Gene expression profiles during early stages of formation of symbiotic nitrogen-fixing nodules in a model legume Lotus japonicus were analyzed by means of a cDNA array of 18,144 non-redundant expressed sequence tags (ESTs) isolated from L. japonicus. Expression of a total of 1,076 genes was significantly accelerated during the successive stages that represent infection of Mesorhizobium loti, nodule primordium initiation, nodule organogenesis, and the onset of nitrogen fixation. These include 32 nodulin and nodulinhomolog genes as well as a number of genes involved in the catabolism of photosynthates and assimilation of fixed nitrogen that were previously known to be abundantly expressed in root nodules of many legumes. We also identified a large number of novel nodule-specific or enhanced genes, which include genes involved in many cellular processes such as membrane transport, defense responses, phytohormone synthesis and responses, signal transduction, cell wall synthesis, and transcriptional regulation. Notably, our data indicate that the gene expression profile in early steps of Rhizobium-legume interactions is considerably different from that in subsequent stages of nodule development. A number of genes involved in the defense responses to pathogens and other stresses were induced abundantly in the infection process, but their expression was suppressed during subsequent nodule formation. The results provide a comprehensive data source for investigation of molecular mechanisms underlying nodulation and symbiotic nitrogen fixation.
Legume plants establish a symbiotic association with bacteria called rhizobia, resulting in the formation of nitrogen-fixing root nodules. A Lotus japonicus symbiotic mutant, sen1, forms nodules that are infected by rhizobia but that do not fix nitrogen. Here, we report molecular identification of the causal gene, SEN1, by map-based cloning. The SEN1 gene encodes an integral membrane protein homologous to Glycine max nodulin-21, and also to CCC1, a vacuolar iron/manganese transporter of Saccharomyces cerevisiae, and VIT1, a vacuolar iron transporter of Arabidopsis thaliana. Expression of the SEN1 gene was detected exclusively in nodule-infected cells and increased during nodule development. Nif gene expression as well as the presence of nitrogenase proteins was detected in rhizobia from sen1 nodules, although the levels of expression were low compared with those from wild-type nodules. Microscopic observations revealed that symbiosome and/or bacteroid differentiation are impaired in the sen1 nodules even at a very early stage of nodule development. Phylogenetic analysis indicated that SEN1 belongs to a protein clade specific to legumes. These results indicate that SEN1 is essential for nitrogen fixation activity and symbiosome/bacteroid differentiation in legume nodules.
The rnf genes in Rhodobacter capsulatus are unique nitrogen fixation genes that encode potential membrane proteins (RnfA, RnfD, and RnfE) and potential iron-sulfur proteins (RnfB and RnfC). In this study, we first analyzed the localization and topology of the RnfA, RnfB, and RnfC proteins. By activity and immunoblot analysis of expression of translational fusions to Escherichia coli alkaline phosphatase, RnfA protein was shown to span the chromatophore membrane with its odd-numbered hydrophilic regions exposed to periplasm. By alkaline treatment of membrane fractions and following immunoblot analysis using antibodies against recombinant proteins expressed in E. coli, both RnfB and RnfC proteins were revealed to situate at the periphery of the chromatophore membranes. Second, mutual interaction of the Rnf proteins was analyzed by immunochemical determinations of RnfB and RnfC proteins in rnf mutants and their complemented derivatives. The contents in cellular fractions indicated that RnfB and RnfC stabilize each other and that the presence of RnfA is necessary for stable existence of both proteins. These results support a hypothesis that the Rnf products are subunits of a membrane complex. Finally, we detected homologs of rnf genes in Haemophilus influenzae and Vibrio alginolyticus by data base searches and in E. coli by cloning of a fragment of an rnfA homolog followed by a data base search. Close comparisons revealed that RnfC has potential binding sites for NADH and FMN which are similar to those found in proton-translocating NADH:quinone oxidoreductases and that RnfA, RnfD, and RnfE show similarity to subunits of sodium-translocating NADH:quinone oxidoreductases. We predict that the putative Rnf complex represents a novel family of energy-coupling NADH oxidoreductases.
We investigated the efficacy of self-complementary hairpin RNA (hpRNA) expression to induce RNA silencing in the roots and nodules of model legume Lotus japonicus, using hairy root transformation mediated by Agrobacterium rhizogenes. Transgenic lines that express beta-glucuronidase (GUS) by constitutive or nodule-specific promoters were supertransformed by infection of A. rhizogenes harboring constructs for the expression of hpRNAs with sequences complementary to the GUS coding region. GUS activity in more than 60% of the hairy roots was decreased or silenced almost completely. Silencing of the GUS gene was also observed in symbiotic nodules formed on hairy roots in both early and late stages of nodule organogenesis. These results indicate that transient RNA silencing by hairy root transformation provides a powerful tool for loss-of-function analyses of genes that function in roots and root nodules.
Sandal et al. MPMI 4 INTRODUCTIONGenetic analysis and application of genetic approaches in the model legume Lotus japonicus (Handberg and Stougaard 1992) has progressed rapidly. Several key genes important for symbiosis with mycorrhizal fungi, root nodule development and other developmental processes have been identified using molecular genetics. The developmental regulators Nin (Schauser et al. 1999) and Pfo (Zhang et al. 2002) were isolated by transposon tagging while map-based cloning led to the molecular characterisation of Har1, SymRK, Nfr1, Nfr5, Castor and Pollux involved in autoregulation, Nod-factor signal perception or signal transduction (Schauser et al. 1999, Krusell et al. 2002 Nishimura et al. 2002a;Stracke et al. 2002;Radutoiu et al. 2003;Madsen et al. 2003; Imaizumi-Anraku et al. 2005). Genetic loci required for the early stages of endosymbiosis have attracted particular interest. Diallelic crosses together with phenotypical studies defined seven loci, SymRK, Nup133, Castor, Pollux, Sym6, Sym15,Sym24, in the common pathway required for both rhizobial and mycorrhizal symbiosis (Kistner et al. unpublished data) and map-based cloning of these loci has been accomplished or is advancing rapidly. A similar interest and effort is now emerging for genetic dissection of nodule organogenesis and function using the Fix -mutants arrested at various stages of nodule development or impaired in nodule function. Cloning of the Sst1 sulfate transporter required in functional root nodules is a first example (Krusell et al. 2005).Continuous isolation of new plant mutant lines is important for completing the genetic dissection of symbiosis and so far six independent mutant populations have been obtained by chemical (EMS) mutagenesis (Perry et al. 2003;Szczyglowski et al. 1998; Webb et al. unpublished data; Gresshoff et al. unpublished data), four populations after T-DNA or transposon insertion mutagenesis (Thykjaer et al. 1995;Schauser et al. 1998;Webb et al. 2000; Gresshoff et al. unpublished data), one population made with fast neutrons (Gresshoff et al. unpublished Umehara and Kouchi (unpublished data). All in all more than 400 symbiotic Lotus mutant lines were identified by screening in these populations and more are likely to follow. Assignment to complementation groups is next logical step in order to determine the number of loci involved, identify all alleles that contribute to phenotypic characterisation of mutants and genotyping of loci. However, diallelic crossing is a relatively slow process where progress is determined by generation time and slowed by a continuously increasing number of individual crosses necessary to keep up with mutant isolation programs. Given the number of symbiotic mutant lines already available and considering the time used to define seven complementation groups with a total of 26 alleles constituting the common pathway (Kistner et al. unpublished data), this approach is unlikely to encompass all alleles in near future. Detection of alleles in already cloned genes ...
Nitrogen-fixing symbiosis of legume plants with Rhizobium bacteria is established through complex interactions between two symbiotic partners. Similar to the mutual recognition and interactions at the initial stages of symbiosis, nitrogen fixation activity of rhizobia inside root nodules of the host legume is also controlled by specific interactions during later stages of nodule development. We isolated a novel Fix 2 mutant, ineffective greenish nodules 1 (ign1), of Lotus japonicus, which forms apparently normal nodules containing endosymbiotic bacteria, but does not develop nitrogen fixation activity. Map-based cloning of the mutated gene allowed us to identify the IGN1 gene, which encodes a novel ankyrin-repeat protein with transmembrane regions. IGN1 expression was detected in all organs of L. japonicus and not enhanced in the nodulation process. Immunoanalysis, together with expression analysis of a green fluorescent protein-IGN1 fusion construct, demonstrated localization of the IGN1 protein in the plasma membrane. The ign1 nodules showed extremely rapid premature senescence. Irregularly enlarged symbiosomes with multiple bacteroids were observed at early stages (8-9 d post inoculation) of nodule formation, followed by disruption of the symbiosomes and disintegration of nodule infected cell cytoplasm with aggregation of the bacteroids. Although the exact biochemical functions of the IGN1 gene are still to be elucidated, these results indicate that IGN1 is required for differentiation and/or persistence of bacteroids and symbiosomes, thus being essential for functional symbiosis.
ENOD40 is one of the most intriguing early nodulin genes that is known to be induced very early in response to interaction of legume plants with symbiotic Rhizobium bacteria, but its function in the nodulation process is still not known. Lotus japonicus has two ENOD40 genes: LjENOD40-1 is abundantly induced in very early stages of bacterial infection or Nod factor application, whereas LjENOD40-2 is abundantly expressed only in mature nodules. We generated transgenic lines of L. japonicus with an RNAi (RNA interference) construct that expresses hairpin double-stranded RNA for LjENOD40-1 to induce sequence-specific RNA silencing. In the transgenic plants, expression of both LjENOD40-1 and -2 was significantly reduced, and no accumulation of ENOD40 transcripts was detected upon Mesorhizobium loti inoculation. The transgenic plants exhibited very poor nodulation (only 0-2 nodules per plant) and could not grow well without additional nitrogen supply. Analysis of segregation in the T(2) progeny indicated that the suppression of nodulation is perfectly linked with the presence of the transgene. Microscopic observation of the infection process using lacZ-labeled M. loti, together with expression analysis of infection-related nodulin genes, demonstrated that ENOD40 knock-down did not inhibit the initiation of the bacterial infection process. In contrast, nodule primordium initiation and subsequent nodule development were significantly suppressed in the transgenic plants. These results clearly indicate that ENOD40 is required for nodule initiation and subsequent organogenesis, but is not involved in early infection events.
The rnf genes in Rhodobacter capsulatus are essential for nitrogen fixation in the light. Because R. capsulatus grows readily on N2 in the dark by anaerobic respiration with dimethylsulfoxide, the diazotrophic capacities of various strains in the dark were examined. No rnf mutants tested grew diazotrophically, and a nonpolar fdxN-null mutant showed decreased diazotrophic growth in the dark, suggesting that the Rnf and FdxN proteins form the primary electron donor pathway to nitrogenase in the dark as well as in the light. Nonphotosynthetic mutants lacking the component of cyclic electron transport grew diazotrophically and the levels of Rnf proteins were similar to those of the wild-type. These results indicate that rnf gene products play an essential role in nitrogen fixation without any functional link to the cyclic electron transport system.
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