Structure and chromosomal arrangement of leghemoglobin genes in kidney bean suggest divergence in soybean leghemoglobin gene loci following tetraploidization

We have determined the structure of one of the leghemoglobin (Lb) genes of Phaseolus vulgaris (kidney bean) and deduced the chromosomal arrangement of leghemoglobin genes by genomic hybridizations with Lb and two other sequences, each specific to the 5' or 3' region of the soybean leghemoglobin loci. By comparing this organization with two other species of legumes, Glycine max (soybean) and G. soja (wild soybean), a phylogeny of leghemoglobin gene loci was traced. The intragenic structure of the kidney bean leghemoglobin gene shows the same intron/exon arrangement as that of soybean leghemoglobin genes and extensive sequence homologies in both coding as well as 5' and 3' non-coding regions. The presence in the kidney bean genome of four leghemoglobin genes suggests that tandem duplications of a single primordial plant globin gene had occurred to generate four leghemoglobin genes in an `Lb-locus' before Glycine and Phaseolus species diverged. Chromosome duplication by tetraploidization in Glycine generated two loci containing four genes each. A large deletion in one of the two four-gene loci in soybean resulted in the generation of the Lbc₂ locus containing two leghemoglobin genes, one functional and another pseudo (LbΨ₂). This pseudogene, unlike that present on the main locus, is represented by only two and a half exons and appears to be truncated. The two other truncated genes (LbT₁ and LbT₂) were probably generated similarly in the genome of Glycine spp. following tetraploidization before the divergence of G. max and G. soja.     

The primary structures of two leghemoglobin genes from soybean

We present the complete nucleotide sequences of two leghemoglobin genes isolated from soybean DNA. Both genes contain three intervening sequences which interrupt the two coding sequences in identical positions. The 5' and 3' flanking sequences in both genes contain conserved sequences similar to those found in corresponding positions in other eukaryotic genes. Thus, the general DNA sequence organization of these plant genes is similar to that of other eukaryotic genes.     

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.     

The evolution of a plant globin gene family

Summary We have analyzed the sequences of soybean leghemoglobin genes as an initial step toward understanding their mode of evolution. Alignment of the sequences of plant globin genes with those of animals reveals that (i) based on the proportion of nucleotide substitutions that have occurred at the first, second, and third codon positions, the time of divergence of plant and animal globin gene families appears to be extremely remote (between 900 million and 1.4 billion years ago, if one assumes constancy of evolutionary rate in both the plant and animal lineages) and (ii) in addition to the normal regulatory sequences on the 5 end, an approximately 30-base-pair sequence, specific to globin genes, that surrounds the cap site is conserved between the plant and animal globin genes. Comparison of the leghemoglobin sequences with one another shows that (i) the relative amount of sequence divergence in various coding and noncoding regions is roughly similar to that found for animal globin genes and (ii) as in animal globin genes, the positions of insertions and deletions in the intervening sequences often coincide with the locations of direct repeats. Thus, the mode of evolution of the plant globin genes appears to resemble, in many ways, that of their animal counterparts. We contrast the overall intergenic organization of the plant globin genes with that of animal genes, and discuss the possibility of the concerted evolution of the leghemoglobin genes.     

The detection of leghemoglobin-line sequences in legumes and non-legumes

Summary Leghemoglobin is a major component of the nitrogen-fixing nodules formed by legumes in association with bacterial symbionts of the genusRhizobium. It is thought to be involved in regulating the oxygen tension within nodules. In a series of Southern blot experiments using cloned soybean leghemoglobin cDNAs as hybridization probes, cross-hybridizing sequences have been detected in legumes closely related to soybean (members of the Leguminosae subfamily Papilionoideae), as well as in a distantly related legume not reported to be nodulated (subfamily Caesalpinioideae). With the same probes, the presence of cross-hybridizing sequences has also been detected in plants outside the Leguminosae, including two nitrogen-fixing non-legumes and one species which is not nodulated. These results suggest that the genes for oxygen-binding proteins may be more widely dispersed than previously thought.     

Leghemoglobin-like sequences in the DNA of four actinorhizal plants

Summary A cloned cDNA partial copy of a soybean leghemoglobin mRNA was used to probe genomic DNA of four species of actinorhizal plants. Southern blot hybridization revealed the presence of sequences with homology to the leghemoglobin probe in DNA from Alnus glutinosa, Casuarina glauca, Ceanothus americanus and Elaeagnus pungens. The hybridization patterns of the restriction fragments revealed some fragment size conservation between the DNA of soybean and the DNA of four actinorhizal plants which are taxonomically unrelated to soybean or to each other. The results presented here indicate that globin gene sequences are much more widely distributed in the plant kingdom than has previously been thought. Furthermore, if sequence conservation is actually as high as the restriction fragment patterns suggest, the evolution of the DNA surrounding the globin sequences has been highly constrained.     

Purification and characterization of soybean root nodule ferric leghemoglobin reductase

A ferric leghemoglobin reductase from the cytosol of soybean (Glycine max) root nodules was purified to homogeneity and partially characterized. The enzyme is a flavoprotein with flavin adenine dinucleotide as the prosthetic group and consists of two identical subunits, each having a molecular mass of 54 kilodaltons. The pure enzyme shows a high activity for ferric leghemoglobin reduction with NADH as the reductant in the absence of any exogenous mediators. The enzyme also exhibits NADH-dependent 2,6-dichloroindophenol reductase activity. A sequence of the first 50 N-terminal amino acids of the purified protein was obtained. Comparisons with known protein sequences have shown that the sequence of the ferric leghemoglobin reductase is highly related to those of the flavin-nucleotide disulfide oxido-reductases, especially dihydrolipoamide dehydrogenase of the pyruvate dehydrogenase complex.     

Nicotinate, nicotinamide, and the reactivity of leghemoglobin in soybean root nodules

Nicotinate has been postulated to interfere with the binding of O₂ to ferrous leghemoglobin in soybean (Glycine max) root nodules. For such a function, the levels of nicotinate in nodules must be sufficiently high to bind a significant amount of leghemoglobin. We have measured levels of nicotinate, nicotinamide, and leghemoglobin in soybean nodules from plants 34 to 73 days after planting in a glasshouse. On a per gram nodule fresh weight basis, levels between 10.4 and 21 nanomoles for nicotinate, 19.2 and 37.8 nanomoles for nicotinamide, and 170 to 280 nanomoles for leghemoglobin were measured. Even if all the nicotinate were bound to ferrous leghemoglobin, only 11% or less of the total leghemoglobin would be unavailable for binding O₂. Using the measured levels of nicotinate and a pH of 6.8 in the cytosol of presenescent soybean nodules, we estimate that the proportion of ferrous leghemoglobin bound to nicotinate in such nodules would be less than 1%. These levels of nicotinate are too low to interfere with the reaction between ferrous leghemoglobin and O₂ in soybean root nodules.     

Cloning of soybean leghemoglobin structural gene sequences synthesized in vitro.

Double-stranded soybean leghemoglobin DNA was synthesized from leghemoglobin mRNA isolated from soybean nodules. The dsDNA was inserted into the Bam H1 site of plasmid pBR322 using the poly-dAT-joiner method. A cloned DNA fragment of one recombinant plasmid was isolated and characterized by restriction endonuclease digestion. The restriction cleavage map and the DNA sequence of a selected part of the inserted DNA are in complete accordance with the amino-acid sequence of soybean leghemoglobin.     

Chromosomal arrangement of leghemoglobin genes in soybean.

A cluster of four different leghemoglobin (Lb) genes was isolated from AluI-HaeIII and EcoRI genomic libraries of soybean in a set of overlapping clones which together include 45 kilobases (kb) of contiguous DNA. These four genes, including a pseudogene, are present in the same orientation and are arranged in the order: 5'-Lba-Lbc1-Lb psi-Lbc3-3'. The intergenic regions average 2.5 kb. In addition to this main Lb locus, there are other Lb genes which do not appear to be contiguous to this locus. A sequence probably common to the 3' region of Lb loci was found flanking the Lbc3 gene. The 3' flanking region of the main Lb locus also contains a sequence that appears to be expressed more abundantly in root tissue. Another sequence which is primarily expressed in root and leaf is found 5' to two Lb loci. Overall, the main leghemoglobin locus is similar in structure to the mammalian globin gene loci.     

Overproduction in Escherichia coli and Characterization of a Soybean Ferric Leghemoglobin Reductase

We previously cloned and sequenced a cDNA encoding soybean ferric leghemoglobin reductase (FLbR), an enzyme postulated to play an important role in maintaining leghemoglobin in a functional ferrous state in nitrogen-fixing root nodules. This cDNA was sub-cloned into an expression plasmid, pTrcHis C, and overexpressed in Escherichia coli. The recombinant FLbR protein, which was purified by two steps of column chromatography, was catalytically active and fully functional. The recombinant FLbR cross-reacted with antisera raised against native FLbR purified from soybean root nodules. The recombinant FLbR, the native FLbR purified from soybean (Glycine max L.) root nodules, and dihydrolipoamide dehydrogenases from pig heart and yeast had similar but not identical ultraviolet-visible absorption and fluorescence spectra, cofactor binding, and kinetic properties. FLbR shared common structural features in the active site and prosthetic group binding sites with other pyridine nucleotide-disulfide oxidoreductases such as dihydrolipoamide dehydrogenases, but displayed different microenvironments for the prosthetic groups.     

Effect of nitrite upon leghemoglobin and interaction with nitrogen fixation

Nitrite (0.4 mM) added to soybean bacteroid preparations strongly inhibited C2H2 reduction. In the presence of leghemoglobin (0.1mM), a 3-fold enhancement of nitrogen fixation occurred but the inhibitory effect of nitrite was delayed. Spectra of leghemoglobin showed a rapid disappearance of the 574 nm and 541 nm peaks of oxyleghemoglobin the presence of nitrite. Concomitant oxidation of this hemoprotein gave ferric leghemoglobin as the single final product. High nitrite levels could depress nitrogen fixation both by inactivation of nitrogenase and by conversion of leghemoglobin into an inactive form. Nitrite present at low concentrations reacts with this hemoprotein and is then no longer able to penetrate into bacteroids.     

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.     

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.