In vitro production of specialized reproductive torulose hyphae byFrankia strain ORS 021001 isolated fromCasuarina junghuhniana root nodules

Summary AFrankia strain (ORS 021001) isolated fromCasuarina junghuhniana root nodules was shown to produce four type of structuresin vitro: vegetative hyphae, sporangiospores within sporangia, N₂-fixing vesicles, and a fourth type of structure which is described in detail in this report. Structures of this latter type which we propose to call reproductive torulose hyphae: (RTH) result from enlargement and multiple segmentation of vegetative hyphae into torulose chaions of spore-like cells. RTH differ from sporangia in three major aspects: morphology, morphogenesis and outgrowth. RTH play an important role in survival and reproduction ofFrankia strain ORS 021001. Adding activated charcoal to the nutrient medium promotes the formation ofFrankia colonies orginating from RTH.     

Variable compatibility of clonedAlnus glutinosa ecotypes against ineffectiveFrankia strains

Nodulation tests onin-vitro propagated clones ofAlnus glutinosa ecotypes (forest ecotype, pioneer ecotype) withFrankia strains originating from both ecotypes indicated differences in host-plant compatibility. Inoculated plants of the pioneer ecotype clone were not infected by strains, that were unable to fix nitrogen in pure culture. Nodulation could only be induced on the clone of the forest ecotype, but no nitrogen-fixing activity could be detected. Ultra-structural observations of the nodules by SEM and TEM indicated that ineffectivity of these strains was correlated with the lack of vesicles in the infected cells. Cells were only filled with hyphae: neither sporangia nor vesicles could be detected. In contrast, effective nodules could be obtained on both alder clones after inoculation with an effective strain, showing normal development of vesicle clusters in infected cells. In pure culture the ineffective strains produced no vesicles; sporangia were found only during early stage of growth. The results demonstrate the existence ofFrankia strains which were either non-infective or ineffective on different clones ofAlnus glutinosa.     

Presence of sporangia of Frankia in the rhizosphere of Discaria (Rhamnaceae)

Discaria trinervis and Discaria americana are native actinorhizal plants in Argentina. Discaria seedlings growing in N-free liquid culture, inoculated with dry soils, developed Frankia colonies in the rhizosphere. The occurrence of hyphae, vesicles and sporangia characteristic of Frankia are described in these colonies. The presence of sporangia of Frankia has previously neither been reported in the genus Discaria, nor in the other genera of the tribe Colletieae inside root nodules or outside roots. The infective capacity of the colonies has been demonstrated.     

Studies of an effective strain ofFrankia fromAllocasuarina lehmanniana of the Casuarinaceae

Summary Seedlings ofCasuarina spp. andAllocasuarina spp. were grown from seed in the greenhouse and inoculated with a nodule suspension fromC. equisetifolia. Plants ofCasuarina spp. nodulated regularly and were effective in nitrogen-fixation. Only one species ofAllocasuariona, A. lehmanniana formed root nodules. Using these plants as source of inoculum, the isolation of a newFrankia sp. HFPA11I1 (HFP022 801) was made and the strain was grown in pure culture.Frankia sp. HFPA11I1 grows well in a defined medium and shows typical morphological characteristics. In media lacking combined nitrogen, the filamentours bacterium forms terminal vesicles in abundance and differentiaties large intrahyphal or terminal sporangia containing numerous spores. This strain, used as inoculum, nodulates effectively seedlings ofC. equisietifolia andC. cunninghamiana, forming nodules with verically-growing nodule roots. Although effective in acetylene reduction, the endophyte within the nodules is filamentous and lacks veiscles. When used to inoculated seedlings ofA llocasuarina lehmanniana, Frankia sp. HFPA11I1 induces root nodules which are coralloid and lacking nodule roots. The nodules are effective in acetylene reduction and the filamentous hyphae ofFrankia within the nodule lobes lack vesicles. Effective nodulation inA. Lehmanniana depends upon environmental conditions of the seedlings and proceeds much more slowly than in Casuariana.     

Ultrastructure of freeze-substituted hyphae of the basidiomyceteLaetisaria arvalis

Summary The ultrastructure of freeze-substituted (FS) hyphae ofLaetisaria arvalis is described and compared to that of similar hyphae preserved by conventional chemical fixation (CF). The outline of membrane-bound organelles as well as the plasma membrane was smooth in FS cells. In contrast, hyphae preserved by CF exhibited membrane profiles that were extremely irregular. Centers of presumed Golgi activity were best preserved by FS. Microvesicles, 27–45 nm diameter and hexagonal in transverse section, were observed most readily in FS cells. Filasomes (= microvesicles within a filamentous matrix) were only observed in FS cells. Apical vesicles, 70–120 nm diameter, associated with the centers of Golgi activity and within the Spitzenkörper region exhibited finely granular matrices in FS hyphae, whereas in CF hyphae the contents were coarsely fibrous and less electron-dense. Microvesicles were present at hyphal apices and regions of septa formation. Filasomes were also found at regions of septa formation as well as along lateral hyphal tip cell walls. Microvesicles, but not filasomes, were observed in membrane-bound vesicles (= multivesicular bodies) and in larger vacuoles. Filaments, 5.2–5.4 nm wide, were juxtaposed with centripetally developing septa. Cytoplasmic inclusions, 20–40 m in length, composed of bundles of 6.7–8.0 nm wide filaments were observed in both FS and CF hyphae.     

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.     

The influence of fertilizers on root rot of field peas caused by Fusarium oxysporum,Pythium vexans and Rhizoctonia solani inoculated singly or in combination

A Frankia strain ISU 0224887 was isolated from spore negative root nodules of Gymnostoma sumatranum and was grown in pure culture. It was infective and effective for Gymnostoma species but failed to nodulate Allocasuarina and Casuarina seedlings. Light and scanning electron microscopy of it in nitrogen free medium revealed a filamentous mat of septate and branched hyphae bearing sporangia and vesicles capable of fixing nitrogen. The strain also produced an orange pigment after 2 weeks culture. The strain utilized only TWEEN 80 and propionate as sole carbon sources. The different antibiotics used showed varying effects on its growth.     

A comparison of cultural characteristics and infectivity ofFrankia isolates from root nodules ofCasuarina species

Summary The isolations of three new strains ofFrankia were made from root nodules ofCasuarina cunninghamiana growing aeroponically. Two strains, HFPCCI1 and HFPCcI2 isolated by Lopez are typicalFrankia strains, producing sporangia among filamentous mats in culture and, in the absence of combined nitrogen, forming vesicles and showing acetylene reduction. They are red-pigmented and, although failing to nodulateCasuarina hosts, effectively nodulatedElaeagnus andHippophae. A third strain HFPCcI3 isolated by Zhang from the same source, also a typicalFrankia, can form sporangia and vesicles in culture and reduce acetylene, is unpigmented, fails to nodulateElaeagnus but effectively nodulatesC. cunninghamiana andC. equisetifolia. Comparisons are made among all of theCasuarina isolates in our collection from around the world (twelve in all) with regard to their cultural characteristics and capacity to infect host plant species. Questions are raised about the specificity of the various isolates and their possible affinities. Opportunities are suggested for inoculation of seedlings for forestry and field application using the infective, effective strains now available.     

Endophyte differentiation inCasuarina actinorhizae

Summary This is an ultrastructural study of development of infected cells in nitrogen fixing root nodules ofCasuarina spp. While several aspects of development are similar to those found in many other actinorhizae, unusual aspects of development of the host cell and differentiation of the endophyte inCasuarina are correlated with unusual changes in the wall of the infected cell. Instead of vesicles the endophyte forms atypical hyphae in mature infected cells. These unusual hyphal forms are termed intracellular hyphae. Intracellular hyphae are nonseptate hyphae which originate and terminate within the same host cell, and have a varying diameter and a multidirectional growth and branching pattern. A laminate surface layer previously undescribed on hyphae ofFrankia is a feature common to mostCasuarina endophytic hyphae and is probably similar chemically to the laminae comprising the multilamellate envelope of endophytic vesicles in other actinorhizae.This paper is Florida Agricultural Experiment Station Journal Series No. 7350.     

DEVELOPMENT OF ENDOPHYTIC FRANKIA SPORANGIA IN FIELD- AND LABORATORY-GROWN NODULES OF COMPTONIA PEREGRINA AND MYRICA GALE

Field-collected nodules of Comptonia peregrina (L.) Coult. and Myrica gale L. (Myricaceae), infected by the nitrogen-fixing actinomycete Frankia sp., were of two types: those that lacked sporangia entirely, designated spore(-), and those that showed extensive sporangial development, designated spore(+). In spore(+) nodules of C. peregrina, sporangia began to develop after the differentiation of endophytic vesicles and the concomitant onset of nitrogenase activity. At the onset of sporangial differentiation, infected host cells appeared healthy. However, endophytic vesicles and host cell cytoplasm and nuclei began to senesce rapidly as sporangia developed. Staining of sectioned material with the fluorescent stain Calcofluor White suggested that vesicles, hyphae and young sporangia were enclosed within a host-derived encapsulation layer, but mature sporangia were no longer encapsulated. In both C. peregrina and M. gale, vesicles were more short-lived in spore(+) than in spore(-) nodules. Field-collected spore(+) M. gale nodules exhibited a pronounced seasonality of sporangial formation. Sporangia began to differentiate in June, after the formation of vesicles and became more prominent in late summer. Inter- and intraspecific cross-inoculations suggest that the ability to form sporangia in the symbiotic state is controlled by endophytic strain type rather than host genotype or host/endophyte combination. The host may, however, influence the number and seasonal appearance of sporangia formed.     

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.     

Paramural bodies of Albugo candida

The paramural bodies of Albugo candida were formed solely by elaboration of the plasmalemma. Two major forms were recognized: one consisting of plasmalemmal invaginations projecting into the cytoplasm; the other appearing like a pocket containing a number of vesicles and tubules. It is suggested that the first is the basic form of paramural body. In sporangia the paramural bodies break away from the plasmalemma and undergo autodigestion while in vegetative hyphae their tubules and lamellae break up into vesicles that are finally sequestered into the wall.     

Survival ofFrankia strains introduced into soil

Factors affecting the establishment of Alnus/Frankia symbioses were studied partly by following the survival ofFrankia strains exposed to different soil conditions, and partly by investigating the effect of pH on nodulation. TwoFrankia strains were used, both of the Sp⁻ type (sporangia not formed in nodules). One of the strains sporulated heavily, while the other formed mainly hyphae. The strains originated fromAlnus incana root nodules growing in soils of pH 3.5 and 5.0. The optimum pH for their growth in pure culture was found to be 6.7 and 6.2, respectively. The strains were introduced into twoFrankia-free soils, peat and fine sand. Their survival, measured as the persistance of nodulation capacity using the plant infection technique, was followed for 14 months. The survival curves of the strains were similar despite the morphological differences between the strains in pure culture. The nodulation capacities declined over time both at 14 and 22°C. Survival was better in soils limed to a pH above 6 than in soils at their original pH (peat 2.9, fine sand 4.2). The effect of pH on nodule formation in Alnus seedlings by theFrankia strains was studied in liquid culture. The number of nodules increased linearly within the pH range studied (3.5–5.8). No nodules were formed at pH 3.5.     

Morphology,physiology and infectivity of twoFrankia isolates An 1 and An 2 from root nodules ofAlnus nitida

Summary Two different strains, An 1 and An 2, were obtained from root nodules ofAlnus nitida Endl., collected from one locality in the area of its natural habitat near Bahrin, District Swat, Pakistan. The light and electron microscopy of the isolates revealed the occurrence of septate and branched hyphae bearing sporangia and vesicles. The strains differed in their growth requirements, nitrogen-fixing ability and production of extracellular pigments, thus indicating the existence of more than oneFrankia strain in the same locality. In the absence of combined nitrogen in the medium strain An 1 formed vesicles and fixed N₂ (up to 200 nmol C₂H₄. mg protein^–1.h^–1), while strain An 2 under the experimental conditions formed only few vesicles and fixed N₂ at a very low rate (ca 10 nmol C₂H₄. mg protein^–1 .h^–1). The nitrogenase activity of strain An 1 was strongly affected by the O₂ concentration.Frankia An 1 and An 2 were infective and effective onA. nitida andA. glutinosa but not onDatisca cannabina andElaeagnus umbellata. Both An 1 and An 2 strains were more infective and effective onA. glutinosa thanFrankia strains AvcIl and CpI1.     

Comparison of the ultrastructure of conventionally fixed and high pressure frozen/freeze substituted root tips ofNicotiana andArabidopsis

Summary To circumvent the limitations of chemical fixation (CF) and to gain more reliable structural information about higher plant tissues, we have cryofixed root tips ofNicotiana andArabidopsis by high pressure freezing (HPF). Whereas other freezing techniques preserve tissue to a relatively shallow depth, HPF in conjunction with freeze substitution (FS) resulted in excellent preservation of entire root tips. Compared to CF, in tissue prepared by HPF/FS: (1) the plasmalemma and all internal membranes were much smoother and often coated on the cytoplasmic side by a thin layer of stained material, (2) the plasmalemma was appressed to the cell wall, (3) organelle profiles were rounder, (4) the cytoplasmic, mitochondrial, and amyloplast matrices were denser, (5) vacuoles contained electron dense material, (6) microtubules appeared to be more numerous and straighter, with crossbridges observed between them, (7) cisternae of endoplasmic reticulum (ER) were wider and filled with material, (8) Golgi intercisternal elements were more clearly resolved and were observed between both Golgi vesicles and cisternae, and (9) larger vesicles were associated with Golgi stacks. This study demonstrates that HPF/FS can be used to successfully preserve the ultrastructure of relatively large plant tissues without the use of intracellular cryoprotectants.Abbreviations CF chemical fixation - ER endoplasmic reticulum - FF freeze fracture - FS freeze substitution - HPF high pressure freezing Dedicated to the memory of Professor Oswald Kiermayer     

Characterization of nativeFrankia strains isolated from chilean shrubs (Rhamnaceae)

Nine nativeFrankia strains were isolated from root nodules of four chilean actinorhizal plants (Rhamnaceae). The strains were designated as ChI1, ChI2, ChI3 and ChI4 fromColletia hystrix; ReI4 and ReI6 fromRetanilla ephedra; TqI12 and TqI15 fromTalguenea quinquinervis and TtI42 fromTrevoa trinervis. By scanning electron microscopy, all the strains exhibited similar actinomycetal structures: hyphae, sporangia and vesicles. The growth patterns of the isolates in BAP medium were similar. All showed a lag phase of approximately 6–7 days, then exhibited a logarithmic phase, except the ReI4 strain which seems to follow a linear growth pattern. A common feature of all the strains was a rapid loss of biomass at the end of the growth phase. All native strains grew on BAP medium supplemented with glucose. In six out of nine strains, the glucose was the best of the carbon sources tested. However, the strains differed in their ability to use other carbon sources such as arabinose, mannitol, maltose, succinate, sucrose, pyruvate, propionate and galactose. The isolates were sensitive to six antibiotics assayed (ampicillin, penicillin G, rifampicin, chloramphenicol, erythromycin and kanamycin). Using the acetylene reduction assay, the nitrogenase activity of the strains was determined. All strains grown in BAP medium lacking a combined nitrogen source were able to reduce acetylene ‘in vitro’.     

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.     

In vitro physiological approach to classification ofFrankia isolates of ‘the Alnus group’, based on urease,protease and β-glucosidase activities

Summary Most of theFrankia strains isolated fromAlnus andMyrica species are morphologically almost indistinguishable, when grown under standard culture conditions. They form similar vegetative hyphae while sporangia are produced in variable amounts from strain to strain.Physiological reactions were assessed in order to compare 20 strains isolated from various species ofAlnus and one species ofMyrica in Europe and North America. Among invariant negative or positive characteristics, differences in urease, protease and -glucosidase activities appeared to be of significant value.     

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.     

Consequences of Sporangial Development for Nodule Function in Root Nodules of Comptonia peregrina and Myrica gale

Frankia sp., the actinomycetous endophyte in nitrogen-fixing actinorhizal nodules, may differentiate two forms from its hyphae: vesicles and sporangia. In root nodules of Comptonia peregrina (L.) Coult. and Myrica gale L., sporangia may be either absent or present. Nitrogenase activity and symbiotic efficiency were contrasted in spore(+) and spore(−) nodules of these two host genera. Seedlings of C. peregrina nodulated with the spore(+) inoculum showed only 60% of the nitrogenase activity and 50% of the net size of their spore(−) counterparts after 12 weeks of culture. Measurements of acetylene reduction (i.e., nitrogenase activity) were coordinated with samplings of nodules for structural studies. Significant differences in acetylene reduction rates were discernible between spore(+) and spore(−) nodules commencing 4 weeks after nodulation, concomitant with the maturation of sporangia in the nodule. Spore(+) nodules ultimately reached less than half of the rate of nitrogenase activity of spore(−) nodules. Both types of nodules evolved only small amounts of molecular hydrogen, suggesting that both were equally efficient in recycling electrons lost to the reduction of hydrogen ions by nitrogenase. Respiratory cost of nitrogen fixation, expressed as the quotient of micromole CO₂ to micromole ethylene evolved by excised nodules, was significantly greater in spore(+) than in spore(−) nodules. M. gale spore(−) nodules showed variable effectivity, though all had low CO₂ to ethylene evolution ratios. M. gale spore(+) nodules resembled C. peregrina spore(+), with low effectivity and high respiratory cost for nitrogen fixation.