Primary structure of the soybean nodulin-23 gene and potential regulatory elements in the 5'-flanking regions of nodulin and leghemoglobin genes

Nodule-specific PLAT domain proteins are expanded in the Medicago lineage and required for nodulation

Symbiotic nitrogen fixation in legumes is mediated by an interplay of signaling processes between plant hosts and rhizobial symbionts. In legumes, several secreted protein families have undergone expansions and play key roles in nodulation. Thus, identifying lineage-specific expansions (LSEs) of nodulation-associated genes can be a strategy to discover candidate gene families. Using bioinformatic tools, we identified 13 LSEs of nodulation-related secreted protein families, each unique to either Glycine, Arachis or Medicago lineages. In the Medicago lineage, nodule-specific Polycystin-1, Lipoxygenase, Alpha Toxin (PLAT) domain proteins (NPDs) expanded to five members. We examined NPD function using CRISPR/Cas9 multiplex genome editing to create Medicago truncatula NPD knockout lines, targeting one to five NPD genes. Mutant lines with differing combinations of NPD gene inactivations had progressively smaller nodules, earlier onset of nodule senescence, or ineffective nodules compared to the wild-type control. Double- and triple-knockout lines showed dissimilar nodulation phenotypes but coincided in upregulation of a DHHC-type zinc finger and an aspartyl protease gene, possible candidates for the observed disturbance of proper nodule function. By postulating that gene family expansions can be used to detect candidate genes, we identified a family of nodule-specific PLAT domain proteins and confirmed that they play a role in successful nodule formation.

Primary structure of the soybean nodulin-35 gene encoding uricase II localized in the peroxisomes of uninfected cells of nodules

Nodulin-35 (N-35), a subunit of nodule-specific uricase (uricase II) of soybean (Glycine max), is shown to be preferentially synthesized on free polysomes during nodule development and is localized in peroxisomes of the uninfected cells of this tissue. A cDNA clone, isolated by using mRNA from immunoprecipitated polysomes, revealed the primary structure of this protein with a molecular mass of 35,100. That this clone represents N-35 was confirmed by comparing the deduced amino acid sequence with the partial sequence of a CNBr-cleaved peptide of purified N-35. Southern blot hybridizations with genomic DNA suggest that there are several EcoRI fragments containing N-35 sequences. Three of these sequences were isolated from a genomic library of soybean. Nucleotide sequence analysis showed that the complete gene extends almost 5000 base pairs on two EcoRI fragments and the coding region (309 codons) is interrupted by seven introns ranging in size from 154 to 1341 base pairs. Lack of a signal sequence and its translation on free polysomes suggest that N-35 is posttranslationally transported to the peroxisomes. Furthermore, there is no cross-hybridization of N-35 cDNA with RNA from young (3- to 4-day) roots and leaves, indicating that the observed "uricase" activity in these tissues is due to the product of a different gene.

Multiple transcripts of a gene for a leucine-rich repeat receptor kinase from morning glory (Ipomoea nil) originate from different TATA boxes in a tissue-specific manner

TATA boxes are the most common regulatory elements found in the promoters of eukaryotic genes because they are associated with basal transcription initiation by RNA polymerase II. Often only a single TATA element is found in a given promoter, and tissue-, stage- and/or stimulus-specific expression occurs because the TATA box is associated with other cis -acting elements that enhance or repress transcription. We used software tools for gene analysis to assist in locating potential TATA box(es) in an AT-rich region of the promoter of a gene, inrpk1, which codes for a leucine-rich receptor protein kinase in morning glory (Ipomoea nil). Through the use of RT-PCR and various combinations of forward primers bracketing most of the promoter region we were able to define the 5'-ends of transcripts in this region. The region was then targeted for analysis by RNA Ligase-Mediated-5' Rapid Amplification of cDNA Ends (RLM-5' RACE) to identify the transcript initiation site(s). Positioning of initiation sites with respect to TATA boxes identified by gene analysis tools allowed us to identify three operational TATA elements which regulate basal transcription from this gene. Two TATA boxes were responsible for all of the inrpk1 transcripts found in leaves and cotyledons, and about 25-30% of the transcripts in roots. A third TATA box was involved only in expression in roots and accounted for the remaining 50-70% of root transcripts. RNAs expressed from this element lack two potentially functional upstream AUG codons, and may be translated more efficiently than transcripts originating from the other TATA boxes.

Two distinct uricase II (nodulin 35) genes are differentially expressed in soybean plants

Nodule-specific uricase (uricase II) is a homotetramer of a 33-kDa polypeptide, nodulin 35, and plays a key role in the assimilation of nitrogen fixed by microsymbionts in most legumes that have determinate nodules. We have isolated two distinct genes, UR2 and UR9, that encode for nodulin 35 from a soybean genomic library. Their corresponding cDNAs were also isolated from a nodule cDNA library. UR2 and UR9 both encode for 309 amino acid proteins with 12 amino acid differences. The expression of these two genes in various organs of soybean was examined by reverse transcription-polymerase chain reaction with primers specific to each cDNA sequences. Expression of UR9 was almost specific in root nodules, although it was expressed in roots, primary leaves, and developing seed at very low levels. In contrast, the UR2 transcripts were present in almost all plant organs at low levels, but no enhancement of the expression was observed in nodules. Thus, UR9 behaves as a nodulin gene, whereas UR2 is a nonsymbiotic uricase II gene. The sequences of their potential promoter regions share high homology within regions up to about 400 bp upstream from the translation initiation sites. These results suggest that symbiotic and nonsymbiotic uricase II genes diverged by gene duplication and that relatively small alterations in the promoter sequence enable the nodule-specific expression.

Characterization and gene expression of nodulin Npv30 from common bean

We previously reported that transcripts for a 30-kD nodulin (Npv30) are very abundant in the nodule. In this paper we describe the isolation and characterization of Npv30 cDNA and genomic clones. Npv30 has the following characteristic features: (a) a putative signal sequence at the deduced amino-terminal region, (b) a proline-rich stretch at the carboxy terminus, and (c) a characteristic domain of four cysteines that resemble metal-binding sites. In Phaseolus vulgaris L., Npv30 is encoded by a small gene family that shares discrete sequence homologies with another small gene family in soybean. An antibody against a beta-galactosidase-Npv30 fusion protein detected two proteins of 28 and 30 kD. Although Npv30 transcripts are very abundant, they encode proteins that are hardly detected in nodule fractions, suggesting that these proteins have a short half-life and/or the mRNAs are strongly regulated at the translational level. Npv30 transcripts were detected in the infected cells of the nodule by in situ hybridization experiments.

Functional characterization of the brain-specific FGF-1 promoter, FGF-1.B

Expression of alternatively spliced human FGF-1 (or aFGF) transcripts is regulated in a tissue-specific manner via multiple promoters. To identify the cis-regulatory elements in the brain-specific FGF-1.B promoter, we constructed a series of promoter deletions fused to the luciferase reporter gene and transfected into an FGF-1.B positive glioblastoma cell line, U1240MG, and a 1.B negative cell line, U1242MG. Results of transient transfections indicate three elements that are involved in the positive regulation of FGF-1.B expression. The core promoter is located in a 40-base pair region (between -92 and -49), and two regulatory regions (RR-1 and RR-2) are located within the 540-base pair region 5' to the major transcription start site (defined as +1). Electrophoretic mobility shift assays and footprinting analysis have identified sequence-specific binding sites in RR-1 and RR-2. Mutants of RR-2 abolished binding to nuclear proteins and showed diminished luciferase reporter activity. The effects seen are specific for the U1240MG cell line, supporting a role for RR-2 in the tissue-specific regulation of FGF-1.B. Southwestern analysis using an oligonucleotide probe derived from RR-2 (nucleotides -489 to -467) further identified a 37-kDa protein that is present in nuclear extracts from U1240MG and brain but not from U1242MG.

Soybean nodulin-26 gene encoding a channel protein is expressed only in the infected cells of nodules and is regulated differently in roots of homologous and heterologous plants

Nodulin-26 (N-26) is a major peribacteroid membrane protein in soybean root nodules. The gene encoding this protein is a member of an ancient gene family conserved from bacteria to humans. N-26 is specifically expressed in root nodules, while its homolog, soybean putative channel protein, is expressed in vegetative parts of the plant, with its highest level in the root elongation zone. Analysis of the soybean N-26 gene showed that its four introns mark the boundaries between transmembrane domains and the surface peptides, suggesting that individual transmembrane domains encoded by a single exon act as functional units. The number and arrangement of introns between N-26 and its homologs differ, however. Promoter analysis of N-26 was conducted in both homologous and heterologous transgenic plants. The cis-acting elements of the N-26 gene are different from those of the other nodulin genes, and no nodule-specific cis-acting element was found in this gene. In transgenic nodules, the expression of N-26 was detected only in the infected cells; no activity was found in nodule parenchyma and uninfected cells of the symbiotic zone. The N-26 gene is expressed in root meristem of transgenic Lotus corniculatus and tobacco but not in untransformed and transgenic soybean roots, suggesting the possibility that this nodulin gene is controlled by a trans-negative regulatory mechanism in homologous plants. This study demonstrates how a preexisting gene in the root may have been recruited for symbiotic function and brought under nodule-specific developmental control.

Isolation and characterization of novel nodulin cDNAs representing genes expressed at early stages of soybean nodule development

We took advantage of a subtractive hybridization procedure to isolate a set of cDNA clones of nodule-specific genes (nodulin genes) from developing soybean root nodules. Single-stranded 32P-labelled cDNA synthesized from nodule poly(A)+ RNA was hybridized with a large excess of uninfected root poly(A)+ RNA. Unhybridized cDNA was selected and used to screen nodule cDNA libraries. By this procedure we isolated several novel nodulin cDNA clones together with most of the nodulin cDNAs previously described. Four novel nodulin genes, which were expressed long before the onset of nitrogen fixation, were further characterized. GmN#36 and GmN#93 transcripts appeared in the roots less than 3 days after sowing and inoculation with Bradyrhizobium, but GmN#36 transcripts were also detected at very low levels in the stems of uninfected plants. Transcripts of GmN#315 and GmN#70 first appeared at 6-7 days, just before nodule emergence. Amino acid sequences of the predicted products of GmN#36, GmN#93 and GmN#70 exhibited no significant homology to proteins identified so far. The GmN#315 encoded protein has a limited but significant homology to some plant cyanins, suggesting that it is a metal-binding glycoprotein. In situ hybridization studies revealed that GmN#36 transcripts first appeared in the pericycle cells of the root stele near the infected site. During nodule emergence they were found in a few cell layers surrounding the vascular strands connecting the nodule meristem with the root stele, and in mature nodules they were present specifically in the pericycle cells in vascular bundles. These observations led us to hypothesize that GmN#36 gene products play a role in the transport and/or degradation of photosynthate. On the other hand, GmN#93 transcripts first appeared in the primary nodule meristem just below the root epidermis. In mature nodules they were only present in the infected cells.

Characterization and genomic organization of a highly expressed late nodulin gene subfamily in soybeans

A soybean nodulin cDNA clone (E41) hybrid-selected mRNA for three in vitro translation products with apparent molecular weights of 26 kDa, 25 kDa and 24 kDa. Based on Southern analysis of soybean genomic DNA, combined with mapping and sequencing of genomic clones, we identified four genes that are related to E41, one of which was identified to be the previously characterized N-20 gene. Our data indicate the linkage of three of the genes, of which one is a truncated version and suggest that they originated by gene duplication combined with deletion and conversion. The genes are highly expressed and we postulate that the sequence conservation in the 5' and 3' flanking regions of all four genes, has a functional role in their expression. Hybrid-selected translation products of E41 are not immunoprecipitable with antibody to the soluble fraction of nodules suggesting that they are membrane associated. The N-20 gene, which is a member of this gene subfamily, showed sequence similarity to four previously characterized nodulin genes and a phylogenetic tree is proposed based on the extent of sequence similarity.

Characterization of the pea ENOD12B gene and expression analyses of the two ENOD12 genes in nodule, stem and flower tissue

The ENOD12 gene family in pea consists of two different members. The cDNA clone, pPsENOD12, represents the PsENOD12A gene. The second ENOD12 gene, PsENOD12B, was selected from a genomic library using pPsENOD12 as a probe and this gene was sequenced and characterized. The coding regions of the two genes are strikingly similar. Both encode proteins having a signal peptide sequence and a region with pentapeptide units rich in prolines. ENOD12A has a series of rather conserved repeating pentapeptide units, whereas in ENOD12B the number of pentapeptide units is less and these are less conserved. From the amino acid sequence it is obvious that the PsENOD12 genes encode proline-rich proteins which are closely related to proteins that have been identified as components of soybean cell walls (SbPRPs). Previously, Northern blot analyses had shown that ENOD12 genes are expressed in a tissue-specific manner. A high expression level is found in Rhizobium-infected roots and in nodules, whereas expression in flower and stem is lower. This raised the question of which gene is expressed where and when. The availability of the sequences of both ENOD12 genes allowed us to analyse the expression of the two genes separately. Specific oligonucleotides were used to copy the ENOD12 mRNAs and to amplify the cDNAs in a polymerase chain reaction. It was demonstrated that in all the tissues containing ENOD12 mRNA, both genes PsENOD12A and PsENOD12B are transcribed and that the relative amounts of PsENOD12A and PsENOD12B mRNA within each tissue are more or less equal. Moreover, the expression pattern during infection and nodule development is the same for the two genes.(ABSTRACT TRUNCATED AT 250 WORDS)

Characterization of a novel nodulin gene in soybean that shares sequence similarity to the gene for nodulin-24

A gene encoding for nodulin-16 (N-16) was isolated from a soybean genomic library. Nucleotide sequence analysis of the cDNA and the genomic clone of N-16 indicated that the coding region of this gene is 330 bp long and is interrupted by a single intron of 494 bp. The coding region of the N-16 gene shows a high degree of localized sequence similarity with the coding sequence of soybean nodulin-24 (N-24). Sequence similarity between the two genes is limited to the coding region of 90 bp in the first exon and the first 54 bp in the second exon of the N-16 gene which is repeated as the 2nd, 3rd, and 4th exons in the N-24 gene. The N-24 gene has been postulated to be a result of repeated duplication of an insertion element consisting of the 54 bp exon and the flanking intron sequences. In the absence of sequence similarity in the regions flanking the 54 bp sequence between the N-16 and N-24 genes, the N-16 gene does not appear to be the ancestral gene. Both N-16 and N-24 have a similar hydrophobic amino terminal end suggesting that N-16 like N-24 is targeted to the peribacteroid membrane. Southern analysis of soybean genomic DNA shows the presence of other related sequences to the N-16 gene, one of which is found to be closely linked to it. Analysis of the temporal accumulation of the N-16 transcripts during nodule development in effective and ineffective nodules suggests that N-16 and related genes might differ from leghemoglobin and some other late nodulin genes in their mechanism of regulation.

The 5' splice site: phylogenetic evolution and variable geometry of association with U1RNA

The 5' splice site sequences of 3294 introns from various organisms (1-672) were analyzed in order to determine the rules governing evolution of this sequence, which may shed light on the mechanism of cleavage at the exon-intron junction. The data indicate that, currently, in all organisms, a common sequence 1GUAAG6U and its derivatives are used as well as an additional sequence and its derivatives, which differ in metazoa (G/1GUgAG6U), lower eucaryotes (1GUAxG6U) and higher plants (AG/1GU3A). They all partly resemble the prototype sequence AG/1GUAAG6U whose 8 contigous nucleotides are complementary to the nucleotides 4-11 of U1RNA, which are perfectly conserved in the course of phylogenetic evolution. Detailed examination of the data shows that U1RNA can recognize different parts of 5' splice sites. As a rule, either prototype nucleotides at position -2 and -1 or at positions 4, 5 or 6 or at positions 3-4 are dispensable provided that the stability of the U1RNA-5' splice site hybrid is conserved. On the basis of frequency of sequences, the optimal size of the hybridizable region is 5-7 nucleotides. Thus, the cleavage at the exon-intron junction seems to imply, first, that the 5' splice site is recognized by U1RNA according to a "variable geometry" program; second, that the precise cleavage site is determined by the conserved sequence of U1RNA since it occurs exactly opposite to the junction between nucleotides C9 and C10 of U1RNA. The variable geometry of the U1RNA-5' splice site association provides flexibility to the system and allows diversification in the course of phylogenetic evolution.

Root nodule specific gene regulation: analysis of the soybean nodulin N23 gene promoter in heterologous symbiotic systems

The nodulin N23 gene promoter was analysed in transgenic plants using the chloramphenicol acetyltransferase (CAT) coding sequence as a reporter. A 5' flanking region of less than 1 kb was sufficient for the organ-specific expression of a chimeric N23-CAT-3'lbc3 gene in root nodules formed on Lotus corniculatus and Trifolium repens after infection by their respective Rhizobium symbionts. Expression was regulated at the level of RNA in both species of transgenic plants. Promoter deletion analysis defined the 5' region required for high level expression and delimited two putative regulatory sequences involved in positive control of the N23 gene in L. corniculatus.

Putative polyadenylation signals in nuclear genes of higher plants: a compilation and analysis

In animal and viral pre-mRNAS, the process of polyadenylation is mediated through several cis-acting poly (A) signals present upstream and downstream from poly (A) sites. The situation regarding polyadenylation of higher plant pre-mRNAS, however, has remained obscure so far. In this paper, a search for putative poly (A) signals is made by considering the published data from 46 plant genomic DNA sequences. Certain domains in the 3' untranslated regions from nuclear genes of higher plants were compiled and occurrence of sequence motifs such as AATAAA, CAYTG, YGTGTTYY and YAYTG was scored in relation to poly (A) sites. Moreover, consensus sequences for important regions in the 3' untranslated sequences and poly (A) signals were also deduced from the data. It was inferred that sequence motifs similar to poly (A) signals exist around poly (A) sites but some of them are in entirely different spatial relationship than observed in other eukaryotes. This indicates their probable non-involvement in the process of polyadenylation in higher plants necessitating a functional analysis approach to define the plant specific poly (A) signals.

An inspection of the domain between putative TATA box and translation start site in 79 plant genes

Over 75 published genomic DNA sequences from several higher plants have been collected and flanking regions of the leader sequences have been analysed. In a majority of the plants, the first AUG codon on processed mRNA acted as a translation initiation site. The consensus sequence for the context was TAAACAATGGCT (on plus strand of DNA). This differed from the earlier suggestion for eukaryotic mRNAs based mainly on data from animals. Leader sequences were generally 40-80 nucleotides in length and were A+T rich. Adenine was present in a majority of the cases at the transcription start site which was flanked by pyrimidine bases. The putative TATA box was present 32 +/- 7 nucleotides upstream from the transcription initiation site. The consensus sequence for TATA box and surrounding region was TCACTATATATAG.

A block in the endocytosis of Rhizobium allows cellular differentiation in nodules but affects the expression of some peribacteroid membrane nodulins

A transposon-induced mutant (T8-1) of Bradyrhizobium japonicum (61A76) was unable to develop into the nitrogen-fixing endosymbiotic form, the bacteroid. Comparison between this mutant and T5-95, an ineffective (non-nitrogen fixing, Fix(-)) mutant, confirmed that the process of bacteroid development is a distinct phase of differentiation of the endosymbiont and is independent of nitrogen fixation activity. The T8-1 mutant was able to induce normal-size nodules which differentiated two plant cell types and contained numerous infection threads. However, the infected cells were devoid of bacteroids. Electron microscopy revealed that the ends of the infection threads were broken down in a normal manner once the thread had penetrated the cells, but the mutant was not internalized by endocytosis. The lack of peribacteroid membrane (PBM) in nodules induced by this mutant was correlated with a reduced level of expression of plant genes coding for PBM nodulins. These genes were expressed in the T5-95 mutant, showing that the low expression in T8-1 was not due to the lack of nitrogen fixation. One of the PBM nodulins, nodulin-26, was found at normal levels in the nodules which lack PBM, suggesting that there are at least two developmental stages in PBM biosynthesis. These data suggest that a coordination of plant and Rhizobium gene expression is required for the release and internalization of bacteria into the PBM compartments of infected cells of nodules.

A small family of nodule specific genes from soybean

The primary structure of two nodule specific soybean genes are presented. The two genes code for primary products of 20.0 (nodulin 20) and 22.7 (nodulin 22) kdaltons, respectively. Both genes are related to the nodulin 23 and 44 genes. Alignment of the deduced amino acid sequences of all four genes revealed three domains of high homology interrupted by highly diverged regions due to numerous duplication and insertion events. The first conserved domain codes for a putative signal peptide, while the two others each contain four Cys residues that can be arranged in a way reminiscent of the metal binding domains present in some enzymes and in several DNA binding proteins.

Several nodulins of soybean share structural domains but differ in their subcellular locations

Four soybean cDNA nodule-specific clones encoding nodulin-23, -26b, -27 and -44 were observed to cross-hybridize under low stringency conditions. Nucleotide sequence analysis revealed that the cDNAs contain three distinct domains: two domains with 70 to 95% homology separated by a third domain unique to each cDNA. Despite a number of nucleotide insertions and deletions, the protein sequences are conserved in the two domains which correlate with the homologous nucleotide domains. The amino terminal domain of each nodulin contains putative signal sequences for membrane translocation, although only two (nodulin-23 and -44) meet all the criteria for a functional signal. Immuno-precipitation of hybrid-release translation products of the four cDNAs revealed that nodulin-23 is associated with the peribacteroid membrane while nodulin-27 is in the cytoplasmic fraction of the nodule. These four nodulins are members of a diverse family with conserved structural features and the genes encoding them appear to have recently evolved from a common ancestor.

Nodulins and nodulin genes of Glycine max

Nodulins are organ-specific plant proteins induced during symbiotic nitrogen fixation. Nodulins play both metabolic and structural roles within infected and uninfected nodule cells. In soybean, several nodulin genes, coding for abundant nodulins, have been identified and isolated. Structural analysis of some of these genes has revealed their possible mode of regulation and the subcellar location of the protein product. Studies of ineffective symbiosis based on cultivar-strain genotype differences suggested that both partners influence the expression of nodulin genes. Concomitant with nodule organogenesis, the Rhizobium undergoes substantial differentiation leading to the accumulation of nodule-specific bacterial proteins, bacteroidins. The major structural alteration occuring in the infected cell is the formation of a membrane enclosing the bacteroid (peribacteroid membrane). A number of nodulins are specifically targetted to this membrane during endosymbiosis. The induction of nodulins and bacteroidins leads to the formation of an effective nodule. Nodulin genes can be induced in vitro by factors derived from nodules suggesting that trans-activators may be involved in derepression of the host genes necessary for Rhizobium-legume symbiosis.

Nucleotide sequence of a B1 hordein gene and the identification of possible upstream regulatory elements in endosperm storage protein genes from barley, wheat and maize

The B-hordeins are the major group of prolamin storage proteins in barley (Hordeum vulgare L.) and they are encoded by a small multigene family that is expressed specifically in the developing endosperm. We report the complete nucleotide sequence of a clone of one B-hordein gene (pBHR184). The cloned gene contains no introns and belongs to the B1 sub-family of B-hordein genes. Comparison of the 5'-flanking sequences of pBHR184 with those of related S-rich prolamin genes from wheat shows that several short sequences within 600 bp upstream of the translation initiation codon are strongly conserved. A sequence that is conserved at around -300 bp in the S-rich prolamins is also conserved at similar locations in genes encoding the two major classes of maize prolamin (the Z19 and Z21 zeins) and appears to be unique to prolamin genes. We discuss the possible role of this '-300 element' in the control of gene expression in the developing cereal endosperm.

Promoter analysis of a soybean nuclear gene coding for nodulin-23, a nodule-specific polypeptide involved in symbiosis with Rhizobium

Soybean nodulin-23 gene, induced in nodules formed due to symbiosis with Rhizobium, was found to contain multiple sequences capable of acting as eucaryotic and procaryotic promoters. The transcription start sites of this gene were localized by S1 nuclease mapping, primer extension with nodule mRNA and in vitro run-off transcription analysis. A major transcription start site was observed by S1 mapping; however, the the primer extension revealed a second start site. Sequence analysis showed the presence of tandemly arranged eucaryotic promoter sequences, each corresponding to one of the observed transcription start sites. In vitro transcription analysis with HeLa cell extract demonstrated the presence of another alpha-amantin-sensitive transcript ('anti-sense') with its direction opposite to that of the nodulin mRNA. The 5' ends for 80 nucleotides of nodulin and 'anti-sense' messages are complementary to each other. In addition, three tandemly arranged, functional procaryotic promoters (assayed in Escherichia coli) are found to be located within the eucaryotic promoter sites is similar to that of the major in vivo transcript in nodules. The potential significance for the presence of several promoter-like sequences in this gene is discussed.