The development and structure of root nodules on bambara groundnut [Voandzeia (Vigna)subterranea]

The infection of Vigna subterranea (formerly Voandzeia subterranea) by Bradyrhizobium strain MAO 113 (isolated from V. subterranea) was examined by light and transmission electron microscopy. Bacteria accumulated on the epidermis close to root hairs, and subsequently entered the latter via infection threads. Most of the steps involved in nodule formation were generally characteristic of determinate nodules, such as those which form on the closely related V. radiata. For example, nodule meristems were induced beneath the root epidermis adjacent to infected root hairs, but prior to infection of the meristem by rhizobia. Moreover, after the infection of some of the meristematic cells by the infection threads, and the release of the rhizobia into membrane-bound vesicles, the infection process ceased and dissemination of the rhizobia was by division of already-infected host cells. However, there were some aspects of this process in V. subterranea which have been more commonly described in indeterminate nodules. These include long infection threads entering a number of cells within the meristems simultaneously and a matrix within infection threads which was strongly labelled with immunogold monoclonal antibodies, MAC236 and MAC265, which recognize epitopes on an intercellular glycoprotein. The MAC236 and MAC265 antibodies also recognized material in the unwalled infection droplets surrounding bacteria which were newly-released from the infection threads. The amount of labelling shown was more characteristic of the long infection threads seen in indeterminate nodules such as pea (Pisum sativum) and Neptunia plena. The structure of mature V. subterranea nodules was similar to that described for other determinate nodules such as Glycine max, Vigna unguiculata and V.radiata, i.e. they were spherical and the infected zone consisted of both infected and uninfected cells. Surrounding the infected tissue was an inner cortex of uninfected cell layers containing the putative components of an oxygen diffusion barrier (including glycoprotein-occluded intercellular spaces), and an outer cortex with cells containing calcium oxalate crystals.     

Temporal Relationships between Nitrogenase and Intercellular Glycoprotein in Developing White Lupin Nodules

The development of the N₂-fixing symbiosis between white lupin (Lupinus albusL.) cv. Multolupa andBradyrhizobiumstrain ISLU16 was followed using the acetylene reduction assay (ARA), immunoblots of protein extracts, and microscopy/immunogold labelling at 0, 8, 12, 17 and 20 d after infection. There was no ARA at 0, 8 and 12 d, although macroscopically visible nodule primordia had formed on roots by 8 d. The lack of nitrogenase at these times was confirmed by a negative signal to immunogold labelling with nitrogenase-specific antibodies. At 17 d three out of six plants had ARA, and nodules from these gave a positive signal with the nitrogenase antibody. By contrast, ARA⁻(fix⁻) nodules at 17 d were smaller (mean radius of 0.49 mm compared to 1.01 mm with fix⁺nodules) and gave a negative signal with the nitrogenase antibody. Western blots of nodule protein extracts using the monoclonal antibodies MAC236 and MAC265 (which recognize two epitopes on a glycoprotein which is considered to be involved in both rhizobial infection and the regulation of nodule oxygen diffusion) gave a strong signal with nodules (fix⁺) from 20 d plants and with 17 d fix⁺plants. The signal with MAC236/MAC265 was substantially weaker with nodules from 17 d fix⁻plants, and there was no signal apparent from nodules/nodulated roots from the 0, 8 and 12 d harvests. However, further investigation using immunogold labelling revealed that not only were MAC236 and MAC265 expressed within cortical intercellular spaces in 20 d and 17 d fix⁺/fix⁻nodules, but they were also strongly expressed in the developing cortex surrounding the newly-infected tissue in 8 d nodules, as well as in intercellular spaces within the cortex and infected tissue of 12 d nodules. These data demonstrate that the glycoprotein recognized by MAC236 and MAC265 is present before the onset of nitrogenase expression and function, but expression of the epitopes appears to be enhanced from the onset of N₂fixation. Nodules at all harvests were investigated for the presence of infection threads, as the MAC236/MAC265-recognized glycoprotein is also a component of the infection thread matrix in nodules from other legumes. Infection threads were not seen in nodules from any of the harvests except for the 20 d nodules, and then only after serial sectioning. The latter revealed occasional short wide infection threads entering and releasing rhizobia into small pockets of uninfected cells, within the infected tissue, but not within the meristems. The matrix of these infection threads labelled weakly, or not at all, with MAC236 and MAC265, and it was concluded that the majority of the MAC236/MAC265 detected in lupin nodule extracts originated from glycoprotein within cortical intercellular spaces.     

Development of N2-fixing nodules on the wetland legume Lotus uliginosus exposed to conditions of flooding

Seeds of the wetland legume, Lotus uliginosus , were germinated and grown in vermiculite which was either continuously flooded or well-drained. Plants from both treatments were infected by Mesorhizobium loti strain DUS341 via a 'classical' root hair pathway, although some flooded plants appeared to be infected via enlarged epidermal cells. Subsequent to infection by M. loti , nodule meristems, which had developed within the root outer cortex, were penetrated by infection threads that released bacteria into the meristematic cells. The infection threads and infection droplets were immunogold labelled with monoclonal antibodies (MAC265 and MAC236) that recognize epitopes (at approx. 155/170 and 170/210 kDa, respectively) on a glycoprotein component of the matrix that surrounded the bacteria within the threads or droplets. Although labelling of infection threads or infection droplets with MAC236 was stronger than that with MAC265, both antibodies strongly labelled material occluding intercellular spaces in the cortices of developing nodules that had not yet expressed nitrogenase (as determined by a lack of signal after immunogold labelling with an antibody raised against nitrogenase component II). After 60 d, nitrogenase activity, shoot and root dry weights, and nodule fresh weight per plant did not differ between the treatments. After a further 30 d submergence, the flooded stems developed extensive aerenchyma and there was profuse development of (nodulated) adventitious roots. Nodules also formed at the junction of adventitious roots and the subtending stem and these were connected vascularly to a small stalk of tissue which gave rise to both a nodule and an adventitious root. The flooded nodules had prominent lenticels, and possible air pathways from the atmosphere to the nitrogen-fixing bacteroids are discussed.     

Infection and Nodule Development in Aotus ericoides (Vent.) G. Don, A Woody Native Australian Legume

Infection and nodule development were studied by light and electronmicroscopy in Aotus ericoides, a woody native Australian legume,inoculated with a slow-growing field isolate of Rhizobium. Rhizobiabound to straight, but not deformed, root hairs, as detectedby immunofluorescence. Neither markedly curled root hairs norroot hairs with infection threads were seen. Nodules were indeterminate(astragaloid), with a peripheral meristematic layer, few vasculartraces and both infected and uninfected cells in the centralinfected zone. Infection threads containing contorted bacteriawere present throughout the nodule. Swollen, rod-shaped bacteriain infected cells were in groups in vesicles bounded by plasmalemma-derivedperibacteroid membranes. Senescence in infected cells was associatedwith accumulation of a fibrillar matrix inside peribacteroidmembranes, distortion of bacteria and destruction of most cytoplasmiccontents of the bacteria and host cells; however, most bacterialand plant membranes and plant cell walls remained intact. Ineffectivenesswas associated with relatively little, short-lived infectedtissue. Events in infection and nodule development were similarto those in most herbaceous legumes but showed characters ofboth determinate and indeterminate nodules. Key words: Bacteroids, Legume, Nitrogen-fixing, Nodule, Rhizobium     

Infection and invasion of roots by symbiotic, nitrogen-fixing rhizobia during nodulation of temperate legumes.

Bacteria belonging to the genera Rhizobium, Mesorhizobium, Sinorhizobium, Bradyrhizobium, and Azorhizobium (collectively referred to as rhizobia) grow in the soil as free-living organisms but can also live as nitrogen-fixing symbionts inside root nodule cells of legume plants. The interactions between several rhizobial species and their host plants have become models for this type of nitrogen-fixing symbiosis. Temperate legumes such as alfalfa, pea, and vetch form indeterminate nodules that arise from root inner and middle cortical cells and grow out from the root via a persistent meristem. During the formation of functional indeterminate nodules, symbiotic bacteria must gain access to the interior of the host root. To get from the outside to the inside, rhizobia grow and divide in tubules called infection threads, which are composite structures derived from the two symbiotic partners. This review focuses on symbiotic infection and invasion during the formation of indeterminate nodules. It summarizes root hair growth, how root hair growth is influenced by rhizobial signaling molecules, infection of root hairs, infection thread extension down root hairs, infection thread growth into root tissue, and the plant and bacterial contributions necessary for infection thread formation and growth. The review also summarizes recent advances concerning the growth dynamics of rhizobial populations in infection threads.     

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.     

Infection and Invasion of Roots by Symbiotic, Nitrogen-Fixing Rhizobia during Nodulation of Temperate Legumes

Bacteria belonging to the genera Rhizobium, Mesorhizobium, Sinorhizobium, Bradyrhizobium, and Azorhizobium (collectively referred to as rhizobia) grow in the soil as free-living organisms but can also live as nitrogen-fixing symbionts inside root nodule cells of legume plants. The interactions between several rhizobial species and their host plants have become models for this type of nitrogen-fixing symbiosis. Temperate legumes such as alfalfa, pea, and vetch form indeterminate nodules that arise from root inner and middle cortical cells and grow out from the root via a persistent meristem. During the formation of functional indeterminate nodules, symbiotic bacteria must gain access to the interior of the host root. To get from the outside to the inside, rhizobia grow and divide in tubules called infection threads, which are composite structures derived from the two symbiotic partners. This review focuses on symbiotic infection and invasion during the formation of indeterminate nodules. It summarizes root hair growth, how root hair growth is influenced by rhizobial signaling molecules, infection of root hairs, infection thread extension down root hairs, infection thread growth into root tissue, and the plant and bacterial contributions necessary for infection thread formation and growth. The review also summarizes recent advances concerning the growth dynamics of rhizobial populations in infection threads.     

Common components of the infection thread matrix and the intercellular space identified by immunocytochemical analysis of pea nodules and uninfected roots

Three rat hybridoma cell lines have been isolated which produce monoclonal antibodies identifying a noduleenhanced, soluble component of Pisum sativum root nodules. These antibodies each recognized a protease-sensitive band (M_r 95K) on SDS-polyacrylamide gels. The 95K antigen was resolved by isoelectric focusing into acidic and neutral components which were separately detected by AFRC MAC 236 and MAC 265 respectively. The third antibody (MAC 204) reacted with both acidic and neutral components through an epitope that was sensitive to periodate oxidation. These monoclonal antibodies were used for immunogold localizations at light and electron microscopic levels. In each case, the antigen was shown to be present in the matrix that surrounds the invading rhizobia in infection threads and infection droplets, as well as in the intercellular spaces between plant cell walls of nodules and also of uninfected roots. By contrast, a fourth monoclonal antibody, AFRC JIM 5, labelled a pectic component in the walls of infection threads, and JIM 5 was also found to label the middle lamella of plant cell walls, especially at three-way junctions between cells. The composition and structure of the infection thread lumen is thus comparable to that of an intercellular space.     

Root nodulation of Sesbania rostrata.

The tropical legume Sesbania rostrata can be nodulated by Azorhizobium caulinodans on both its stem and its root system. Here we investigate in detail the process of root nodulation and show that nodules develop exclusively at the base of secondary roots. Intercellular infection leads to the formation of infection pockets, which then give rise to infection threads. Concomitantly with infection, cortical cells of the secondary roots dedifferentiate, forming a meristem which has an "open-basket" configuration and which surrounds the initial infection site. Bacteria are released from the tips of infection threads into plant cells via "infection droplets," each containing several bacteria. Initially, nodule differentiation is comparable to that of indeterminate nodules, with the youngest meristematic cells being located at the periphery and the nitrogen-fixing cells being located at the nodule center. Because of the peculiar form of the meristem, Sesbania root nodules develop uniformly around a central axis. Nitrogen fixation is detected as early as 3 days following inoculation, while the nodule meristem is still active. Two weeks after inoculation, meristematic activity ceases, and nodules then show the typical histology of determinate nodules. Thus, root nodule organogenesis in S. rostrata appears to be intermediate between indeterminate and determinate types.     

Rhizobium meliloti nodulation genes allow Agrobacterium tumefaciens and Escherichia coli to form pseudonodules on alfalfa.

Regions of the Rhizobium meliloti symbiotic plasmid (20 to 40 kilobase pairs long) containing nodulation (nod) genes were transferred to Agrobacterium tumefaciens or Escherichia coli by conjugation. The A. tumefaciens and E. coli transconjugants elicited root hair curling and the formation of ineffective pseudonodules on inoculated alfalfa plants. A tumefaciens elicited pseudonodules formed at a variable frequency, ranging from 15 to 45%, irrespective of the presence of the Ti plasmid. These pseudonodules developed characteristic nodule meristems, and in some nodules, infection threads were found within the interior of nodules. Infrequently, infection threads penetrated deformed root hairs, but these threads were found only in a minority of nodules. There was no evidence of bacterial release from the infection threads. In addition to being found within threads, agrobacteria were also found in intercellular spaces and within nodule cells that had senesced . In the latter case, the bacteria appeared to invade the nodule cells independently of infection threads and degenerated at the same time as the senescing host cells. No peribacteroid membranes enclosed any agrobacteria , and no bacteroid differentiation was observed. In contrast to the A. tumefaciens-induced pseudonodules , the E. coli-induced pseudonodules were completely devoid of bacteria; infection threads were not found to penetrate root hairs or within nodules. Our results suggest that relatively few Rhizobium genes are involved in the earliest stages of nodulation, and that curling of root hairs and penetration of bacteria via root hair infection threads are not prerequisites for nodule meristem formation in alfalfa.     

Structure and growth of infection threads in the legume symbiosis with Rhizobium leguminosarum

Specific antibodies and enzyme–gold probes were used to study the structure and development of infection threads in nodules induced by Rhizobium leguminosarum on the roots of Vicia, Pisum and Phaseolus. In Pisum nodules, the tubular infection thread wall contains polysaccharides antigenically similar to those of the cell wall, including cellulose, xyloglucan, methyl-esterified pectin and non-esterified pectin, but none of these wall components is present around the infection droplet structures from which bacteria are internalized by plant plasma membrane. As reported previously for pea nodules, the luminal matrix of infection threads and infection droplets contains a plant glycoprotein; this glycoprotein is also secreted by infected and uninfected cortical cells of a Vicia root at the earliest stages of nodule initiation. Synthesis of a transcellular infection thread apparently involves reorganized deposition of components normally targeted to the cell wall, and infection thread growth is orientated anticlinally through the outer cortex in the same plane observed for the deposition of new cell walls following mitosis. Both the development of infection threads in the outer cortex and the initiation of cell division in the inner cortex are preceded by a similar process of cell reactivation involving centralization of nuclei and the development of anticlinal transvacuolar strands. It is therefore suggested that the two Rhizobium-induced processes of infection thread growth and cortical cell division may both be consequences of a similar plant cell response in the inner and outer root cortex, respectively. Phaseolus nodules contained only short intracellular infection structures which terminated within individual cells and contained no luminal matrix material. The differences in infection thread structure between Pisum and Phaseolus nodules may reflect differences in ontogeny between “indeterminate” and “determinate” nodule meristems.     

Early cytological events in the infection of the root hairs ofTrifolium repens byRhizobium leguminosarum biovartrifolii observed by glass slide culture in living seedlings

This report describes the early cytological events in the infection byRhizobium leguminosarum biovartrifolii of the root hairs ofTrifolium repens seedlings kept alive on agar medium in glass slide culture experiment. The infection threads bearing rhizobia were formed as soon as the epidermal cells began to emerge as root hairs. On the top of some of these infected emerging root hairs, there were smoky, cell-debris-like bodies, which appeared to be derived from the cell wall dug by rhizobia. Similar bodies were also observed in longer root hairs. None of the root hair cells along the length of the roots which contained infection threads were curled or distorted. A substantial number of pink-colored nodules were later formed on the roots with non-curled infected root hairs.     

60Ma of legume nodulation. What's new? What's changing?

Current evidence suggests that legumes evolved about 60 million years ago. Genetic material for nodulation was recruited from existing DNA, often following gene duplication. The initial process of infection probably did not involve either root hairs or infection threads. From this initial event, two branched pathways of nodule developmental processes evolved, one involving and one not involving the development of infection threads to 'escort' bacteria to young nodule cells. Extant legumes have a wide range of nodule structures and at least 25% of them do not have infection threads. The latter have uniform infected tissue whereas those that have infection threads have infected cells interspersed with uninfected (interstitial) cells. Each type of nodule may develop indeterminately, with an apical meristem, or show determinate growth. These nodule structures are host determined and are largely congruent with taxonomic position. In addition to variation on the plant side, the last 10 years have seen the recognition of many new types of 'rhizobia', bacteria that can induce nodulation and fix nitrogen. It is not yet possible to fit these into the emerging pattern of nodule evolution.     

Nod factors of Rhizobium are a key to the legume door

Symbiotic interactions between rhizobia and legumes are largely controlled by reciprocal signal exchange. Legume roots excrete flavonoids which induce rhizobial nodulation genes to synthesize and excrete lopo-oligosaccharide Nod factors. In turn, Nod factors provoke deformation of the root hairs and nodule primordium formation. Normally, rhizobia enter roots through infection threads in markedly curled root hairs. If Nod factors are responsible for symbiosis-specific root hair deformation, they could also be the signal for entry of rhizobia into legume roots. We tested this hypothesis by adding, at inoculation, NodNGR-factors to signal-production-deficient mutants of the broad-host-range Rhizobium sp. NGR234 and Bradyrhizobium japorticum strain USDA110. Between 10 ⁻⁷ M and 10⁻⁶ M NodNGR factors permitted these NodABC mutants to penetrate, nodulate and fix nitrogen on Vigna unguiculata and Glycine max, respectively. NodNGR factors also allowed Rhizobium fredii strain USDA257 to enter and fix nitrogen on Calopogonium caeruleum, a non-host. Detailed cytological investigations of V. unguiculata showed that the NodABC mutant UGR AnodABC, in the presence of NodNGR factors, entered roots in the same way as the wild-type bacterium. Since infection threads were also present in the resulting nodules, we conclude that Nod factors are the signals that permit rhizobia to penetrate legume roots via infection threads.     

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.     

Borate promotes the formation of a complex between legume AGP‐extensin and Rhamnogalacturonan II and enhances production of Rhizobium capsular polysaccharide during infection thread development in Pisum sativum symbiotic root nodules

The capacity to bind to biomolecules is considered to be the basis for any physiological role of boron (B). Legume arabinogalactan protein‐extensin (AGPE), a major component of the infection thread matrix of legume nodules is a potential B‐ligand. Therefore, its role in infection threads development was investigated in Pisum sativum grown under B deficiency. Using the AGPE‐specific antibody MAC265, immunochemical analysis revealed that a 175 kDa MAC265 antigen was abundant in +B but much weaker in –B nodule extracts. A B‐dependent complex involving AGPE and rhamnogalacturonan II (RGII) could be co‐purified using anti‐RGII antiserum. Following fractionation of –B nodules, MAC265 antigens were mostly associated with the bacterial pellet. Immunogold staining confirmed that AGPE was closely associated with the surface of rhizobia in the lumen of threads in ?B nodules whereas in +B nodules, AGPE was separated from the bacterial surface by a sheath of capsular polysaccharide. Interestingly, colonies of rhizobia grown in free‐living culture without B developed low capsule production. Therefore, we propose that B could be important for apical growth of infection threads by strengthening thread wall through a B‐dependent AGPE‐RGII interaction and by promoting bacterial advance through a B‐dependent production of a stable rhizobial capsule that prevents AGPE attachment.     

A new type of infected cell in root nodules of Andira spp. (leguminosae)

Active nitrogen fixing nodules of seven species of Andira were collected in the field in Brazil. They showed indeterminate growth, a cortex containing many sclereids and vascular bundles with numerous thick walled xylem elements. The infected cells were packed with infection threads in which the rhizobia were retained. This is the first observation of this infected cell type in a legume nodule, and it may represent a primitive stage in evolution.     

crinkle,a novel symbiotic mutant that affects the infection thread growth and alters the root hair,trichome, and seed development in Lotus japonicus

To elucidate the mechanisms involved in Rhizobium-legume symbiosis, we examined a novel symbiotic mutant, crinkle (Ljsym79), from the model legume Lotus japonicus. On nitrogen-starved medium, crinkle mutants inoculated with the symbiont bacterium Mesorhizobium loti MAFF 303099 showed severe nitrogen deficiency symptoms. This mutant was characterized by the production of many bumps and small, white, uninfected nodule-like structures. Few nodules were pale-pink and irregularly shaped with nitrogen-fixing bacteroids and expressing leghemoglobin mRNA. Morphological analysis of infected roots showed that nodulation in crinkle mutants is blocked at the stage of the infection process. Confocal microscopy and histological examination of crinkle nodules revealed that infection threads were arrested upon penetrating the epidermal cells. Starch accumulation in uninfected cells and undeveloped vascular bundles were also noted in crinkle nodules. Results suggest that the Crinkle gene controls the infection process that is crucial during the early stage of nodule organogenesis. Aside from the symbiotic phenotypes, crinkle mutants also developed morphological alterations, such as crinkly or wavy trichomes, short seedpods with aborted embryos, and swollen root hairs. crinkle is therefore required for symbiotic nodule development and for other aspects of plant development.