A Comparative Study of the Physiology of Symbioses Formed by Rhizobium japonicum with Glycine max, Vigna unguiculata, and Macroptilium atropurpurem

No disruption of rhizobial symbiosis during early stages of cowpea domestication

Modern agriculture intensely selects aboveground plant structures, while often neglecting belowground features, and evolutionary tradeoffs between these traits are predicted to disrupt host control over microbiota. Moreover, drift, inbreeding, and relaxed selection for symbiosis in crops might degrade plant mechanisms that support beneficial microbes. We studied the impact of domestication on the nitrogen fixing symbiosis between cowpea and root-nodulating Bradyrhizobium. We combined genome-wide analyses with a greenhouse inoculation study to investigate genomic diversity, heritability, and symbiosis trait variation among wild and early-domesticated cowpea genotypes. Cowpeas experienced modest decreases in genome-wide diversity during early domestication. Nonetheless, domesticated cowpeas responded efficiently to variation in symbiotic effectiveness, by forming more root nodules with nitrogen-fixing rhizobia and sanctioning non-fixing strains. Domesticated populations invested a larger proportion of host tissues into root nodules than wild cowpeas. Unlike soybean and wheat, cowpea showed no compelling evidence for degradation of symbiosis during domestication. Domesticated cowpeas experienced a less severe bottleneck than these crops and the low nutrient conditions in Africa where cowpea landraces were developed likely favored plant genotypes that gain substantial benefits from symbiosis. Breeders have largely neglected symbiosis traits, but artificial selection for improved plant responses to microbiota could increase plant performance and sustainability. This article is protected by copyright. All rights reserved.

Identification of Bradyrhizobium elkanii USDA61 Type III Effectors Determining Symbiosis with Vigna mungo

Bradyrhizobium elkanii USDA61 possesses a functional type III secretion system (T3SS) that controls host-specific symbioses with legumes. Here, we demonstrated that B. elkanii T3SS is essential for the nodulation of several southern Asiatic Vigna mungo cultivars. Strikingly, inactivation of either Nod factor synthesis or T3SS in B. elkanii abolished nodulation of the V. mungo plants. Among the effectors, NopL was identified as a key determinant for T3SS-dependent symbiosis. Mutations of other effector genes, such as innB, nopP2, and bel2-5, also impacted symbiotic effectiveness, depending on host genotypes. The nopL deletion mutant formed no nodules on V. mungo, but infection thread formation was still maintained, thereby suggesting its pivotal role in nodule organogenesis. Phylogenetic analyses revealed that NopL was exclusively conserved among Bradyrhizobium and Sinorhizobium (Ensifer) species and showed a different phylogenetic lineage from T3SS. These findings suggest that V. mungo evolved a unique symbiotic signaling cascade that requires both NFs and T3Es (NopL).

High-quality permanent draft genome sequence of the Bradyrhizobium elkanii type strain USDA 76T, isolated from Glycine max (L.) Merr

Bradyrhizobium elkanii USDA 76^T (INSCD = ARAG00000000), the type strain for Bradyrhizobium elkanii, is an aerobic, motile, Gram-negative, non-spore-forming rod that was isolated from an effective nitrogen-fixing root nodule of Glycine max (L. Merr) grown in the USA. Because of its significance as a microsymbiont of this economically important legume, B. elkanii USDA 76^T was selected as part of the DOE Joint Genome Institute 2010 Genomic Encyclopedia for Bacteria and Archaea-Root Nodule Bacteria sequencing project. Here the symbiotic abilities of B. elkanii USDA 76^T are described, together with its genome sequence information and annotation. The 9,484,767 bp high-quality draft genome is arranged in 2 scaffolds of 25 contigs, containing 9060 protein-coding genes and 91 RNA-only encoding genes. The B. elkanii USDA 76^T genome contains a low GC content region with symbiotic nod and fix genes, indicating the presence of a symbiotic island integration. A comparison of five B. elkanii genomes that formed a clique revealed that 356 of the 9060 protein coding genes of USDA 76^T were unique, including 22 genes of an intact resident prophage. A conserved set of 7556 genes were also identified for this species, including genes encoding a general secretion pathway as well as type II, III, IV and VI secretion system proteins. The type III secretion system has previously been characterized as a host determinant for Rj and/or rj soybean cultivars. Here we show that the USDA 76^T genome contains genes encoding all the type III secretion system components, including a translocon complex protein NopX required for the introduction of effector proteins into host cells. While many bradyrhizobial strains are unable to nodulate the soybean cultivar Clark (rj1), USDA 76^T was able to elicit nodules on Clark (rj1), although in reduced numbers, when plants were grown in Leonard jars containing sand or vermiculite. In these conditions, we postulate that the presence of NopX allows USDA 76^T to introduce various effector molecules into this host to enable nodulation.

Photosynthetic Bradyrhizobium sp. strain ORS285 is capable of forming nitrogen-fixing root nodules on soybeans (Glycine max)

The ability of photosynthetic Bradyrhizobium strains ORS285 and ORS278 to nodulate soybeans was investigated. While the nod gene-deficient ORS278 strain induced bumps only on soybean roots, the nod gene-containing ORS285 strain formed nitrogen-fixing nodules. However, symbiotic efficiencies differed drastically depending on both the soybean genotype used and the culture conditions tested.

Uptake Hydrogenase (Hup) in Common Bean (Phaseolus vulgaris) Symbioses

Strains of Rhizobium forming nitrogen-fixing symbioses with common bean were systematically examined for the presence of the uptake hydrogenase (hup) structural genes and expression of uptake hydrogenase (Hup) activity. DNA with homology to the hup structural genes of Bradyrhizobium japonicum was present in 100 of 248 strains examined. EcoRI fragments with molecular sizes of approximately 20.0 and 2.2 kb hybridized with an internal SacI fragment, which contains part of both bradyrhizobial hup structural genes. The DNA with homology to the hup genes was located on pSym of one of the bean rhizobia. Hup activity was observed in bean symbioses with 13 of 30 strains containing DNA homologous with the hup structural genes. However, the Hup activity was not sufficient to eliminate hydrogen evolution from the nodules. Varying the host plant with two of the Hup strains indicated that expression of Hup activity was host regulated, as has been reported with soybean, pea, and cowpea strains.

Rhizobium japonicum Serogroup and Hydrogenase Phenotype Distribution in 12 States

A survey was conducted in 1980 on 972 isolates of Rhizobium japonicum obtained from 65 soybean field locations in 12 states. Isolates were examined for the hydrogenase (Hup) phenotype and somatic serogroup identity. Only 20% of the isolates were Hup, with a majority of Hup isolates occurring in 10 of the 12 states. The most predominant serogroup was 31 (21.5%), followed by 123 (13.6%). Although most serogroups contained a majority of Hup isolates, marked differences occurred. None of the isolates in serogroup 135 were Hup, but 93% of the isolates in serogroup 122 were Hup. The serogroups with relatively high frequencies of Hup isolates (122 and 110) constitute only a small part (<5% each) of the R. japonicum field population in the 12 states.

Diversity among Field Populations of Bradyrhizobium japonicum in Poland

Genetic structure in field populations of Bradyrhizobium japonicum isolated in Poland was determined by using several complementary techniques. Of the 10 field sites examined, only 4 contained populations of indigenous B. japonicum strains. The Polish bradyrhizobia were divided into at least two major groups on the basis of protein profiles on polyacrylamide gels, serological reaction with polyclonal antisera, repetitive extragenic palindromic PCR fingerprints of genomic DNA, and Southern hybridization analyses with nif and nod gene probes. Serological analyses indicated that 87.5% of the Polish B. japonicum isolates tested were in serogroups 123 and 129, while seven (12.5%) of the isolates tested belonged to their own unique serogroup. These seven strains also could be grouped together on the basis of repetitive extragenic palindromic PCR fingerprints, protein profiles, and Southern hybridization analyses. Cluster analyses indicated that the seven serologically undefined isolates were genetically dissimilar from the majority of the Polish B. japonicum strains. Moreover, immuno-cross-adsorption studies indicated that although the Polish B. japonicum strains reacted with polyclonal antisera prepared against strain USDA123, the majority failed to react with serogroup 123- and 129-specific antisera, suggesting that Polish bradyrhizobia comprise a unique group of root nodule bacteria which have only a few antigens in common with strains USDA123 and USDA129. Nodulation studies indicated that members of the serologically distinct group were very competitive for nodulation of Glycine max cv. Nawiko. None of the Polish serogroup 123 or 129 isolates were restricted for nodulation by USDA123- and USDA129-restricting soybean plant introduction genotypes. Taken together, our results indicate that while genetically diverse B. japonicum strains were isolated from some Polish soils, the majority of field sites contained no soybean-nodulating bacteria. In addition, despite the lack of long-term soybean production in Poland, field populations of unique B. japonicum strains are present in some Polish soils and these strains are very competitive for nodulation of currently used Polish soybean varieties.

Genetic Diversity in Bradyrhizobium japonicum Serogroup 123 and Its Relation to Genotype-Specific Nodulation of Soybean

The genetic diversity among 20 field isolates of Bradyrhizobium japonicum serogroup 123 was examined by using restriction endonuclease digestions, one-dimensional sodium dodecyl sulfate-polyacrylamide gel electrophoresis of total cell proteins, Southern hybridization analysis of nif and nod genes, and intrinsic antibiotic resistance profiles. All of the isolates were previously separated into three broad nodulation classes (low, medium, and high) based on their ability to form symbioses with specific soybean genotypes. Results of our studies indicate that there is a relationship between these three genotype-specific nodulation classes and groupings that have been made based on genomic DNA digestion patterns, sodium dodecyl sulfate-protein profiles, and Southern hybridizations to a nifHD gene probe. Intrinsic antibiotic resistance profiles and nodAB gene hybridizations were not useful in determining interrelationships between isolates and nodulation classes. Southern hybridizations revealed that two of the isolates had reiterated nod genes; however, there was no correlation between the presence of extra nodAB genes and the nodulation classes or symbiotic performance on permissive soybean genotypes. Hybridizations with the nif gene probe indicated that there is a relationship among serogroup, nodulation class, and the physical organization of the genome.

Symbiotic Expression of Cosmid-Borne Bradyrhizobium japonicum Hydrogenase Genes

The expression of cosmid-borne Bradyrhizobium japonicum hydrogenase genes in alfalfa, clover, and soybean nodules harboring Rhizobium transconjugants was studied. Cosmid pHU52 conferred hydrogen uptake (Hup) activity in both free-living bacteria and in nodules on the different plant hosts, although in nodules the instability of the cosmid resulted in low levels of Hup activity. In contrast, cosmid pHU1, which does not confer Hup activity on free-living bacteria, gave a Hup phenotype in nodules on alfalfa and soybean. Nodules formed by B. japonicum USDA 123Spc(pHU1) recycled about 90% of nitrogenase-mediated hydrogen evolution. Both subunits of hydrogenase (30- and 60-kilodalton polypeptides) were detected in enzyme-linked immunosorbent assays of bacteroid preparations from nodules harboring B. japonicum strains with pHU1 or pHU52. Neither pHU53 nor pLAFR1 conferred detectable Hup activity in either nodules or free-living bacteria. Based on the physical maps of pHU1 and pHU52, it is suggested that a 5.5-kilobase EcoRI fragment unique to pHU52 contains a gene or part of a gene required for Hup activity in free-living bacteria but not in nodules. This conclusion is supported by the observation that two Tn5 insertions in the chromosome of B. japonicum USDA 122DES obtained by marker exchange with Tn5-mutagenized pHU1 abolished Hup activity in free-living bacteria but not in nodules.

Fingerprinting and diversity of bacterial copA genes in response to soil types, soil organic status and copper contamination

A molecular fingerprinting assay was developed to assess the diversity of copA genes, one of the genetic determinants involved in bacterial resistance to copper. Consensus primers of the copA genes were deduced from an alignment of sequences from proteobacterial strains. A PCR detection procedure was optimized for bacterial strains and allowed the description of a novel copA genetic determinant in Pseudomonas fluorescens. The copA DNA fingerprinting procedure was optimized for DNA directly extracted from soils differing in their physico-chemical characteristics and in their organic status (SOS). Particular copA genetic structures were obtained for each studied soil and a coinertia analysis with soil physico-chemical characteristics revealed the strong influence of pH, soil texture and the quality of soil organic matter. The molecular phylogeny of copA gene confirmed that specific copA genes clusters are specific for each SOS. Furthermore, this study demonstrates that this approach was sensitive to short-term responses of copA gene diversity to copper additions to soil samples, suggesting that community adaptation is preferentially controlled by the diversity of the innate copA genes rather than by the bioavailability of the metal.

Some processes related to nitrogen fixation in nodulated legumes

We have summarized information in four areas of the broad topic of legume- Rhizobium symbiosis. These include: carbon substrates provided to nodule bacteroids by the host, assimilation of fixed nitrogen by the host, O 2 metabolism in legume nodules and involvement of H 2 in nodule metabolism. Although nodules contain a variety of carbon substrates, both biochemical and genetic evidence indicate that C4 dicarboxylates are the major carbon substrates that support N 2 fixation in nodules. The biochemical pathways for utilization of products of N 2 fixation are fairly well understood but relatively little is known about the regulation of the assimilation of fixed nitrogenous compounds at the gene level. Ureides are primary nitrogenous compounds exported from nodules of the tropical legumes. Because the catabolism of these products may involve the hydrolysis of urea by nickel-dependent urease, the possible importance of nickel as a trace element in the nutrition of legumes is raised. The O 2 supply to nodule bacteroids is regulated by a barrier to free-O 2 diffusion and by leghaemoglobin. Progress has been made in understanding of the molecular genetics and biochemistry of leghaemoglobin but little is known about the mechanisms that control the physical barrier to O 2 diffusion. Legume nodules contain mechanisms for the disposition of peroxide and free radicals of oxygen. The importance of these systems as protective mechanisms for the O 2 -labile nitrogenase is discussed. Some strains of Rhizobium form nodules which recycle the H 2 produced as a byproduct of N 2 fixation. The genes necessary for H 2 oxidation have been cloned and transferred within and among species of Rhizobium . The advantages and disadvantages of H 2 recycling in legume nodules are discussed.

Isolation and characterization of rhizobitoxine mutants of Bradyrhizobium japonicum

To explore the role of rhizobitoxine in Bradyrhizobium-legume symbiosis, 11 rhizobitoxine mutants of B. japonicum USDA61 were isolated on the basis of their inability to synthesize the toxin in culture. Each mutant is prototrophic and symbiotically effective on soybean, cowpea, siratro, and Glycine soja. The rhizobitoxine mutants differ in their chlorosis phenotypes and rhizobitoxine production in planta. As expected, one group of mutant fail to make toxin in planta, resulting in the absence of chlorosis. Another group of mutants causes severe chlorosis on all cultivars of soybean tested. Surprisingly, this group of mutants makes more rhizobitoxine in soybean nodules than the wild-type strain does. This phenotype is only observed on soybean and not on other hosts such as cowpea, siratro, or G. soja. The remaining mutants all produce rhizobitoxine in planta but vary in the amount of toxin they produce and the severity of chlorosis they induce in soybean plants. Biochemical analysis of mutants demonstrates that one mutant is unable to synthesize serinol, a molecule hypothesized to be an intermediate in rhizobitoxine biosynthesis. By using these mutants, it was found that rhizobitoxine plays no apparent role in the nodulation of rj1 soybeans. Recently, it was found that inhibition of ethylene biosynthesis allows Rhizobium meliloti to overcome nitrate inhibition of nodule formation on alfalfa. Because rhizobitoxine also inhibits ethylene biosynthesis, we tested the ability of mutants which accumulate high levels of toxin in planta to overcome nitrate inhibition of nodule formation on soybean plants and found that the nodule formation induced by the wild type and that induced by mutant strains were equally suppressed in the presence of nitrate.

Hydrogen Oxidation by the Host-Controlled Uptake Hydrogenase Phenotype of Bradyrhizobium japonicum in Symbiosis with Soybean Host Plants

Symbioses between uptake hydrogenase host-regulated (Hup-hr) phenotypes of Bradyrhizobium japonicum and exotic, agronomically unadapted soybean germ plasm were examined for expression of uptake hydrogenase activity. Determinations for hydrogen evolution and uptake hydrogenase activity identified five plant introduction (PI) lines which formed hydrogen-oxidizing symbioses with strains USDA 61 and PA3 6c. Hup-hr strains belonging to serogroup 94 expressed uptake hydrogenase activity in symbioses with PI 181696 and PI 219655 at rates sufficient to prevent hydrogen from escaping the nodules. The identification of soybean germ plasm forming hydrogen-oxidizing symbioses with Hup-hr bradyrhizobia potentially has implications for enhancing nitrogen fixation efficiency in soybean production.

Evidence for a Third Uptake Hydrogenase Phenotype among the Soybean Bradyrhizobia

The existence of a hydrogen uptake host-regulated (Hup-hr) phenotype was established among the soybean bradyrhizobia. The Hup-hr phenotype is characterized by the expression of uptake hydrogenase activity in symbiosis with cowpea but not soybean. Uptake hydrogenase induction is not possible under free-living cultural conditions by using techniques developed for uptake hydrogenase-positive (Hup + ) Bradyrhizobium japonicum . Hydrogen oxidation by Hup-hr phenotype USDA 61 in cowpea symbioses was significant because hydrogen evolution from nitrogen-fixing nodules was not detected. An examination for uptake hydrogenase activity in soybean and cowpea with 123 strains diverse in origin and serology identified 16 Hup + and 28 Hup-hr phenotype strains; the remainder appeared to be Hup − . The Hup-hr phenotype was associated with serogroups 31, 76, and 94, while strains belonging to serogroups 6, 31, 110, 122, 123, and 38/115 were Hup + . Hup + strains of the 123 serogroup typed positive with USDA 129-specific antiserum. The presence of the uptake hydrogenase protein in cowpea bacteroids of Hup + strains was demonstrated with immunoblot analyses by using antibodies against the 65-kDa subunit of uptake hydrogenase purified from strain SR470. However, the hydrogenase protein of Hup-hr strains was not detected. Results of Southern hybridization analyses with pHU1 showed the region of DNA with hydrogenase genes among Hup + strains to be similar. Hybridization was also obtained with Hup-hr strains by using a variety of cloned DNA as probes including hydrogenase structural genes. Both hydrogenase structural genes also hybridized with the DNA of four Hup − strains.

Photosynthesis and photosynthate partitioning in n(2)-fixing soybeans

Leaf area, chlorophyll content, net CO(2) photoassimilation, and the partitioning of fixed carbon between leaf sucrose and starch and soluble protein were examined in Glycine max (L) Merr. cv Williams grown under three different nitrogen regimes. One group (Nod+/+) was inoculated with Bradyrhizobium and watered daily with a nutrient solution containing 6 millimolar NH(4)NO(3). A second set (Nod+/-) was inoculated and had N(2) fixation as its sole source of nitrogen. A third group (Nod(-)) was not inoculated and was watered daily with a nutrient solution containing 6 millimolar NH(4)NO(3). The mean net micromole CO(2) uptake per square decimeter per hour of the most recently matured source leaves was similar among the three groups of plants, being about 310. Mean leaf area of the source leaves, monitored for net photosynthesis was also similar. However, the mean milligram of chlorophyll per square decimeter of Nod+/- test leaves was about 50% lower than the other groups' leaves and indicated nitrogen deficiency. Thus, Nod+/- utilized their chlorophyll more efficiently for photosynthetic CO(2) uptake than the plants of the other treatments. The ratio of foliar carbohydrate:protein content was high in Nod+/- but low in the plants from the other two treatments. This inverse relationship between foliar protein and carbohydrate content suggests that more fixed carbon is diverted to the synthesis of protein when nitrogen availability is high. It was also found that Nod+/- sequestered more storage protein in their paraveinal mesophyll than plants of the other treatments. This study indicates that when inorganic nitrogen regimes are used to control photosynthate partitioning, then both leaf carbohydrate and leaf protein must be considered as end products of carbon assimilate allocation.

Differential expression of hydrogen uptake (hup) genes in vegetative and symbiotic cells of Rhizobium leguminosarum

The genetic determinants responsible for H2-uptake (hup genes) in Rhizobium leguminosarum are organized in six transcriptional units, designated regions hupI to hupVI, with region hupI coding for the hydrogenase structural genes (Leyva et al. 1990). Regulation of the expression of hup genes from R. leguminosarum was examined by using hup-lacZ fusions and mRNA dot-blot analysis. None of the six hup regions is transcribed in vegetative cells grown under normal aerobic conditions, whereas all six regions are transcribed in pea bacteroids. Additionally, exposure of cell cultures to low oxygen tensions specifically induces the expression of regions hupV and hupVI. By studying the expression of hupV- and hupVI-lacZ fusions in R. meliloti mutants it was determined that the microaerobic induction of these two regions is dependent on the regulatory fixLJ system, and that this control is exerted through fixK. Such expression was also shown to be nifA and ntrA independent. The functions of the hupV and hupVI gene products are unknown. The possibility that they play a regulatory role in hup gene expression is unlikely, since pea bacteroids from R. leguminosarum Hup- mutants carrying Tn5 insertions in regions hupV and hupVI contained normal levels of mRNA transcripts corresponding to the remaining hup regions.

Development and Partial Characterization of Nearly Isogenic Pea Lines (Pisum sativum L.) that Alter Uptake Hydrogenase Activity in Symbiotic Rhizobium

Some Rhizobium bacteria have H(2)-uptake (Hup) systems that oxidize H(2) evolved from nitrogenase in leguminous root nodules. Pea (Pisum sativum L.) cultivars ;JI1205' and ;Alaska' produce high Hup (Hup(++)) and moderate Hup (Hup(+)) phenotypes, respectively, in Rhizobium leguminosarum 128C53. The physiological significance and biochemical basis of this host plant genetic effect are unknown. The purpose of this investigation was to advance basic Hup studies by developing nearly isogenic lines of peas that alter Hup phenotypes in R. leguminosarum strains containing hup genes. Eight pairs of nearly isogenic pea lines that produce Hup(++) and Hup(+) phenotypes in R. leguminosarum 128C53 were identified in 173 F(2)-derived F(6) families produced from crosses between JI1205 and Alaska. Tests with the pea isolines and three strains of hup-containing R. leguminosarum showed that the isolines altered Hup activity significantly (P </= 0.05) in 19 of 24 symbiotic combinations. Analyses of Hup phenotypes in F(6) families, the F(1) population, and two backcrosses suggested involvement of a single genetic locus. Three of the eight pairs of isolines were identified as being suitable for physiological studies, because the two lines in each pair showed similar growth, N assimilation, and flowering traits under nonsymbiotic conditions. Tests of those lines under N(2)-dependent conditions with isogenic Hup(+) and negligible Hup (Hup(-)) mutants of R. leguminosarum 128C53 showed that, in symbioses with Hup(+) rhizobia, two out of three Hup(++) pea lines decreased N(2) fixation relative to Hup(+) peas. In one of those cases, however, the Hup(++) plant line also decreased fixation by Hup(-) rhizobia. When results were averaged across all rhizobia tested, Hup(+) pea isolines had 8.2% higher dry weight (P </= 0.05) and fixed 12.6% more N(2) (P </= 0.05) than Hup(++) isolines. Pea lines described here may help identify host plant factors that influence rhizobial Hup activity and should assist in clarifying how Hup systems influence other physiological processes.

Mutational analysis of the Bradyrhizobium japonicum common nod genes and further nod box-linked genomic DNA regions

By insertional and deletional marker replacement mutagenesis the common nod region of Bradyrhizobium japonicum was examined for the presence of additional, essential nodulation genes. An open reading frame located in the 800 bp large intergenic region between nodD1 and nodA did not appear to be essential for nodulation of soybean. Furthermore, a strain with a deletion of the nodI- and nodJ-like genes downstream of nodC had a Nod+ phenotype. A mutant with a 1.7 kb deletion immediately downstream of nodD1 considerably delayed the onset of nodulation. This region carried a second copy of nodD (nodD2). A nodD1-nodD2 double mutant had a similar phenotype to the nodD2 mutant. Using a 22-mer oligonucleotide probe partially identical to the nod box sequence, a total of six hybridizing regions were identified in B. japonicum genomic DNA and isolated from a cosmid library. Sequencing of the hybridizing regions revealed that at least three of them represented true nod box sequences whereas the others showed considerable deviations from the consensus sequence. One of the three nod box sequences was the one known to be associated with nodA, whereas the other two were located 60 to 70 kb away from nif cluster I. A deletion of one of these two sequences plus adjacent DNA material (mutant delta 308) led to a reduced nodulation on Vigna radiata but not on soybean. Thus, this region is probably involved in the determination of host specificity.

Occurrence of H(2)-Uptake Hydrogenases in Bradyrhizobium sp. (Lupinus) and Their Expression in Nodules of Lupinus spp. and Ornithopus compressus

Fifty-four strains of Bradyrhizobium sp. (Lupinus) from worldwide collections were screened by a colony hybridization method for the presence of DNA sequences homologous to the structural genes of the Bradyrhizobium japonicum hydrogenase. Twelve strains exhibited strong colony hybridization signals, and subsequent Southern blot hybridization experiments showed that they fell into two different groups on the basis of the pattern of EcoRI fragments containing the homology to the hup probe. All strains in the first group (UPM860, UPM861, and 750) expressed uptake hydrogenase activity in symbiosis with Lupinus albus, Lupinus angustifolius, Lupinus luteus, and Ornithopus compressus, but both the rate of H(2) uptake by bacteroids and the relative efficiency of N(2) fixation (RE = 1 - [H(2) evolved in air/acetylene reduced]) by nodules were markedly affected by the legume host. L. angustifolius was the less permissive host for hydrogenase expression in symbiosis with the three strains (average RE = 0.76), and O. compressus was the more permissive (average RE = 1.0). None of the strains in the second group expressed hydrogenase activity in lupine nodules, and only one exhibited low H(2)-uptake activity in symbiosis with O. compressus. The inability of these putative Hup(+) strains to induce hydrogenase activity in lupine nodules is discussed on the basis of the legume host effect. Among the 42 strains showing no homology to the B. japonicum hup-specific probe in the colony hybridization assay, 10 were examined in symbiosis with L. angustifolius. The average RE for these strains was 0.51. However, one strain, IM43B, exhibited high RE values (higher than 0.80) and high levels of hydrogenase activity in symbiosis with L. angustifolius, L. albus, and L. luteus. In Southern blot hybridization experiments, no homology was detected between the B. japonicum hup-specific DNA probe and total DNA from vegetative cells or bacteroids from strain IM43B even under low stringency hybridization conditions. We conclude from these results that strain IM43B contains hup DNA sequences different from those in B. japonicum and in other lupine rhizobia strains.

Efficiency of nodule initiation in cowpea and soybean

When serial dilutions of a suspension of Bradyrhizobium japonicum strain 138 were inoculated onto both soybean and cowpea roots, the formation of nodules in the initially susceptible region of the roots of both hosts was found to be linearly dependent on the log of the inoculum dosage until an optimum dosage was reached. Approximately 30- to 100-fold higher dosages were required to elicit half-maximal nodulation on cowpea than on soybean in the initially susceptible zone of the root. However, at optimal dosages, about six times as many nodules formed in this region on cowpea roots than on soybean roots. There was no appreciable difference in the apparent rate of nodule initiation on these two hosts nor in the number of inoculum bacteria in contact with the root. These results are consistent with the possibility that cowpea roots have a substantially higher threshold of response to symbiotic signals from the bacteria than do soybean roots. Storage of B. japonicum cells in distilled water for several weeks did not affect their viability or efficiency of nodule initiation on soybean. However, the nodulation efficiency of these same cells on cowpea diminished markedly over a 2 week period. These differential effects of water storage indicate that at least some aspects of signal production by the bacteria during nodule initiation are different on the two hosts. Mutants of B. japonicum 138 defective in synthesis of soybean lectin binding polysaccharide were defective in their efficiency of nodule initiation on soybean but not on cowpea. These results also suggest that B. japonicum may produce different substances to initiate nodules on these two hosts.

Lack of carbon substrate repression of uptake hydrogenase activity in Bradyrhizobium japonicum SR

The expression of ex planta uptake hydrogenase (Hup) activity in Bradyrhizobium japonicum SR induced in the absence or presence of carbon substrates was compared. Hup activity was influenced by pH, indicating that acidification of induction medium with low buffering capacity resulting from carbon substrate metabolism inhibited Hup activity. Cell suspensions in medium with adequate buffering capacity and carbon substrate were limited in O2; increasing O2 availability to cells during induction stimulated Hup expression. The data showed a lack of carbon substrate repression of Hup activity in cell suspensions provided with adequate O2 and buffering capacity.

Nodulation, Nitrogen Fixation, and Hydrogen Oxidation by Pigeon Pea Bradyrhizobium spp. in Symbiotic Association with Pigeon Pea, Cowpea, and Soybean

The pigeon pea strains of Bradyrhizobium CC-1, CC-8, UASGR(S), and F4 were evaluated for nodulation, effectiveness for N 2 fixation, and H 2 oxidation with homologous and nonhomologous host plants. Strain CC-1 nodulated Macroptilium atropurpureum, Vigna unguiculata, Glycine max , and G. soja but did not nodulate Pisum sativum, Phaseolus vulgaris, Trigonella foenum-graecum , and Trifolium repens . Strain F4 nodulated G. max cv. Peking and PI 434937 (Malayan), but the symbioses formed were poor. Similarly, G. max cv. Peking, cv. Bragg, PI 434937, PR 13-28-2-8-7, and HM-1 were nodulated by strain CC-1, and symbioses were also poor. G. max cv. Williams and cv. Clark were not nodulated. H 2 uptake activity was expressed with pigeon pea and cowpea, but not with soybean. G. max cv. Bragg grown in Bangalore, India, in local soil not previously exposed to Bradyrhizobium japonicum formed nodules with indigenous Bradyrhizobium spp. Six randomly chosen isolates, each originating from a different nodule, formed effective symbioses with pigeon pea host ICPL-407, nodulated PR 13-28-2-8-7 soybean forming moderately effective symbioses, and did not nodulate Williams soybean. These results indicate the six isolates to be pigeon pea strains although they originated from soybean nodules. Host-determined nodulation of soybean by pigeon pea Bradyrhizobium spp. may depend upon the ancestral backgrounds of the cultivars. The poor symbioses formed by the pigeon pea strains with soybean indicate that this crop should be inoculated with B. japonicum for its cultivation in soils containing only pigeon pea Bradyrhizobium spp.

Cloning and Mapping of a Novel Nodulation Region from Bradyrhizobium japonicum by Genetic Complementation of a Deletion Mutant

The phenotypes of a set of Bradyrhizobium japonicum 110 mutants with large deletions in the region of symbiotic gene cluster I were tested. The majority of the mutants showed a delayed nodulation on soybean and, by mixed-infection experiments, were found to be strongly reduced in their competitiveness. Phenotypic comparison of mutants with different deletion endpoints allowed a preliminary localization of two genomic regions, called nod-1 and nod-2, which were required for normal nodulation on soybean. Loss of nod-1 was found to result in a Nod phenotype on cowpea, mung bean, and siratro. A recombinant cosmid was identified which fully restored nodulation ability of a mutant lacking nod-1. Using Tn5-containing derivatives and subclones of this cosmid for complementation, we delimited the nod-1 region to a DNA segment of 3.1 to 3.5 kilobase pairs.

Expression of uptake hydrogenase and hydrogen oxidation during heterotrophic growth of Bradyrhizobium japonicum

Strains I-110 ARS, SR, USDA 136, USDA 137, and AK13 1c of Bradyrhizobium japonicum induced Hup activity when growing heterotrophically in medium with carbon substrate and NH4Cl in the presence of 2% H2 and 2% O2. Hup activity was induced during heterotrophic growth in the presence of carbon substrates, which were assimilated during the time of H2 oxidation. Strains I-110 ARS and SR grown heterotrophically or chemoautotrophically for 3 days had similar rates of H2 oxidation. Similar rates of Hup activity were also observed when cell suspensions were induced for 24 h in heterotrophic or chemoautotrophic growth medium with 1% O2, 10% H2, and 5% CO2 in N2. These results are contrary to the reported repression of Hup activity by carbon substrates in B. japonicum. Bradyrhizobial Hup activity during heterotrophic growth was limited by H2 and O2 and repressed by aerobic conditions, and CO2 addition had no effect. Nitrogenase and ribulosebisphosphate carboxylase activities were not detected in H2-oxidizing cultures of B. japonicum during heterotrophic growth. Immunoblot analysis of cell extracts with antibodies prepared against the 65-kilodalton subunit of uptake hydrogenase indicated that Hup protein synthesis was induced by H2 and repressed under aerobic conditions.

Long-Term Effects of Metal-Rich Sewage Sludge Application on Soil Populations of Bradyrhizobium japonicum

The application of sewage sludge to land may increase the concentration of heavy metals in soil. Of considerable concern is the effect of heavy metals on soil microorganisms, especially those involved in the biocycling of elements important to soil productivity. Bradyrhizobium japonicum is a soil bacterium involved in symbiotic nitrogen fixation with Glycine max , the common soybean. To examine the effect of metal-rich sludge application on B. japonicum , the MICs for Pb, Cu, Al, Fe, Ni, Zn, Cd, and Hg were determined in minimal media by using laboratory reference strains representing 11 common serogroups of B. japonicum . Marked differences were found among the B. japonicum strains for sensitivity to Cu, Cd, Zn, and Ni. Strain USDA 123 was most sensitive to these metals, whereas strain USDA 122 was most resistant. In field studies, a silt loam soil amended 11 years ago with 0, 56, or 112 Mg of digested sludge per ha was examined for total numbers of B. japonicum by using the most probable number method. Nodule isolates from soybean nodules grown on this soil were serologically typed, and their metal sensitivity was determined. The number of soybean rhizobia in the sludge-amended soils was found to increase with increasing rates of sludge. Soybean rhizobia strains from 11 serogroups were identified in the soils; however, no differences in serogroup distribution or proportion of resistant strains were found between the soils. Thus, the application of heavy metal-containing sewage sludge did not have a long-term detrimental effect on soil rhizobial numbers, nor did it result in a shift in nodule serogroup distribution.

Enrichment for Hydrogen-Oxidizing Acinetobacter spp. in the Rhizosphere of Hydrogen-Evolving Soybean Root Nodules

Field soybean plants were inoculated with Hup + wild-type or H 2 uptake-negative (Hup − ) mutants of Bradyrhizobium japonicum . For two consecutive summers we found an enrichment for acinetobacters associated with the surfaces of the H 2 -evolving nodules. Soybean root nodules that evolved H 2 had up to 12 times more Acinetobacter spp. bacteria associated with their surfaces than did nodules incapable of evolving H 2 . All of the newly isolated strains identified as Acinetobacter obtained from the surfaces of root nodules, as well as known established Acinetobacter strains, were capable of oxidizing H 2 , a property not previously described for this alkane-degrading soil bacterium.

Relationship between Ureide N and N(2) Fixation, Aboveground N Accumulation, Acetylene Reduction, and Nodule Mass in Greenhouse and Field Studies with Glycine max L. (Merr)

The relationship between ureide N and N(2) fixation was evaluated in greenhouse-grown soybean (Glycine max L. Merr.) and lima bean (Phaseolus lunatus L.) and in field studies with soybean. In the greenhouse, plant N accumulation from N(2) fixation in soybean and lima bean correlated with ureide N. In soybean, N(2) fixation, ureide N, acetylene reduction, and nodule mass were correlated when N(2) fixation was inhibited by applying KNO(3) solutions to the plants. The ureide-N concentrations of different plant tissues and of total plant ureide N varied according to the effectiveness of the strain of Bradyrhizobium japonicum used to inoculate plants. The ureide-N concentrations in the different plant tissues correlated with N(2) fixation. Ureide N determinations in field studies with soybean correlated with N(2) fixation, aboveground N accumulation, nodule weight, and acetylene reduction. N(2) fixation was estimated by (15)N isotope dilution with nine and ten soybean genotypes in 1979 and 1980, respectively, at the V9, R2, and R5 growth stages. In 1981, we investigated the relationship between ureide N, aboveground N accumulation, acetylene reduction, and nodule mass using four soybean genotypes harvested at the V4, V6, R2, R4, R5, and R6 growth stages. Ureide N concentrations of young stem tissues or plants or aboveground ureide N content of the four soybean genotypes varied throughout growth correlating with acetylene reduction, nodule mass, and aboveground N accumulation. The ureide-N concentrations of young stem tissues or plants or aboveground ureide-N content in three soybean genotypes varied across inoculation treatments of 14 and 13 strains of Bradyrhizobium japonicum in 1981 and 1982, respectively, and correlated with nodule mass and acetylene reduction. In the greenhouse, results correlating nodule mass with N(2) fixation and ureide N across strains were variable. Acetylene reduction in soybean across host-strain combinations did not correlate with N(2) fixation and ureide N. N(2) fixation, ureide N, acetylene reduction, and nodule mass correlated across inoculation treatments with strains of Bradyrhizobium spp. varying in effectiveness on lima beans. Our data indicate that ureide-N determinations may be used as an additional method to acetylene reduction in studies of the physiology of N(2) fixation in soybean. Ureide-N measurements also may be useful to rank strains of B. japonicum for effectiveness of N(2) fixation.

A transmissible plant shoot factor promotes uptake hydrogenase activity in Rhizobium symbionts

Shoot/root grafting studies showed organ and host cultivar effects on net H(2) evolution from Pisum sativum L. root nodules. Net H(2) evolution from those nodules represents the sum of H(2) formed by Rhizobium nitrogenase and H(2) oxidized by any uptake hydrogenase present in the bacteria. Grafts between pea cultivars ;JI1205' or ;Alaska' and ;Feltham First' in symbioses with R. leguminosarum 128C53 showed that shoots of both JI1205 and Alaska increased H(2) uptake significantly (P </= 0.05) in Feltham First root nodules. The same plants also had less net H(2) evolution at similar rates of C(2)H(2) reduction than plants formed by grafting Feltham First shoots on Feltham First roots. Although JI1205 and Alaska shoots increased H(2)-uptake activity of Feltham First root nodules 28 days after the graft was made, intermediate to high levels of H(2) uptake activity were still present in nodules on roots of both JI1205 and Alaska grafted to Feltham First shoots. These results indicate the presence of a transmissible shoot factor(s) which can increase uptake hydrogenase activity in a Rhizobium symbiont and show that root genotype also can influence that parameter.Parallel grafting experiments using the same pea cultivars in symbioses with R. leguminosarum strain 300, which lacks uptake hydrogenase activity, suggested that a transmissible shoot factor(s) altered H(2) formation from nitrogenase by changing the electron allocation coefficient of that enzyme complex.The root and shoot factor(s) detected in this study had no permanent effect on strain 128C53. Bacterial cells isolated from Feltham First nodules with low H(2) uptake activity formed root nodules on JI1205 and Alaska with high H(2) uptake activity. Bacteroids isolated from nodules on intact JI1205, Alaska, or Feltham First plants with high, medium, or low H(2) uptake activity, respectively, maintained those phenotypes during in vitro assays.

Host Plant Cultivar Effects on Hydrogen Evolution by Rhizobium leguminosarum

The effect of host plant cultivar on H(2) evolution by root nodules was examined in symbioses between Pisum sativum L. and selected strains of Rhizobium leguminosarum. Hydrogen evolution from root nodules containing Rhizobium represents the sum of H(2) produced by the nitrogenase enzyme complex and H(2) oxidized by any uptake hydrogenase present in those bacterial cells. Relative efficiency (RE) calculated as RE = 1 - (H(2) evolved in air/C(2) H(2) reduced) did not vary significantly among ;Feltham First,' ;Alaska,' and ;JI1205' peas inoculated with R. leguminosarum strain 300, which lacks uptake hydrogenase activity (Hup(-)). That observation suggests that the three host cultivars had no effect on H(2) production by nitrogenase. However, RE of strain 128C53 was significantly (P </= 0.05) greater in symbiosis with cultivar JI1205 than in root nodules of Feltham First. At a similar rate of C(2)H(2) reduction on a whole-plant basis, nearly 24 times more H(2) was evolved from the Feltham First/128C53 symbiosis than from the JI1205/128C53 association. Root nodules from the Alaska/128C53 symbiosis had an intermediate RE over the entire study period, which extended from 21 to 36 days after planting. Direct assays of uptake hydrogenase by two methods showed significant (P </= 0.05) host cultivar effects on H(2) uptake capacity of both strain 128C53 and the genetically related strain 3960. The (3)H(2) incorporation assay showed that strains 128C53 and 3960 in symbiosis with Feltham First had about 10% of the uptake hydrogenase activity measured in root nodules of Alaska or JI1205. These data are the first demonstration of significant host plant effects on rhizobial uptake hydrogenase in a single plant species.