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     

Transport of Nitrate and Calcium into Legume Root Nodules

Nitrate transport into nodulated plants of soybean (Glycinemax), cowpea (Vigna unguiculata) and faba bean (Vicia faba)was investigated. Nitrate entering the root system of soybeandid not pass out of the vascular system into nodular tissuesin detectable quantities. On the other hand, nitrate could passfrom soil through the outer surface of nodules but did not penetratethe infected tissue. Similarly, nitrate was restricted to corticaltissues of cowpea and faba bean. Thus, nitrate cannot inhibitnitrogen fixation as a result of reduction to nitrite by nitratereductase within the bacteroid zone. These results are, however,consistent with an effect of nitrate on an oxygen diffusionresistance located in the nodule cortex. Unlike nitrate, measurable quantities of ⁴⁵calcium were transportedvia the xylem into infected and cortical tissues of soybeannodules: it also passed from the soil into the free space ofthe nodule cortex. Key words: Nitrate, legume nodules, calcium     

The Effect of Irradiance on the Recovery of Soybean Nodules from Sodium Chloride-Induced Senescence

Soybean (Glycine max L. Merr) cv. Clarke plants inoculated withBradyrhizobium japonicum strain RCR3407 were grown either ina greenhouse with a low irradiance (200–400)µmolm^–2 s^–1) or in a controlled-environment growth cabinetwith a higher irradiance (600 µimol m^–2 s^–1).At 42 d plants were given a nitrogen-free nutrient solutioncontaining 50 mol m^–3 sodium chloride for 2 weeks andthen allowed to recover from salt-stress for a further 2 weeks. Salt treatment reduced plant growth by at least half in bothgrowth regimes, however, the controlled environment-grown (CEG)plants were five times larger than the greenhouse-grown (GG)plants in terms of dry weight and number/weight of nodules perplant, regardless of treatment. The structure of nodules, from both growth regimes, harvestedat the end of the 2 week salt-stress was similar to unstressedcontrol nodules. However, nodules harvested 1 week later fromboth CEG and GG plants had structural changes including degradationof bacteria in vacuoles around host cell nuclei, particularlyin the outer cell layers of the infected tissue. In addition,meristematic activity was seen in the cortex of some nodulesfrom GG plants. Young cells here contained infection threadsand newly-released bacteria. Nodules harvested 2 weeks after removal of the salt-stress fromCEG plants showed an apparent recovery from the stress. However,there was a very marked increase in the amount of starch inthe cortex which was not seen in equivalent GG nodules. In contrast,nodules from GG plants contained many vacuolate infected cellsand, consequently, a lowered bacteroid population. Further,meristematic activity was seen in a zone concentric to the infectedzone, newly-formed cells contained many large infection threadsand were interspersed with intercellular bacteria. The meristematicactivity increased the relative volume of cortical to infectedcells in these nodules. Growth conditions did not affect control nodule specific nitrogenaseactivity or oxygen diffusion resistance (R) and these parameterswere also not altered in CEG nodules exposed to salt plus the14 d recovery period. However, nitrogenase activity was greatlyreduced, and R increased by more than eight times in equivalentGG nodules exposed to salt plus recovery. It is hypothesized that the gross morphological changes werean attempt to counter salt toxicity and/or oxygen damage underconditions of reduced photosynthate supply to the nodules dueto the poor light levels in the greenhouse. However, soybeannodules supplied with adequate photosynthate were able to withstandand recover from long-term salt-stress with little alterationto their structural integrity. Key words: Soybean, sodium chloride, nitrogen fixation, light intensity, oxygen diffusion resistance     

Direct Evidence for Changes in the Resistance of Legume Root Nodules to O2 Diffusion

Indirect evidence suggests that legumes can adjust rapidly theresistance of their root nodules to O₂ diffusion. Here we describeexperiments using O₂ specific micro-electrodes and dark fieldmicroscopy to study directly the operation of this diffusionbarrier. The O₂ concentration sensed by the electrode decreasedsharply in the region of the inner cortex and was less than1.0 mmol m^–3 throughout the infected tissue in nodulesof both pea (Pisum sativum) and french bean (Phaseolus vulgaris).In a number of experiments the ambient O₂ concentration wasincreased to 40% while the electrode tip was just inside theinner cortex. In 13 out of 21 cases the O₂ concentration atthis position either remained low and unchanged or increasedirreversibly to near ambient values. In the remaining casesthe O₂ concentration increased after 1 to 2.5 min and then decreasedto its former value. These results are ascribed to an increasein resistance of the barrier in response to increased O₂ fluxinto the nodule. It was shown microscopically that air spacesboth at the boundary between the infected zone and the innercortex, and within the infected zone started to disappear 3min after nodules were exposed to high ambient O₂ concentrationsand had disappeared completely after 8 min. These spaces werenot changed by exposure of the nodule for 10 min to either N₂or air. Key words: Oxygen, root nodules, air spaces     

Fine structure of nitrogen-fixing leguminous root nodules from the Canadian Arctic

Effective (nitrogen-fixing) root nodules of Oxytropis maydelliana Trautv., O. arctobia Bunge and Astragulus alpinus L. were collected in the high Arctic tundra and subsequently processed for structural studies. The cylindrically-shaped perennial nodules consisted of the following tissues: nodule cortex, nodule meristem, nodular vascular bundles, an active central region with uninfected and infected cells at various stages of development, and a proximal region of senescent cells. The active central region was dark red-coloured due to the presence of the pigment leghemoglobin. The host cells became infected by the growth of infection threads into cells recently derived from the nodule meristem and the subsequent endocytotic release of rhizobia from unwalled membrane-bound regions of the infection thread. The host plasma membrane adjacent to the unwalled regions of infection thread gave rise to the peribacteroid membrane which surrounded the released bacteria. Thus, nodule development and the basic tissue arrangement of the arctic nodules was similar to that of cylindrically-shaped nodules formed on temperate species of legumes.
The arctic legume nodules are unique in having large numbers of lipid droplets present in the cytoplasm of the nodule cortex and uninfected cells of the central active region. Newly infected cells also have lipid droplets. More developed infected cells lack lipid droplets but often contain amyloplasts. Mature differentiated bacteria were spherically-shaped and contained electron-dense inclusions. Electron-dense material was also present in vesicles formed from dilated endoplasmic reticulum and in the peribacteroid space. The lipid droplets present in the host cytoplasm of the nodule cortex and uninfected cells of the central tissue may be storage products which are used to support nitrogen-fixation in nodules growing under cool temperatures of this harsh environment.     

The Structure of Nitrogen Fixing Root Nodules on the Aquatic Mimosoid Legume Neptunia plena

Nodules of the aquatic mimosoid legume Neptunia plena (L.) Benth.were always found associated with roots but not stems. Theyappeared macroscopically 10 and 20 d after inoculation on plantsgrown hydroponically and in vermiculite, respectively. The developmentof nitrogen-fixing cells occurred in a series of stages notyet reported in legume nodule formation: initial infection wasapparently intercellular and rhizobia spread between cells andthrough intercellular spaces before penetrating individual hostcells by means of infection threads. Subsequently nodule developmentwas broadly similar to that described for indeterminate papilionoidnodules. The infection threads of Neptunia and pea nodules containeda matrix with a common epitope, which was, in Neptunia, extrudedfrom the infection thread at the point of bacterial release. The central tissue contained infected and interstitial cellsand was surrounded by a three-layered cortex and a phellem.Bounding the infected region was a layer two to three cellsthick with large, unoccluded intercellular spaces. Externalto this was a layer, one or more cells thick, in which the cellwalls were interlocked, reducing the number of radially orientedintercellular spaces. The outer layer, several cells thick,contained intercellular spaces many of which were occluded.These features did not vary with growth conditions in a waywhich might influence oxygen diffusion characteristics. However,the phellem of water-cultured nodules was much more aerenchymatousthan that of vermiculite-grown nodules. Aquatic legume, Neptunia plena, nitrogen fixation, oxygen, root nodules, Rhizobium     

Location of two isoenzymes of NADH-dependent glutamate synthase in root nodules of Phaseolus vulgaris L.

The two isoenzymes of NADH-dependent glutamate synthase (NADH-GOGAT; EC 1.4.1.14), previously identified in root nodules of Phaseolus vulgaris L., have both been shown to be located in root-nodule plastids. The nodule specific NADH-GOGAT II accounts for the majority of the activity in root nodules, and is present almost exclusively in the central tissue of the nodule. However about 20% of NADH-GOGAT I activity is present in the nodule cortex, at about the same specific activity as this isoenzyme is found in the central tissue. Glutamine synthetase (GS; EC 6.3.1.2) occurs predominantly as the polypeptide in the central tissue, whereas in the cortex, the enzyme is represented mainly by the polypeptide. Over 90% of both GS and NADH-GOGAT activities are located in the central tissue of the nodule and GS activity exceeds NADH-GOGAT activity by about twofold in this region. Using the above information, a model for the subcellular location and stoichiometry of nitrogen metabolism in the central tissue of P. vulgaris root nodules is presented.Abbreviations Fd-GOGAT ferredoxin-dependent glutamate synthase - GOGAT glutamate synthase - GS glutamine synthetase - NADH-GOGAT NADH-dependent glutamate synthase - IEX-HPLC ion-exchange high-performance liquid chromatography     

Composition and Distribution of Adenylates in Soybean (Glycine max L.) Nodule Tissue

Adenylates (ATP, ADP, and AMP) may play a central role in the regulation of the O2-limited C and N metabolism of soybean nodules. To be able to interpret measurements of adenylate levels in whole nodules and to appreciate the significance of observed changes in adenylates associated with changes in O2-limited metabolism, methods were developed for measuring in vivo levels of adenylate pools in the cortex, plant central zone, and bacteroid fractions of soybean (Glycine max L. Merr cv Maple Arrow x Bradyrhizobium japonicum strain USDA 16) nodules. Intact nodulated roots were either frozen in situ by flushing with prechilled Freon-113(-156[deg]C) or by rapidly (<1 s) uprooting plants and plunging them into liquid N2. The adenylate energy charge (AEC = [ATP + 0.5 x ADP]/[ATP + ADP + AMP]) of whole-nodule tissue (0.65 [plus or minus] 0.01, n = 4) was low compared to that of subtending roots (0.80 [plus or minus] 0.03, n = 4), a finding indicative of hypoxic metabolism in nodules. The cortex and central zone tissues were dissected apart in lyophilized nodules, and AEC values were 0.84 [plus or minus] 0.04 and 0.61 [plus or minus] 0.03, respectively. Although the total adenylate pool in the lyophilized nodules was only 41% of that measured in hydrated tissues, the AEC values were similar, and the lyophilized nodules were assumed to provide useful material for assessing adenylate distribution. The nodule cortex contained 4.4% of whole-nodule adenylates, with 95.6% being located in the central zone. Aqueous fractionation of bacteroids from the plant fraction of whole nodules and the use of marker enzymes or compounds to correct for recovery of bacteroids and cross-contamination of the bacteroid and plant fractions resulted in estimates that 36.2% of the total adenylate pool was in bacteroids, and 59.4% was in the plant fraction of the central zone. These are the first quantitative assessments of adenylate distribution in the plant and bacteroid fractions of legume nodules. These estimates were combined with theoretical calculations of rates of ATP consumption in the cortex (9.5 nmol g-1 fresh weight of nodule s-1), plant central zone (38 nmol g-1 fresh weight of nodule s-1), and bacteroids (62 nmol g-1 fresh weight of nodule s-1) of soybean nodules to estimate the time constants for turnover of the total adenylate pool and the ATP pool within each nodule fraction. The low values for time constant (1.6-5.8 s for total adenylate, 0.9-2.5 s for ATP only) in each fraction reflect the high metabolic activity of soybean nodules and provide a background for further studies of the role of adenylates in O2-limited nodule metabolism.     

Nitrogen Fixation, Assimilation and Transport During the Initial Growth Stage of Phaseolus vulgaris L

In nodulated common bean (Phaseolus vulgaris L.), there is typicallya period of N stress between 15 and 20 d after emergence (DAE),due to a lack of synchronization between the depletion of Nin the cotyledons and the beginning of N² fixation and transport.Screening trials identified some Rhizobium leguminosarum bv.phaseoli strains with which symptoms of N deficiency were notvisible (‘precocious’ strains). Cultivar Negro Argelwas then inoculated with two ‘traditional’ strains(C-05 and CIAT 727) and two ‘precocious’ strains(CNPAF 146 and CNPAF 512), and plants were harvested from 8to 30 DAE. There were no differences between the two groupsof strains in nodule dry weight or in the acetylene reductionrates between 8 and 16 DAE. However, nodules induced by the‘precocious’ strains showed earlier onset of glutaminesynthetase (GS) (EC 6.3.1.2 [EC] ) and glutamate synthase (GOGAT)(EC 1.4.1.14 [EC] ) activities, and ureide synthesis. The N concentrationin the nodules formed by ‘precocious’ strains variedfrom 4.2 to 4.5%, whereas with the ‘traditional’strains, it increased from 3.2% at 8 DAE to 65% at 18 DAE, atwhich time plants exhibited N-deficiency symptoms. By 21 DAE,GS and GOGAT activities in ‘traditional’ noduleswere increased, as well as the ureide-N-concentration in thexylem sap, nodule N content declined to 4.5% and the leavesbecame green. These results suggest that the N stress with ‘traditional’strains is not a limitation in early N² fixation activity butrather in the rates of expression of the processes of N assimilationand transport. Key words: Glutamate synthase, glutamine synthetase, nitrogen fixation, Phaseolus vulgaris, Rhizobium     

Effect of hydro- and osmopriming of chickpea (Cicer arietinum L.) seeds on enzymes of sucrose and nitrogen metabolism in nodules

Three year data on the effect of water- and mannitol (4%) priming of chickpea seeds (12 h at 25°C) showed higher number and biomass of nodules in the plants from primed seeds than from non-primed seeds. The biomass of nodules increased to 75 DAS but decreased by 90 DAS. Activities of sucrose metabolism enzymes (sucrose synthase (SS) and alkaline invertase) and of nitrogen metabolism (glutamine synthetase (GS), glutamate synthase (GOGAT) and glutamate dehydrogenase (GDH)) in nodules of primed and non-primed crops during development are reported. SS and alkaline invertase activities increased to 70 DAS and then decreased. In primed plants, the higher SS activity in nodules at 60 and 70 DAS might be responsible for providing more energy and carbon skeleton for nitrogen fixation and for ammonium assimilation in primed plants. At 85 DAS, though the SS activity decreased in comparison with the earlier growth stages, it was still higher in nodules of the primed crops than the non-primed crop. Activity of alkaline invertase was maximum at 70 DAS in the nodules of primed and non-primed crops. Priming increased nodule GS activity at 70 and 85 DAS. GOGAT activity was unaffected by priming but GDH activity was greater in nodules from primed crops at 50 DAS. Elevated SS and GS nodule activities in primed chickpeas might be responsible in increasing nodule biomass and metabolic activity thereby increasing seed fill.     

Oxygen Diffusion in Lupin Nodules: I.VISUALIZATION OF DIFFUSION BARRIER OPERATION

Root nodules of Lupinus albus (L.) cv. Multolupa were subjectedto short- and medium-term stresses by lowering rhizosphere temperaturefrom 25 to 16°C (2 h), detopping plants (3 h), darkeningplants (21 h) or exposing roots to 20 mol m^–3 KNO₃ for4 d. All experimental treatments produced increases in oxygendiffusion resistance, compared with control plants. These correlatedwith structural changes in the nodule cortex, which is describedin detail for the first time. The most noticeable change isthe occlusion of intercellular spaces by a glycoprotein whichwas identified using the monoclonal antibody MAC236. This glycoproteinwas also found surrounding bacteria in intercellular spacesof the cortex of control nodules. Key words: Oxygen diffusion resistance, glycoprotein, nodules, nitrogen fixation, Lupinus albus     

Detopping causes production of intercellular space occlusions in both the cortex and infected region of soybean nodules

A structural analysis was conducted to determine whether glycoprotein‐containing intercellular space occlusions are involved in medium‐term regulation of O₂ diffusion in soybean (Glycine max) nodules. Alterations in O₂ diffusion were induced by a 3 h detopping treatment, and glycoprotein was immunolocalized with the monoclonal antibodies MAC236 and MAC265. Western blots of unstressed nodules revealed that these antibodies recognize antigens with two different molecular weights in soybean nodules. Tissue printing of halved nodules showed that both antigens were present in fresh nodules from control and 3 h detopped plants. The main localization appeared to be the inner cortex, but some immunolabelling also occurred in the infected region. ELISAs demonstrated a significant increase in total nodule concentration of intercellular glycoprotein following detopping, and cryosections of fresh nodules from this treatment also showed localization of antigens within the intercellular spaces of the infected region. The production of intercellular space occlusions in both the mid‐cortex and infected regions after 3 h detopping was confirmed by light microscopy and silver‐enhanced immunolabelling; cortical changes were quantified by image analysis techniques. Electron microscopy revealed that the occlusions within the infected region were less dense and less heavily labelled than those in the cortex. These results are discussed in relation to O₂ diffusion regulation in soybean nodules     

The role of sucrose synthase in the response of soybean nodules to drought

Experiments were carried out to investigate the effects of droughtstress on enzymatic activities related to carbon and nitrogenmetabolism in soybean nodules. Gradual drought stress, imposedby withholding water nutrients, resulted in declines in thewater potential of leaves and nodules consistent with a significantdecline in N2 fixation. However, the amounts of nitrogenasecomponents 1 and 2 were virtually unaffected by drought stress.Similarly, no significant changes could be detected in aspartateaminotransferase, phosphoenolpyruvate carboxylase, glutaminesynthetase or alkaline invertase activities throughout the experiment.In contrast, sucrose synthase (SS), one of the enzymes involvedin sucrose metabolism in legume nodules, declined dramaticallyin activity and in content within a few days of withholdingwater. Coincident with this decline in SS activity were significantincreases in the nodule contents of sucrose, total free aminoacids and ureides. The amounts of proline, however, did notincrease until some days later. It is suggested that SS mayplay a key role in the regulation of nodule carbon metabolismand, therefore, of nitrogen fixation under drought stress conditions. Key words: Glycine max, soybean, nodule metabolism, drought stress, sucrose synthase     

Newly featured infection events in a supernodulating soybean mutant SS2-2 by Bradyrhizobium japonicum

Supernodulating soybean (Glycine max L. Merr.) mutant SS2-2 and its wild-type counterpart, Sinpaldalkong 2, were examined for the microstructural events associated with nodule formation and development. SS2-2 produced a substantially higher percentage of curled root hairs than the wild type, especially at 14 days after inoculation with Bradyrhizobium japonicum. In addition, there was new evidence that in SS2-2, B. japonicum also entered through fissures created by the emerging adventitious root primordia. Early steps of nodule ontogeny were faster in SS2-2, and continued development of initiated nodules was more frequent and occurred at a higher frequency than in the wild type. These data suggest that the early expression of autoregulation is facilitated by decreasing the speed of cortical cell development, leading to the subsequent termination of less-developed nodules. The nodules of SS2-2 developed into spherical nodules like those formed on the wild type. In both the wild type and supernodulating mutant, vascular bundles bifurcate from root stele and branch off in the nodule cortex to surround the central infected zone. These findings indicate that SS2-2 has complete endosymbiosis and forms completely developed nodule vascular bundles like the wild type, but that the speed of nodule ontogeny differs between the wild type and SS2-2. Thus, SS2-2 has a novel symbiotic phenotype with regard to nodule organogenesis.     

Effectiveness of Lotus Root Nodules: I. MORPHOLOGY AND FLAVOLAN CONTENT OF NODULES FORMED ON LOTUS PEDUNCULATUS BY FAST-GROWING LOTUS RHIZOBIA

The morphology of root nodules formed on Lotus pedunculatusby two fast-growing strains of Rhizobium, NZP2037 which formseffective (nitrogen-fixing) nodules and NZP2213 which formsineffective (non-nitrogen-fixing) nodules, has been studied.The nodules formed by NZP2037 contained a central zone of bacteroid-filledplant cells surrounded by a cortex. In contrast the nodulesformed by NZP2213 contained no Rhizoblum-infected plant cells,but rhizobia were found in localized areas on the nodule surfaceand between the outer two or three cell layers of the nodule.Electron-dense osmiophilic deposits identified as flavolans(condensed tannins) were present in the vacuoles of many uninfectedplant cells in the nodules formed by both Rhizobium strains.This is the first time that flavolans have been positively identifiedin legume root nodules. In the NZP2037 nodule flavolans werepresent in the outer cortical and epidermal cells. In the ineffecitveNZP2213 nodule fiavolans were present in many of the centralnodule cells. The concentration of flavolan in the NZP2213 nodulewas 12 times higher than in the NZP2037 nodule.     

Effect of Contrasting Patterns of Nitrate Application on the Nitrate Uptake, N2-Fixation, Nodulation and Growth of White Clover

White clover (Trifolium repens L.) plants were grown from seedin perlite, inoculated with effective rhizobia and exposed tothe same ‘concentration x days’ of ¹⁵N-labellednitrate in four contrasting patterns of doses. Acetylene reductionwas measured at intervals using an open, continuous-flow sytem.Mean dry weight per nodule and rates of acetylene reductionfell rapidly (2–3 d) during periods of exposure to highnitrate concentrations (> 7 mM N) and rose again, equallyrapidly, when nitrate was withdrawn or substantially reduced.The fall in mean dry weight per nodule (50–66 per cent)was almost certainly too large to be accounted for by loss ofsoluble or storage carbohydrate only. No new nodules were formedduring periods of high nitrate availability. When nitrate wassupplied continuously at a moderate concentration (5.7 mM N)nodule numbers stabilised although existing nodules increasedin dry weight by almost four-fold over the 30 d measurementperiod. Treatment had no effect on the percentage nitrogen in planttissues although there were large differences in the proportionsderived from nitrate and N₂-fixation. Plants exposed continuouslyor frequently to small doses of nitrate took up more nitrate,and hence relied less heavily on N₂-fixation, than those exposedto larger doses less often. Increased reliance on nitrate broughtwith it increased total dry weight and shoot: root ratios. Possiblemechanisms involved in bringing about these differences in nitrogennutrition and growth are discussed. White clover, Trifolium repens, nitrate, N₂-fixation, nodule, acetylene reduction, ¹⁵N     

Nodulin gene expression in effective root nodules of white sweetclover (Melilotus alba Desr.) and in ineffective nodules elicited by mutant strains of Rhizobium meliloti

Fifteen nodulins and several nodule-stimulated gene productswere expressed in effective, nitrogen-fixing root nodules ofwhite sweetclover (Melilotus alba Desr. cv. U389), as determinedby two-dimensional gel electrophoresis of in vitro translationproducts. The number and gel position of eight leghaemoglobin(Lb) products, as well as a product tentatively identified asnodule-stimulated glutamine synthetase (GS), was similar toprevious reports of alfalfa (Medicago sativa L. cv. Iroquois)nodulins. Three mutants of Rhizobium meliloti, including anexoH mutant, a lipopolysaccharide mutant, and a nifH mutant,elicited ineffective sweetclover nodules blocked at empty (bacteria-free),partially infected, or fully infected stages of nodule development,respectively. In these ineffective nodules, the nodulin Nma30and nodule-stimulated NSTma42 were expressed early in development,while a group of four nodulins and two nodule-stimulated productswere intermediate in order of expression. Lb, GS and the latenodulin Nmal2a were expressed later, following infection. TheexoH mutant, Rm7154, appeared to be a leaky mutant, as a smallpercentage of the plants developed nitrogen-fixing nodules about4 weeks after inoculation. The sequential expression of a largenumber of nodulins and nodule-stimulated products, as well asthe availability of sweetclover nodulation mutants indicatesthat sweetclover is a useful diploid system for analysis ofhost genes essential to the Rhizobium/legume symbiosis. Key words: Nitrogen fixation, nodulation mutants, nodulins