolitoxin-sensitive strain of R. meliloti did not nodulate alfalfa when co-inoculated with T24 and a trifolitoxin-resistant strain of R. meliloti. Thus, a trifolitoxin-producing strain was useful in regulating nodule occupancy on a legume host other than clover. Trifolitoxin production was constitutive in both minimal and enriched media. Trifolitoxin was found to inhibit the growth of 95% of all strains of R. leguminosarum bvs. trifolii, viceae, and phaseoli tested. Strains of all 13 biotypes of R. leguminosarum bv. trifolii were inhibited by trifolitoxin. Three strains of R. fredii were also inhibited. Strain T24 ineffectively nodulated 46 clover species, did not nodulate Trifolium ambiguum, and induced partially effective nodules on Trifolium micranthum. Since T24 produced partially effective nodules on T. micranthum and since a trifolitoxin-minus mutant of T24 induced ineffective nodules, trifolitoxin production is not the cause of the symbiotic ineffectiveness of T24.     

Biochemical Analysis of a Mutant Tetrahymena Lacking Outer Dynein Arms

ABSTRACT. Tetrahymena thermophila mutants homozygous for the oad mutation become nonmotile when grown at the restrictive temperature, and axonemes isolated from nonmotile mutants lack approximately 90% of their outer dynein arms. Electrophoretic analyses of axonemes isolated from nonmotile mutants ( oad axonemes) indicate they contain significantly fewer of the 22 S dynein heavy chains that axonemes isolated from wild-type cells (wild-type axonemes) contain. The 22 S dynein heavy chains that remain in axonemes isolated from nonmotile, oad mutants are assembled into 22 S dynein particles that exhibit wild-type levels of ATPase activity. Two-dimensional gel electrophoresis of oad axonemes show that they are deficient in no proteins other than those proteins thought to be components of 22 S dynein. This report is the first formal proof that outer dynein arms in Tetrahymena cilia are composed of 22 S dynein.     

Conserved Nodulation Genes in Rhizobium meliloti and Rhizobium trifolii

Plasmids which contained wild-type or mutated Rhizobium meliloti nodulation (nod) genes were introduced into Nod⁻R. trifolii mutants ANU453 and ANU851 and tested for their ability to nodulate clover. Cloned wild-type and mutated R. meliloti nod gene segments restored ANU851 to Nod⁺, with the exception of nodD mutants. Similarly, wild-type and mutant R. meliloti nod genes complemented ANU453 to Nod⁺, except for nodCII mutants. Thus, ANU851 identifies the equivalent of the R. meliloti nodD genes, and ANU453 specifies the equivalent of the R. meliloti nodCII genes. In addition, cloned wild-type R. trifolii nod genes were introduced into seven R. meliloti Nod⁻ mutants. All seven mutants were restored to Nod⁺ on alfalfa. Our results indicate that these genes represent common nodulation functions and argue for an allelic relationship between nod genes in R. meliloti and R. trifolii.     

Expression by Soil Bacteria of Nodulation Genes from Rhizobium leguminosarum biovar trifolii

Gram-negative, rod-shaped bacteria from the soil of white clover-ryegrass pastures were screened for their ability to nodulate white clover (Trifolium repens) cultivar Grasslands Huia and for DNA homology with genomic DNA from Rhizobium leguminosarum biovar trifolii ICMP2668 (NZP582). Of these strains, 3.2% were able to hybridize with strain ICMP2668 and nodulate white clover and approximately 19% hybridized but were unable to nodulate. Strains which nodulated but did not hybridize with strain ICMP2668 were not detected. DNA from R. leguminosarum biovar trifolii (strain PN165) cured of its symbiotic (Sym) plasmid and a specific nod probe were used to show that the relationship observed was usually due to chromosomal homology. Plasmid pPN1, a cointegrate of the broad-host-range plasmid R68.45 and a symbiotic plasmid pRtr514a, was transferred by conjugation to representative strains of nonnodulating, gram-negative, rod-shaped soil bacteria. Transconjugants which formed nodules were obtained from 6 of 18 (33%) strains whose DNA hybridized with that of PN165 and 1 of 9 (11%) strains containing DNA which did not hybridize with that of PN165. The presence and location of R68.45 and nod genes was confirmed in transconjugants from three of the strains which formed nodules. Similarly, a pLAFR1 cosmid containing nod genes from a derivative of R. leguminosarum biovar trifolii NZP514 formed nodules when transferred to soil bacteria.     

A Temperature-Sensitive Mutation Affecting Synthesis of Outer Arm Dyneins in Tetrahymena thermophila

ABSTRACT. We have characterized a novel, temperature-sensitive mutation affecting motility in Tetrahymena thermophila . Mutants grew and divided normally at the restrictive temperature (38°C), but became nonmotile. Scanning electron microscopic analysis indicated that nonmotile mutants contained the normal number of cilia and that the cilia were of normal length. Transmission electron microscopic analysis indicated that axonemes isolated from nonmotile mutants lacked outer dynein arms, so the mutation was named oad I ( outer arm defficient ). Motile mutants shifted to 38° C under conditions that prevent cell growth and division (starvation) remained motile suggesting that once assembled into axonemes at the permissive temperature (28° C) the outer arm dyneins remain functional at 38° C. Starved, deciliated mutants regenerated a full complement of functional cilia at 38° C, indicating that the mechanism that incorporates the outer arm dynein into developing axonemes is not affected by the oad I mutation. Starved, nonmotile mutants regained motility when shifted back to 28° C, but not when incubated with cycloheximide. We interpret these results to rule out the hypothesis that the oad I mutation affects the site on the microtubules to which the outer arm dyneins bind. Axonemes isolated from mutants grown for one generation at 38° C had a mean of 6.0 outer arm dyneins, and axonemes isolated from mutants grown for two generations at 38° C had a mean of 3.2 outer arm dyneins. Taken together, these results indicate that the oad I mutation affects the synthesis of outer arm dyneins in Tetrahymena .     

Evidence for the Transfer of Rhizobial Metabolites to the Polyploid Nuclei of Young Clover Nodules

Autoradiography was used to provide evidence for the transfer of Rhizobium produced moieties to the host nuclei of young clover nodule cells. Cells of Rhizobium trifolii Dangeard were labeled with ³H-adenine or 4,5-³H-l -leucine and 3,4-³H-l .-proline, washed free of external label, and allowed to nodulate young seedlings of white clover (Trifolium repens L. cv. White Dutch). Sections (0.5–1.0 μm) of young nodules up to four days old were autoradiographed using the dipping technique. Grain counts indicated movement of tritium from the leucine-proline labeled rhizobia to the polyploid nuclei of two day old clover nodule cells. Acetylene reduction was not detected until approximately 24 hours after the transfer of tritium was observed. No transfer of tritium was observed with ³H-adenine labeled rhizobia. It is hypothesized that nodulating rhizobia may induce clover nodule cells to initiate leghemoglobin synthesis by the transfer of a bacterially produced inducer.     

A temperature-sensitive mutation affecting synthesis of outer arm dyneins in Tetrahymena thermophila.

We have characterized a novel, temperature-sensitive mutation affecting motility in Tetrahymena thermophila. Mutants grew and divided normally at the restrictive temperature (38 degrees C), but became nonmotile. Scanning electron microscopic analysis indicated that nonmotile mutants contained the normal number of cilia and that the cilia were of normal length. Transmission electron microscopic analysis indicated that axonemes isolated from nonmotile mutants lacked outer dynein arms, so the mutation was named oad 1 (outer arm deficient). Motile mutants shifted to 38 degrees C under conditions that prevent cell growth and division (starvation) remained motile suggesting that once assembled into axonemes at the permissive temperature (28 degrees C) the outer arm dyneins remain functional at 38 degrees C. Starved, deciliated mutants regenerated a full complement of functional cilia at 38 degrees C, indicating that the mechanism that incorporates the outer arm dynein into developing axonemes is not affected by the oad 1 mutation. Starved, nonmotile mutants regained motility when shifted back to 28 degrees C, but not when incubated with cycloheximide. We interpret these results to rule out the hypothesis that the oad 1 mutation affects the site on the microtubules to which the outer arm dyneins bind. Axonemes isolated from mutants grown for one generation at 38 degrees C had a mean of 6.0 outer arm dyneins, and axonemes isolated from mutants grown for two generations at 38 degrees C had a mean of 3.2 outer arm dyneins. Taken together, these results indicate that the oad 1 mutation affects the synthesis of outer arm dyneins in Tetrahymena.     

Identification of Rhizobium plasmid sequences involved in recognition of Psophocarpus, Vigna, and other legumes

Symbiotic DNA sequences involved in nodulation by Rhizobium must include genes responsible for recognizing homologous hosts. We sought these genes by mobilizing the symbiotic plasmid of a broad host-range Rhizobium MPIK3030 (= NGR234) that can nodulate Glycine max, Psophocarpus tetragonolobus, Vigna unguiculata, etc., into two Nod- Rhizobium mutants as well as into Agrobacterium tumefaciens. Subsequently, cosmid clones of pMPIK3030a were mobilized into Nod+ Rhizobium that cannot nodulate the chosen hosts. Nodule development was monitored by examining the ultrastructure of nodules formed by the transconjugants. pMPIK3030a could complement Nod- and Nif- deletions in R. leguminosarum and R. meliloti as well as enable A. tumefaciens to nodulate. Three non-overlapping sets of cosmids were found that conferred upon a slow-growing Rhizobium species, as well as on R. loti and R. meliloti, the ability to nodulate Psophocarpus and Vigna, thus pointing to the existence of three sets of host-specificity genes. Recipients harboring these hsn regions had truly broadened host-range since they could nodulate both their original hosts as well as MPIK3030 hosts.     

Effect of transposon-induced motility mutations on colonization of the host light organ by Vibrio fischeri.

Vibrio fischeri is found both as a free-living bacterium in seawater and as the specific, mutualistic light organ symbiont of several fish and squid species. To identify those characteristics of symbiosis-competent strains that are required for successful colonization of the nascent light organ of juvenile Euprymna scolopes squids, we generated a mutant pool by using the transposon Mu dI 1681 and screened this pool for strains that were no longer motile. Eighteen independently isolated nonmotile mutants that were either flagellated or nonflagellated were obtained. In contrast to the parent strain, none of these nonmotile mutants was able to colonize the juvenile squid light organ. The flagellated nonmotile mutant strain NM200 possessed a bundle of sheathed polar flagella indistinguishable from that of the wild-type strain, indicating that the presence of flagella alone is not sufficient for colonization and that it is motility itself that is required for successful light organ colonization. This study identifies motility as the first required symbiotic phenotype of V. fischeri.     

Sym plasmid genes of Rhizobium trifolii expressed in Lignobacter and Pseudomonas strains.

A 14-kilobase (kb) fragment of Rhizobium trifolii Sym plasmid containing nodulation (nod) genes or the pSym plasmid of R. trifolii cointegrated with a broad-host-range vector R68.45 (pPN1) were transferred to Lignobacter strain K17 and Pseudomonas aeruginosa strain PAO5 by conjugation. Lignobacter transconjugants carrying Sym plasmid pPN1 formed nodules on white, red, and subterranean clover plants. Lignobacter transconjugants containing a 14-kb fragment of nod genes cloned into a multicopy plasmid nodulated only white and subterranean clover plants, whereas transconjugants carrying the same fragment cloned into a low-copy plasmid vector nodulated only white clover plants. All nodules formed by Lignobacter transconjugants showed bacterial release from the infection threads into the host cytoplasm. Pseudomonas transconjugants with plasmid pPN1 formed nodule-like structures on white clover plants. These structures were not invaded by bacteria; however, a few bacteria were found within the intercellular spaces of the outermost cells of the structures. Pseudomonas transconjugants carrying the 14-kb fragment of R. trifolii nod genes did not form nodules on tested clover plants. All clover plants inoculated with either Pseudomonas or Lignobacter transconjugants containing a 14-kb fragment of nod genes (but not entire Sym plasmid) showed the "thick-and-short-root" response when compared to the control plants inoculated with the R. trifolii wild-type strain.     

Mechanisms of microbial movement in subsurface materials

The biological factors important in the penetration of Escherichia coli through anaerobic, nutrient-saturated, Ottawa sand-packed cores were studied under static conditions. In cores saturated with galactose-peptone medium, motile strains of E. coli penetrated four times faster than mutants defective only in flagellar synthesis. Motile, nonchemotactic mutants penetrated the cores faster than did the chemotactic parental strain. This, plus the fact that a chemotactic galactose mutant penetrated cores saturated with peptone medium at the same rate with or without a galactose gradient, indicates that chemotaxis may not be required for bacterial penetration through unconsolidated porous media. The effect of gas production on bacterial penetration was studied by using motile and nonmotile E. coli strains together with their respective isogenic non-gas-producing mutants. No differences were observed between the penetration rates of the two motile strains through cores saturated with peptone medium with or without galactose. However, penetration of both nonmotile strains was detected only with galactose. The nonmotile, gas-producing strain penetrated cores saturated with galactose-peptone medium five to six times faster than did the nonmotile, non-gas-producing mutant, which indicates that gas production is an important mechanism for the movement of nonmotile bacteria through unconsolidated porous media. For motile strains, the penetration rate decreased with increasing galactose concentrations in the core and with decreasing inoculum sizes. Also, motile strains with the faster growth rates had faster penetration rates. These results imply that, for motile bacteria, the penetration rate is regulated by the in situ bacterial growth rate.(ABSTRACT TRUNCATED AT 250 WORDS)     

Mechanisms of microbial movement in subsurface materials.

The biological factors important in the penetration of Escherichia coli through anaerobic, nutrient-saturated, Ottawa sand-packed cores were studied under static conditions. In cores saturated with galactose-peptone medium, motile strains of E. coli penetrated four times faster than mutants defective only in flagellar synthesis. Motile, nonchemotactic mutants penetrated the cores faster than did the chemotactic parental strain. This, plus the fact that a chemotactic galactose mutant penetrated cores saturated with peptone medium at the same rate with or without a galactose gradient, indicates that chemotaxis may not be required for bacterial penetration through unconsolidated porous media. The effect of gas production on bacterial penetration was studied by using motile and nonmotile E. coli strains together with their respective isogenic non-gas-producing mutants. No differences were observed between the penetration rates of the two motile strains through cores saturated with peptone medium with or without galactose. However, penetration of both nonmotile strains was detected only with galactose. The nonmotile, gas-producing strain penetrated cores saturated with galactose-peptone medium five to six times faster than did the nonmotile, non-gas-producing mutant, which indicates that gas production is an important mechanism for the movement of nonmotile bacteria through unconsolidated porous media. For motile strains, the penetration rate decreased with increasing galactose concentrations in the core and with decreasing inoculum sizes. Also, motile strains with the faster growth rates had faster penetration rates. These results imply that, for motile bacteria, the penetration rate is regulated by the in situ bacterial growth rate.(ABSTRACT TRUNCATED AT 250 WORDS)