The pea (Pisum sativum L.) genes sym33 and sym40 control infection thread formation and root nodule function

Two novel non-allelic mutants that were unable to fix nitrogen (Fix^?) were obtained after EMS (ethyl methyl sulfonate) mutagenesis of pea (Pisum sativum L.). Both mutants, SGEFix^?–1 and SGEFix^?–2, form two types of nodules: SGEFix^?–1 forms numerous white and some pink nodules, while mutant SGEFix^?–2 forms white nodules with a dark pit at the distal end and also some pinkish nodules. Both mutations are monogenic and recessive. In both lines the manifestation of the mutant phenotype is associated with the root genotype. White nodules of SGEFix^?–1 are characterised by hypertrophied infection threads and infection droplets, mass endocytosis of bacteria, abnormal morphological differentiation of bacteroids, and premature degradation of nodule symbiotic structures. The structure of the pink nodules of SGEFix^?–1 does not differ from that of the parental line, SGE. White nodules of SGEFix^?–2 are characterised by “locked” infection threads surrounded with abnormally thick plant cell walls. In these nodules there is no endocytosis of bacteria into host-cell cytoplasm. The pinkish nodules of SGEFix^?–2 are characterised by virtually undifferentiated bacteroids and premature degradation of nodule tissues. Thus, the novel pea symbiotic genes, sym40 and sym33, identified after complementation analysis in SGEFix^?–1 and SGEFix^?–2 lines, respectively, control early nodule developmental stages connected with infection thread formation and function.     

The Sym31Gene Responsible for Bacteroid Differentiation Is Involved in Nitrate-Dependent Nodule Formation in Pea Plants

The effects of exogenous nitrate on the number of developing nodules and their leghemoglobin content in the original pea (Pisum sativumL.) line and its symbiotic mutants were studied. Mutation in the Sym31gene conferred the tolerance to nitrate in the corresponding pea line and manifested itself as the number of nodules independent of the nitrate concentration. Thus, the Sym31gene was identified as the only known symbiotic gene involved in both the differentiation of symbiotic compartments and the nitrate-dependent process of nodule formation. The presence of leghemoglobin in double mutants (sym13, sym31) indicates the possibility of the complementary contribution of these genes in the control of leghemoglobin synthesis.     

Rhizobium leguminosarum strains forming nitrogen-rich nodules inPisum sativum

The nodules which developed on the roots ofPisum sativum after inoculation withRhizobium leguminosarum bv.viciae strains showing a Hup⁺ symbiotic phenotype and/or a high relative efficiency of electron transfer to dinitrogen (RE) had a high nitrogen content of their tissue. In comparison with the nodules initiated by a strain possessing the Hup⁻ symbiotic phenotype or by an indigenous soilRhizobium population, the nitrogen-rich root nodules contained up to four times more nitrogen (9.2% of dry mass). In the nitrogen-rich nodules, total amino acid, and especially Ala, Lys and Phe contents were significantly increased. The nitrogen-rich nodule symbiotic phenotype (Nrn) was well expressed, irrespective of pea cultivars and host plant age. If a strain showing the Nrn phenotype was applied in double-strain inocula, a significant correlation was found between increasing rates of the strain and increasing percentage nitrogen content of nodule tissue in the nodulated plants.     

Compatibility of Rhizobial Genotypes within Natural Populations of Rhizobium leguminosarum Biovar viciae for Nodulation of Host Legumes

Populations of Rhizobium leguminosarum biovar viciae were sampled from two bulk soils, rhizosphere, and nodules of host legumes, fava bean (Vicia faba) and pea (Pisum sativum) grown in the same soils. Additional populations nodulating peas, fava beans, and vetches (Vicia sativa) grown in other soils and fava bean-nodulating strains from various geographic sites were also analyzed. The rhizobia were characterized by repetitive extragenomic palindromic-PCR fingerprinting and/or PCR-restriction fragment length polymorphism (RFLP) of 16S-23S ribosomal DNA intergenic spacers as markers of the genomic background and PCR-RFLP of a nodulation gene region, nodD, as a marker of the symbiotic component of the genome. Pairwise comparisons showed differences among the genetic structures of the bulk soil, rhizosphere, and nodule populations and in the degree of host specificity within the Vicieae cross-inoculation group. With fava bean, the symbiotic genotype appeared to be the preponderant determinant of the success in nodule occupancy of rhizobial genotypes independently of the associated genomic background, the plant genotype, and the soil sampled. The interaction between one particular rhizobial symbiotic genotype and fava bean seems to be highly specific for nodulation and linked to the efficiency of nitrogen fixation. By contrast with bulk soil and fava bean-nodulating populations, the analysis of pea-nodulating populations showed preferential associations between genomic backgrounds and symbiotic genotypes. Both components of the rhizobial genome may influence competitiveness for nodulation of pea, and rhizosphere colonization may be a decisive step in competition for nodule occupancy.     

The pea ( Pisum sativum L.) genes sym33 and sym40 control infection thread formation and root nodule function

Two novel non-allelic mutants that were unable to fix nitrogen (Fix⁻) were obtained after EMS (ethyl methyl sulfonate) mutagenesis of pea (Pisum sativum L.). Both mutants, SGEFix⁻–1 and SGEFix⁻–2, form two types of nodules: SGEFix⁻–1 forms numerous white and some pink nodules, while mutant SGEFix⁻–2 forms white nodules with a dark pit at the distal end and also some pinkish nodules. Both mutations are monogenic and recessive. In both lines the manifestation of the mutant phenotype is associated with the root genotype. White nodules of SGEFix⁻–1 are characterised by hypertrophied infection threads and infection droplets, mass endocytosis of bacteria, abnormal morphological differentiation of bacteroids, and premature degradation of nodule symbiotic structures. The structure of the pink nodules of SGEFix⁻–1 does not differ from that of the parental line, SGE. White nodules of SGEFix⁻–2 are characterised by “locked” infection threads surrounded with abnormally thick plant cell walls. In these nodules there is no endocytosis of bacteria into host-cell cytoplasm. The pinkish nodules of SGEFix⁻–2 are characterised by virtually undifferentiated bacteroids and premature degradation of nodule tissues. Thus, the novel pea symbiotic genes, sym40 and sym33, identified after complementation analysis in SGEFix⁻–1 and SGEFix⁻–2 lines, respectively, control early nodule developmental stages connected with infection thread formation and function. Received: 12 June 1998 / Accepted: 25 June 1998     

Immunocytological evidence for abnormal symbiosome development in nodules of the pea mutant line Sprint2Fix− (sym31)

Summary Using a series of antibody probes as markers of symbiosome development, we have investigated the impaired development of symbiosomes in nodules formed by the plant mutant line Sprint2Fix⁻ (sym31). In wild-type pea (Pisum sativum L.) nodules, bacteria differentiate into large pleiomorphic, nitrogen-fixing bacteroids and are singly enclosed within a peribacteroid membrane. In thesym31 mutant, several small undifferentiated bacteroids were often enclosed within one peribacteroid membrane, or were found within a vacuole-like compartment. In wild-type nodules, the monoclonal antibody JIM18, which recognizes a plasmalemma glycolipid antigen, bound to the juvenile peribacteroid membrane, and did not recognize the mature peribacteroid membrane. However, in the mutant, the antibody bound to all peribacteroid membranes within the nodule, suggesting that differentiation of the peribacteroid membrane was arrested. Another antibody, MAC266, recognized plant glycoproteins which normally accumulate in symbiosomes at a late stage of nodule development. Binding of this antibody was much reduced within mutant nodules, labelling only a few mature cells. Similarly, MAC301, which normally recognizes a lipopolysaccharide epitope expressed on differentiated bacteroids prior to the induction of nitrogenase, failed to react with rhizobial cell extracts isolated from nodules of thesym31 mutant. On the basis of these developmental markers, the symbiosomes ofsym31 nodules appeared to be blocked at an early stage of development. The distribution of infection structures was also found to be abnormal in the mutant nodules. Models of symbiosome development are presented and discussed in relation to the morphological and developmental lesions observed in thesym31 mutant.     

Polyamines in Nodules from Various Plant-Microbe Symbiotic Associations

Polyamine compositions of root or stem nodules collected fromvarieties of nitrogen-fixing leguminous (22 species) and non-leguminous(5 species) plants were investigated. Relatively high concentrationsof homospermidine were observed in root or stem nodules of allthe leguminous plants. Based on the ratio of homospermidineto spermidine, legume nodules were generally characterized intotwo major groupes; one containing almost equal amounts of homospermidineand spermidine, and the other a high homospermidine/spermidineratio. Root nodules from pigeon pea (Cajanus cajan L. Millsp)was the only exception which exhibited very low homospermidine/spermidineratio. Amongst the legumes, nodules of adzuki bean (Vigna angularis),siratro (Macroptilium atropurpureum DC. Urb.), pea (Pisum sativumL.), and hairly vetch (Vicia hirsuta S.F. Gray) were rich indiamine putrescine. Such characters of nodule polyamine compositionwere inherent characteristics of each legume species, and notrelated to the type of infected rhizobia (Rhizobium or Bradyrhizobium).In contrast to herbaceous leguminous plants, nonleguminous woodyplants, which symbiotically associate with actinomycete Frankiaspecies, contained little polyamines in their root nodules.Root nodules of non-leguminous Parasponia andersonii infectedby bradyrhizobia were found to contain large quantities of putrescineand homospermidine. No significant differences in polyaminecomposition were observed between root and stem nodules bothin Aeschynomene indica and Sesbania rostrata. (Received June 13, 1994; Accepted August 17, 1994)     

New Gene Crt(Curly Roots) Controlling Pea (Pisum sativum L.) Root Development

Using ethyl methane sulfonate (EMS) treatment of the seeds ofline SGE, a new mutant of pea (Pisum sativum L.) with alterationsin root development was obtained. The mutant phenotype dependson the density of the growth substrate: on sand (a high densitysubstrate) the mutant forms a small compact curly root systemwhereas on vermiculite (a low density substrate) differencesbetween the root systems of the mutant and wild type plantsare less pronounced. Genetic analysis revealed that the mutantcarries a mutation in a new pea gene designedcrt (curly roots).Gene crt has been localized in pea linkage group V. The mutantline named SGEcrt showed increased sensitivity to exogenousauxin and an increased concentration of endogenous indole-3-aceticacid (IAA) in comparison with the wild type line SGE. Copyright2000 Annals of Botany Company Pisum sativum L., root development, garden pea mutant, curly roots, auxin, environmental stimulus response     

NODULE ROOT and COCHLEATA Maintain Nodule Development and Are Legume Orthologs of Arabidopsis BLADE-ON-PETIOLE Genes

During their symbiotic interaction with rhizobia, legume plants develop symbiosis-specific organs on their roots, called nodules, that house nitrogen-fixing bacteria. The molecular mechanisms governing the identity and maintenance of these organs are unknown. Using Medicago truncatula nodule root (noot) mutants and pea (Pisum sativum) cochleata (coch) mutants, which are characterized by the abnormal development of roots from the nodule, we identified the NOOT and COCH genes as being necessary for the robust maintenance of nodule identity throughout the nodule developmental program. NOOT and COCH are Arabidopsis thaliana BLADE-ON-PETIOLE orthologs, and we have shown that their functions in leaf and flower development are conserved in M. truncatula and pea. The identification of these two genes defines a clade in the BTB/POZ-ankyrin domain proteins that shares conserved functions in eudicot organ development and suggests that NOOT and COCH were recruited to repress root identity in the legume symbiotic organ.     

Root system growth and nodule establishment on pea (Pisum sativum L.)

Development of the root system, appearance of nodules, and relationshipsbetween these two processes were studied on pea (Pisum sativumL., cv. Solara). Plants were grown in growth cabinets for 4weeks on a nitrogen—free nutrient solution inoculatedwith Rhizobium leguminosarum. Plant stages, primary root length,distance from the primary root base to the most distal first-orderlateral root, and distance from the root base to the most distalnodule, were recorded daily. Distribution of nodules along theprimary root and distribution of laterals were recorded by samplingroot systems at two plant stages. Primary root elongation ratewas variable, and declined roughly in conjunction with the exhaustionof seed reserves. First-order laterals appeared acropetallyon the primary root. A linear relationship was found betweenthe length of the apical unbranched zone and root elongationrate, supporting the hypothesis of a constant time lag betweenthe differentiation of first-order lateral's primordia and theiremergence. Decline of the primary root elongation rate was precededby a reduction in density and length of first-order laterals.Nodules appeared not strictly but roughly acropetally on theprimary root. A linear relationship was found between the lengthof the apical zone without nodule and root elongation rate,supporting the hypothesis of a constant time lag between infectionand appearance of a visible nodule. A relationship was foundbetween the presence/absence of nodules on a root segment andthe root elongation rate between infection and appearance ofnodules on the considered root segment. Regulation of both processesby carbohydrate availability, as a causal mechanism, is proposed. Key words: Pisum sativum L, root system, nodules     

Distribution of legume arabinogalactan protein-extensin (AGPE) glycoproteins in symbiotically defective pea mutants with abnormal infection threads

The interface between the host cell and the microsymbiont is an important zone for development and differentiation during consecutive stages of Rhizobium-legume symbiosis. Legume root nodule extensins, otherwise known as arabinogalactan protein-extensins (AGPEs) are abundant components of infection thread matrix. We have characterized the origin and distribution of these glycoproteins at the symbiotic interface of root nodules of symbiotically defective mutants of pea (Pisum sativum L.) by using immunogold localization with MAC265 an anti-AGPE monoclonal antibody. For mutants with defective growth of infection threads, the AGPE epitope was abundant in the extracellular matrix surrounding infected host cells in the central infected tissue of the nodule, as well as in the lumen of Rhizobiuminduced infection threads. This seems to indicate a mistargeting of AGPE as a consequence of abnormal growth of the infection threads. Furthermore, mutants in the gene sym33 showed reduced labeling with MAC265 and, in some infection threads and droplets, the label was completely absent, a phenomenon that is not observed in wild-type nodules. This suggests an alteration in the composition of the infection thread matrix for sym33 mutants, which may be correlated to the absence of endocytosis of rhizobia into the host cytoplasm.     

Developmentally Regulated Expression of the Gene Family for Cytosolic Glutamine Synthetase in Pisum sativum

In Pisum sativum, two classes of genes encode distinct isoforms of cytosolic glutamine synthetase (GS). The first class comprises two nearly identical or “twin” GS genes (GS341 and GS132), while the second comprises a single GS gene (GS299) distinct in both coding and noncoding regions from the “twin” GS genes. Gene-specific analyses were used to monitor the individual contribution of each gene for cytosolic GS during root nodule development and in cotyledons during germination, two contexts where large amounts of ammonia must be assimilated by GS for nitrogen transport. mRNAs corresponding to all three genes for cytosolic GS were shown to accumulate coordinately during a time course of nodule development. All the GS mRNAs also accumulate to wild-type levels in mutant nodules formed by a nifD⁻ strain of Rhizobium leguminosarum indicating that induced GS expression in pea root nodules does not depend on the production of ammonia. Distinct patterns of expression for the two classes of GS genes were observed in certain mutant root nodules and most dramatically in cotyledons of germinating seedlings. The different patterns of expression between the two classes of genes for cytosolic GS suggests that their distinct gene products may serve nonoverlapping functions during pea development.     

Anatomy, physiology and biochemistry of root nodules of Sprint-2 Fix-, a symbiotically defective mutant of pea (Pisum sativum L.)

A plant-determined pea mutant Sprint-2 Fix^– and the parentalline Sprint-2 were compared for selected physiological and biochemicalparameters. The Fix^– mutation prevented differentiationof Rhizobium leguminosarum bacteria into bacteroids and producedlarge, white, non-fixing nodules. These lacked nitrogenase-linkedrespiration, but had a background rate of CO₂ evolution similarto the normal Fix⁺ nodules. The cortical structure of the ineffectivenodules suggests the existence of an oxygen diffusion barrierand this was supported by a low oxygen concentration in thecentral region (0.5–3.0%), measured using an O₂ sensitivemicro-electrode. Sucrose and starch contents were similar innormal and ineffective nodules while ononitol content was about15 times lower in the Fix^– nodules. The distribution ofstarch was also different in the two nodule types. The activitiesof glutamine synthetase (GS), sucrose synthase (SS), phosphoenolpyruvatecarboxylase (PEPC) and alanine pyruvate aminotransferase (APAT)were markedly higher in Fix⁺ nodules while the activities ofpyruvate decarboxylase (PDC), alcohol dehydrogenase (ADH) andglutamate dehydrogenase (GDH) were higher in Fix^– nodules.The data from immunodetection of host nodule proteins confirmedthe reduced levels of sucrose synthase and the almost completeabsence of glutamine synthetase and leghaemoglobin in mutantnodules. There was no significant difference in the amount ofnitrogenase component 1 extracted from the microsymbiont ofnormal and ineffective nodules, but component 2 was hardly detectablein the Fix^– mutant. Key words: Pisum sativum, Fix^– mutant, nodules     

Comparison of Enzymes Involved in Carbon and Nitrogen Metabolism in Normal Nodules and Ineffective Nodules Induced by a Pea Mutant E135 (sym 13)

Activities of enzymes involved in carbon and nitrogen metabolismwere examined in nodules of normal pea (Pisum sativum L. cv.Sparkle) and an ineffective plant mutant E135 (sym 13). Specificactivities of some enzymes were lower in ineffective nodulesthan in effective nodules. However, there were no major differencesbetween respective bacteroid fractions. ¹Present address: Department of Life Science, Aichi Universityof Education, Kariya, Aichi, 448 Japan