Translational and structural requirements of the early nodulin gene enod40, a short-open reading frame-containing RNA, for elicitation of a cell-specific growth response in the alfalfa root cortex.

A diversity of mRNAs containing only short open reading frames (sORF-RNAs; encoding less than 30 amino acids) have been shown to be induced in growth and differentiation processes. The early nodulin gene enod40, coding for a 0.7-kb sORF-RNA, is expressed in the nodule primordium developing in the root cortex of leguminous plants after infection by symbiotic bacteria. Ballistic microtargeting of this gene into Medicago roots induced division of cortical cells. Translation of two sORFs (I and II, 13 and 27 amino acids, respectively) present in the conserved 5' and 3' regions of enod40 was required for this biological activity. These sORFs may be translated in roots via a reinitiation mechanism. In vitro translation products starting from the ATG of sORF I were detectable by mutating enod40 to yield peptides larger than 38 amino acids. Deletion of a Medicago truncatula enod40 region between the sORFs, spanning a predicted RNA structure, did not affect their translation but resulted in significantly decreased biological activity. Our data reveal a complex regulation of enod40 action, pointing to a role of sORF-encoded peptides and structured RNA signals in developmental processes involving sORF-RNAs.

Cell cycle function of a Medicago sativa A2-type cyclin interacting with a PSTAIRE-type cyclin-dependent kinase and a retinoblastoma protein.

In plants multiple A-type cyclins with distinct expression patterns have been isolated and classified into three subgroups (A1-A3), while in animal somatic cells a single type of cyclin A is required for cell-cycle regulation from the S to M phases. We studied the function of an A2-type cyclin from Medicago sativa (Medsa;cycA2) which, in contrast to animal and most plant A-type cyclins, was expressed in all phases of the cell cycle. Using synchronized alfalfa cell cultures and anti-Medsa;CycA2 polyclonal antibodies, we showed that while the mRNA level increased steadily from the late G1 to the G2-M phase, the protein level after a rapid increase in S-phase reached a plateau during the G2 phase. In the yeast two-hybrid system, the Medsa;CycA2 protein interacted with the PSTAIRE-motif-containing cyclin-dependent kinase Cdc2MsA and with the maize retinoblastoma protein. Unexpectedly, the CycA2-associated kinase activity was biphasic: a first activity peak occurred in the S phase while the major one occurred during the G2/M transition, with no apparent dependence upon the actual levels of the Medsa;CycA2 and Cdc2MsA proteins. Immunohistological localization of the cyclin A2 protein by immunofluorescence and immunogold labelling revealed the presence of Medsa;CycA2 in the nucleus of the interphase and prophase cells, while it was undetectable thereafter during mitosis. Together these data suggest that Medsa;CycA2 plays a role both in the S phase and at the G2/M transition.

Nod factors of Rhizobium leguminosarum bv. viciae and their fucosylated derivatives stimulate a nod factor cleaving activity in pea roots and are hydrolyzed in vitro by plant chitinases at different rates.

Nod factors (NFs) are rhizobial lipo-chitooligosaccharide signals that trigger root nodule development in legumes. Modifications of NF structures influence their biological activity and affect their degradation by plant chitinases. Nodulation of certain pea cultivars by Rhizobium leguminosarum bv. viciae requires modification of NFs at the reducing end by either an O-acetyl or a fucosyl group. Fucosylated NFs were produced by an in vitro reaction with NodZ fucosyltransferase and purified. Their biological activity on pea was tested by measuring their capacity to stimulate the activity of a hydrolase that cleaves NFs. Nonmodified and fucosylated NFs displayed this activity at nano- to picomolar concentrations, while a sulfated NF from Sinorhizobium meliloti was inactive. In an additional series of experiments, the stability of non-modified and fucosylated NFs in the presence of purified tobacco chitinases was compared. The presence of the fucosyl group affected the degradation rates and the accessibility of specific cleavage sites on the chitooligosaccharide backbone. These results suggest that the fucosyl group in NFs also weakens the interaction of NFs with certain chitinases or chitinase-related proteins in pea roots.

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.

Elevation of the cytosolic free [Ca2+] is indispensable for the transduction of the Nod factor signal in alfalfa.

In root hairs of alfalfa (Medicago sativa), the requirement of Ca(2+) for Nod factor signaling has been investigated by means of ion-selective microelectrodes. Measured 50 to 100 microm behind the growing tip, 0.1 microM NodRm-IV(C16:2,S) increased the cytosolic free [Ca2+] by about 0.2 pCa, while the same concentration of chitotetraose, the nonactive glucosamine backbone, had no effect. We demonstrate that NodRm-IV(C16:2,S) still depolarized the plasma membrane at external Ca(2+) concentrations below cytosolic values if the free EGTA concentration remained low (

Identification of novel putative regulatory genes induced during alfalfa nodule development with a cold-plaque screening procedure.

Until now very few plant genes with possible regulatory functions during nodule development have been isolated. We have used a modified cold-plaque screening method to identify new transcripts expressed at low levels that are induced during nodulation. Several clones were isolated and characterized by their mRNA expression patterns during nodule development and in spontaneous nodules. Sequence homology with known genes of other organisms indicated that transcripts corresponded to (i) "basic" genes probably required during the growth of the nodule organ (e.g., structural proteins), (ii) genes related to the metabolic adaptations taking place during nodule morphogenesis and function (e.g., carbonic anhydrase), and (iii) genes containing regulatory motifs and/or homologies (three clones out of the 20 identified). The latter genes encode a zinc-finger-containing protein, a putative protein kinase, and a Wilm's tumor (WT) suppressor homologue, respectively. Expression of the kinase and WT suppressor homologues was induced early in nodulation, although the latter was activated transiently. Accumulation of the Zn-finger gene transcripts was detected at a later stage of development and seems to be regulated in a complex manner. Hence, using a cold-plaque screening procedure, we could identify genes that may play regulatory roles in the signal transduction pathways activated during nodule development.

Cloning of a WD-repeat-containing gene from alfalfa (Medicago sativa): a role in hormone-mediated cell division?

Rhizobium meliloti can interact symbiotically with Medicago plants thereby inducing the formation of root nodules. Screening of a young nodule cDNA library led to the isolation of a cDNA from Medicago sativa, Msgbl, that comprises a new member of the RACK1 (Receptor of Activated C Kinase) subfamily of WD-repeat proteins. This subfamily shows homology to the beta-subunit of heterotrimeric G proteins. Besides RACK1, this subfamily contains several plant genes including the well characterized auxin-inducible ArcA of tobacco. The Msgbl gene is strongly expressed in young embryos and in leaves, and is induced upon cytokinin treatment of roots. Whereas northern analysis failed to reveal differences in expression between total RNA from roots and nodules, in situ hybridization demonstrated that the transcript was most abundant in dividing cells of nodule primordia and in the nodule meristem. Msgbl may be related to the signal transduction acting in response to hormone-mediated cell division.

Defense reaction in Medicago sativa: a gene encoding a class 10 PR protein is expressed in vascular bundles.

Infiltration of Medicago sativa leaves with a suspension of Pseudomonas syringae pv. pisi elicits the accumulation of several mRNA classes. A clone, designated as MsPR10-1, encoding a polypeptide exhibiting strong similarity to the class 10 PR protein was isolated and characterized from a cDNA library prepared from leaf mRNA. The corresponding gene was shown to be developmentally regulated: Except in roots, its expression was not detectable in other analyzed organs of healthy plants (hypocotyls, cotyledons, stems, leaves, and flower buds). MsPR10-1 transcript accumulation was especially high in leaf blades during an incompatible interaction: It was already detectable 3 h after infection, reached its maximum level 24 h postinfection, and remained at a high level over a period of at least 72 h. In addition, the expression of this gene was induced by salicylic acid treatment of the leaves. Southern hybridizations showed that this gene belongs to a multigene family. Using a 5' extension technique for cDNA, we demonstrated that during the incompatible interaction with P. syringae pv. pisi several genes or allelic variants of this class were expressed. Measurements of transcript accumulation in both the infiltrated and noninfiltrated zones by Northern and in situ hybridization allowed to demonstrate the "systemic" expression pattern of the MsPR10-1. In situ hybridizations indicated that MsPR10-1 was expressed in the vascular bundles adjacent to and distant from the infection site.

The expression pattern of alfalfa flavanone 3-hydroxylase promoter-gus fusion in Nicotiana benthamiana correlates with the presence of flavonoids detected in situ.

Flavanone 3-hydroxylase is an enzyme acting in the central part of the flavonoid biosynthesis pathway. It is generally encoded by a single gene and seems to have a key position for the regulation in this pathway. These two features make a single f3h promoter-gus fusion a suitable tool to study both the f3h expression and the regulation of this pathway. We present here the spatial and temporal analysis of the expression of an alfalfa flavanone 3-hydroxylase (f3h) promoter-gus fusion introduced into Nicotiana benthamiana. The Medicago sativa (alfalfa) f3h promoter directed gus expression in flowers, stems, leaves and roots. In flowers, GUS activity was observed in pollen grains, in ovules, in ovary placenta and in the epidermis, medullary parenchyma, trichomes and second cortical cellular layer surrounding the vascular bundles of the peduncle. In stems, GUS activity was detected at the same places as in the peduncle except for the medullary parenchyma. In roots, we found GUS staining in root hairs, epidermis and in the vascular bundles of the elongated zone. Finally, in leaves, the f3h promoter expressed essentially in the stalk cells of the multicellular trichomes. The expression pattern of the f3h-gus fusion was correlated to the presence of flavonoids in situ. These data indicate that this construct can be very useful to study factors controlling the production of flavonoids.

enod40, a gene expressed during nodule organogenesis, codes for a non-translatable RNA involved in plant growth.

Rhizobium meliloti can interact symbiotically with Medicago plants, thereby inducing root nodules. However, certain Medicago plants can form nodules spontaneously, in the absence of rhizobia. A differential screening was performed using spontaneous nodule versus root cDNAs from Medicago sativa ssp. varia. Transcripts of a differentially expressed clone, Msenod40, were detected in all differentiating cells of nodule primordia and spontaneous nodules, but were absent in fully differentiated cells. Msenod40 showed homology to a soybean early nodulin gene, Gmenod40, although no significant open reading frame (ORF) or coding capacity was found in the Medicago sequence. Furthermore, in the sequences of cDNAs and a genomic clone (Mtenod40) isolated from Medicago truncatula, a species containing a unique copy of this gene, no ORFs were found either. In vitro translation of purified Mtenod40 transcripts did not reveal any protein product. Evaluation of the RNA secondary structure indicated that both msenod40 and Gmenod40 transcripts showed a high degree of stability, a property shared with known non-coding RNAs. The Mtenod40 RNA was localized in the cytoplasm of cells in the nodule primordium. Infection with Agrobacterium tumefaciens strains bearing antisense constructs of Mtenod40 arrested callus growth of Medicago explants, while overexpressing Mtenod40 embryos developed into teratomas. These data suggest that the enod40 genes might have a role in plant development, acting as 'riboregulators', a novel class of untranslated RNAs associated with growth control and differentiation.

Homology of the ligand-binding regions of Rhizobium symbiotic regulatory protein NodD and vertebrate nuclear receptors.

The signal specificity and structure of sensor-activator proteins from different species (NodD of Rhizobium bacteria and vertebrate nuclear receptors) were compared. Several compounds (including flavonoids, coumestrol and estradiol) that bind to mammalian receptors also interact with NodD proteins. NodD-dependent synergism of the signal compounds luteolin and catechin was observed suggesting that these compounds bind directly to NodD. Two regions comprising 63 and 37 amino acids in NodD showed 45% and 36% homology, respectively, with the estrogen receptor. These regions, designated as modules M1 and M2, coincide with conserved parts of the ligand-binding domains of the nuclear receptors. A part of NodD overlapping with the M1 module was predicted to be membrane associated and was 46% homologous to a membrane-spanning sensory segment of the Agrobacterium VirA protein. We suggest that the homologous polypeptide modules detected in NodD and the nuclear receptors originate from a common ancestor protein and may be directly involved in ligand binding.

Rhizobium meliloti insertion element ISRm2 and its use for identification of the fixX gene.

Two of the three plasmids of the wild-type Rhizobium meliloti 41 (pRme41a and pRme41c) carry a copy of ISRm2, a 2.7-kilobase-long transposable element. ISRm2 is terminated by 22-base-pair (bp) inverted repeat sequences, exhibiting some homology to the inverted repeats of elements generating 9-bp target sequence duplication. Transposition of ISRm2 results in a duplication of 8 bp in length, rather rare among transposable elements. DNA sequences homologous to an internal fragment of ISRm2 were found in several Rhizobium species. Transposition of ISRm2 into fixation and nodulation genes located on the symbiotic plasmid pRme41b was detected at a high frequency. Exact locations of two copies of ISRm2 which transposed into the nod-nif region on the megaplasmid were determined. In one case, integration into the protein-coding region of the hsnD gene that determines a host specificity function of nodulation occurred. In the other mutant, ISRm2 was localized upstream of nifA, where a short open reading frame coding for a new fix gene (fixX) was identified. The product of fixX is a ferredoxin carrying a characteristic cluster of cysteine residues. On the basis of the observation that the arrangement of the ISRm2 copies is identical in the free-living wild-type cells and in nitrogen-fixing nodules, we concluded that the involvement of ISRm2 transposition in the development of nitrogen-fixing symbiosis is unlikely.

Mapping of the protein-coding regions of Rhizobium meliloti common nodulation genes.

An 8.5-kb EcoRI fragment containing the common nod region of the megaplasmid pRme41b of Rhizobium meliloti was recloned in plasmids of Escherichia coli, and a detailed restriction map was established. The region can express at least eight proteins in E. coli minicells and in an in vitro transcription/translation system, prepared from E. coli. Protein coding regions were determined by subcloning of restriction fragments, deletion mutations and by transposon mutagenesis. The coding regions for at least three polypeptide chains (mol. wts. 23 000, 28 500 and 44 000) were mapped on a 3.3-kb nod gene cluster. The 44 000 mol. wt. protein is expressed from a nod region, which is highly conserved in two Rhizobium species. The protein map of the 8.5-kb fragment was correlated to a map of insertion mutations with Nod and Fix phenotypes. The data suggest that the proteins encoded by the nod gene cluster may be involved in early steps of the nodulation process. Nod Fix symbiotic mutations were localized in the coding region for a 33 000 mol. wt. protein, suggesting that this polypeptide might be a fix gene product.

Nucleotide sequence of the R.meliloti nitrogenase reductase (nifH) gene.

The nucleotide sequence of the structural gene (nifH) of nitrogenase reductase (Fe protein) from R.meliloti 41 with its flanking ends is reported. The amino acid sequence of nitrogenase reductase was deduced from the DNA sequence. The predicted R.meliloti nitrogenase reductase protein consists of 297 amino acid residues, has a molecular weight of 32,740 daltons and contains 5 cysteine residues. The codon usage in the nifH gene is presented. In the 5' flanking region, sequences resembling to consensus sequences of bacterial control regions were found. Comparison of the R.meliloti nifH nucleotide and amino acid sequences with those from different nitrogen-fixing organisms showed that the amino acid sequences are more conserved than the nucleotide sequences. This structural conservation of nitrogenase reductase may be related to its function and may explain the conservation of the nifH gene during evolution.

Location of nodulation and nitrogen fixation genes on a high molecular weight plasmid of R. meliloti.

R. meliloti strain 41 (Rm41) was shown to harbour two indigenous plasmids with molecular weights of 140 Mdal (pRme41a) and more than 300 Mdal (pRme41b), respectively. Using a heat-treatment procedure, derivatives of Rm41 defective in nodulation (Nod-) or nitrogen fixation (Fix-) have been readily obtained. In some Nod- mutants the deletion of a segment of plasmid pRme41b was found. Based on the demonstrated homology between the nitrogen fixation (nif) genes of Klebsiella pneumoniae and of R. meliloti the Rhizobium nif region has been cloned into the cosmid vector pHC79, then recloned into pBR322 and the restriction map of the nif region has been determined. 32P-labelled nick-translated probe prepared from the cloned nif DNA fragment hybridized to pRme41b of Rm41 but for most Nod- mutants this hybridization was not detected. Hybridization of a cosmid containing Rm41 DNA to total DNA digest from the wild-type bacterium and from a series of Nod- mutants revealed that at least a 2 kb DNA fragment including the nif structural genes was missing from most of the Nod- mutants. These results, together with the genetic analyses of these symbiotic mutations suggest that some nod and fix genes are located on pRme41b.