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.     

Identification of the endophypte ofDryas andRubus (Rosaceae)

Summary Root nodules ofDryas drummondii are of the coralloid type (Alnus type). The endophyte is present in the middle cortical cells of the root-nodule tissue. Transmission electron micrographs revealed an actinorhizal endophyte with septate hyphae and non-septate spherical or ovoid vesicles. Vesicles always possess at the base a septum; septa formation in the endophyte is always associated with the presence of mesosomes. Branching of the endophyte is not necessarily correlated with septum formation. Hyphal structures are more prominent in the apical part of the root nodule and vesicles are more numerous in a broad zone below this. In the middle and towards the base of the root nodule the endophytic structures appear in a stage of disintegration. Vesicles appear in a broad region near the periphery of the host cell and regularly show no strict orientation towards the host-cell wall. In the center of the host cells only hyphae occur. In the intercellular spaces between the host cells theFrankia endophyte produces spore-like structures although the outline of the sporangia is often faint.The coralloid root ofRubus ellipticus shows characteristically a basal rootlet initiated below the dichotomous branching of the nodular lobes, but extending beyond the root nodule. The endophyte is only present in the outer cortex of the root nodule in a 1–2 cell wide layer. This endophytic layer is bounded, internally as well as externally, with a 4–5 cell wide layer of tannin-filled host cells. The implications of this situation are discussed. Tannin-filled cells occur regularly inRubus species and their arrangement has been used for taxonomic purposes within the genus. TheRubus endophyte is aFrankia species with septate hyphae and distinctly septate spherical vesicles. The ultrastructure of the vesicles of theRubus endophyte is very similar to that of theAlnus endophyte.     

Demonstration of the isolation of non-infective Alnus crispa var. mollis Fern, nodule endophyte by morphological immunolabelling and whole cell composition studies.

Two filamentous, branched, and septate actinomycetes were isolated from field-collected and from axenic in vitro produced root nodules of Alnus crispa var. mollis Fern. host plant. After their transfer to a chemically defined medium, these nodule isolates could not be distinguished from each other on the basis of morphology, cultural reactions, and whole cell composition and were considered to be the same species. They were morphologically similar to the root nodule endophyte, but were incapable of nodulating aseptic host plants growing in a nitrogen-deficient substrate. Whole cells of the nodule isolates were used for the production of rabbit antibodies. The resulting specific antiisolate antibodies were conjugated with fluorescein isothiocyanate and used in staining tests of the nodule endophyte. The immunofluorescence reactions demonstrated the homology of the nodule isolates with the nodule endophyte. After pectinase degradation of the endophyte capsule, the indirect immunoferritin method corroborated the fluorescent anti-body (FA) staining reactions. There was no antigenic relationship between the nodule isolates and 13 known strains of actinomycetes as determined by the FA techique. Fluorescent antibody reactions of adsorbed conjugates suggested that endophytes of both Alnus crispa var. mollis Fern. and Alnus rugosa (DuRoi) Spreng. root nodules belong to a common serotype. The LL and mesoisomers of diaminopimelic acid were present in similar proportions in the nodule endophyte and in the nodule isolates. Glucose, mannose, and an unknown sugar were the predominant whole cell sugars in the nodule isolates, although trace amounts of arabinose and rhamnose were also displayed. The unknown sugar found in the nodule isolates was also present in trace amounts in the endophyte-suspension hydrolysate.     

Observations on the fine structure of the root nodule endophyte of Hippophaë rhamnoides L.

Summary Electron microscopy of ultra-thin sections of Hippophaë rhamnoides root nodules has been carried out in order to elucidate the nature of the endophyte. The organism is seen as a branching, septate filament approximately 0.6 microns in diameter bearing on its terminal ends spherical sub-divided vesicles 3–4 microns in diameter. In the mature nodule the vesicles are the most prominent endophyte form and appear to be formed by swelling of the hyphal tips. It is concluded that the endophyte is an actinomycete closely related to but not identical with that of Alnus glutinosa.     

Enzymes of the tricarboxylic acid cycle and the malate-aspartate shuttle in the N2-fixing endophyte of Alnus glutinosa

The occurrence and localization of enzymes involved in energy supply and biosynthesis was studied in root nodules of Alnus glutinosa (L.) Vill. Vesicle clusters of the endophyte, Frankia sp., contain NADP-dependent isocitrate dehydrogenase, succinate dehydrogenase, fumarase and malate dehydrogenase. The data indicate that both the endophyte and the host are capable of metabolizing carbon compounds via the tricarboxylic acid cycle. Both vesicle clusters of the endophyte and root nodule cells contain glutamate-oxaloacetate transaminase which can function in a malate-aspartate shuttle. This might enable transport of reducing equivalents from the host cell cytoplasm to the endophyte.     

Observations on the ultrastructure ofFrankia sp. in root nodules ofDatisca cannabina L.

Summary The fine structures of the microsymbiont inside the root nodules ofDatisca cannabina have been studied by light, by transmission- and by scanning-electron microscopy. The endophyte is prokaryotic and actinomycetal in nature. The hyphae are septate and branched, diameter 0.3–0.5 m. The tips of hyphae are swollen to form electron-dense, clubshaped to filamentous vesicles, ranging in diameter: 0.4–1.4 m. The endophyte penetrates through walls of the cortial cells. The infected zone is kidney shaped and confined to one side of the acentric stele. The orientation of infection is reversed from other actinorhizae exceptCoriaria. The hyphae are near the host cell wall and vesicles are directed towards the central vacuole. Vesicles are aseptate and no collapsing of the vesicle cell wall (void area) has been observed. Vesicle clusters structures are globular with an opening at one side of the cluster. The host cell is multinucleate or contains a lobed nucleus. Groups of mitochondria are located in between the hyphae, suggesting a strong association between the host and the endophyte for energy supply and amino acid production. The consequences of the inability to separate the mitochondria from the vesicle clusters in nodule homogenates in physiological studies have been discussed.Isolated vesicles clusters showed dehydrogenase activity, indicated by the presence of formazan crystals, after incubation with NADH and NBT. Strongest reducing activity was found within the vesicles. The possible role of filamentous vesicles in nitrogen fixation has been discussed.     

The structure and development of the haustorium in parasitic Scrophulariaceae*

The structure and development of roots and haustoria in 37 species of parasitic Scrophulariaceae was studied using light microscopy. The mature haustorium consists of two regions: the swollen “body” and the parent root, which resembles non-haustorial roots in structure. The body arises from the parent root and is composed of an epidermis, cortex, central region of xylem (the vascular core), a region of parenchyma (the central parenchymatous core), and the portion of the haustorium contained in the host tissue (the endophyte). The xylem of the vascular core is composed predominately of vessel elements. The central parenchymatous core is composed of parenchyma and col-lenchyma. Vessels extend from the vascular core through the central parenchymatous core to the endophyte. The endophyte is composed of parenchyma cells and vessel elements. No phloem is present in the body of the haustorium. Early stages in the development of the haustorium are exogenous. Initial periclinal divisions in the epidermis or outer cortex are followed by hypertrophy of cortical parenchyma. These events are followed by development of the vascular core from the pericycle, attachment of haustorium to the host by a specialized layer of cementing cells or root hairs, and penetration of the host by dissolution of host cells.     

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.     

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.     

Time course of nodule development in the Discaria trinervis (Rhamnaceae) –Frankia symbiosis

The time course of initiation and development of root nodules was investigated in the South American actinorhizal shrub Discaria trinervis (Rhamnaceae). A local strain of Frankia (BCU110501) which was isolated from D. trinervis nodules, was used as inoculum. Inoculated seedlings were periodically studied under the light microscope after clearing with aqueous NaClO. In parallel, semithin and ultrathin sections were analysed by light and electron microscopy. Infection by Frankia BCU110501 involved intercellular penetration among epidermal and cortical root cells. Nodule primordia were detected from 6 d after inoculation, while bacteria were progressing through intercellular spaces of the outer layers of cortical cells. Invasion of host cells by the symbiont occurred 7–9 d after inoculation, and hypertrophy of the primordium cells was associated with Frankia penetration. Root hairs were not deformed during the early events of nodule formation. From 13 to 16 d after inoculation, the proximal cellular zone of the primordia behaved differently from the other tissues after NaClO treatment and remained darkly pigmented. At the same time, differentiation of Frankia vesicles started to occur inside already infected cells. By 16 d after inoculation, spherical vesicles of BCU110501 were homogeneously distributed in the host cells. These vesicles were septate and surrounded by void space. Frankia spores or sporangia were not observed in the nodule tissue. This study has clarified the mode of Frankia penetration in D. trinervis , one of the Rhamnaceae which also includes Ceanothus . The events involved in infection, nodule induction, host-cell infection and vesicle differentiation have been characterized and identified as time-segregated developmental processes in the ontogeny of D. trinervis root nodules.     

Some Observations on Infection of Arachis hypogaea L. by Rhizobium

The infection process in Arachis hypogaea by rhizobia differsfrom that normally found in Trifolium spp. in that no infectionthreads are formed. The root hairs, which are long (up to 4mm), septate, and often with large basal cells, occur only atthe sites of emerging lateral roots. Infection occurs only wherethe root hairs have large basal cells. Rhizobia cause curlingand deformation of the root hairs (as in Trifolium spp.) butenter the root at the junction of the root hair and the epidermaland cortical cells. The bacteria are distributed intercellularlyvia the middle lamellae and enter the cortical cells throughthe structurally altered cell wall, often close to the hostcell nucleus. The root hairs and large basal cells become infectedin the same way. Within the cortical cells of the emerging lateralroot the rhizobia multiply rapidly and the invaded cells dividerepeatedly to form the nodule tissue. Bacteriod formation occursonly when the host cell ceases to divide.     

Branched absorbing structures (BAS): a feature of the extraradical mycelium of symbiotic arbuscular mycorrhizal fungi

The present work describes the morphogenesis and cytological characteristics of 'branched absorbing structures' (BAS, formely named arbuscule-like structures, ALS), small groups of dichotomous hyphae formed by the extraradical mycelium of arbuscular mycorrhizal (AM) fungi. Monoxenic cultures of the AM fungus Glomus intraradices Smith & Schenck and tomato ( Lycopersicum esculentum Mill.) roots allowed the continuous, non-destructive study of BAS development. These structures were not observed in axenic cultures of the fungus under different nutritional conditions or in unsuccessful (asymbiotic) monoxenic cultures. However, extraradical mycelium of G. intraradices formed BAS immediately after fungal penetration of the host root and establishment of the symbiosis. The average BAS development time was 7 d under our culture conditions, after which they degenerated, becoming empty septate structures. Certain BAS were closely associated with spore formation, appearing at the spore's substending hypha. Branches of these spore-associated BAS (spore-BAS) usually formed spores. Electron microscopy studies revealed that BAS and arbuscules show several ultrastructural similarities. The possible role of BAS in nutrient uptake by the mycorrhizal plant is discussed.     

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.     

Fine structure of actinorhiza of theRhamnaceae growing in Chile I.Talguenea quinquenervia (Gill et Hook)

Summary Root nodulesTalguenea quinquenervia Gill et Hook (Rhamnaceae) are restricted to the middle region of the root cortex. The root endophyte possesses hyphae which are septate and vesicles. The vesicles are spherical and are continuous with that of the hyphae. The endophyte fine structure is similar to otherFrankia-induced root nodules.     

Endophytic hyphal compartmentalization is required for successful symbiotic Ascomycota association with root cells

Root endophytic fungi are seen as promising alternatives to replace chemical fertilizers and pesticides in sustainable and organic agriculture systems. Fungal endophytes structure formations play key roles in symbiotic intracellular association with plant-roots. To compare the morphologies of Ascomycete endophytic fungi in wheat, we analyzed growth morphologies during endophytic development of hyphae within the cortex of living vs. dead root cells. Confocal laser scanning microscopy (CLSM) was used to characterize fungal cell morphology within lactofuchsin-stained roots. Cell form regularity Ireg and cell growth direction Idir, indexes were used to quantify changes in fungal morphology. Endophyte fungi in living roots had a variable Ireg and Idir values, low colonization abundance and patchy colonization patterns, whereas the same endophyte species in dead (γ-irradiated) roots had consistent form of cells and mostly grew parallel to the root axis. Knot, coil and vesicle structures dominated in living roots, as putative symbiotic functional organs. Finally, an increased hypha septation in living roots might indicate local specialization within endophytic Ascomycota. Our results suggested that the applied method could be expanded to other septate fungal symbionts (e.g. Basidiomycota). The latter is discussed in light of our results and other recent discoveries.     

Observations on the fine structure of the endophyte of the root nodules of alnus glutinosa (L.) gaertn.

Summary Electron micrographs have been prepared showing different stages in the development of the endophyte in Alnus glutinosa root nodules. Although the complete life cycle of the organism has not yet been worked out it is concluded that it is an Actinomycete. The organism can exist as a septate, branching filament of diameter 0.7–1.0 . However, under certain conditions within the nodule, the endophyte can form spherical sub-divided vesicles 4–5 in diameter and it is suggested that these vesicles are analogous to sporangia. Yet again under other conditions the organism fragments to form bacteroids. It would appear that the different forms of the organism are associated with different seasons of the year and with different metabolic patterns, of particular interest in this connection is the fixation of nitrogen which is associated with the nodule symbiosis.     

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.     

The effects of fungal root endophytes on plant growth: a meta-analysis

Fungal root endophytes are plant associates that colonize root tissue internally without causing any obvious harm to their host. Although ubiquitous, this relationship is not well understood. Our objectives were to determine the effects of fungal root endophyte inoculation on plant biomass and nitrogen concentration by conducting an extensive meta-analysis. We also explored the effects of experimental conditions on the host–endophyte relationship. We performed analyses weighted with non-parametric variance on plant response to root endophytes from the Ascomycetes (excluding the Clavacipitaceae), including categorical analyses of 21 experimental factors, ranging from the identity of the host and the endophyte, to the composition of the growing medium. The response of total biomass to endophyte inoculation was 18 % lower than non-inoculated controls, while individually, root biomass, shoot biomass, and nitrogen concentration responses to endophyte inoculation were neutral. The identities of both the host and the endophyte had an influence, as did the original source of the endophyte (whether or not the isolate used originated from the same host species). Experimental conditions also influenced the plant–endophyte relationship, with the most important being the availability and sources of carbon and organic nitrogen, particularly peat moss. Although our analysis demonstrates that overall plant biomass and nitrogen concentration responses to ascomycetous root endophyte inoculation is neutral to negative, these results are somewhat confounded by among-study differences in experimental conditions, which undoubtedly contribute to the high levels of variability in plant response seen in the literature.     

A Legume Genetic Framework Controls Infection of Nodules by Symbiotic and Endophytic Bacteria

Legumes have an intrinsic capacity to accommodate both symbiotic and endophytic bacteria within root nodules. For the symbionts, a complex genetic mechanism that allows mutual recognition and plant infection has emerged from genetic studies under axenic conditions. In contrast, little is known about the mechanisms controlling the endophytic infection. Here we investigate the contribution of both the host and the symbiotic microbe to endophyte infection and development of mixed colonised nodules in Lotus japonicus. We found that infection threads initiated by Mesorhizobium loti, the natural symbiont of Lotus, can selectively guide endophytic bacteria towards nodule primordia, where competent strains multiply and colonise the nodule together with the nitrogen-fixing symbiotic partner. Further co-inoculation studies with the competent coloniser, Rhizobium mesosinicum strain KAW12, show that endophytic nodule infection depends on functional and efficient M. loti-driven Nod factor signalling. KAW12 exopolysaccharide (EPS) enabled endophyte nodule infection whilst compatible M. loti EPS restricted it. Analysis of plant mutants that control different stages of the symbiotic infection showed that both symbiont and endophyte accommodation within nodules is under host genetic control. This demonstrates that when legume plants are exposed to complex communities they selectively regulate access and accommodation of bacteria occupying this specialized environmental niche, the root nodule.     

Electron microscopy of the endophyte ofAlnus glutinosa

Earlier light microscopic investigations have revealed that the endophyte ofAlnus glutinosa presents itself in three different forms. In the present study this is confirmed by electron microscopy; also, new data on the cytology of the endophyte have been obtained.The host cells are primarily infected by the hyphal form of the endophyte. A plant cell nucleus and mitochondria can be found in the infected host cells.In the majority of the infected cells, so-called vesicles develop at the tips of the hyphae. Electron micrographs show that these vesicles, as well as the hyphae, are surrounded by the host-cell cytoplasmic membrane. The endophyte cytoplasm inside the vesicles is divided in all directions by cross walls, many of which are incomplete. Plasmalemmosomes are conspicuous. Some vesicles look vigorous but others shrunken or nearly devoid of cytoplasm as if being digested.A minority of host cells situated between the vesicle-containing ones are completely filled by bacteria-like cells. These host cells, in contrast to the other ones, do not contain a nucleus nor mitochondria, nor are the endophyte cells in them enveloped by a host cell cytoplasmic membrane: these host cells are dead. Vesicles are not found in these cells.It is inferred that a living host cell exerts a stimulus on the endophyte to which the latter responds by forming vesicles at the tips of the hyphae. At a later stage the host cells digest the vesicles and the hyphae. On the other hand, if a host cell does not survive the infection, the hyphae divide into bacteria-like cells, which are not digested owing to the absence of host cytoplasm.According to the cytology of the hyphae, the endophyte is an actinomycete.The cytology of the endophyte needs further elucidation. Its plasmalemmosomes, or membranous bodies connected with the cytoplasmic membrane, are beautifully developed. The striated bodies described on p. 359 under 4) may be a new feature, which may turn up in other actinomycetes or bacteria.