Infectivity and reproductive potential of the Oswego strain of Heterorhabditis bacteriophora associated with life stages of the clover root curculio,Sitona hispidulus

The infectivity and reproductive potential of the entomopathogenic nematode Heterorhabditis bacteriophora (Oswego strain), at different concentrations, was studied. Seventy to 80.0% mortality to late instar larvae of the clover root curculio, Sitona hispidulus, and 40.0-76.0% mortality to pupae, was observed at concentrations of 15-100 infective juveniles. There were no significant differences in mortality among nematode concentrations. LC(50) levels of 4.0 and 21.4 nematodes were determined for clover root curculio larvae and pupae, respectively. Nematodes did not cause significant mortality to adult or first instar clover root curculio. H. bacteriophora was able to complete its development and reproduce in 74.0-95.0% of clover root curculio late instar larvae and pupae. Reproductive potential in curculio larvae and pupae ranged from 0 to 7040 infective juveniles per host. Larvae exposed to 100 nematodes had a reproductive potential significantly higher than in those larvae exposed to 15 and 50 nematodes. Reproductive potential in pupae decreased with an increased nematode dose, indicating potential crowding effects. Host larval and pupal mass were positively correlated with nematode progeny production.     

Effects of root nodules and taproots on survival and abundance of Sitona hispidulus (Coleoptera: Curculionidae) on Medicago sativa

ABSTRACT.

• 1 The effects of food resources on populations of larvae of Sitona hispidulus (F.), a root and nodule herbivore of Medicago sativa L., were investigated in 1983 and 1984.
• 2 Density-dependent mortality among first-instar larvae indicated that a lack of available root nodules, the primary resource for first instars, contributed to the 66.2±5.2% and 80.7±4.1% mortalities of first-instar larvae in 1983 and 1984, respectively. Initial densities of larvae entering the soil were 31.7±2.4 and 15.6±1.3 per soil sample (10.5 cm diam. ×15 cm deep) in 1983 and 1984, respectively (±SEM).
• 3 Survivorship and number of first-instar larvae per soil core sample were significantly related to number and biomass of nodules per soil sample. Percentage soil moisture was not consistently correlated with survivorship and number of larvae per soil sample.
• 4 Numbers of second- and third-instar larvae were not consistently correlated with either nodule or taproot biomass.
• 5 Numbers of fourth-instar larvae were associated with taproot biomass, suggesting that taproot surface area may also limit population levels of S.hispidulus. No correlations were found between taproot and nodule biomass on any sampling date indicating that high numbers of fourth-instar larvae associated with larger taproots were not merely due to a greater survival of first instars associated with larger taproots.
• 6 The study suggests that population levels of nodule-herbivores are controlled by the availability of root nodules. A sparse distribution of nodules results in high levels of mortality among nodule-herbivores of Medicago sativa.

     

Predation of eggs ofSitona hispidulus [Col.: Curculionidae] in alfalfa

The predation on egg populations ofSitona hispidus (Fabricius) [Col.: Curculionidae] in a stand of alfalfa was evaluated in 1982 and 1983. By using pitfall traps, catches of reproductive adults ofS. hispidulus were correlated with catches of carabid species, and potential egg predators were identified for further evaluation. Results indicated that predators removed 28 % of eggs under field conditions.Amara aenea DeGeer was found to be particularly efficient on eggs ofS. hispidulus under caged-field conditions.      

Development of nodules of Glycine max infected with an ineffective strain of Rhizobium japonicum

Bacteroids in ineffective (nitrogenase negative) nodules of Glycine max, infected with Rhizobium japonicum 61-A-24, as compared to those in effective nodules are characterized by reduced specific activities of alanine dehydrogenase to 15%, of 3-hydroxybutyrate dehydrogenase to 50%, and an increase of glutamine synthetase to 400%. In the plant cytoplasm of ineffective nodules, glutamine synthetase activity is reduced to 10–30%, glutamate dehydrogenase to 50–70%, and the aspartate aminotransferase and alanine aminotransferase are enhanced to 120–200%, depending on the age of the nodules. The total pool of soluble amino acids is reduced to 52 mol per g nodule fresh weight, as compared to 186 mol in effective nodules, with a replacement of asparagine (42 mol% of the amino acids) by an unknown amino compound. This compound is absent in nitrogenase, repressed and derepressed, free-living Rhizobium japonicum cells and in the uninfected root tissue. In nitrogenase derepressed, as compared to the repressed free-living cells of Rhizobium japonicum 61-A-101, arginine shows the most obvious change with a reduction to less than one tenth. The ultrastructure of the ineffective nodule is different from the effective organ even in the early stages. The membrane envelopes of the infection vacuoles are decomposing in heavily infected cells within 18 to 20 d after infection. In lightly infected cells very large vacuoles develop with only a few bacteroids inside. No close associations of cristae-rich mitochondria with amyloplasts are observed as in effective nodules. The uninfected cells keep their large starch granules even 40 d after infection. Some poly--hydroxybutyrate accumulation in the bacteroids is observed but only in the early stages, and it is almost absent in old nodules (40 d). At this age the infected cells are obviously compressed by uninfected cells, whereas in effective nodules with nitrogenase activity and leghaemoglobin formation, the infected cells have a much higher osmotic pressure than the neighbouring uninfected cells.Abbreviations PHBA poly--hydroxybutyric acid Prof. Dr. A. Pirson on the occasion of his 70th birthday     

Rhizobium nod genes are involved in the induction of two early nodulin genes in Vicia sativa root nodules

Nodulin gene expresison was studied in Vicia sativa (common vetch) root nodules induced by several Rhizobium and Agrobacterium strains. An Agrobacterium transconjugant containing a R. leguminosarum symplasmid instead of its Ti-plasmid, that was previously shown to form empty nodules on pea, induced nodules on Vicia roots in which nodule cells were infected with bacteria. In the Vicia nodules induced by this transconjugant, two so-called early nodulin genes were found to be expressed, whereas in the nodules formed on pea the expression of only one early nodulin gene was detected. In both cases the majority of the nodulin genes was not expressed.Apparently, an intracellular location of the bacteria is not sufficient for the induction of the majority of the nodulin genes. All nodulin genes were expressed in nodules induced by cured Rhizobium strains containing cosmid clones that have a 10 kb nod region of the sym-plasmid in common. Since in tumours no nodulin gene expression was found at all, the Agrobacterium chromosome does not contribute to the induction of nodulin genes. Therefore it is concluded that the signal for the induction of the expression of the two Vicia early nodulin genes is encoded by the nod-region, and the signal involved in the induction of all other nodulin genes has to be located outside the sym-plasmid, on the Rhizobium chromosome. The apparent difference in early nodulin gene expression between pea and Vicia is discussed in the light of the usefulness of Agrobacterium transconjugants in the study of nodulin gene expression.     

Aerial root nodules in the tropical legume,Pentaclethra macroloba

Summary Symbiotic nitrogen fixation in angiosperms normally occurs in buried root nodules and is severely inhibited in flooded soils. A few plant species, however, respond to flooding by forming nodules on stems, or, in one case, submerged roots with aerenchyma. We report here the novel occurrence of aerial rhizobial nodules attached to adventitious roots of the legume,Pentaclethra macroloba, in a lowland tropical rainforest swamp in Costa Rica. Swamp sapdings (1–10 cm diameter) support an average 12 g nodules dry weight per plant on roots 2–300 cm above water, and nodules remain in aerial positions at least 6 months. Collections from four swamp plants maintained linear activity rates (3–14 moles C₂H₄/g nodule dry weight/hr) throughout incubations for 6 and 13 hrs; excised nodule activity in most legumes declines after 1–2 hrs. Preliminary study of the anatomy and physiology suggest aerial nodules possess unusual features associated with tolerance to swamp conditions. High host tree abundance and nodulation in the swamp compared to upland sites indicate the aerial root symbiosis may contribute more fixed nitrogen to the local ecosystem than the more typical buried root symbiosis.     

Structure of root nodules formed by Rhizobium on the non-legume Trema cannabina var. scabra

The structure of the nodules formed by Rhizobium on the non-legume Trema cannabina var. scabra was studied using the light microscope. The overall features of the nodules showed greater resemblance to the non-legume rather than the legume nodule. Nodule squashes yielded bundles of infection threads and bacteroids with morphological differences from rhizobial cells grown on yeast-mannitol-glucose agar. Two types of cell infection occurred within the bacterial zone; plant cells were either, like legumes, filled with rhizobia released from the infection threads (less than one third of infected cells) or were filled with the extensive growth and development of the infection thread. The rate of nitrogen fixation in the Trema nodule was high. It seemed that host cells filled with threads were active in N fixation.     

Coculture of Pachyrhizus erosus (L.) hairy roots with Rhizobium spp.

Summary We have established an in vitro system for the induction and study of nodulation in Pachyrhizus erosus (jicama) via a hairy root-Rhizobium coculture. In vitro-grown P. erosus plantlets were infected with Agrobacterium rhizogenes (ATCC No. 15834) and two hairy root lines were established. Hairy roots were grown in a split-plate system in which compartment I (CI) contained MS medium with nitrogen and different sucrose levels (0–6%), while CII held MS medium without nitrogen and sucrose. Nodule-like structures developed in transformed roots grown in CI with 2–3% surcose, inoculated with Rhizobium sp. and transferred to CII. Nodule-like structures that developed from hairy roots lacked the rigid protective cover observed in nodules from plants grown in soil. Western blot analysis of nodules from hairy roots and untransformed roots (of greenhouse-grown jicama) showed expression of glutamine synthetase leghemoglobin and nodulins. Leghemoglobin was expressed at low levels in hairy root nodules.     

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.     

Arctic and subarctic soil populations of Rhizobium leguminosarum biovar trifolii nodulating three different clover species: Characterisation by diversity at chromosomal and symbiosis loci

Indigenous soil populations of Rhizobium leguminosarum biovar trifolii from Arctic and subarctic regions have been characterised with emphasis on chromosomal and symbiotic genes. Three clover species were used to trap rhizobia from soils along a latitudinal gradient from 78°N to 60°N in Norway. For the first time R. l. bv. trifolii was isolated from Svalbard at 78°N. Under the extreme conditions in the Arctic, rhizobia have survived as saprophytes and in symbiosis with clover legumes. The chromosomal diversity of the soil populations was mapped by rep-PCR. Separation of chromosomal types were strongly influenced by geographic origin. Symbiotic genes, the nodEF and nifDK IGS gene regions, were investigated by PCR-RFLP. The nifDK IGS were more conserved than the nodEF genes. Sym plasmids were widely distributed in different chromosomal types and across the latitudinal gradient.     

Host-specificity mutants of Rhizobium meliloti have additive effects in situ on initiation of alfalfa nodules

Pairs of Rhizobium meliloti nod mutants were co-inoculated onto alfalfa (Medicago saliva L.) roots to determine whether one nod mutant could correct, in situ, for defects in nodule initiation of another nod mutant. None of the Tn5 or nod deletion mutants were able to help each other form nodules when co-inoculated together in the absence of the wild-type. However, as previously observed, individual nod mutants significantly increased nodule initiation by low dosages of co-inoculated wild-type cells. Thus, nod mutants do produce certain signal substances or other factors which overcome limits to nodule initiation by the wild-type. When pairs of nod mutants were co-inoculated together with the wild-type, the stimulation of nodulation provided by individual nodABC mutants was not additive. However, clearly additive or synergistic stimulation was observed between pairs of mutants with a defective host-specificity gene (nodE, nodF, or nodH). Each pair of host-specificity mutants stimulated first nodule formation to nearly the maximum levels obtainable with high dosages of the wild-type. Mutant bacteria were recovered from only about 10% of these nodules, whereas the co-inoculated wild-type was present in all these nodules and substantially outnumbered mutant bacteria in nodules occupied by both. Thus, these mutant co-inoculants appeared to help their parent in situ even though they could not help each other. Sterile culture filtrates from wild-type cells stimulated nodule initiation by low dosages of the wild-type, but only when a host-specificity mutant was also present. The results from our studies seem consistent with the possibility that pairs of host-specificity mutants are able to help the wild-type initiate nodule formation by sustained production of complementary signals required for induction of symbiotic host responses.     

Leghaemoglobin within bacteroid-enclosing membrane envelopes from soybean root nodules

Methods are reported for the preparation from soybean (Glycine max (L.) Merr.) root nodules, of well-washed, intact membrane envelopes containing bacteroids. The intact envelopes are of much lower density than the bacteroids within and therefore only low speed centrifugation (approx. 150 g) may be used. The optimum osmotic strength is 600 mOsm/kg H₂O. The envelope contents were recovered following mild osmotic shock and-or hard centrifugal packing at >10,000 g. Extracts prepared in this way contained leghaemoglobin (identified spectrophotometrically), low-molecular-weight fluorescent materials and other components which are yet to be identified. Envelope leghaemoglobin did not react with specific antibody until the envelopes were ruptured. ¹³¹I-Labelled leghaemoglobin or bovine serum albumin, added during initial breakage of nodule cells, was not released when envelopes were ruptured to release leghaemoglobin. It is therefore concluded that this leghaemoglobin is located within the envelope space and did not arise from adhering or occluded cytosol leghaemoglobin. Based on the number and dimensions of microscopically intact envelopes in these preparations, the concentration within that space was in the range 178–523 M. Based on these estimates, leghaemoglobin within envelopes represented about one third of the total amount present in the nodule cells. Flat-bed isoelectric focusing of partially-purified envelope leghaemoglobin demonstrated that the latter contained all of the leghaemoglobin components previously reported for soybean nodules and an additional minor component focusing between leghaemoglobins a and b.     

Arabinogalactan proteins during the development of soybean root nodules

In soybean (Glycine max (L.) Merr.) root nodules the level of hydroxyproline-containing molecules is developmentally regulated. Hydroxyproline accumulates in both nodule cortex and medulla. In the cortex, the hydroxyproline is mainly localized in the cell wall, presumably as extensin, but in the medulla it is mainly in the soluble fraction as an arabinogalactan protein (AGP). Nodule-specific AGPs are present at early nodulation. The highest concentration of AGP is in the nodule medulla, followed by nodule cortex, uninfected roots, leaves, flowers, pods and seeds. Root nodules and all organs of the soybean plant that were tested were found to express a tissue-specific set of arabinogalactan proteins.Abbreviation AGP Arabinogalactan protein     

Isolation of monoclonal antibodies reacting with peribacteriod membranes and other components of pea root nodules containing Rhizobium leguminosarum

Plant and bacterial antigens contributing to nodule development and symbiosis in pea (Pisum sativum L.) roots were identified after isolation of a set of monoclonal antibody (McAb)-producing hybridoma lines. Rats were immunised with the peribacteriod material released by mild osmotic shock treatment from membrane-enclosed bacteroids of Rhizobium leguminosarum bv. viceae. In order to diversify the range of McAb specificities, this material was either used as immunogen directly (method 1), or after immunodepletion of a set of glycoprotein and lipopolysaccharide antigens (method 2), or after deglycosylation (method 3). After fusion and screening of cloned hybridoma lines, these three immunisation methods gave respectively 4, 2 and 1 classes of McAb with unique antigen specificities. Ultrastructural immunogold localisation studies showed four different antigens to be present on peribacteriod and plasma membranes (identified by MAC 64, 202, 206 or 209); in addition, a glycoprotein of plant origin but present in the infection-thread matrix was identified by MAC 204. Although none of the epitopes recognised by these McAb was nodule-specific, several were found to be more abundant in extracts of nodule tissue than in uninfected roots (MAC 64, 202, 204, 206). Two McAb reacted with new bacterial antigens: MAC 203 identified a bacterial antigen expressed upon infection but not in free-living cultures of Rhizobium, and MAC 115 identified a bacterial polypeptide (55 kdaltons) that was present in both free-living and bacteroid forms. There were also some McAb of broader specificity that react with antigens present in both plant and bacterial cytoplasms.Abbreviations ELISA enzyme-linked immunosorbent assay - Ig inmunoglobulin - kDa kilodalton - LPS lipopolysaccharide - McAb monoclonal antibody - PBM peribacteroid membrane - SDS-PAGE sodium dodecyl sulfate-polyacryl-amide gel electrophoresis - TFMS trifluoromethane sulfonic acid     

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.     

Spatial relationships between uninfected and infected cells in root nodules of soybean

In soybean (Glycine max (L.) Merr.) the uninfected cells of the root nodule are responsible for the final steps in ureide production from recently fixed nitrogen. Stereological methods and an original quantitative method were used to investigate the organization of these cells and their spatial relationships to infected cells in the central region of nodules of soybean inoculated with Rhizobium japonicum strain USDA 3I1B110 and grown with and without nitrogen (as nitrate) in the nutrient medium. The volume occupied by the uninfected tissue was 21% of the total volume of the central infected region for nodules of plants grown without nitrate, and 31% for nodules of plants grown with nitrate. Despite their low relative volume, the uninfected cells outnumbered the much larger infected cells in nodules of plants grown both without and with nitrate. The surface density of the interface between the ininfected and infected tissue in the infected region was similar for nodules in both cases also, the total range being from 24 to 26 mm²/mm³. In nodules of plants grown without nitrate, all sampled infected cells were found to be in contact with at least one uninfected cell. The study demonstrates that although the uninfected tissue in soybean nodules occupies a relatively small volume, it is organized so as to produce a large surface area for interaction with the infected tissue.     

Growth regulators,Rhizobium and nodulation in peas

The cytokinin content of roots and nodules of pea and the culture supernatants from two strains of Rhizobium leguminosarum has been examined. Roots, nodules and wild-type Rhizobium culture medium contained very little cytokinin as indicated by bioassay. Chemical ionisation gas chromatography-mass spectrometric analysis of the isopentenyladenine content of the culture medium from the Rhizobium strains confirmed that the content of the wild-type was low (approx. 1 ng dm^-3) but that it was increased by the introduction of the Agrobacterium Ti plasmid into the Rhizobium strain.Abbreviations CI chemical ionisation - GCMS gas chromatography-mass spectrometry - HPLC high performance liquid chromatography - iPAde isopentenyladenine - MIM multiple ion monitoring