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.     

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.     

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.     

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.     

cDNA cloning and developmental expression of pea nodulin genes

A cDNA library prepared from pea nodule poly(A)⁺ RNA was screened by differential hybridization with cDNA probes synthesized from root and nodule RNA respectively. From the cDNA clones that hybridized exclusively with the nodule probe five clones, designated pPsNod 6, 10, 11, 13 and 14 and each containing unique sequences, were further characterized together with one leghemoglobin and one root-specific cDNA clone. In vitro translation of RNA selected by the pPsNod clones showed that the corresponding genes encode nodulins with molecular weights ranging from 5 800 to 19 000. During pea root nodule development expression of the five PsNod genes starts more or less concomitantly with the onset of nitrogen fixing activity in the nodules and the time course of appearance and accumulation of the nodulin mRNAs is similar to that of leghemoglobin mRNA. In ineffective pea root nodules expression of the PsNod genes is induced but the final accumulation levels of the mRNAs are markedly reduced to various degrees. The expression of another nodulin gene, designated ENOD2, was followed using a heterologous soybean cDNA clone as probe. In pea root nodules the ENOD2 gene is expressed at least five days before the PsNod and leghemoglobin genes, and in contrast to the PsNod mRNAs the concentration of the ENOD2 mRNA is the same in wild type and fix ^- nodules. The results described suggest that in root nodules several regulatory mechanisms exist which determine the final nodulin mRNA amounts accumulating in the root nodule.     

Molecular cloning of actin genes in Trichomonas vaginalis and phylogeny inferred from actin sequences

The parasitic protozoan Trichomonas vaginalis is known to contain the ubiquitous and highly conserved protein actin. A genomic library and a cDNA library have been screened to identify and clone the actin gene(s) of T. vaginalis. The nucleotide sequence of one gene and its flanking regions have been determined. The open reading frame encodes a protein of 376 amino acids. The sequence is not interrupted by any introns and the promoter could be represented by a 10 bp motif close to a consensus motif also found upstream of most sequenced T. vaginalis genes. The five different clones isolated from the cDNA library have similar sequences and encode three actin proteins differing only by one or two amino acids. A phylogenetic analysis of 31 actin sequences by distance matrix and parsimony methods, using centractin as outgroup, gives congruent trees with Parabasala branching above Diplomonadida.     

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.     

斑马鱼DrSpin-1基因的克隆和特征分析

Spin蛋白家族是具有Spin/Ssty保守结构域并在配子发生过程中发挥关键作用的一类分子。研究利用简并引物PCR,从斑马鱼成熟卵母细胞SMART cDNA文库中筛选到260 bp的DrSpin-1和DrSpin-2部分序列,经序列同源性比对,斑马鱼DrSpin-1的部分氨基酸序列与银鲫CagSpin一致性高达81%。利用RACEPCR从该cDNA文库中获得斑马鱼DrSpin-1的全长cDNA序列。序列分析表明,DrSpin-1全长cDNA为1082 bp,开放阅读框771 bp,编码257个氨基酸,具有三个Spin/Ssty保守域,8个可能的磷酸化位点,初步确定斑马鱼DrSpin-1是Spin基因家族成员。斑马鱼DrSpin-1蛋白与已报道的鱼类Spin蛋白多重序列比对表明,DrSpin-1蛋白与银鲫CagSpin蛋白同源性最高。可以推测克隆得到的斑马鱼DrSpin-1与已知功能的银鲫CagSpin具有相近的表达谱和生物学功能,可能在配子发生和受精过程中发挥重要作用。     

Root nodule development: origin, function and regulation of nodulin genes

The symbiotic root nodule, an organ formed on leguminous plants, is a product of successful interactions between the host plant and the soil bacteria, Rhizobium spp. Plant hormones play an important role in the genesis of this organ. The hormonal balance appears to be modulated by the signals produced by bacteria. Many host genes induced during nodule organogenesis and the symbiotic state have been identified and characterized from several legumes. These genes encode nodule-specific proteins (nodulins) which perform diverse functions in root nodule development and metabolism. Formation of a subcellular compartment housing the bacteria is essential to sustain the symbiotic state, and several nodulins are involved in maintaining the integrity and function of this compartment. The bacteroid enclosed in the perbacteroid membrane behaves as an 'organelle,'completely dependent on the host for all its requirements for carbon, nitrogen and other essential elements. Thus it seems likely that the nodulins in the peribacteroid membrane perform specific transport functions. While the function of a few other nodulins is known (e.g. nodulin-100, nodulin-35), a group of uncharacterized nodulins exists in soybean root nodules. These nodulins share structural similarities and seem to have been derived from a common ancestor. Induction of nodulin genes occurs prior to and independent of nitrogen fixation, and thus is a prelude to symbiosis. Although some of the early nodulin genes are induced prior to or during infection, induction of late nodulins requires endocytotic release of bacteria.