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.     

Determination of the site of phosphorylation of nodulin 26 by the calcium-dependent protein kinase from soybean nodules.

Nodulin 26 is a nodule-specific protein that is associated with the symbiosome membrane of soybean root nodules. Nodulin 26 is an endogenous substrate for a novel calcium-dependent protein kinase (CDPK) of soybean root nodules. By phosphopeptide mapping of endoproteinase Lys-C-digested nodulin 26 and automated and manual peptide sequence analyses, we have identified the site on nodulin 26 phosphorylated by CDPK. We have also established that the phosphorylation site of nodulin 26 is identical to the phosphorylation site of CK-15, a synthetic peptide with the carboxyl-terminal sequence of nodulin 26. The phosphorylation of nodulin 26 occurs at position Ser262, and the phosphorylation of CK-15 occurs at the analogous position, Ser,6 in vitro. Thus, the CK-15 sequence apparently contains sufficient structural features of the phosphorylation site of nodulin 26 to be recognized by CDPK. On the basis of peptide mapping analysis of nodulin 26 from nodules that are metabolically labeled with [32P]phosphate, it appears that the site of nodulin 26 that is phosphorylated in vitro is also labeled in vivo. The data indicate that the carboxyl terminus of nodulin 26 is phosphorylated by CDPK and provide initial sequence data for the phosphorylation site of an endogenous substrate for a plant CDPK.     

Characterization of nodule-specific cDNA clones from Sesbania rostrata and expression of the corresponding genes during the initial stages of stem nodules and root nodules formation

We have constructed a Sesbania rostrata stem nodule-specific cDNA library. By screening with heterologous probes from pea and soybean, we have isolated several nodulin cDNA clones. On the basis of nucleotide and amino acid sequence homology, two nearly full-length cDNA clones coding for two different leghemoglobin-like proteins have been identified. The inserts of two other clones reveal a high degree of amino acid sequence homology (81% and 72%) to the early nodulin Enod2 from soybean; the characteristic heptapeptide repeat units PPHEKPP and PPYEKPP of the soybean Enod2 are conserved in the proteins encoded by these Sesbania cDNA clones. The time course of Enod2 and leghemoglobin mRNA appearance during the formation of stem nodules and root nodules on S. rostrata was analyzed by northern blot hybridization. Significant differences were found for the initiation of mRNA accumulation of these nodulins between S. rostrata and soybean.     

HMG I-like proteins from leaf and nodule nuclei interact with different AT motifs in soybean nodulin promoters.

Three different nuclear factors recognizing short AT-rich DNA sequences were identified in different organs of soybean. One factor (NAT2) was found to be present in mature nodules, another factor (NAT1) was detected in roots and nodules, and a third one (LAT1) was only observed in leaves. All three factors recognized several DNA sequences in the promoter region of the soybean nodulin N23 gene. Footprinting, deletion, and point mutation analyses revealed different binding properties for all three factors and further showed that even single base pair substitutions had a dramatic effect on binding affinity. The LAT1 and NAT1 factors were released from chromatin by extraction with a low-salt buffer and were soluble in 2% trichloroacetic acid, implying a relationship to high-mobility group (HMG) proteins. DNA binding studies further indicated a functional relationship of these factors to the human HMG I protein. Purification of the LAT1 factor from leaf nuclei revealed the presence of two polypeptides with molecular masses of 21 kilodaltons and 23 kilodaltons, respectively, binding the same DNA sequence with equal affinity.     

Appearance and accumulation of nodulin mRNAs and their relationship to the effectiveness of root nodules

Summary Cloned cDNAs corresponding to mRNAs which accumulate in nitrogen-fixing root nodules of soybean (nodulin mRNAs) were used as probes to investigate the sizes, sequence relationships, tissue specificities and developmental accumulations of individual nodulin mRNA sequences. Northern blot analysis indicated that the NodB, NodC and NodD mRNA sequences are 1 150, 770, and 3 150 nucleotides long, respectively, which is consistent with the previously determined sizes of the hybrid-selected translation products (27 000, 24 000 and 100 000 MW, respectively). The NodA clones pNodA15 and pNodA25 hybridized to two mRNAs of lengths 1 600 and 1 100 nucleotides, indicating that they contain significant sequence homologies. However, increasing the hybridization stringency showed that the pNodA15 clone encodes the 1 600 nucleotide mRNA corresponding to the major NodA hybrid-selected translation product (44 000 MW) while pNodA25 encodes an mRNA of 1 100 nucleotides. The latter probably corresponds to one of two smaller (23 500 and 24 500 MW) in vitro translation products. RNA dot-blot hybridizations indicated that nodulin and leghemoglobin mRNAs began to appear and accumulate in Rhizobium infected root tissue very early (day 3 to 5) and reached fully induced levels by day 11. This accumulation was specific for nodule tissue (except for the NodD sequence) and preceded the accumulation of nitrogen fixation activity. Nodules produced by different effective Rhizobium strains accumulated similar levels of leghemoglobin and nodulin mRNAs while ineffective strains had a pleiotropic affect. While one ineffective strain (61A24) gave reduced levels of all these mRNAs, the other (SM5) gave levels which were nearly normal by the time nitrogen fixation activity should have reached its maximal level (day 17). Thus, leghemoglobin and nodulin genes are switched on soon after infection, prior to nodule morphogenesis, and the switch occurs prior to and is independent of nitrogen fixation activity.     

Molecular organisation of the malate synthase genes of Aspergillus nidulans and Neurospora crassa

Summary 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.     

Nuclear factors interact with conserved A/T-rich elements upstream of a nodule-enhanced glutamine synthetase gene from French bean.

The gln-gamma gene, encoding the gamma subunit of glutamine synthetase in French bean (Phaseolus vulgaris), is strongly induced during nodule development. We have determined the nucleotide sequence of a 1.3-kilobase region at its 5' end and have identified several sequences common to the promoter regions of late nodulin genes from other legume species. The 5'-flanking region was analyzed for sequence-specific interactions with nuclear factors from French bean. A factor from nodules (PNF-1) was identified that binds to multiple sites between -860 and -154, and a related but distinct factor (PRF-1) was detected in extracts from uninfected roots. PNF-1 and PRF-1 bound strongly to a synthetic oligonucleotide containing the sequence of an A/T-rich 21-base pair imperfect repeat found at positions -516 and -466. The same factors also had a high affinity for a protein binding site from a soybean leghemoglobin gene and appeared to be closely related to the soybean nodule factor NAT2, which binds to A/T-rich sequences in the lbc3 and nodulin 23 genes [Jacobsen et al. (1990). Plant Cell 2, 85-94]. Comparison of NAT2/PNF-1 binding sites from a variety of nodulin genes revealed the conservation of the short consensus core motif TATTTWAT, and evidence was obtained that this sequence is important for protein recognition. Cross-recognition by PNF-1 of a protein binding site in a soybean seed protein gene points to the existence of a ubiquitous family of factors with related binding affinities. Our data suggest that PNF-1 and PRF-1 belong to an evolutionarily conserved group of nuclear factors that interact with specific A/T-rich sequences in a diverse set of plant genes. We consider the possible role of these factors in coregulating the expression of gln-gamma and other late nodulin genes.     

Analysis of rice (Oryza sativa L.) genome using pulsed-field gel electrophoresis and rare-cutting restriction endonucleases

TheOryza sativa (rice) genome is small (600 to 900 megabase pairs) when compared to that of other monocotyledonous plants. Rice was the first of the major cereals to be successfully transformed and regenerated. An RFLP map with approximately 300 markers is readily available, and the DNA content per map unit is only two to three times that ofArabidopsis thaliana. Rice is also the main staple food for the majority of peoples in the world. We developed techniques for the preparation of intact genomic DNA from Indica and Japonica subspecies of rice, used statistical methods to determine which restriction endonucleases are rare-cutting, and used pulsed-field gel electrophoresis (PFE) to separate large fragments of rice DNA. Southern hybridization to blotted rice PFE gels was used to show that the digests were complete. The long-term goal of our work is to generate an integrated genetic/physical map for the rice genome, as well as helping to establish rice as a model for map-based gene cloning and genome analysis.     

Identification with proteomics of novel proteins associated with the peribacteroid membrane of soybean root nodules

Soybean peribacteroid membrane (PBM) proteins were isolated from nitrogen-fixing root nodules and subjected to N-terminal sequencing. Sequence data from 17 putative PBM proteins were obtained. Six of these proteins are homologous to proteins of known function. These include three chaperones (HSP60, BiP [HSP70], and PDI) and two proteases (a serine and a thiol protease), all of which are involved in some aspect of protein processing in plants. The PBM homologs of these proteins may play roles in protein translocation, folding, maturation, or degradation in symbiosomes. Two proteins are homologous to known, nodule-specific proteins from soybean, nodulin 53b and nodulin 26B. Although the function of these nodulins is unknown, nodulin 53b has independently been shown to be associated with the PBM. All of the eight proteins with identifiable homologs are likely to be peripheral rather than integral membrane proteins. Possible reasons for this apparent bias are discussed. The identification of homologs of HSP70 and HSP60 associated with the PBM is the first evidence that the molecular machinery for co- or post-translational import of cytoplasmic proteins is present in symbiosomes. This has important implications for the biogenesis of this unique, nitrogen-fixing organelle.     

The aberrant cell walls of boron-deficient bean root nodules have no covalently bound hydroxyproline-/proline-rich proteins.

B-deficient bean (Phaseolus vulgaris L.) nodules examined by light microscopy showed dramatic anatomical changes, mainly in the parenchyma region. Western analysis of total nodule extracts examined by sodium dodecyl sulfate-polyacrylamide gel electrophoresis showed that one 116-kD polypeptide was recognized by antibodies raised against hydroxyproline-rich glycoproteins (HRGPs) from the soybean (Glycine max) seed coat. A protein with a comparable molecular mass of 116 kD was purified from the cell walls of soybean root nodules. The amino acid composition of this protein is similar to the early nodulin (ENOD2) gene. Immunoprecipitation of the soybean ENOD2 in vitro translation product showed that the soybean seed coat anti-HRGP antibodies recognized this early nodulin. Furthermore, we used these antibodies to localize the ENOD2 homolog in bean nodules. Immunocytochemistry revealed that in B-deficient nodules ENOD2 was absent in the walls of the nodule parenchyma. The absence of ENOD2 in B-deficient nodules was corroborated by performing hydroxyproline assays. Northern analysis showed that ENOD2 mRNA is present in B-deficient nodules; therefore, the accumulation of ENOD2 is not affected by B deficiency, but its assembly into the cell wall is. B-deficient nodules fix much less N2 than control nodules, probably because the nodule parenchyma is no longer an effective O2 barrier.     

Characterization of the soybean early nodulin cDNA clone GmENOD55

Two cDNA clones of the soybean early nodulin GmENOD55 were characterized. These clones may represent two members of the soybean early nodulin gene family GmENOD55. GmENOD55 has an N-terminal signal peptide and it contains an internal domain consisting of proline and serine residues. Analyses of nodules lacking infection threads and intracellular bacteria suggest that the GmENOD55 gene is first expressed after release ofBradyrhizobium japonicum in plant cells. This conclusion is supported byin situ hybridization studies showing that the expression is restricted to the infected cell type.     

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

The nodulin-23 gene of soybean is one of the most abundantly transcribed genes induced during symbiosis with Rhizobium. Using a plasmid (pNod25) from a nodule cDNA library, we have isolated the nodulin-23 gene from a soybean genomic library. Nucleotide sequence analysis of the cDNA and of the genomic clone indicated that the coding region of this gene is 669 bp long and is interrupted by a single intron of about 530 bp. The deduced protein sequence suggests that nodulin-23 may have a signal sequence. The 5'-flanking sequence of two other nodulin genes, nodulin-24 encoding for a membrane polypeptide and one of the leghemoglobin genes (LbC3), were obtained. Comparison of these sequences revealed three conserved regions, one of which, an octanucleotide (GTTTCCCT), has 100% homology. The conserved sequences are arranged in a unique fashion and have a spatial organization with respect to order and position, which may suggest a potential regulatory role in controlling the expression of nodulin and leghemoglobin genes during symbiosis.     

Nodulin gene expression during soybean (Glycine max) nodule development

In vitro translation products of total RNA isolated from soybean nodules at successive stages of nodule development were analyzed by two-dimensional gel electrophoresis. In that way the occurrence of over 20 mRNAs specifically transcribed from nodulin genes was detected. The nodulin genes could be divided into two classes according to the time of expression during nodule development. Class A comprises at least 4 nodulin mRNAs which are found when a globular meristem is present in the root cortex. These class A nodulin genes have a transient expression. Class B nodulin genes are expressed when the formation of a nodule structure has been completed. Bradyrhizobium japonicum nod ⁺ fix^-mutants, with large deletions spanning the nif H,DK region, still induced nodules showing normal expression of all nodulin genes, indicating that the nif H,DK region is not involved in the induction of nodulin genes. In nodules induced by Bradyrhizobium japonicum nod ⁺ fix^-mutant HS124 the bacteria are rarely released from the infection thread and the few infected cells appear to be collapsed. All class A and class B nodulin genes are expressed in HS124 nodules with the exception of 5 class B genes.     

Oxygen regulation of uricase and sucrose synthase synthesis in soybean callus tissue is exerted at the mRNA level

The effect of lowering oxygen concentration on the expression of nodulin genes in soybean callus tissue devoid of the microsymbiont has been examined. Poly(A)⁺ RNA was isolated from tissue cultivated in 4% oxygen and in normal atmosphere.Quantitative mRNA hybridization experiments using nodule-specific uricase (Nodulin-35) and sucrose synthase (Nodulin-100) cDNA probes confirmed that the synthesis of the uricase and sucrose synthase is controlled by oxygen at the mRNA level.The steady-state levels of uricase and sucrose synthase mRNA increased significantly (5–6- and 4-fold respectively) when the callus tissue was incubated at reduced oxygen concentration. Concomitant with the increase in mRNA level a 6-fold increase in specific activity of sucrose synthase was observed.Two messengers representing poly-ubiquitin precursors also responded to lowering the oxygen concentration. The increase was about 5-fold at 4% oxygen. No expression at atmospheric oxygen or in response to low oxygen was observed when using cDNA probes for other nodulin genes such as leghemoglobin c₃, nodulin-22 and nodulin-44.     

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.