Toward More Productive,Efficient, and Competitive Nitrogen-Fixing Symbiotic Bacteria

The prospects of developing strains of legume nodule bacteria that provide higher productivity of leguminous plants are described. The generic, biochemical, physiological, regulatory, and economic constraints that govern the ability of private and public efforts to construct better inoculants for legume nodulation are discussed. Success in constructing better inoculants requires a two-pronged approach. First, strains need to be improved in order to compete successfully with indigenous strains for root nodulation of legumes. Several loci have been identified to date that affect competitiveness for strain nodule occupancy. Usually mutations in these loci affect the ability of a strain to form nodules rapidly and efficiently. Other loci, such as those that confer antibiotic production, can be added to strains to enhance nodulation competitiveness when co-inoculated with antibiotic-sensitive strains. Second, the inoculum strains must be improved with respect to symbiotic nitrogen fixation. Efforts to enhance the symbiotic productivity of legume nodule bacteria either by mutation or genetic engineering are also described. The best characterized example of these is the hydrogenase system. Due to nitrogenase-dependent catalysis of proton reduction, diazotrophs evolve large amounts of H₂. An approach to maximize the efficiency of symbiotic N₂ fixation, and therefore of legume productivity, is to construct strains of Rhizobium with the ability to oxidize this otherwise wasted H₂. The electrons produced by H₂ oxidation are funneled through energy-conserving electron transport chains. Our knowledge of the genetics and biochemistry of H₂ oxidation in Bradyrhizobium japonicum and Rhizobium leguminosarum has developed rapidly in recent years. At least 20 genes are needed for these bacteria to manufacture and efficiently express a nickel-containing H₂-uptake hydrogenase. These genes include those encoding regulatory elements, posttranslational processing enzymes, nickel-sensing and nickel-metabolism proteins, and electron transport components for integrating the electrons from H₂ oxidation into the respiratory chain. Some of the components for oxidizing H₂ in the symbiotic N₂ fixing bacteria are distinct from the analogous components in (nonsymbiotic) H₂ oxidizing bacteria.     

(Brady)Rhizobium-plant communications involved in infection and nodulation

Conclusion The interactions between(Brady)Rhizobium and legume plants involves many interesting problems. In the last ten years, there were remarkable experiments which have detected excreted flavonoid compounds at pmol levels from plant roots, which induce(Brady)Rhizobium nod gene expression (Long 1989, Nap and Bisseling 1990, Dénariéet al. 1992, Schlamanet al. 1992). The responses of rhizobial genes to the various kinds of chemical compound are different (Maxwellet al. 1989, Zaatet al. 1989, Davis and Johnston 1990, Hartwiget al. 1990, Hungriaet al. 1992). The resolution of pSym genes controlling those mechanisms makes way for the long-term goal of introducing nitrogen fixation ability into nonlegume plants. Recently, some experiments have shown thatRhizobium and other nitrogen fixing bacteria form nodule-like strutures on rice, barley or wheat (Al-Mallah 1989, Jinget al. 1990, Rolfe and Bender 1991). Some O₂ protection mechanism instead of leghemoglobin must be needed for nitrogen fixation byRhizobium or other N₂-fixing bacteria which have invaded in the nonlegume root tissue. The isolation of the plant mutants or preparation of transgenic plants capable of hyper-nodule formation having efficient nitrogen fixation ability may be major goals. For the attainment of these goals, transformation of a foreign genome (nif-ornod gene cassette) into the plant cell might be a good way to proceed (Barkeret al. 1990). It is also necessary to clarify the relationships between the level of relative endogenous plant hormones and the exchange of the differentiation of the root tissue to the nodule tissue. This phenomenon of redifferentiation of plant tissue by the results from(Brady)Rhizobium and legume communications will be an important approach likely to lead to solve the molecular basis of plant having “TOTIPOTENCY”.     

Nodulation competitiveness in the Rhizobium-legume symbiosis

Successful nodulation of legumes by rhizobia is a complex process that, in the open field, depends on many different environmental factors. Generally, legume productivity in an agricultural field may be improved by inoculation with selected highly effective N₂-fixing root nodule bacteria. However, field legume inoculation with Rhizobium and Bradyrhizobium spp. has often been unsuccessful because of the presence in the soil of native strains that compete with the introduced strain in nodule formation on the host plants. This ability to dominate nodulation is termed competitiveness and is critical for the successful use of inoculants.The author is with the Departmentode Microbiologia del Suelo y Sistemas Simbioticos, Estation Experimental del Zaidin, Consejo Superior de Investigaciones Cientificas, C/Professor Albareda 1, 18008 Granada, Spain     

Complete sequence of a Rhizobium plasmid carrying genes necessary for symbiotic association with the plant host

The soil bacteria rhizobia have the capacity to establish nitrogen-fixing symbiosis with their leguminous host plants. In most Rhizobium species the genes for nodule development and nitrogen fixation have been localized on large indigenous plasmids that are transmissible, allowing lateral transfer of symbiotic functions. A recent paper reports on the complete sequencing of the symbiotic plasmid pNGR234a from Rhizobium species NGR234⁽¹⁾, revealing not only putative new symbiotic genes but also possible mechanisms for evolution and lateral dispersal of symbiotic nitrogen-fixing abilities among rhizobia.     

Bacteria-plant interactions in symbiotic nitrogen fixation

In the inter- and intracellular N₂-fixing symbioses between plants and micro-symbionts, the development of an endophytic form of the micro-symbiont is essential. This development includes a series of steps consisting of plant-bacteria interactions. Considerable progress in the elucidation of these steps has been made by applications of the methods of molecular genetics. Several genes with a role during infection and nodulation have been indicated in Rhizobium and Bradyrhizobium like the common nod genes A, B, C, I and J, and the host-specific genes nod E, F and H. The nod D gene is the only constitutive gene, and its product is essential for activity of all other nod genes, provided some flavonoids from the root exudate are present as well. Mutants in these genes show phenotypic effects, in which the products of the genes must be involved. Far more difficult is the biochemical and physiological study of these products and their direct effects. The difficulties involved in such biochemical-physiological studies is illustrated by a short discussion of the controversies around the possible role of plant lectins. While in Rhizobium the nod genes are present on a large sym-plasmid, other essential genes must be present on the bacterial chromosome and on other plasmids. Induction of plant genes is evident from the formation of nodule-specific proteins, the nodulins. Though many different plant and bacterial genes are involved in the series of steps in the development of an effective root nodule, there are indications that regulation is affected by a smaller number of essential regulatory genes. This is illustrated by the effect of the regulatory nod D gene during infection and nodulation, and of ntrA and nifA genes for the formation and activation of the nitrogen-fixing systems. Moreover, every step, once initiated, may lead to cascade effects on subsequent reactions. Finally, some further consequences of the endophytic way of life are discussed, which affect either the metabolic and transport activities of the endophytes or their viability. This is illustrated by the possible role of membrane integrity as evident during the isolation of Frankia from its endophytic form.     

A multiple-trait breeding program for improving the symbiosis for N2 fixation betweenMedicago sativa L. andRhizobium meliloti

Summary The goal of breeding alfalfa for increased N₂ fixation potential is addressed. A chronological progression of breeding, physiological, microbiological, and plant pathological research is described. Studies describing the interrelationships among plant morphological, plant physiological, andRhizobium effectiveness traits are summarized. It was concluded that N₂ fixation in alfalfa is affected by coordinated responses among many physiological and biochemical traits. The simultaneous improvement of many factors in the symbiosis requires a comprehensive multiple-step breeding program. The current program includes selection in the glasshouse for seedling vigor,Rhizobium preference, shoot growth, nodule mass, root growth, nitrogenase (as measured by acetylene reduction), and nodule enzyme activity. The inclusion of additional selection traits is anticipated. Field evaluations of N₂ fixation potential of alfalfa populations are made with¹⁵N isotope dilution techniques. Plant germplasm sources used in the breeding program include several heterogeneous populations which have good combining ability and pest resistance when they are intercrossed. Significant progress has been made in achieving the goal of breeding alfalfa for improved N₂ fixation.     

Structural identification of the iipo-chitin oligosaccharide nodulation signals of Rhizobium loti

Rhizobium loti is a fast-growing Rhizobium species that has been described as a microsymbiont of plants of the genus Lotus. Nodulation studies show that Lotus plants are nodulated by R loti, but not by most other Rhizobium strains, indicating that R. loti produces specific lipo-chitin oligosaccharides (LCOs) which are necessary for the nodulation of Lotus plants. The LCOs produced by five different Rhizobium ioti strains have been purified and were shown to be N-acetylglucosamine pentasaccharides of which the non-reducing residue is N-methylated and N-acylated with c/s-vaccenic acid (C18:1) or stearic acid (C18:O) and carries a carbamoyl group. In one R. loti strain, NZP2037, an additional carbamoyl group is present on the non-reducing terminal residue. The major class of LCO molecules is substituted on the reducing terminal residue with 4-O-acetylfucose. Addition of LCOs to the roots of Lotus plants results in abundant distortion, swelling and branching of the root hairs, whereas spot inoculation leads to the formation of nodule primordia.     

Induction of nodule primordia on Phaseolus and Acacia by lipo-chitin oligosaccharide nodulation signals from broad-host-range Rhizobium strain GRH2

Rhizobium wild-type strain GRH2 was originally isolated from the tree, Acacia cyanophylla, and has a broad host-range which includes herbaceous legumes, such as Phaseolus and Trifolium species. Here we show that strains of Rhizobium sp. GRH2, into which heterologous nodD alleles have been introduced, produce a large diversity of both sulphated and non-sulphated lipo-chitin oligosaccharides (LCOs). Most of the molecular species contain an N-methyl group on the reducing-terminal N-acetyl-glucosamine. The LCOs vary in the nature of the fatty acyl chain and in the length of the chitin backbone. The majority of the LCOs have an olgosaccharide chain length of five GlcNAc residues, but a few are oligomers having six GlcNAc units. LCOs purified from GRH2 are able to induce root hair formation and deformation on Acacia cyanophylla and A. melanoxylon plants. We show that an N-vaccenoyl-chitopentaose bearing an N-methyl group is able to induce nodule primordia on Phaseolus vulgaris, A. cyanophylla, and A. melanoxylon, indicating that for these plants an N-methyl modification is sufficient for nodule primordia induction.     

Endomycorrhizal and rhizobial symbiosis: How much do they share?

Abstract

Legume plants enter two important endosymbioses – with soil fungi, forming phosphorus acquiring arbuscular mycorrhiza (AM), and with nitrogen-fixing bacteria, leading to the formation of nitrogen-fixing root nodules. Both symbioses have been studied extensively because these symbioses have great potential for agricultural applications. Although 80% of all living land plants form AM, the nitrogen-fixing root nodule symbiosis with rhizobia is almost exclusively restricted to legumes. Despite varying degree of differences in the morphological responses induced by both endosymbionts in the host plants, significant similarities in the development of both fungal and bacterial symbioses have been reported. The signal perception and signal transduction cascades that initiate nodulation and mycorrhization in legumes partially overlap. Legume genes have been identified that are required for the establishment of both AM and root nodule symbiosis and are referred to as the common SYM genes. Genetic dissection of the common SYM signal transduction pathway required for bacterial and fungal root endosymbiosis has not only unraveled the players involved but also provided a first glimpse at conservation and specialization of signaling cascades essential for nodulation and mycorrhiza development. Based on the observation of common signaling cascades, it is tempting to speculate that the root nodule symbiosis, where fossil records date back to the late Cretaceaous, adopted and subsequently modified more ancient signal transduction pathways leading to AM formation, having already been in place 400 million years ago. This review discusses the common aspects of recognition of mycorrhizal fungi and Rhizobium by the host, and further signal transduction that leads to an effective symbiosis.     

Fundamental Concepts in Symbiotic Interactions: Light and Dark, Day and Night, Squid and Legume

Abstract The legume-Rhizobium symbiosis and that between Euprymna scolopes and Vibrio fischeri show some surprising physiological similarities as well as differences. Both interactions rely on exchange of signal molecules, some of which are derived from bacterial cell surface molecules. Although the legume-Rhizobium symbiosis is nutritionally based as are many animal-microbe symbioses, it is not obligate because the plant initiates nodule formation only when the soil is deficient in nitrogen. In contrast, the squid-Vibrio symbiosis is obligate for the squid but is not nutritionally based. Rather, the bacteria produce light, which enables the animal to evade predators. These similarities and differences are described and discussed in term of the overall question of whether or not these two symbiotic relationships have evolved from commensal or pathogenic/parasitic interactions between prokaryotes and eukaryotes.     

Estimation of root nodule development by <Emphasis Type="Italic">Rhizobium</Emphasis> sp. Using hydroponic culture

A nitrogen-fixing bacterium isolated from the root nodules of a cultivated leguminous plant, soybean (Glycine max L.), was cultivable and was identified as Rhizobium sp. Bacterial species isolated from root nodules of wild leguminous plants including -bush clover, white dutch clover, wisteria, and false acacia were identified as Burkholderia cepacia, Pseudomonas migulae, Pseudomonas putida, and Flavobacterium sp, respectively, all of which are heterotrophic bacteria that grow in the rhizosphere. Temperature gradient gel electrophoresis (TGGE) 16S-rDNA bands extracted directly from the bacterial population within the root nodules of the wild leguminous plants were identified as Rhizobium sp, Mesorhizobium sp, and Bradyrhizobium sp. none were cultivable. Rhizobium sp. isolated from soybean root nodule generated approximately 48 and 19 mg/L of ammonium in glucose- and starch-defined medium, respectively, during 8 days of growth. The growth rate of Rhizobium sp. was increased by the addition of yeast extract but not by the addition of ammonium. K _m and V _max for starch saccharification measured with the extracellular crude enzyme of Rhizobium sp. were 0.7556 mg/L and 0.1785 mg/L/min, respectively. The inoculation of Rhizobium sp. culture into a hydroponic soybean plant culture activated root nodule development and soybean plant growth. The inoculated Rhizobium sp. survived for at least 4 weeks, based on the TGGE pattern of 16S-rDNA. The 16S-rDNA of Rhizobium sp. isolated from newly developed root nodules was homologous with the inoculated species.     

Positive role of nodulation on the establishment ofRhizobium japonicum in subsequent crops of soybean

The influence of soybean nodulation on the establishment ofRhizobium japonicum inRhizobium-free soil was examined. Seeds of nodulating (Rj ₁) and nonnodulating (rj ₁) isolines of soybeans and four other crop species (cowpeas, mungbeans, corn, and alfalfa) were grown in field plots that were inoculated with a genetically marked strain ofRhizobium (strain I-110 ARS) and the following year nodulating soybeans were grown in these plots and were inoculated with a different genetically marked subline of the same strain (strain I-110 FN). The proportion of nodules containing strain I-110 ARS relative to strain I-110 FN was determined and interpreted as reflecting the relative numbers of the two genetically marked sublines in the soil. The results clearly demonstrate that nodulation with the specific host plant (soybeans) has a significant positive role in the establishment ofRhizobium inRhizobium-free soil and suggests that alfalfa plants diminish the establishment of soybean rhizobia in soil.     

A critical evaluation of the prospects for nitrogen fixation with non-legumes

Some twenty years ago many speculations were made about possibilities to improve the use of the well-known nitrogen-fixing plant symbioses and to extend the use of atmospheric nitrogen to the most important agricultural plants, like cereals. Since then our understanding of the molecular biology of nitrogenase and the symbiotic interactions during root nodule formation and activity enable a reconsideration of these original speculations. Besides the possibilities for better practical use of the existing systems some more far-reaching speculations will be discussed: the introduction ofnif genes into cells of higher plants, the extension of the host range ofRhizobium orFrankia and the possibilities to transform rhizosphere bacteria, likeAzospirillum, into more efficient endosymbionts. In all cases it will be evident that the more we know, the more we realize what we still have to understand.     

Complex quorum-sensing regulatory systems regulate bacterial growth and symbiotic nodulation in <Emphasis Type="Italic">Mesorhizobium tianshanense</Emphasis>

LuxR/LuxI-type quorum-sensing systems have been shown to be important for symbiotic interactions between a number of rhizobium species and host legumes. In this study, we found that different isolates of Mesorhizobium tianshanense, a moderately-growing Rhizobium that forms nodules on a number of types of licorice plants, produces several different N-acyl homoserine lactone-like molecules. In M. tianshanense CCBAU060A, we performed a genetic screen and identified a network of regulatory components including a set of LuxI/LuxR-family regulators as well as a MarR-family regulator that is required for quorum-sensing regulation. Furthermore, compared with the wild-type strains, quorum-sensing deficient mutants showed a reduced growth rate and were defective in nodule formation on their host plant Glycyrrhiza uralensis. These data suggest that different M. tianshanense strains may use diverse quorum-sensing systems to regulate symbiotic process. H. Cao, M. Yang, and H. Zheng contributed equally to this work.     

The unique root-nodule symbiosis between Rhizobium and the aquatic legume,Neptunia natans (L. f.) Druce

We examined the development of the aquatic N₂-fixing symbiosis between Rhizobium sp. (itNeptunia) and roots of Neptunia natans L. f. (Druce) (previously N. oleracea Lour.) under natural and laboratory conditions. When grown in its native marsh habitat, this unusual aquatic legume does not develop root hairs, the primary sites of rhizobial infection for most temperate legumes. Under natural conditions, the aquatic plant floats and develops nitrogen-fixing nodules at emergence of lateral roots on the primary root and on adventitious roots at stem nodes, but not from the stem itself. Cytological studies using various microscopies revealed that the mode of root infection involved an intercellular route of entry followed by an intracellular route of dissemination within nodule cells. After colonizing the root surface, the bacteria entered the primary root cortex through natural wounds caused by splitting of the epidermis and emergence of young lateral roots, and then stimulated early development of nodules at the base of such roots. The bacteria entered the nodule through pockets between separated host cells, then spread deeper in the nodule through a narrower intercellular route, and eventually evoked the formation of infection threads that penetrated host cells and spread throughout the nodule tissue. Bacteria were released from infection droplets at unwalled ends of infection threads, became enveloped by peribacteroid membranes, and transformed into enlarged bacteroids within symbiosomes. In older nodules, the bacteria within symbiosomes were embedded in an unusual, extensive fibrillar matrix. Cross-inoculation tests of 18 isolates of rhizobia from nodules of N. natans revealed a host specificity enabling effective nodulation of this aquatic legume, with lesser affinity for Medicago sativa and Ornithopus sp., and an inability to nodulate several other crop legume species. Acetylene reduction (N₂ fixation) activity was detected in nodules of N. natans growing in aquatic habitats under natural conditions in Southern India. These studies indicate that a specific group of Rhizobium sp. (Neptunia) occupies a unique ecological niche in aquatic environments by entering into a N₂-fixing root-nodule symbiosis with Neptunia natans.We thank J. Whallon for technical assistance, G. Truchet, J. Vasse, S. Wagener, J. Beaman, F. DeBruijn, F. Ewers, and A. Squartini for helpful comments, and N.N. Prasad and G. Birla for assistance in conducting field observations. This work was supported by the Michigan Agricultural Experiment Station and National Science Foundation grants DIR-8809640 and BIR-9120006 awarded to the MSU Center for Microbial Ecology. This study is dedicated to the memory of Dr. Joseph C. Burton, a friend and colleague who made many contributions to the study of the Rhizobiumlegume symbiosis.     

Plant genes induced in the Rhizobium-legume symbiosis

Rhizobium, Bradyrhizobium and Azorhizobium can elicit the formation of N₂-fixing nodules on the roots or stems of their leguminous host plants. The nodule formation involves several developmental steps determined by different sets of genes from both partners, the gene expression being temporally and spatially coordinated. The plant proteins that are specifically synthesised during the formation and function of the nodule are called nodulins. The nodulins that are expressed before the onset of N₂ fixation are termed early nodulins. These proteins are probably involved in the infection process as well as in nodule morphogenesis rather than in nodule function. The nodulins expressed just before or during N₂ fixation are termed late nodulins and they participate in the function of the nodule by creating the physiological conditions required for nitrogen fixation, ammonium assimilation and transport. In this review we will describe nodulins, nodulin genes and the relationship between nodulin gene expression and nodule development. The study of nodulin gene expression may provide insight into root-nodule development and the mechanism of communication between bacteria and host plant.J.A. Muñoz and A.J. Palomares are with the Departamento de Microbiologia y Parasitología, Facultad de Farmacia, Universidad de Sevilla, 41012 Sevilla, Spain. P. Ratet is with the Institut des Sciences Végétales, CNRS, Avenue de la Terrasse, F-91198 Gif-sur-Yvette, Fance     

Host-specific nodulation is encoded on a 14kb DNA fragment in Rhizobium trifolii

Summary The Rhizobium trifolii genes necessary for nodule induction and development have been isolated on a 14.0kb fragment of symbiotic (Sym) plasmid DNA. When cloned into a broad-host-range plasmid vector, these sequences confer a clover nodulation phenotype on a derivative of R. trifolii which has been cured of its endogenous Sym plasmid. Furthermore, these sequences encode both host specificity and nodulation functions since they confer the ability to recognize and nodulate clover plants on Agrobacterium and a fast-growing cowpea Rhizobium. This indicates that the bacterial genes essential for the initial, highly-specific interaction with plants are closely linked.     

Advances in Rhizobium Research

Referee: Prof. Dr. Dietrich Werner, FG Zellbiologie und Angewandte Botanik, Fachbereich Biologie, Philipps-Universität Marburg, Karl-von-Frisch-Strasse, D-35032 Marburg, Germany Rhizobia are well known for their capacity to establish a symbiosis with legumes. They inhabit root nodules, where they reduce atmospheric nitrogen and make it available to the plant. Biological nitrogen fixation is an important component of sustainable agriculture, and rhizobial inoculants have been applied frequently as biofertilizers. In this review we present recently developed technologies and strategies for selecting quality inoculant strains by taking into consideration the complex interaction between the edaphic environment with the genotypes of both the legume and its microsymbiont. Enhanced competitive ability in an inoculant strain is a key requirement for successful colonization of plant roots, nodule formation, and subsequent N²-fixation. We discuss several avenues for the management and manipulation of rhizobial competition as well as genes that influence competition in the rhizosphere. The use of molecular techniques has greatly contributed to our knowledge of nodule-bacterial diversity and phylogeny. Approaches to the study of rhizobial diversity as well as mechanisms for the evolutionary diversification of nodulating bacteria are presented. Rhizobium genomes ranging from 5.5 to 9?Mb have been sequenced recently and deposited in public databases. A comparison of sequence data has led to a better understanding of genes involved in the symbiotic process as well as possible mechanisms responsible for horizontal transfer of genetic elements and symbiosis genes among rhizobia. Furthermore, rhizobia are frequent rhizosphere colonizers of a wide range of plants and may also inhabit nonleguminous plants endophytically. In these rhizospheric and endophytic habitats they may exhibit several plant growth-promoting effects, such as hormone production, phosphate solubilization, and the suppression of pathogens.     

Spontaneous nodules induce feedback suppression of nodulation in alfalfa

A small subpopulation of alfalfa (Medicago saliva L.) plants grown without fixed nitrogen can develop root nodules in the absence of Rhizobium. Cytological studies showed that these nodules were organized structures with no inter- or intracellular bacteria but with the histological characteristics of a normal indeterminate nodule. Few if any viable bacteria were recovered from the nodules after surface sterilization, and when the nodular content was used to inoculate alfalfa roots no nodulation was observed. These spontaneous nodules were formed mainly on the primary roots in the region susceptible to Rhizobium infection between 4 and 6 d after seed imbibition. Spontaneous nodules appeared as early as 10 d after germination and emerged at a rate comparable to normal nodules. The formation of spontaneous nodules on the primary root suppressed nodulation in lateral roots after inoculation with R. meliloti RCR2011. Excision of spontaneous nodules at inoculation eliminated the suppressive response. Our results indicate that the presence of Rhizobium is not required for nodule organogenesis and the elicitation of feedback regulation of nodule formation in alfalfa.Abbreviation RT root tip This work was supported by an endowment to the Racheff Chair of Excellence of the University of Tennessee, and the Soybean Promotion Board, Haskinsville, Tenn., USA. We are indebted to Noel Gerahty for performing the acetylene-reduction assays, and Dr. E.T. Graham for allowing the use of microscope facilities.     

Nitrogen nutrition and the development and senescence of nodules on cowpea seedlings

Cowpea (Vigna unguiculata (L.) Walp cv. Vita 3) seedlings inoculated with Rhizobium strain CB756 were cultured with their root systems maintained in air or in Ar: O₂ (80:20, v/v) during early nodule development (up to 24 d after sowing). Compared with those in air, seedlings in Ar:O₂ showed progressive N deficiency with inhibited shoot growth, reduced ribulose-1,5-bisphosphate carboxylase and total protein levels and loss of chlorophyll in the leaves. Nodule initiation, differentiation of infected and uninfected nodule tissues and the ultrastructure of bacteriod-containing cells were similar in the air and Ar: O₂ treatments up to 16 d after sowing. Thereafter the Ar: O₂ treatment caused cessation of growth and development of nodules, reduced protein levels in bacteroids and nodule plant cells, and progressive degeneration of nodule ultrastructure leading to premature senescence of these organs. Provision of NO ₃ ^- (0.1–0.2 mM) to Ar: O₂-grown seedlings overcame the abovementioned consequences of N₂ deficiency on nodule and plant growth, but merely delayed the degenerative effects of Ar: O₂ treatment on nodule structure and senescence. Treatment of Ar: O₂-grown seedlings with NO ₃ ^- greatly increased the protein level of nodules but the increase was largely restricted to the plant cell fraction as opposed to the bacteroids. By contrast, NO ₃ ^- treatment of air-grown seedlings increased protein of bacteroid and host nodule fractions to the same relative extents when compared with air-grown plants not supplemented with NO ₃ ^- . These findings, taken together with studies of the distribution of N in nodules of symbiotically effective plants grown from ¹⁵N-labeled seed, indicate that direct incorporation of fixation products by bacteroids may be a critical feature in the establishment and continued growth of an effective symbiosis in the cowpea seedling.Abbreviation RuBPCase ribulose-1,5-bisphosphate carboxylase