Legumes display common and host-specific responses to the rhizobial cellulase CelC2 during primary symbiotic infection.

Primary infection of legumes by rhizobia involves the controlled localized enzymatic breakdown of cell walls at root hair tips. Previous studies determined the role of rhizobial CelC2 cellulase in different steps of the symbiotic interaction Rhizobium leguminosarum-Trifolium repens. Recent findings also showed that CelC2 influences early signalling events in the Ensifer meliloti-Medicago truncatula interaction. Here, we have monitored the root hair phenotypes of two legume plants, T. repens and M. sativa, upon inoculation with strains of their cognate and non-cognate rhizobial species, R. leguminosarum bv trifolii and E. meliloti, (over)expressing the CelC2 coding gene, celC. Regardless of the host, CelC2 specifically elicited 'hole-on-the-tip' events (Hot phenotype) in the root hair apex, consistent with the role of this endoglucanase in eroding the noncrystalline cellulose found in polarly growing cell walls. Overproduction of CelC2 also increased root hair tip redirections (RaT phenotype) events in both cognate and non-cognate hosts. Interestingly, heterologous celC expression also induced non-canonical alterations in ROS (Reactive Oxygen Species) homeostasis at root hair tips of Trifolium and Medicago. These results suggest the concurrence of shared unspecific and host-related plant responses to CelC2 during early steps of symbiotic rhizobial infection. Our data thus identify CelC2 cellulase as an important determinant of events underlying early infection of the legume host by rhizobia.

Rhizobium cellulase CelC2 is essential for primary symbiotic infection of legume host roots.

The rhizobia-legume, root-nodule symbiosis provides the most efficient source of biologically fixed ammonia fertilizer for agricultural crops. Its development involves pathways of specificity, infectivity, and effectivity resulting from expressed traits of the bacterium and host plant. A key event of the infection process required for development of this root-nodule symbiosis is a highly localized, complete erosion of the plant cell wall through which the bacterial symbiont penetrates to establish a nitrogen-fixing, intracellular endosymbiotic state within the host. This process of wall degradation must be delicately balanced to avoid lysis and destruction of the host cell. Here, we describe the purification, biochemical characterization, molecular genetic analysis, biological activity, and symbiotic function of a cell-bound bacterial cellulase (CelC2) enzyme from Rhizobium leguminosarum bv. trifolii, the clover-nodulating endosymbiont. The purified enzyme can erode the noncrystalline tip of the white clover host root hair wall, making a localized hole of sufficient size to allow wild-type microsymbiont penetration. This CelC2 enzyme is not active on root hairs of the nonhost legume alfalfa. Microscopy analysis of the symbiotic phenotypes of the ANU843 wild type and CelC2 knockout mutant derivative revealed that this enzyme fulfils an essential role in the primary infection process required for development of the canonical nitrogen-fixing R. leguminosarum bv. trifolii-white clover symbiosis.

Erosion of root epidermal cell walls by Rhizobium polysaccharide-degrading enzymes as related to primary host infection in the Rhizobium-legume symbiosis.

A central event of the infection process in the Rhizobium-legume symbiosis is the modification of the host cell wall barrier to form a portal of entry large enough for bacterial penetration. Transmission electron microscopy (TEM) indicates that rhizobia enter the legume root hair through a completely eroded hole that is slightly larger than the bacterial cell and is presumably created by localized enzymatic hydrolysis of the host cell wall. In this study, we have used microscopy and enzymology to further clarify how rhizobia modify root epidermal cell walls to shed new light on the mechanism of primary host infection in the Rhizobium-legume symbiosis. Quantitative scanning electron microscopy indicated that the incidence of highly localized, partially eroded pits on legume root epidermal walls that follow the contour of the rhizobial cell was higher in host than in nonhost legume combinations, was inhibited by high nitrate supply, and was not induced by immobilized wild-type chitolipooligosaccharide Nod factors reversibly adsorbed to latex beads. TEM examination of these partially eroded, epidermal pits indicated that the amorphous, noncrystalline portions of the wall were disrupted, whereas the crystalline portions remained ultrastructurally intact. Further studies using phase-contrast and polarized light microscopy indicated that (i) the structural integrity of clover root hair walls is dependent on wall polymers that are valid substrates for cell-bound polysaccharide-degrading enzymes from rhizobia, (ii) the major site where these rhizobial enzymes can completely erode the root hair wall is highly localized at the isotropic, noncrystalline apex of the root hair tip, and (iii) the degradability of clover root hair walls by rhizobial polysaccharide-degrading enzymes is enhanced by modifications induced during growth in the presence of chitolipooligosaccharide Nod factors from wild-type clover rhizobia. The results suggest a complementary role of rhizobial cell-bound glycanases and chitolipooligosaccharides in creating the localized portals of entry for successful primary host infection.

Sinorhizobium meliloti putA gene regulation: a new model within the family Rhizobiaceae.

Proline dehydrogenase (PutA) is a bifunctional enzyme that catalyzes the oxidation of proline to glutamate. In Sinorhizobium meliloti, as in other microorganisms, the putA gene is transcriptionally activated in response to proline. In Rhodobacter capsulatus, Agrobacterium, and most probably in Bradyrhizobium, this activation is dependent on an Lrp-like protein encoded by the putR gene, located immediately upstream of putA. Interestingly, sequence and genetic analysis of the region upstream of the S. meliloti putA gene did not reveal such a putR locus or any other encoded transcriptional activator of putA. Furthermore, results obtained with an S. meliloti putA null mutation indicate the absence of any proline-responsive transcriptional activator and that PutA serves as an autogenous repressor. Therefore, the model of S. meliloti putA regulation completely diverges from that of its Rhizobiaceae relatives and resembles more that of enteric bacteria. However, some differences have been found with the latter model: (i) S. meliloti putA gene is not catabolite repressed, and (ii) the gene encoding for the major proline permease (putP) does not form part of an operon with the putA gene.

Analysis of Medicago truncatula nodule expressed sequence tags.

Systematic sequencing of expressed sequence tags (ESTs) can give a global picture of the assembly of genes involved in the development and function of organs. Indeterminate nodules representing different stages of the developmental program are especially suited to the study of organogenesis. With the vector lambdaHybriZAP, a cDNA library was constructed from emerging nodules of Medicago truncatula induced by Sinorhizobium meliloti. The 5' ends of 389 cDNA clones were sequenced, then these ESTs were analyzed both by sequence homology search and by studying their expression in roots and nodules. Two hundred fifty-six ESTs exhibited significant similarities to characterized data base entries and 40 of them represented 26 nodulin genes, while 133 had no similarity to sequences with known function. Only 60 out of the 389 cDNA clones corresponded to previously submitted M. truncatula EST sequences. For 117 cDNAs, reverse Northern (RNA) hybridization with root and nodule RNA probes revealed enhanced expression in the nodule, 48 clones are likely to code for novel nodulins, 33 cDNAs are clones of already known nodulin genes, and 36 clones exhibit similarity to other characterized genes. Thus, systematic analysis of the EST sequences and their expression patterns is a powerful way to identify nodule-specific and nodulation-related genes.

Expression profiles of 22 novel molecular markers for organogenetic pathways acting in alfalfa nodule development.

During symbiotic nodule development, a variety of molecular signals of rhizobia and plant origin are likely to be involved in the control of the expression of specific genes in the legume Medicago sativa (alfalfa). Twenty-two new, nodule-associated Expressed Sequence Tags (ESTs, MsNod clones) as well as 16 clones for previously reported alfalfa nodulins were identified by cold-plaque screening. Protein homologs were found for 10 of the 22 MsNod-encoded polypeptides, revealing putative novel functions associated with this symbiosis. Expression of these MsNod genes was investigated in spontaneous nodules (generated in the absence of bacteria), in nodules induced by a Sinorhizobium meliloti wild-type strain and Eps- and Bac- mutant derivatives, as well as in roots inoculated with a Nod- mutant strain. This analysis enabled us to correlate plant gene expression with the different stages of nodule ontogeny and invasion. The effect of phytohormones on MsNod gene expression was analyzed in cytokinin- and auxin-treated alfalfa roots. Cytokinin induced the accumulation of seven MsNod transcripts, four of them were also regulated by the synthetic auxin 2,4-D (2,4-dichlorophenoxyacetic acid). Comparison of MsNod expression profiles in wild-type and transgenic M. truncatula roots overexpressing the early nodulin Enod40 suggested that one clone, the M. sativa L3 ribosomal protein homolog (MsNod377), is a putative component of an Enod40-dependent pathway acting during nodule development. These novel molecular markers may help in the investigation of gene networks and regulatory circuits controlling nodule organogenesis.

The Rhizobium meliloti putA gene: its role in the establishment of the symbiotic interaction with alfalfa.

Little is known about the energy sources used by rhizobia during colonization, invasion and root nodule formation on leguminous plants. We have recently reported that an impaired proline metabolism in rhizobium meliloti leads to a reduced nodulation efficiency and competitiveness on alfalfa roots. In the present study we have characterized the R. meliloti proline dehydrogenase gene (putA) and addressed the question of its role in symbiosis. This rhizobial gene encodes a 1224-amino-acid-long polypeptide which is homologous to enteric bacteria, Rhodobacter capsulatus and Bradyrhizobium japonicum PutA proteins. Like the situation in these bacteria, sequence analysis identified the proline dehydrogenase (PDH) and pyrroline-5-carboxylate dehydrogenase (P5CDH) domains in the R. meliloti putA-encoded protein. Beta-galactosidase assays performed with free-living cells carrying a putA-lacZ transcriptional fusion revealed that R. meliloti putA gene expression is induced by proline, autoregulated by its encoded product, and independent of the general nitrogen regulatory system (Ntr). In addition, analysis of putA expression during the different steps of the symbiotic interaction with alfalfa showed that expression of this gene is turned on by the root exudates (RE), during root invasion and nodule formation, but not in differentiated nitrogen-fixing bacteroids. Furthermore, we show that the PutA- phenotype leads to a significant reduction of alfalfa root colonization by R. meliloti.

Characterization of a Rhizobium meliloti proline dehydrogenase mutant altered in nodulation efficiency and competitiveness on alfalfa roots.

Rhizobium meliloti strain GRM8 is able to transform ornithine into proline by means of an ornithine cyclodeaminase and, therefore, has the ability to use either of these amino acids as its sole carbon and nitrogen source. By Tn5 insertion mutagenesis we obtained a GRM8 mutant derivative strain (LM1) unable to catabolize either ornithine or proline. DNA hybridization studies showed that the LM1 mutant carries a single Tn5 insertion within a chromosomally located gene that, as deduced from a partial nucleotide sequence, encodes a proline dehydrogenase (ProDH). Enzymatic assays confirmed the lack of ProDH activity in cell extracts of strain LM1 and revealed that production of this enzyme is inducible in the parental strain by proline and ornithine. Ultrastructural nodule microscopy analysis, acetylene reduction assays, and dry-weight determinations of nodulated alfalfa plants showed no obvious defect in the nitrogen fixation process of the ProDH- mutant LM1. However, nodulation tests and competition assays demonstrated that in R. meliloti ProDH is required for nodulation efficiency and competitiveness on alfalfa roots.

Cell-associated pectinolytic and cellulolytic enzymes in Rhizobium leguminosarum biovar trifolii.

The involvement of Rhizobium enzymes that degrade plant cell wall polymers has long been an unresolved question about the infection process in root nodule symbiosis. Here we report the production of enzymes from Rhizobium leguminosarum bv. trifolii that degrade carboxymethyl cellulose and polypectate model substrates with sensitive methods that reliably detect the enzyme activities: a double-layer plate assay, quantitation of reducing sugars with a bicinchoninate reagent, and activity gel electrophoresis-isoelectric focusing. Both enzyme activities were (i) produced commonly by diverse wild-type strains, (ii) cell bound with at least some of the activity associated with the cell envelope, and (iii) not changed appreciably by growth in the presence of the model substrates or a flavone that activates expression of nodulation (nod) genes on the resident symbiotic plasmid (pSym). Equivalent levels of carboxymethyl cellulase activity were found in wild-type strain ANU843 and its pSym-cured derivative, ANU845, consistent with previous results of Morales et al. (V. Morales, E. Martínez-Molina, and D. Hubbell, Plant Soil 80:407-415, 1984). However, polygalacturonase activity was lower in ANU845 and was not restored to wild-type levels in the recombinant derivative of pSym- ANU845 containing the common and host-specific nod genes within a 14-kb HindIII DNA fragment of pSym from ANU843 cloned on plasmid pRt032. Activity gel electrophoresis resolved three carboxymethyl cellulase isozymes of approximately 102, 56, and 33 kDa in cell extracts from ANU843. Isoelectric focusing activity gels revealed one ANU843 polygalacturonase isozyme with a pI of approximately 7.2. These studies show that R. leguminosarum bv. trifolii produces multiple enzymes that cleave glycosidic bonds in plant cell walls and that are cell bound.