Ultrastructure of transfer cells in spontaneous nodules of alfalfa (Medicago sativa)

Summary Spontaneous nodules were formed on the primary roots of alfalfa plants in the absence ofRhizobium. Histologically, these white single-to-multilobed structures showed nodule meristems, cortex, endodermis, central zone, and vascular strands. Nodules were devoid of bacteria and infection threads. Instead, the larger cells were completely filled with many starch grains while smaller cells had very few or none. Xylem parenchyma and phloem companion cells exhibited long, filiform and branched wall ingrowths. The characteristic features of both types of transfer cells were polarity of wall ingrowths, high cytoplasmic density, numerous mitochondria, abundant ribosomes, well-developed nucleus and nucleolus, and vesicles originated from rough endoplasmic reticulum. These results were compared with normal nodules induced byRhizobium. Our results suggest that xylem parenchyma and phloem companion transfer cells are active and probably involved in the short distance transport of solutes in and out of spontaneous nodules. Since younger nodules showed short, papillate, and unbranched wall ingrowths, and older tissue showed elongated, filiform and branched wall ingrowths, the development of wall ingrowths seemed to be gradual rather then abrupt. The occurrence of both type-A and -B wall ingrowths suggests that phloem companion transfer cells may be active in loading and unloading of sieve elements. Since there were no symbiotic bacteria and thus no fixed nitrogen, it is tempting to speculate that xylem parenchyma transfer cells may be re-transporting accumulated carbon from starch grains to the rest of the plant body by loading xylem vessels. Fusion of ER-originated vesicles with wall ingrowth membrane indicated the involvement of ER in the membrane formation for elongating wall ingrowths. Since transfer cells were a characteristic feature of both spontaneous andRhizobium-induced nodules, their occurrence and development is controlled by the genetic make-up of alfalfa plant and not by a physiological source or sink emanating from symbiotic bacteria.Abbreviations ATP adenosine triphosphate - ATPase adenosine triphosphatase - EH emergent root hair - EM electron microscope - Nar nodulation in the absence of Rhizobium - RT root tip - RER rough endoplasmic reticulum - YEMG yeast extract mannitol-gluconate     

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.     

Initial proliferation of cortical cells in the formation of root nodules in Pisum sativum L.

Summary Root nodule initiation in Pisum sativum begins with cell divisions in the inner cortex at some distance from the advancing infection thread. After penetrating almost the entire cortex, the branches of the thread infiltrate the meristematic area previously initiated in the inner cortical cells. These cells are soon invaded by bacteria released from the infection thread and subsequently differentiate into non-dividing, bacteriod-containing cells. As the initial meristematic centre in the inner cortex is thus lost to bacteroid formation, new meristematic activity is initiated in neighbouring cortical cells. As development proceeds, more cortical layers contribute to the nodule, with the peripheral layer and apical meristem of the nodule not invaded by bacteria.Lateral root primordia are initiated in a region separate from that in which nodules are formed, with the lateral primordia being closer to the root apex. This is interpreted to indicate that the physiological basis for nodule initiation is distinct from that for initiation of lateral roots. The role of a single tetraploid cell in nodule initiation is refuted, as is the existence of incipient meristematic foci in the root. It is suggested that the tetraploid cells in nodule meristems arise from pre-existing endoreduplicated cells, or by the induction of endoreduplication in diploid cortical cells by Rhizobium.     

Alfalfa Controls Nodulation during the Onset of Rhizobium-induced Cortical Cell Division

The formation of first nodules inhibits subsequent nodulation in younger regions of alfalfa (Medicago sativa L.) roots by a feedback regulatory mechanism that controls nodule number systemically (G Caetano-Anollés, WD Bauer [1988] Planta 175: 546-557). Following inoculation with wild-type Rhizobium meliloti, almost all infections associated with cortical cell division developed into mature nodules. While the distribution of Rhizobium- induced cell divisions closely paralleled the distribution of first emergent nodules, only 9 to 15% of total cell division foci failed to become functional nodules. Nodule formation was restricted to the primary root when plants were inoculated before lateral root emergence. Excision of these primary root nodules allowed nodules to reappear in lateral roots clustered around the location of the root tip at the time of nodule removal. Apparently, this region regained susceptibility to infection within the first hours after excision of primary nodules and suppression of nodulation was restored a day later probably due to the development of new infection foci. Our results suggest that alfalfa controls nodulation during the onset of cell division in the root cortex and not during infection development as in soybean.     

Early development ofRhizobium-induced root nodules ofParasponia rigida. I. Infection and early nodule initiation

Summary The first of two major steps in the infection process in roots ofParasponia rigida (Ulmaceae) following inoculation byRhizobium strain RP501 involves the invasion ofRhizobium into the intercellular space system of the root cortex. The earliest sign of root nodule initiation is the presence of clumps of multicellular root hairs (MCRH), a response apparently unique amongRhizobium-root associations. At the same time or shortly after MCRH are first visible, cell divisions are initiated in the outer root cortex of the host plant, always subjacent to the MCRH. No infection threads were observed in root hairs or cortical cells in early stages. Rhizobial entry through the epidermis and into the root cortex was shown to occur via intercellular invasion at the bases of MCRH. The second major step in the infection process is the actual infectionper se of host cells by the rhizobia and formation of typical intracellular infection threads with host cell accommodation. This infection step is probably the beginning of the truly symbiotic relationship in these nodules. Rhizobial invasion and infection are accompanied by host cortical cell divisions which result in a callus-like mass of cortical cells. In addition to infection thread formation in some of these host cortical cells, another type of rhizobial proliferation was observed in which large accumulations of rhizobia in intercellular spaces are associated with host cell wall distortion, deposition of electron-dense material in the walls, and occasional deleterious effects on host cell cytoplasm.     

Nodulation of white clover (Trifolium repens) in the absence ofRhizobium

Summary Spontaneous nodules developed on the roots of white clover (Trifolium repens cv. Ladino) in the absence ofRhizobium. A small subpopulation of uninoculated clover plants (0.2%) exhibited white, single-to-multilobed elongated structures on their root systems when grown without fixed nitrogen. Clonal propagation using aseptic stolons confirmed the genetic stability of the observation. Few if any viable bacteria of unknown origin were recovered from surfacesterilized structures. Nodule contents were incapable of eliciting nodulation. Histological observations showed that these structures possessed all the characteristic features of indeterminate nodules, such as active meristem, cortex, endodermal layer, vascular strands, and a central zone with parenchyma cells. Infection threads, intercellular or intracellular bacteria were absent. Instead, numerous starch grains were observed in the central zone, a feature absent in normal nitrogen-fixing nodules. Our observation broadens the concept of spontaneous nodulation, believed to be restricted to alfalfa (Medicago sativa), to other legumes, and suggests a degree of generality among indeterminately nodulated legumes displaying natural heterozygosity.     

Subnanomolar concentrations of membrane chitolipooligosaccharides from Rhizobium leguminosarum biovar trifolii are fully capable of eliciting symbiosis-related responses on white clover

Axenic seedling bioassays were performed on white clover, vetch, and alfalfa to assess the variety and dose responses of biological activities exhibited by membrane chitolipooligosaccharides (CLOSs) from wild type Rhizobium leguminosarum bv. trifolii ANU843. Subnanomolar concentrations of CLOSs induced deformation of root hairs (Had) and increased the number of foci of cortical cell divisions (Ccd) in white clover, some of which developed into nodule meristems. In contrast, ANU843 CLOSs were unable to induce Had in alfalfa and required a 10⁴-fold higher threshold concentration to induce this response in vetch. Also, ANU843 CLOSs were not mitogenic on either of these non-host legumes. In addition, CLOS action also increased chitinase activity in white clover root exudate. Thus, the membrane CLOSs from wild type R. leguminosarum bv. trifolii are fully capable of eliciting various symbiosis-related responses in white clover in the same concentration range as extracellular CLOSs of other rhizobia on their respective legume hosts. These results and our earlier studies indicate that membrane CLOSs represent one of many different classes of bioactive metabolites made by R. leguminosarum bv. trifolii which elicit more intense symbiosis-related responses in white clover than in other legumes. Therefore, CLOSs evidently play an important role in symbiotic development, but they may not be the sole determinant of host-range in the Rhizobium-clover symbiosis.Abbreviations Ccd cortical cell division - CLOS chitolipooligosaccharide - Had root hair deformation     

Nodules are induced on alfalfa roots by Agrobacterium tumefaciens and Rhizobium trifolii containing small segments of the Rhizobium meliloti nodulation region.

Regions of the Rhizobium meliloti nodulation genes from the symbiotic plasmid were transferred to Agrobacterium tumefaciens and Rhizobium trifolii by conjugation. The A. tumefaciens and R. trifolii transconjugants were unable to elicit curling of alfalfa root hairs, but were able to induce nodule development at a low frequency. These were judged to be genuine nodules on the basis of cytological and developmental criteria. Like genuine alfalfa nodules, the nodules were initiated from divisions of the inner root cortical cells. They developed a distally positioned meristem and several peripheral vascular bundles. An endodermis separated the inner tissues of the nodule from the surrounding cortex. No infection threads were found to penetrate either root hairs or the nodule cells. Bacteria were found only in intercellular spaces. Thus, alfalfa nodules induced by A. tumefaciens and R. trifolii transconjugants carrying small nodulation clones of R. meliloti were completely devoid of intracellular bacteria. When these strains were inoculated onto white clover roots, small nodule-like protrusions developed that, when examined cytologically, were found to more closely resemble roots than nodules. Although the meristem was broadened and lacked a root cap, the protrusions had a central vascular bundle and other rootlike features. Our results suggest that morphogenesis of alfalfa root nodules can be uncoupled from infection thread formation. The genes encoded in the 8.7-kilobase nodulation fragment are sufficient in A. tumefaciens or R. trifolii backgrounds for nodule morphogenesis.     

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.     

Morphogenesis of lucerne root nodules incited by Rhizobium meliloti in the presence of combined nitrogen

Combined light and transmission electron microscopy were used to examine the effect of nitrate on the development of root nodules in lucerne (alfalfa, Medicago sativa L.) following induction by the nitrogen-fixing symbiont, Rhizobium meliloti. The timing of NO ₃ ^- addition was varied in order to study its effect on all of the recognized morphogenetic steps of nodule formation. Roots of plants inoculated in the presence of 18 mM NO ₃ ^- had straight root hairs which were devoid of adherent rhizobia and infection threads, and developed no nodules. However, nodules were formed on roots if 18 mM NO ₃ ^- was added 5 d after inoculation. At this time, the initiation of nodule primordia had already commenced in the root cortex. The histology and ultrastructure of young nodules which had developed for 5 d in the absence of NO ₃ ^- and another 5 d in the presence of 18 mM NO ₃ ^- resembled nodules developing under N-free conditions, except that in the infection threads within the infection zone of the nodule 1) some bacteria tended to loose their normal shape and gain more electron density, indicating premature degradation, and 2) the matrix of the infection threads was abnormally enlarged. In the presence of high NO ₃ ^- levels in the medium, lysis and degeneration of the bacteria released from the infection threads were observed in the infection and bacteroid zones of developing nodules, indicative of premature senescence. On the other hand, the nodule meristems continued to proliferate even after 12 d of exposure of 18 mM NO ₃ ^- . This was the only morphogenetic step of root nodulation which was insensitive to levels of combined nitrogen that completely prevented infection if present at the time of inoculation. These data indicate that all of the recognized steps of root nodule morphogenesis in which the bacteria play a key role are sensitive to the inhibitory effect of combined nitrogen.     

Effect of time of inoculation on in vitro ectomycorrhizal colonization and nodule initiation in Acacia holosericea seedlings

The complex interactions that occur in systems with more than one type of symbiosis were studied using one isolate of Bradyrhizobium sp. and the ectomycorrhizal fungus Pisolithus tinctorius (Pers.) Coker and Couch inoculated on to the roots of Acacia holosericea A. Cunn. ex G. Don in vitro. After a single inoculation with Bradyrhizobium sp., bacteria typically entered the roots by forming infection threads in the root hair cells via the curling point of the root hair and/ or after intercellular penetration. Sheath formation and intercellular penetration were observed on Acacia roots after a single inoculation with Pisolithus tinctorius but no radial elongation of epidermal cells. Simultaneous inoculation with both microorganisms resulted in nodules and ectomycorrhiza on the root system, occasionally on the same lateral root. On lateral roots bearing nodules and ectomycorrhiza, the nodulation site was characterized by the presence of a nodule meristem and the absence of an infection thread; sheath formation and Hartig net development occurred regularly in the region of the roots adjacent to nodules. Prior inoculation with Bradyrhizobium sp. did not inhibit ectomycorrhizal colonization in root segments adjacent to nodules in which nodule meristems and infection threads were clearly present. Conversely, in ectomycorrhizae inoculated by bacteria, the nodule meristem and the infection thread were typically absent. These results show that simultaneous inoculation with both microorganisms inhibits infection thread development, thus conferring an advantage on fungal hyphae in the competition for infection sites. This suggests that fungal hyphae can modify directly and/or indirectly the recognition factors leading to nodule meristem initiation and infection thread development.     

The ethylene-inhibitor aminoethoxyvinylglycine restores normal nodulation by Rhizobium leguminosarum biovar. viciae on Vicia sativa subsp. nigra by suppressing the ‘Thick and short roots’ phenotype

Nodulation of Vicia sativa subsp. nigra L. by Rhizobium bacteria is coupled to the development of thick and short roots (Tsr). This root phenotype as well as root-hair induction (Hai) and root-hair deformation (Had) are caused by a factor(s) produced by the bacteria in response to plant flavonoids. When very low inoculum concentrations (0.5–5 bacteria·ml^-1) were used, V. sativa plants did not develop the Tsr phenotype and became nodulated earlier than plants with Tsr roots. Furthermore, the nodules of these plants were located on the primary root in contrast to nodules on Tsr roots, which were all located at sites of lateral-root emergence. The average numbers of nodules per plant were not significantly different for these two types of nodulation. Root-growth inhibition and Hai, but not Had, could be mimicked by ethephon, and inhibited by aminoethoxyvinylglycine (AVG). Addition of AVG to co-cultures of Vicia sativa and the standard inoculum concentration of 5·10⁵ bacteria·ml^-1 suppressed the development of the Tsr phenotype and restored nodulation to the pattern that was observed with very low concentrations of bacteria (0.5–5 bacteria·ml^-1). The delay in nodulation on Tsr roots appeared to be caused by the fact that nodule meristems did not develop on the primary root, but only on the emerging laterals. The relationship between Tsr, Hai, Had, and nodulation is discussed.Abbreviations AVG aminoethoxyvinylglycine - cfu colonyforming units - Had root-hair deformation - Hai root-hair induction - NB naringenin-bacteria filtrate - Tsr Thick and short roots     

The role of hormones and gradients in the initiation of cortex proliferation and nodule formation in Pisum sativum L.

Summary The effect of exogenous phytohormones on proliferation of the root cortex, and their relation to the division factors from Rhizobium which participate in the initiation of root nodules, were studied using explants of root-cortex tissue from 7-day-old, sterile pea plants. The explants were cultured for 7 days on a synthetic nutrient medium supplemented with auxin, or auxin and cytokinin. With only auxin present in the medium, ca. 10% of the explants showed cell proliferation. With both auxin and cytokinin this percentage was much higher (ca. 80%). The active explants showed proliferation patterns which were similar to or could be derived from a pattern with three predominant meristematic areas in the inner cortex opposite the three xylem radii of the excised central cylinder. These proliferation patterns were similar to the initial proliferative stages in root-nodule formation in seedling intact roots. From this restricted division response of the explants to the hormones, a hypothesis of endogenous division factors is proposed. To test this hypothesis, extractions of root tissue were performed. The addition of a crude alcoholic extract from the central cylinder or the cortex to the medium resulted in cell divisions throughout the cortex. The results are interpreted as evidence for the presence of a transverse gradient system of (an) unknown cell-division factor(s) in the root cortex which may control the induction of cell divisions in nodule initiation brought about by the release of auxin and cytokinin from Rhizobium.     

In-situ localization of chalcone synthase mRNA in pea root nodule development

In this paper studies on the role of flavonoids in pea root nodule development are reported. Flavonoid synthesis was followed by localizing chalcone synthase (CHS) mRNA in infected pea roots and in root nodules. In a nodule primordium, CHS mRNA is present in all cells of the primordium. Therefore it is hypothesized that the Rhizobium Nod factor induces cell division in the root cortex by stimulating the production of flavonoids that function as auxin transport inhibitors. In nodules CHS mRNA is predominantly present in a region at the apex of the nodule consisting of meristematic and cortical cells. These cells are not infected by Rhizobium. Therefore it is postulated that CHS plays a role in nodule development rather than in a defence response. In roots CHS mRNA is located at a similar position as in nodules, suggesting that CHS has the same function in both root and nodule development. When nodules are formed by mutants of Rhizobium leguminosarum bv. viciae that are unable to secrete β(1-2) glucan and to synthesize the O-antigen containing LPS I, CHS genes are also expressed in regions of the nodule that are infected by Rhizobium. It is postulated that the impaired development of nodules formed by these mutants is due to an induction of a plant defence response.     

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.     

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.     

Morphogenetic Rescue of Rhizobium meliloti Nodulation Mutants by trans-Zeatin Secretion

The development of nitrogen-fixing nodules is induced on the roots of legume host plants by Rhizobium bacteria. We employed a novel strategy to probe the underlying mechanism of nodule morphogenesis in alfalfa roots using pTZS, a broad host range plasmid carrying a constitutive trans-zeatin secretion (tzs) gene from Agrobacterium tumefaciens T37. This plasmid suppressed the Nod- phenotype of Rhizobium nodulation mutants such that mutants harboring pTZS stimulated the formation of nodulelike structures. Alfalfa roots formed more or fewer of these nodules according to both the nitrogen content of the environment and the position along the root at which the pTZS+ bacteria were applied, which parallels the physiological and developmental regulation of true Rhizobium nodule formation. This plasmid also conferred on Escherichia coli cells the ability to induce root cortical cell mitoses. Both the pattern of induced cell divisions and the spatially restricted expression of an alfalfa nodule-specific marker gene (MsENOD2) in pTZS-induced nodules support the conclusion that localized cytokinin production produces a phenocopy of nodule morphogenesis.     

Chemical composition and ultrastructure of broad bean (<Emphasis Type="Italic">Vicia faba</Emphasis> L.) nodule endodermis in comparison to the root endodermis

Ultrastructure and development of apoplastic barriers within indeterminate root nodules formed by Vicia faba L. were examined by light and electron microscopy. The nodule outer cortex is separated from the inner cortex by a heavily suberized nodule endodermis, which matures in submeristematic regions and possesses suberin lamellae. Unsuberized passage cells are present near vascular strands, which are surrounded by a vascular endodermis attached on the inner side of the nodule endodermal cell walls. The vascular endodermis appears immediately below the meristematic apex in developmental state I (Casparian bands), gradually develops suberin lamellae, and attains developmental state II at the base of the nodule. For chemical analysis apoplastic barrier tissues were dissected after enzymatic digestion of non-impregnated tissues. Root epidermal and endodermal cell walls as well as nodule outer cortex could be isolated as pure fractions; nodule endodermal cell walls could not be separated from vascular endodermal cell walls and enclosed xylem vessels. Gas chromatography-flame ionization detection and gas chromatography-mass spectrometry were applied for quantitative and qualitative analysis of suberin and lignin in isolated cell walls of these tissues. The suberin content of isolated endodermal cell walls of nodules was approximately twice that of the root endodermal cell walls. The suberin content of the nodule outer cortex and root epidermal cell walls was less than one-tenth of that of the nodule endodermal cell wall. Substantial amounts of lignin could only be found in the nodule endodermal cell wall fraction. Organic solvent extracts of the isolated tissues revealed long-chain aliphatic acids, steroids, and triterpenoid structures of the lupeol type. Surprisingly, extract from the outer cortex consisted of 89% triterpenoids whereas extracts from all other cell wall isolates contained not more than 16% total triterpenoids. The results of ultrastructural and chemical composition are in good correspondence and underline the important role of the examined tissues as apoplastic barriers.