Glutathione and homoglutathione synthetases of legume nodules. Cloning, expression, and subcellular localization.

The thiol tripeptides glutathione (GSH) and homoglutathione (hGSH) are very abundant in legume root nodules and their synthesis is catalyzed by the enzymes gamma-glutamylcysteine synthetase (gammaECS), GSH synthetase (GSHS), and hGSH synthetase (hGSHS). As an essential step to elucidate the role of thiols in N(2) fixation we have isolated cDNAs encoding the three enzymes and have quantified the transcripts in nodules. Assay of enzyme activities in highly purified nodule organelles revealed that gammaECS is localized in the plastids, hGSHS in the cytosol, and GSHS in the cytosol and mitochondria. These results are consistent with sequence analyses. Subcellular fractionation of nodules also showed that bacteroids contain high thiol concentrations and high specific gammaECS and GSHS activities. Results emphasize the role of nodule plastids in antioxidant protection and in control of thiol synthesis, and suggest that plastids may be important in the stress response of nodules. Overall, our results provide further evidence that thiol synthesis is critical for nodule functioning.

Construction of transgenic pea lines with modified expression of diamine oxidase and modified nodulation responses with exogenous putrescine.

Diamine oxidase (DAO) might influence pea nodule development either by regulating the peroxide-driven cross-linking of glycoproteins in the infection thread matrix or by modifying the metabolism of diamines and polyamines in host cells. Transformed lines of pea (Pisum sativum) with the coding sequence for DAO (PSAO-1) in sense orientation behind a tissue-specific promoter (pENOD12A) showed strong co-suppression of DAO activity in extracts from nodules and epicotyls, whereas the antisense constructs were relatively unaffected. No difference in nodule number was observed between transformed lines and controls, suggesting that DAO does not normally have an essential role in nodule initiation. However, lines showing co-suppression of DAO were less sensitive to the inhibitory effects of exogenous putrescine and less active in the cross-linking of matrix glycoprotein, indicating that putrescine-derived products of DAO activity could retard nodule development. Inoculation of co-suppressed lines with Rhizobium strain B661 (a lipopolysaccharide-defective mutant) resulted in more extreme impairment of nodule development and nitrogen fixation capacity, relative to lines with normal levels of DAO, which suggests that DAO may serve to reduce the endogenous level of inhibitory diamines or polyamines in nodules under physiological stress. We conclude that the most critical role of DAO in pea nodule development is apparently in the regulation of diamine levels in host tissues.

Immunolocalization of a cysteine protease in vacuoles, vesicles, and symbiosomes of pea nodule cells.

PsCYP15A is a cysteine protease from pea (Pisum sativum L.). It was first recognized as an up-regulated transcript in wilted shoots and subsequently in root nodules containing Rhizobium. Proteolytic activity of PsCYP15A in nodule extracts is now reported following immunopurification with polyclonal antiserum raised against recombinant antigen. Western-blot analysis indicated two forms of PsCYP15A, a pro-form (approximately 38 kD) and a mature form (approximately 30 kD). Both forms were present in most tissue samples, but only the mature form was isolated from cell-fractionated symbiosomes containing nitrogen-fixing bacteroids. Immunolabeling of nodule sections showed localization of PsCYP15A antigen in large vacuolar bodies, cytoplasmic vesicles, and the perisymbiont space. Immunolabeling of tissue sections from wilted shoots also indicated the presence of PsCYP15A in vacuoles and cytoplasmic vesicles. This protease may be involved in the adaptation to changes in cell turgor, both in wilted shoots and in nodule tissue. Additionally, the protease may be involved in protein turnover in the symbiosome compartment.

Nodule-expressed Cyp15a cysteine protease genes map to syntenic genome regions in Pisum and Medicago spp.

PsCyp15a is a gene that encodes a vacuolar cysteine protease expressed in wilt-induced shoots of Pisum sativum (pea) and in root nodules. To further the understanding of nodular PsCyp15a expression, a region 5' to the coding sequence of the gene was cloned. Varying lengths of 5' untranslated sequence were fused with the uidA coding region and introduced from Agrobacterium rhizogenes into "hairy roots" of Vicia hirsuta. In this transgenic root nodulation assay, a promoter sequence of 900 bp was sufficient to give an expression pattern indistinguishable from that obtained in pea nodules by in situ hybridization. An orthologue of PsCyp15a was cloned from nodule mRNA of Medicago sativa and a corresponding gene identified in M. truncatula was also shown to express strongly in nodules. With molecular mapping techniques, it was demonstrated that these genes map to a syntenic genome location in pea and Medicago spp., but the map positions of the Cyp15a genes cannot be correlated with existing nodulation mutants.

Localized expression of cathepsin B-like sequences from root nodules of pea (Pisum sativum).

Cathepsin B is an ancient family of eukaryotic cysteine proteases. We describe PsCat1, a plant cathepsin B-like transcript, identified as an expressed sequence in Rhizobium-induced, nitrogen-fixing root nodules of pea. In situ hybridization studies in root nodules showed strong, extremely localized expression of PsCat1 in individual cells associated with the central infected tissue. Restriction fragment polymorphism mapping of the PsCat1 locus in pea shows no correlation with existing mutant lines defective in symbiosis.

Involvement of diamine oxidase and peroxidase in insolubilization of the extracellular matrix: implications for pea nodule initiation by Rhizobium leguminosarum.

Rhizobium leguminosarum colonizes host cells and tissues through infection threads, which are tubular in-growths of the plant cell wall. Monoclonal antibody MAC265 recognizes a plant matrix glycoprotein (MGP) associated with the lumen of these infection threads. This glycoprotein is also released in soluble form from the root tips of pea seedlings. In the presence of hydrogen peroxide, release of glycoprotein from root tips was not observed. Extractability from root tips was therefore used as the basis for investigating the peroxide-driven insolubilization of MGP and the possible involvement of two extracellular enzymes, peroxidase (POD) and diamine oxidase (DAO), was investigated. Release of MGP from root tips was enhanced by application of POD and DAO inhibitors (salicylhydroxamic acid and o-phenanthroline, respectively). Furthermore, release of MGP was inhibited by pretreatment of roots with putrescine (the substrate of DAO) and also by application of a partially purified extract of DAO from pea shoots. Following inoculation of pea roots with R. leguminosarum, elevated levels of DAO transcript were observed by reverse transcriptase-polymerase chain reaction (RT-PCR), but these then dropped to a low level from 4 to 10 days post inoculation, rising again in more mature nodules. In situ hybridization studies indicated that the bulk of the transcription was associated with the infected tissue in the center of the nodule. On the basis of these observations, we postulate that DAO may be involved in the peroxide-driven hardening of MGP in the lumen of infection threads and in the intercellular matrix.

Isolation of lipoxygenase cDNA clones from pea nodule mRNA.

The pattern of lipoxygenase (LOX) gene expression was investigated in pea nodule tissues using the technique of in situ hybridization. Five lipoxygenase cDNAs were cloned from nodule mRNA by the RT-PCR and 3' RACE procedures. These clones (loxN1 to loxN5) show a high degree of sequence homology, except in the 3'-untranslated region. Gene-specific riboprobes were therefore generated from subclones carrying the 3'-untranslated regions in order to investigate tissue-specific gene expression. Northern blotting analysis revealed that loxN1 corresponded to a transcript that was expressed exclusively in roots and nodules but not in the aerial parts of the plant. However, none of the LOX genes appeared to be up-regulated in nodule tissue relative to uninfected roots. Starting with the incomplete cDNA clone for loxN1, the full coding sequence termed lox1:P.s:1 was obtained by further rounds of RT-PCR and 5' RACE procedures. In situ hybridization with nodule tissues revealed several different patterns of expression for the various LOX probes. However, none of the corresponding transcripts was expressed exclusively in the invasion zone, as might have been expected if one LOX gene product had been uniquely associated with the invasion process. In conclusion, this study provides no evidence for a direct role for any LOX gene product in plant-microbe interaction or host defence, but the fact that all the transcripts were expressed at the nodule apex suggests that LOX could be involved in the development of this organ.

Comparison of Mg2+-dependent ATP hydrolase activities of pea nodule symbiosomes and of pea root plasmalemma, obtained by an aqueous polymer two-phase system.

The characteristics of the Mg2+-dependent ATPase activity from the peribacteroid membrane of pea symbiosomes was compared with that from pea root plasma membranes. Enzyme inhibitors, optimum reaction pH, substrate specificity and antibody recognition were the main parameters examined. Both the symbiosomes and the root plasma membrane were purified with an aqueous polymer two-phase system (APS). The final concentration of the APS for the purification of symbiosomes were: 6.3% w/w dextran T500, 6.3% w/w poly(ethylene glycol) 3350, 5 mM KH2PO4-K2HPO4, 5 mM KCl, 0.33 M sucrose, (pH 7.85); for the root plasma membrane was: 6.2% (w/w) dextran T500, 6.2% poly(ethylene glycol) 3350, 330 mM sucrose, 5 mM K2HPO4 and 4 mM KCl (pH 7.8). The lack of contamination of pea symbiosomes with endoplasmic reticulum, mitochondria, broken bacteroids and/or tonoplast vesicles was established. Similarly, the aqueous two-phase system used here provided a fairly enriched root plasma membrane with low cross-contamination from other sources. Both symbiosomal and root plasma membrane ATPase activities were highly specific to ATP. The symbiosome ATPase apparently corresponds to an E1E2-ATPase mechanism, similar to that found at the plasma membrane. The similarity between these two ATPases was further supported by immuno-analysis. Mg2+-ATPase of pea symbiosome and root plasma membranes were very similar, by all parameters tested.

Immunolocalization of PsNLEC-1, a lectin-like glycoprotein expressed in developing pea nodules.

The pea (Pisum sativum) nodule lectin gene PsNlec1 is a member of the legume lectin gene family that is strongly expressed in infected pea nodule tissue. A full-length cDNA sequence of PsNlec1 was expressed in Escherichia coli and a specific antiserum was generated from the purified protein. Immunoblotting of material from isolated symbiosomes revealed that the glycoprotein was present in two antigenic isoforms, PsNLEC-1A and PsNLEC-1B. The N-terminal sequence of isoform A showed homology to an eight-amino acid propeptide sequence previously identified from the cDNA sequence of isoform B. In nodule homogenates the antiserum recognized an additional fast-migrating band, PsNLEC-1C. Fractionation studies indicated that PsNLEC-1C was associated with a 100,000 g nodule membrane fraction, suggesting an association with cytoplasmic membrane or vesicles. Immunogold localization in pea nodule tissue sections demonstrated that the PsNLEC-1 antigen was present in the symbiosome compartment and also in the vacuole but revealed differences in distribution between infected host cells in different parts of the nodule. These data suggest that PsNLEC-1 is subject to posttranslational modification and that the various antigenic isoforms can be used to monitor membrane and vesicle targeting during symbiosome development.

Expression of cysteine protease genes in pea nodule development and senescence.

Coding sequences for two cysteine proteases were amplified from cDNA derived from pea nodule mRNA using primers based on conserved regions of plant cysteine proteases. One of the amplified cDNA sequences corresponded to a previously described cysteine protease gene, Cyp15a, expressed in pea shoots in response to dehydration (J.T. Jones and J.E. Mullet, Plant Mol. Biol. 28:1055-1065, 1995). Inside the pea root nodule, in situ hybridization revealed that this gene is expressed strongly in the apical region and more weakly in the uninfected cortex and in the central infected tissue where nitrogen fixation takes place. The complete sequence of the cDNA corresponding to the other gene, PsCyp1, was obtained. Expression of this gene, which was studied both on RNA blots and in situ, showed good correlation with the onset of nodule senescence. In situ hybridization studies revealed that PsCyp1 was expressed in senescent infected tissue at the base of the nodule. This signal was just detectable in normal symbiotically wild-type nodules but was much stronger in the early senescing nodules formed by a symbiotically defective mutant of Rhizobium leguminosarum.

Detection of glycolipids as biotinylated derivatives using enhanced chemiluminescence.

A new method for the detection of glycolipids as biotinylated derivatives is presented. This method is based on the detection of lipids by enhanced chemiluminescence (ECL) following conjugation with streptavidin-horseradish peroxidase (SHRP). Partial biotinylation of glycolipids is achieved after mild oxidation of the glycan moiety with Na-meta-periodate to increase the availability of biotin-reactive sites. There are several significant advantages of the glycolipid ECL detection: it avoids the need for radio-labeling; it provides the possibility of antibody probing; it allows reprobing of SHRP conjugate to adjust background and luminol light emission levels; it permits easy and accurate quantification of glycolipids at low concentrations; and it involves nondestructive staining, thereby enabling further molecular analysis.

Identification of a new pea gene, PsNlec1, encoding a lectin-like glycoprotein isolated from the symbiosomes of root nodules.

A 27-kD glycoprotein antigen recognized by monoclonal antibody MAC266 was purified from isolated symbiosomes derived from pea (Pisum sativum) root nodules containing Rhizobium. The N-terminal amino acid sequence was obtained, and the corresponding cDNA clone was isolated by a polymerase chain reaction-based strategy. The clone contained a single open reading frame, and the gene was termed PsNlec1. Phylogenetic analysis of 31 legume sequences showed that the PsNlec1 protein is related to the legume lectin family but belongs to a subgroup that is very different from pea seed lectin. Expression of the PsNlec1 transcript was much stronger in nodules than in other parts of the plant. It was found in both infected and uninfected cells in the central tissue of the nodule and in the stele of the root near the attachment point of the nodule. When uninfected pea seedlings were grown on medium containing nitrate, weak transcription of PsNlec1 was observed in the root system. The identification of PsNlec1 inside the symbiosome is consistent with the observation that legume lectins are generally vacuolar proteins that may serve as transient storage components.

Isolation of monoclonal antibodies reacting with the core component of lipopolysaccharide from Rhizobium leguminosarum strain 3841 and mutant derivatives.

Monoclonal antibodies reacting with the core oligosaccharide or lipid A component of Rhizobium lipopolysaccharide (LPS) could be useful for the elucidation of the structure and biosynthesis of this group of macromolecules. Mutant derivatives of Rhizobium leguminosarum 3841 with LPS structures lacking the major O-antigen moiety were used as immunogens, and eight antibodies were selected for further study. All the antibodies reacted with the fast-migrating species known as LPS-2 following gel electrophoresis of Rhizobium cell extracts. For four of these antibodies, reactivity with affinity-purified LPS was lost after mild acid hydrolysis, indicating that they probably recognized the core oligosaccharide component. The four other antibodies still reacted with acid-treated LPS and may recognize the lipid A moiety, which is stable to mild acid hydrolysis. The pattern of antibody staining after gel electrophoresis revealed differences in LPS-2 epitope structure between each of the mutants and the wild type. Furthermore, for each of the mutants the antibodies crossreacted with a minor band that migrated more slowly than LPS-2; we have termed this more slowly migrating form LPS-3. The majority of the antibodies also reacted with LPS from strain CE109, a derivative of Rhizobium etli CE3, confirming that the LPS core antigens can be relatively conserved between strains of different Rhizobium species. One of the antibodies isolated in this study (JIM 32) was unusual because it appeared to react with all forms of LPS from strain 3841 (namely, LPS-1, LPS-2, and LPS-3). Furthermore, JIM 32 reacted positively with the LPS from many strains of Rhizobium tested (excluding the Rhizobium meliloti subgroup). JIM 32 did not react with representative strains from Bradyrhizobium, Azorhizobium or other related bacterial species.

Effects of Boron on Rhizobium-Legume Cell-Surface Interactions and Nodule Development.

Boron (B) is an essential micronutrient for the development of nitrogen-fixing root nodules in pea (Pisum sativum). By using monoclonal antibodies that recognize specific glycoconjugate components implicated in legume root-nodule development, we investigated the effects of low B on the formation of infection threads and the colonization of pea nodules by Rhizobium leguminosarum bv viciae. In B-deficient nodules the proportion of infected host cells was much lower than in nodules from plants supplied with normal quantities of B. Moreover, the host cells often developed enlarged and abnormally shaped infection threads that frequently burst, releasing bacteria into damaged host cells. There was also an over-production of plant matrix material in which the rhizobial cells were embedded during their progression through the infection thread. Furthermore, in a series of in vitro binding studies, we demonstrated that the presence of B can change the affinity with which the bacterial cell surface interacts with the peribacteroid membrane glycocalyx relative to its interaction with intercellular plant matrix glycoprotein. From these observations we suggest that B plays an important role in mediating cell-surface interactions that lead to endocytosis of rhizobia by host cells and hence to the correct establishment of the symbiosis between pea and Rhizobium.

Ionic Stress and Osmotic Pressure Induce Different Alterations in the Lipopolysaccharide of a Rhizobium meliloti Strain.

A halotolerant strain of Rhizobium meliloti was isolated from nodules of a Melilotus plant growing in a salt marsh in Donana National Park (southwest Spain). This strain, EFB1, is able to grow at NaCl concentrations of up to 500 mM, and no effect on growth is produced by 300 mM NaCl. EFB1 showed alterations on its lipopolysaccharide (LPS) structure that can be related to salt stress: (i) silver-stained electrophoretic profiles showed a different mobility that was dependent on ionic stress but not on osmotic pressure, and (ii) a monoclonal antibody, JIM 40, recognized changes in LPS that were dependent on osmotic stress. Both modifications on LPS may form part of the adaptive mechanism of this bacterium for saline environments.

Host-plant invasion by Rhizobium: the role of cell-surface components.

Rhizobia are soil bacteria that can become endosymbionts, reducing atmospheric nitrogen within nodules formed on the roots of legume plants. During tissue and cell invasion, bacterial cell-surface components adapt the bacterium to survive as an endophyte without eliciting host-defence responses. The structures of many of these components have been established recently, allowing their possible roles in invasion to be defined more clearly.