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.     

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.     

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.     

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.     

A two-component nodule-specific enhancer in the soybean N23 gene promoter.

The two positive cis elements in the soybean nodulin N23 gene promoter were investigated in transgenic Lotus corniculatus plants and shown to constitute a two-component nodule-specific enhancer. Equal quantitative contributions from the two components were suggested by the similar expression level of chimeric N23-chloramphenicol acetyltransferase genes after deletion of either the distal positive element (PE-A, -320 to -298) or the proximal positive element (PE-B, -257 to -165). A combined effect of the two elements was indicated by orientation-dependent effects in the N23 promoter, and by the observation that neither PE-A nor PE-B separately was able to confer any activity to the cauliflower mosaic virus 35S minimal promoter. Reactivation of the minimal N23 and the minimal cauliflower mosaic virus 35S promoters by the inverted complete element (PE-AB) further suggested that PE-AB is a nodule-specific enhancer containing two equally strong enhancer components. Two 12-bp sequence motifs, InvA and InvB, constituting an inverted repeat, were identified as the core of the enhancer components PE-A and PE-B, respectively. Point mutations in InvA or InvB resulted in lower expression levels and mutations in both abolished enhancer activity. Point mutations in two nodulin consensus sequences, 5'-CTCTT and 5'-AAAGAT located downstream of PE-AB, resulted in a decreased level of expression, confirming the involvement of these two motifs in nodulin gene expression. The binding site for the nodule-specific trans-acting factor, NAT2, present in the PE-A segment, was removed without affecting expression significantly. This interaction is, therefore, dispensable for enhancer activity.     

Cotyledon nuclear proteins bind to DNA fragments harboring regulatory elements of phytohemagglutinin genes.

The effects of deleting DNA sequences upstream from the phytohemagglutinin-L gene of Phaseolus vulgaris have been examined with respect to the level of gene product produced in the seeds of transgenic tobacco. Our studies indicate that several upstream regions quantitatively modulate expression. Between -1000 and -675, a negative regulatory element reduces expression approximately threefold relative to shorter deletion mutants that do not contain this region. Positive regulatory elements lie between -550 and -125 and, compared with constructs containing only 125 base pairs of upstream sequences (-125), the presence of these two regions can be correlated with a 25-fold and a 200-fold enhancement of phytohemagglutinin-L levels. These experiments were complemented by gel retardation assays, which demonstrated that two of the three regions bind cotyledon nuclear proteins from mid-mature seeds. One of the binding sites maps near a DNA sequence that is highly homologous to protein binding domains located upstream from the soybean seed lectin and Kunitz trypsin inhibitor genes. Competition experiments demonstrated that the upstream regions of a bean beta-phaseolin gene, the soybean seed lectin gene, and an oligonucleotide from the upstream region of the trypsin inhibitor gene can compete differentially for factor binding. We suggest that these legume genes may be regulated in part by evolutionarily conserved protein/DNA interactions.     

Disease-resistance related sequences in common bean.

Primers based on a conserved nucleotide binding site (NBS) found in several cloned plant disease resistance genes were used to amplify DNA fragments from the genome of common bean (Phaseolus vulgaris). Cloning and sequence analysis of these fragments uncovered eight unique classes of disease-resistance related sequences. All eight classes contained the conserved kinase 2 motif, and five classes contained the kinase 3a motif. Gene expression was noted for five of the eight classes of sequences. A clone from the SB3 class mapped 17.8 cM from the Ur-6 gene that confers resistance to several races of the bean rust pathogen Uromyces appendiculatus. Linkage mapping identified microclusters of disease-resistance related sequence in common bean, and sequences mapped to four linkage groups in one population. Comparison with similar sequences from soybean (Glycine max) revealed that any one class of common bean disease-resistance related sequences was more identical to a soybean NBS-containing sequence than to the sequence of another common bean class.     

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.     

Two glutamine synthetase genes from Phaseolus vulgaris L. display contrasting developmental and spatial patterns of expression in transgenic Lotus corniculatus plants.

The gln-gamma gene, which specifies the gamma subunit of glutamine synthetase in Phaseolus vulgaris L., has been isolated and the regulatory properties of its promoter region analyzed in transgenic Lotus corniculatus plants. A 2-kilobase fragment from the 5'-flanking region of gln-gamma conferred a strongly nodule-enhanced pattern of expression on the beta-glucuronidase reporter gene. Parallel studies on the promoter of another glutamine synthetase gene (gln-beta) showed that a 1.7-kilobase fragment directed 20-fold to 140-fold higher levels of beta-glucuronidase expression in roots than in shoots. Histochemical localization of beta-glucuronidase activity in nodules of the transgenic plants indicated that the chimeric gln-gamma gene was expressed specifically in the rhizobially infected cells; expression of the gln-beta construct was detected in both cortical and infected regions of young nodules, and became restricted to the vascular tissue as the nodule matured. We conclude that gln-beta and gln-gamma genes are differentially expressed both temporally and spatially in plant development and that the cis-acting regulatory elements responsible for conferring these contrasting expression patterns are located within a 2-kilobase region upstream of their coding sequences.     

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.