NITROGEN FIXATION IN THE BAYBERRY (MYRICA PENSYLVANICA) AND ITS ROLE IN COASTAL SUCCESSION

The nodules on roots of Myrica pensylvanica (bayberry) contain a bacterial endophyte. By using the acetylene reduction technique these plant endophyte associations were shown to be capable of fixing nitrogen. As nodulation was plentiful and fixation vigorous, it is proposed that the success of M. pensylvanica as an early successional plant of dunes and impoverished coastal soils is due in part to the nitrogen-fixing capacity of its nodular association.     

The initiation,development and structure of root nodules inElaeagnus angustifolia L. (Elaeagnaceae)

Summary A correlated light and electron microscopic study was undertaken of the initiation and development of root nodules of the actinorhizal tree species,Elaeagnus angustifolia L. (Elaeagnaceae).Two pure culturedFrankia strains were used for inoculation of plants in either standing water culture or axenic tube cultures. Unlike the well known root hair infection of other actinorhizal genera such asAlnus orMyrica the mode of infection ofElaeagnus in all cases was by direct intercellular penetration of the epidermis and apoplastic colonization of the root cortex. Root hairs were not involved in this process and were not observed to be deformed or curled in the presence of the actinomyceteFrankia. In response to the invasion of the root, host cells secreted a darkly staining material into the intercellular spaces. The colonizingFrankia grew through this material probably by enzymatic digestion as suggested by clear dissolution zones around the hyphal strands. A nodule primordium was initiated from the root pericycle, well in advance of the colonizingFrankia. No random division of root cortical cells, indicative of prenodule formation was observed inElaeagnus. As the nodule primordium grew in size it was surrounded by tanninised cells of a protoperiderm. The endophyte easily traversed this protoperiderm, and once inside the nodule primordium cortex ramified within the intercellular spaces at multiple cell junctions. Invasion of the nodule cortical cells occurred when a hyphal branch of the endophyte was initiated and grew through the plant cell wall, again by apparent enzymatic digestion. The plant cell plasmalemma of invaded cells always remained intact and numerous secretory vesicles fused with it to encapsulate the advancingFrankia within a fibrous cell wall-like material. Once within the host cell some endophyte cells began to differentiate into characteristic vesicles which are the presumed site of nitrogen fixation. This study clearly demonstrates that alternative developmental pathways exist for the development of actinorhizal nitrogen-fixing root symbioses.     

OXYGEN CONCENTRATION WITHIN THE NITROGEN-FIXING ROOT NODULES OF MYRICA GALE L.

Microelectrodes were used to study the oxygen concentration within Myrica gale L. nodules. Low oxygen concentrations were found only in the region of the mature, nitrogen-fixing endophyte, and appeared to correspond to clusters of infected host cells. The oxygen concentration in the remainder of the nodule was much higher. Interconnected intercellular air spaces were demonstrated by infiltration with India ink. Infiltration of the spaces with water greatly reduced oxygen concentration throughout the nodule, indicating that they function in supplying oxygen to the infected cells and remainder of the nodule. These results differ from those found previously for soybean nodules and provide evidence that legume and actinorhizal nodules have different mechanisms for protecting nitrogenase from oxygen.     

Scanning electron microscopy of the Alnus crispa var. mollis Fern. root nodule endophyte

Nitrogen-fixing root nodules of the Alnus crispa var. mollis Fern. were studied by scanning electron microscopy (SEM). The critical point drying of glutaraldehyde-osmium fixed nodular tissue permitted an excellent morphological preservation of the three-dimensional structures of the host and endophyte cells. The nodule endophyte was observed as two forms: the hypha which can be branched, and the vesicle which developed at the parental hypha tip. The actinomycetal endophyte penetrated through the host cortical cell wall and became enveloped by a membrane. This enclosing membrane is suggested to be the invaginated host plasmalemma. Perforations of the cell wall of the host infected cell were observed. These perforations are suggested to be the result of an enzymatic degradation process, probably regulated by the penetrating endophyte hyphae. In addition to the polymorphic endophyte, endogenous bacterial contaminants were observed in the nodular tissue. The present SEM study confirms previous light microscopy and transmission electron microscopy studies of the same species of root nodule symbiosis.     

Frankia-Alnus incana symbiosis: Effect of endophyte on nitrogen fixation and biomass production

The efficiency of different FinnishFrankia strains as symbionts onAlnus incana (L.) Moench was evaluated in inoculation experiments by measuring nitrogen fixation and biomass production. Since all available pure cultures ofFrankia are of the Sp⁻ type (sporangia not formed in nodules), but the dominant nodule endophyte ofA. incana in Finland is of the Sp⁺ type (sporangia formed in nodules), crushed nodules of thisFrankia type were included. The Sp⁻ pure cultures, whether originating fromA. incana orA. glutinosa, produced with one exception, similar biomass withA. incana. The highest biomass was produced with an American reference strain fromA. viridis crispa. Using Sp⁺ nodule homogenates fromA. incana as inoculum, the biomass production was only one third of that produced by Sp⁻ pure cultures from the same host. Hence, through selection of the endophyte it is possible to exert a considerable influence on the productivity ofAlnus incana.     

<Emphasis Type="Italic">Rhizobium etli</Emphasis> maize populations and their competitiveness for root colonization

Rhizobium etli, which normally forms nitrogen-fixing nodules on Phaseolus vulgaris (common bean), is a natural maize endophyte. The genetic diversity of R. etli strains from bulk soil, bean nodules, the maize rhizosphere, the maize root, and inside stem tissue in traditional fields where maize is intercropped with P. vulgaris-beans was analyzed. Based on plasmid profiles and alloenzymes, it was determined that several R. etli types were preferentially encountered as putative maize endophytes. Some of these strains from maize were more competitive maize-root colonizers than other R. etli strains from the rhizosphere or from bean nodules. The dominant and highly competitive strain Ch24-10 was the most tolerant to 6-methoxy-2-benzoxazolinone (MBOA), a maize antimicrobial compound that is inhibitory to some bacteria and fungi. The R. tropici strain CIAT899, successfully used as inoculant of P. vulgaris, was also found to be a competitive maize endophyte in inoculation experiments.     

SYMBIOTIC NITROGEN FIXATION IN CEANOTHUS ROOTS

Ceanothus greggii var. perplexans is a common shrub in the southern California chaparral. Clusters of nodules found under the canopy of this species are modified roots which contain a nitrogen-fixing endophyte, Frankia ceanothi (Actinomycetales), within the cortex. The nodule density per m² obtained from root system excavations is much lower than that reported for different Ceanothus species in northern California. Field observations indicate that soil moisture is an important factor in nodule formation. Anatomical studies with the scanning electron microscope and acetylene reduction assays support the hypothesis that the vesicles, spherical swellings of hyphal endings (1.2–3.0 μm in diam), are indeed the sites of N₂ fixation. No bacteria-like bodies were found. The acetylene reduction rates of C. greggii endophytes were of the same order of magnitude as those reported for other members of the genus Frankia. It is estimated that 100 grams of nitrogen are fixed per year per hectare for a specific area in the southern Californian chaparral where C. greggii comprises 1/3 of the ground cover. This amount appears to be large enough to replace the nitrogen that is lost annually by drainage and runoff from winter rain storms.     

Cell and endophyte structure of the nitrogen-fixing root nodules ofCeanothus integerrimus H.and A.

Summary The nitrogen fixing root nodules ofCeanothus integerrimus were very similar in appearance to other non-legume nodules. Each nodule was a cluster of small lobes. Each lobe in cross section had a central vascular cylinder and a hypertrophied cortex. The cortex contained very large infected cells, with large nuclei; among these infected cells were scattered small, normal-appearing cortex cells. The actinomycete endophyte consisted of wavy hyphae 0.4 m in diameter which terminated in pear-shaped vesicles 1.6 m×2 m. The vesicles were not septate. The function of the vesicles was unknown. The infected cells had apparently normal nuclei, chloroplasts and mitochondria and were probably alive, except at the base of the nodule where both infected cells and the endophyte they contained were dead.     

Photosystem II and oxygen regulation in Sesbania rostrata stem nodules

The tropical wetland legume Sesbania rostrata Brem. produces nitrogen-fixing stem nodules which are green and contain chlorophyll, the chloroplasts being concentrated in a hand in the inner and mid-cortex close to the nitrogen-fixing cells. The photosystem II thylakoid membrane proteins D₁, D₂ and PsbO, which are essential for photo-synthetic O₂ evolution, were shown by immunoblotting to be present in extracts of leaves and stem nodules. Immunogold labelling confirmed their presence on stem nodule thylakoids and showed that labelling was most intense in well-developed chloroplasts in the mid-cortex and least intense in the smaller, less-abundant chloroplasts adjacent to the nitrogen-fixing cells. Concentrations of the oxygen-carrying protein leghaemoglobin (Lb) did not differ between stem and S. rostrata root nodules, and Lb was localized in bacteroid-containing cells, including those immediately adjacent to the cortex, in both nodule types. Moreover, nitrogenase component 2 was localized in bacteroids within the outermost layers of infected cells, suggesting that a low pO₂ was maintained, despite the nearby chloroplasts. Nodule extracts examined by ELISA and immunoblots, using the monoclonal antibody MAC265, showed greatly enhanced expression of a 139 kDa glycoprotein in stem compared to root nodules. Immunogold labelling showed that material containing the MAC265 antigen occluded intercellular spaces, and was present in cell walls, throughout the cortex of stem nodules (particularly in the chloroplasl-rich inner and mid-cortex), but was considerably less evident in root nodules.     

Nitrogen fixation by Cercocarpus ledifolius (Rosaceae) in pioneer habitats

Summary Soil properties of pioneer Pinus flexilis stands with similar topography and climate were investigated. Soils supporting this tree in association with Cercocarpus ledifolius were found to have higher percentages of total nitrogen than soils beneath similar stands lacking Cercocarpus.An excavated Cercocarpus ledifolius shrub in a Pinus flexilis stand in the San Bernardino Mountains of California was found to be nodulated and these nodules were found to be capable of fixing nitrogen. Other known nitrogen-fixing shrubs are frequent associates of Pinus flexilis in extreme sites.Implications of the phylogenetic relationship of some nitrogen-fixing species are briefly discussed, as well as their frequent occurrence in pioneer or extreme habitats.     

Plant-endophyte symbiosis in non-leguminous plants

Summary A wide taxonomic range of non-leguminous dicotyledonous plants bear root nodules and are able to fix atmospheric nitrogen. These plants belong to the orders Casuarinales, Myricales, Fagales, Rhamnales, Coriariales, and Rosales. Actinomycetes are involved in the root-nodule symbiosis. Nitrogen fixation is inhibited by hydrogen and carbon monoxide. Combined nitrogen depress nodule formation, but nitrogen fixation still occurs in the presence of combined nitrogen in the medium. In nitrogen-free medium Alnus plants fix in one season of 48 weeks 500 mg N per plant and Ceanothus plants 760 mg N per plant. Fixation by the other plant species is about of the same order. Field estimates showed that the nitrogen increase of the soil was about 61.5–157 kg N per ha per annum, depending on the age of the trees, under Alnus, 58.5 kg N per ha per annum under Casuarina, about 60 kg N per ha per annum under Ceanothus, 27–179 kg N per ha per annum underHippopha? rhamnoides, and about 61.5 kg N per ha per annum underDryas drummondii with someShepherdia spp. Non-leguminous root nodules belong to two types: coralloid root nodules and root nodules where the apex of each nodule lobe produces a negatively geotropic root. The primary infection occurs through the root hairs where a curling effect is observed. In the host cells the endophyte presents itself in three forms: hyphae, vesicles and bacteria-like cells. Vesicles are probably associated with nitrogen fixation, whereas the bacteria-like cells function in the endophyte's survival and dispersal. The endophyte is an obligate symbiont. TheAlnus glutinosa endophyte has been isolated and grownin vitro in root-nodule callus tissue. However, the isolated endophyte produces only ineffective root nodules in re-inoculation tests.     

Field measurements of nitrogen-fixing activity of intact saplings ofAlnus maximowiczii in the subalpine zone of Mt Fuji

Nitrogen-fixing (acetylene-reducing) activity of intact saplings ofAlnus maximowiczii was measured under natural conditions in the subalpine zone of Mt Fuji. The nitrogen-fixing activity was detected from the middle of June when expansion of leaves had just begun to the end of October when the shedding of leaves was almost completed. Diurnal changes in the activity were almost parallel with those of ground temperature. The measured nitrogen-fixing activity was related to ground temperature and total leaf area. Using this relation, annual nitrogen fixation was estimated from the data of ground temperature and leaf area measured in the field. The amount of annual nitrogen fixation was almost the same as that of nitrogen used for annual growth. It was concluded that nitrogen fixation by nodules made a considerable contribution to the nitrogen economy in the saplings ofA. maximowiczii.     

Diffusion Limitation of Oxygen Uptake and Nitrogenase Activity in the Root Nodules of Parasponia rigida Merr. and Perry

Parasponia is the first non-legume genus proven to form nitrogen-fixing root nodules induced by rhizobia. Infiltration with India ink demonstrated that intercellular air spaces are lacking in the inner layers of the nodule cortex. Oxygen must diffuse through these layers to reach the cells containing the rhizobia, and it was calculated that most of the gradient in O₂ partial pressure between the atmosphere and rhizobia occurs at the inner cortex. This was confirmed by O₂ microelectrode measurements which showed that the O₂ partial pressure was much lower in the zone of infected cells than in the cortex. Measurements of nitrogenase activity and O₂ uptake as a function of temperature and partial pressure of O₂ were consistent with diffusion limitation of O₂ uptake by the inner cortex. In spite of the presumed absence of leghemoglobin in nodules of Parasponia rigida Merr. and Perry, energy usage for nitrogen fixation was similar to that in legume nodules. The results demonstrate that O₂ regulation in legume and Parasponia nodules is very similar and differs from O₂ regulation in actionorhizal nodules.     

Nitrogen Fixation and Allantoin Formation in Soybean Plants

The activity of nitrogenase and the concentration of ammonia and allantoin (+ allantoic acid) in root nodules were measured throughout the growth period of soybean plants. Nitrogenase activity measured by acetylene reduction increased with plant growth and reached a maximum level at the flowering period. The level of ammonia and allantoin concentration in nodules was parallel with increased nitrogenase activity. At the late reproductive stage (pod-forming period), nitrogenase activity showed a marked decrease, but the ammonia and allantoin in the nodules remained at a constant level. Detached nodules from 56 day-old soybean plants were exposed to ¹⁵N₂ gas, and the distribution of ¹⁵N among nitrogen compounds was investigated. Enrichment of ¹⁵N in allantoin and allantoic acid reached a fairly high level after 90 min of nitrogen fixation; ca. 22% of ¹⁵N in acid-soluble nitrogen compounds was incorporated into allantoin + allantoic acid. In contrast, enrichment of ¹⁵N in amide nitrogen was relatively low. No significant ¹⁵N was detected in the RNA fraction. The data suggested that ureide formation in nitrogen-fixing root nodules did not take place through the breakdown of nucleic acids, but directly associated with the assimilating system of biologically fixed nitrogen.     

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.     

INITIATION AND DEVELOPMENT OF ROOT NODULES OF CASUARINA (CASUARINACEAE)

Roots of seedlings of the “beefwood” tree, Casuarina cunninghamiana Miq. grown in nitrogen-free nutrient solution were inoculated with a suspension prepared from crashed root nodules taken from mature plants. Marked deformation of root hairs was evident but no infection threads were observed in root hairs. The mode of infection remains undetermined. Root nodules were initiated within three weeks and thereafter numerous upward-growing nodule roots developed from each nodule. Nodules in this symbiotic nitrogen-fixing plant resulted from an infection caused by an unidentified actinomycete-like soil microorganism. Anatomical analysis of nodule formation showed that nodules are the result of repeated endogenous lateral root initiations, one placed upon another in a complexly branched and truncated root system. The endophyte-infected cortical tissues derived from successive root primordia form the swollen nodular mass. Nodule roots develop from nodule lobes after escaping from the initial inhibitory effects of the endophyte. Included is a discussion of the anatomical similarities between nodules of Casuarina which produce nodule roots and those of Alnus which form coralloid nodules usually lacking nodule roots.     

A comparison of symbiotic nitrogen fixation in Scotland inAlnus glutinosa andAlnus rubra

Summary Alnus glutinosa andAlnus rubra growing in the field in Scotland show specific nitrogenase activities of the same order of magnitude. The period of maximum potential nitrogenase activity coincides with that of maximum growth in late Spring and Summer. It is suggested that the retention of nitrogenase activity into the Autumn when growth has virtually ceased may be important as a contribution to the nitrogenous reserves of the tree.Bioassay of different Scottish soils, all collected from the locality of natural stands ofAlnus glutinosa, showed wide variation in the nodulation of seedlings, although generally a soil poor for nodulation ofAlnus glutinosa generally gave poor nodulation ofAlnus rubra. Soils of pH 4.5 to 6.5, best suited for growth and nitrogen fixation of the two species, often gave nodules showing highest specific nitrogen fixing activity. Young (2 to 3 year old) plants in glasshouse or controlled environment cabinet, inoculated withAlnus glutinosa endophyte, differed from mature field grown plants, however, sinceAlnus rubra required a much larger (up to 2.5 times) mass of root nodules to fix a unit quantity of N. Microscopic comparison of the nodules of glasshouse plants showed that the proportion of cells containing the vesicular (nitrogen fixing) form of the endophyte was only slightly lower inAlnus rubra than inAlnus glutinosa and it is suggested that the differences in specific nitrogen fixing activity between the two species may reflect some incompatibility of function of theAlnus glutinosa endophyte when in symbiosis withAlnus rubra.     

Absence of “void area” in freeze-etched vesicles of the Alnus crispa var. mollis Fern. root nodule endophyte

Nitrogen-fixing root nodules of Alnus crispa var. mollis Fern. were studied by transmission electron microscopy and by freeze-etching technique. Ultrathin sectioning of septate vesicles of the actinomycetal endophyte showed an electron transparent zone, the so-called void area, between the vesicle cell wall and its encapsulation material. This void area was not observed in the freeze-etching replicas of cryoprotected nodular tissue. It is suggested that the void area is the result of the coming-off of the vesicle cell wall from the capsule and that its formation reflects difficulty in fixing the voluminous mature vesicle of the root nodule endophyte.