Phylogeny of 12 species of genusGlycine Willd. reconstructed with internal transcribed region in nuclear ribosomal DNA

The ITS-Is of 24 accessions belong to 10 species of subgenusGlycine, and 2 species of subgenusSoja of genusGlycine were amplified, cloned and sequenced. According to the homology of the sequences, the phylogeny of the 24 accessions were reconstructed. The reconstructed dendrogram showed that there were some divergent genomic types found in the previously classified species, such asG. tomentella, G. canescens andG. tabacina, and they might be some cryptic species by morphologic analysis. Project supported by the Chinese Academy of Sciences     

Evaluation of Perennial Glycine Species for Response to Meloidogyne Incognita,Rotylenchulus Reniformis,and Pratylenchus Penetrans

Root-knot (Meloidogyne incognita (Kofoid & White) Chitwood), reniform (Rotylenchulus reniformis Lindford & Oliveira), and lesion nematodes (Pratylenchus penetrans (Cobb) Filipjev & Schuurmans Stekhoven) are plant-parasitic nematodes that feed on soybean (Glycine max (L.) Merr.) roots, limiting seed production. The availability of resistance in soybeans to these nematodes is limited. However, new sources of resistance can be discovered in wild relatives of agronomic crops. Perennial Glycine species, wild relatives to soybean, are a source of valuable genetic resources with the potential to improve disease resistance in soybean. To determine if these perennials have resistance against nematodes, 18 accessions of 10 perennial Glycine species were evaluated for their response to M. incognita and R. reniformis, and eight accessions of six perennial Glycine species were evaluated for their response to P. penetrans. Pot experiments were conducted for M. incognita and R. reniformis in a growth chamber and in vitro experiments were conducted for P. penetrans. We found both shared and distinct interactions along the resistance-susceptible continuum in response to the three plant-parasitic nematode species. Ten and 15 accessions were classified as resistant to M. incognita based on eggs per gram of root and gall index, respectively. Among them, G. tomentella plant introductions (PIs) 446983 and 339655 had a significantly lower gall index than the resistant soybean check cv. Forrest. Of three R. reniformis resistant accessions identified in this study, G. tomentella PI 441001 showed significantly greater resistance to R. reniformis than the resistant check cv. Forrest based on nematodes per gram of root. In contrast, no resistance to P. penetrans was recorded in any perennial Glycine species.     

Seed coat variation in Glycine Willd. subgenus Glycine (Leguminosae) by SEM

Seed of the genusGlycine Willd. typically exhibits a muriculate appearance resulting from adherence to the true seed coat of the perisperm or inner pod wall layer. Thickened cell walls of the perisperm superimpose a reticulate network on the seed coat, the type of network ranging from alveolate to stellate depending on the shape of the perisperm cells. Tubercles distributed at intervals give the seed its roughened appearance. Seed lacking an attached perisperm appears smooth and shiny. Seed morphology of 62 collections representing the six species of the subgenusGlycine is examined in detail to elucidate inter-and intraspecific variability. Seed perisperm pattern appears to be characteristic for each species, but there are exceptions.Glycine canescens F. J. Herrn. andG. clandestina Willd. seeds possess a reticulate network and tubercles of irregular shape, the perisperm appearing granular inG. clandestina. Seeds ofG. latrobeana (Meissn.) Benth. andG. tabacina (Labill.) Benth. lack a distinct network and have stellate tubercles; the perisperm is granular inG. latrobeana and some plants ofG. tabacina. A few collections ofG. clandestina approachG. tabacina in seed appearance.Glycine tomentella Hayata seeds exhibit a regularly alveolate arrangement, while those ofG. falcata Benth. lack a perisperm layer altogether. Variation in seed coat within a species can usually be linked to differences in chromosome number or some aspect of gross morphology. Diploid collections ofG. tomentella (2n = 40) exhibit recognizable differences in seed morphology compared with tetraploids (2n = 80), coincident with other striking dissimilarities in gross morphology. An incompletely attached perisperm is accompanied by aneuploidy in severalG. tomentella accessions, while other 78 and 38 chromosome aneuploids produce normal seeds.     

Phytogeny of 12 species of genus Glycine Willd. reconstructed with internal transcribed region in nuclear ribosomal DNA

The ITS-Is of 24 accessions belong to 10 species of subgenus Glycine, and 2 species of subgenus Soja of genus Glycine were amplified, cloned and sequenced. According to the homology of the sequences, the phy-logeny of the 24 accessions were reconstructed. The reconstructed dendrogram showed that there were some divergent genomic types found in the previously classified species, such as G . tomentella, G. canescens and G. tabacina, and they might be some cryptic species by morphologic analysis.     

Plant regeneration from cotyledon protoplasts of glycine canescens and G. clandestina

Protoplasts isolated enzymatically from cotyledons of wild Glycine species were cultured in agarose-solidified droplets of Kao protoplast culture medium. Incubation of droplets in liquid Kao medium mixed with a B5-based formulation resulted in protoplast-derived colonies. Subculture of tissues with liquid SC2 medium containing B5 salts and vitamins, 3% sucrose, 1.1 mg 1⁻¹ BAP and 0.005 mg 1⁻¹ IBA, followed by transfer to agar solidified SC2 medium, induced shoots in two accessions, G. clandestina G1231 and G. canescens G1171. Shoots elongated on agar B5-based medium with 0.2 mg 1⁻¹ BAP and 0.005 mg 1⁻¹ IBA(SC6), and rooted on hormone-free, half-strength semi-solid B5 medium.     

A REAPPRAISAL OF THE SUBGENUS GLYCINE

The genus Glycine Willd. is divided into three subgenera, Glycine Willd., Soja (Moench) F. J. Herm., and Bracteata Verdc. Six species are currently recognized in the subgenus Glycine: G. canescens F. J. Herm., G. clandestina Willd., G. falcata Benth., G. latrobeana (Meissn.) Benth., G. tabacina (Labill.) Benth., and G. tomentella Hayata. Distribution of the subgenus extends from south China to Tasmania and includes several Pacific islands. A collection of these species was examined cytologically and morphologically in an attempt to evaluate existing variability between and within taxa. Chromosome counts confirmed G. canescens, G. clandestina and G. falcata to be diploid with 2n = 40. Both tetraploids (2n = 80) and diploids were found in G. tabacina, the latter restricted to Australia. Glycine tomentella accessions were primarily tetraploid, but several collections from New South Wales, Australia, were found to be aneuploid with 78 chromosomes. One collection was aneuploid at the diploid level with 38 chromosomes. Meiosis appeared normal in the aneuploids with regular bivalent formation. Several accessions previously identified as G. tomentella were diploid. Seed of G. latrobeana was not available for analysis. Numerical techniques in the form of cluster analysis and principal components analysis were applied to morphological data on vegetative and inflorescence characters obtained from each collection. Numerical analysis grouped the accessions essentially according to current species delimitations with some exceptions. Glycine tabacina specimens from Taiwan approached G. clandestina in several characteristics. The diploid G. tomentella specimens formed a separate cluster and appeared morphologically distinct from the remaining taxa.     

Ribosomal gene variation in soybean (Glycine) and its relatives

Summary The genes encoding the 18S25S ribosomal RNA gene repeat in soybean (Glycine max) and its relatives in the genus Glycine are surveyed for variation in repeat length and restriction enzyme site locations. Within the wild species of subgenus Glycine, considerable differences in repeat size occur, with a maximum observed in G. falcata. Repeat length and site polymorphisms occur in several species, but within individual plants only single repeat types are observed. The rDNA of the cultivated soybean and its wild progenitor, G. soja are identical at the level of this study, and no variation is found in over 40 accessions of the two species. Data from rDNA mapping studies are congruent with those of previous biosystematic studies, and in some instances give evidence of divergences not seen with other approaches.     

Restriction fragment length polymorphism (RFLP) of wild perennial relatives of soybean

Summary Total DNA from callus tissue of 28 accessions representing seven wild perennial Glycine species was compared using recombinant genomic probes derived from G. max, the soybean. Using two probes, we show that this molecular approach both confirms and extends the model for the taxonomic relationships between the species derived from morphological and cytogenetic data, and that it provides clear evidence that RFLP analysis of genomic sequences has the potential for revealing the derivation of the member species of the wild perennial Glycine taxon. Although, in this preliminary report, the sample size for each species is small, it is clear that the greatest between-accession variation occurs in G. tabacina (B₂B₂) and G. clandestine (A₁A₁), suggesting that these may be the taxa from which further speciation occurred in the subgenus.     

Leaf flavonoids of Glycine subgenus Glycine in relation to systematics

A survey of leaf flavonoids and isoflavonoids in several taxa of the genus Glycne subgenus Glycine was undertaken to see if this would help interpret inter- and intraspecific relationships in the genus. C-Glycosylflavones based on apigenin were found in Glycine tomentelia, G. tabacina and G. falcata. Glycosides of quercetin and kaempferol were also detected in G. tabacina. In the cultivated soybean, G. max, and its wild annual relative, G. soja, only quercetin and kaempferol glycosides have been reported. Interspecific hybrids of Glycine species sometimes show additive flavonoid patterns in F₁ hybrid leaf tissue. All perennial wild species analysed including Glycine canescens and G. latifolia have the isoflavonoids genistin (genesitein 7-O-glucoside), daidzein and coumestrol in the leaves.     

Genomic relationships in the genus Glycine (Fabaceae: Phaseoleae): use of a monoclonal antibody to the soybean Bowman-Blrk inhibitor as a genome marker

We investigated the use of a monoclonal antibody (MAb 238) to the soybean Bowman-Birk inhibitor (BBI) to verify and understand the intergenomic relationships among the wild perennial Glycine species. Competitive enzyme linked immunosorbent assay and western blot screening studies revealed that the accessions of B-genome (G. latifolia, G. microphylla, and G. tabacina, 2n = 40) and C-genome (G. curvata and G. cyrtoloba) species did not contain the MAb 238 crossreactive proteins (BBI-nulls). By contrast, all the A-genome (G. argyrea, G. canescens, G. clandestina, and G. latrobeana), E-genome (G. tomentella, 2n = 38), and F-genome (G. falcata) species, G. arenaria (genome unknown), and the polyploid (2n = 78,80) G. tomentella accessions were BBI-positive. The D-genome G. tomentella (2n = 40) and tetraploid G. tabacina (2n = 80) contained both BBI-null and BBI-positive type accessions. Among the recently described species, G. hirticaulis (2n = 40), G. lactovirens, and G. pindanica contained the MAb 238 crossreactive proteins while G. albicans did not. Glycine hirticaulis, G. pindanica, and G. tomentella (2n = 38) displayed highly similar MAb 238 crossreactive isoelectric focusing banding patterns, indicating that they are genomically close to each other. Glycine hirticaulis was found to have both diploid (2n = 40) and tetraploid (2n = 80) cytotypes. We demonstrated that the MAb 238 was specific to the trypsin inhibitor domain of the BBI. The MAb 238 clearly reflected all the previously established relationships in the genus Glycine, validating its use as a genome marker.     

A single nuclear locus phylogeny of soybean based on DNA sequence

Soybean [Glycine max (L.) Merr.] evolution was examined by sequencing portions of the restriction fragment length polymorphism (RFLP) locus A-199a of 21 taxa from the Glycininae and 1 from the Phaseoleae. Four hundred nucleotides were determined in each, aligned, and then compared for these taxa. Within the annual soybean subgenus (Soja), the four accessions differed at as many as 2.2% of the nucleotides. Among 13 perennial soybean species (subgenus Glycine), nucleotide variation ranged from 1.7% to 8.4%. The nucleotide difference between the two soybean subgenera was 3.0–7.0%. Nucleotide variation between the genus Glycine and the related genera of Neonotonia, Amphicarpa, Teramnus, and Phaseolus ranged from 8.2% to 16.4%. In addition to nucleotide substitutions, insertions/deletions (indels) differences were also observed and were consistent with nucleotide-based analysis. Cladistic analysis of the A-199a sequences was performed using Wagner parsimony to construct a soybean phylogeny. Sixteen equally parsimonious trees were produced from these data. The trees were 246 steps in length with a consistency index of 0.78. Indels distribution upon the consensus topology revealed a pattern congruent with the nucleotide-based phylogeny. The current taxonomic status of the soybean subgenera and the related genera of Neonotonia, Amphicarpa, and Teramnus were well-supported and appear monophyletic in this analysis. Homoplasy within the subgenus Glycine led to a lack of resolved topology for many of these 13 taxa. However, the Glycine clade topology was consistent with phylogenies proposed using crossing experiments and cpDNA RFLPs. These genera were arranged from ancestral to derived as: Teramnus, Amphicarpa, Neonotonia, and Glycine when Phaseolus vulgaris was used as an outgroup.     

Restriction fragment length polymorphism diversity in soybean

Summary Fifty-eight soybean accessions from the genus Glycine, subgenus Soja, were surveyed with 17 restriction fragment length polymorphism (RFLP) genetic markers to assess the level of molecular diversity and to evaluate the usefulness of previously identified RFLP markers. In general, only low levels of molecular diversity were observed: 2 of the 17 markers exhibited three alleles per locus, whereas all others had only two alleles. Thirty-five percent of the markers had rare alleles present in only 1 or 2 of the 58 accessions. Molecular diversity was least among cultivated soybeans and greatest between accessions of different soybean species such as Glycine max (L.) Merr. and G. soja Sieb. and Zucc. Principal component analysis was useful in reducing the multidimensional genotype data set and identifying genetic relationships.     

Systematic Status of the Glycine tomentella and G. tabacina Species Complexes (Fabaceae) Based on ITS Sequences of Nuclear Ribosomal DNA

Glycine was reconstructed based on nucleotide sequences of the internal transcribed spacer (ITS) region of the nuclear ribosomal DNA to examine the systematic status of the G. tomentella and G. tabacina species complexes. Rooted at the subgenus Soja (2 species, 7 accessions), parsimony analysis was conducted for 17 species (31 accessions) of the subgenus Glycine, including 9 and 6 populations of G. tomentella s.l. and G. tabacina s.l., respectively. The nrlTS phytogeny indicated polyphyly of G. tomentella s.l. as well as G. tabacina s.l. In the G. tomentella species complex, larger legumes, narrower leaflets, and deflexed indumentum hairs differentiated G. dolichocarpa from G. tomentella s.s. The tetraploid G. dolichocarpa (2n=80) and aneuploid G. tomentella (2n= 38) represented independent lineages from another clade of the remaining diploid (2n=40) and tetraploid species with a DD genome type. Tetraploid G. tabacina (2n=80) was closely related to G. dolichocarpa instead of the diploid G. tabacina (2n=40) with a BB genome type. The nrlTS phytogeny suggested allopolyploidy of G. dolichocarpa and of the tetraploid G. tabacina, both of which possibly share a common parental species with an AA genome type. Their phylogenetic affinity also indicated biased inheritance of the nrDNA ITS and a possible dominant role of the AA genome. Phylogenetically, G. dolichocarpa and allotetraploid G. tabacina should be recognized as distinct species. Received 12 February 2001/ Accepted in revised form 17 August 2001     

5S ribosomal gene variation in the soybean and its progenitor

Summary The soybean, Glycine max and its wild progenitor, Glycine soja, have been surveyed for repeat length variation for the nuclearly encoded 5S ribosomal RNA genes. There is little variation among the 33 accessions assayed, with a common repeat length of 345 bases being typical of both taxa. A 334 base size variant was encountered in individuals from two populations of G. soja from China. The low level of variability is in marked contrast to the variation observed within and between the species of the perennial subgenus Glycine.     

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.     

Serological comparisons of seed proteins of some representatives of the genusAllium

Results obtained by comparison of similarity of seed protein spectra of 15 species of the genusAllium (in 22 samples) by means of immunochemical methods more or less correspond to the contemporary division of this genus. Species belonging to the sectionCepa (according to Vvedenskiy) andPhyllodolon have very similar spectra, which suggests that they either should be allocated to one sectionCepa or to two subsections (Cepa andPhyllodolon). Species belonging to the subgenusRhizirideum considerably differ in seed proteins. The investigated species of the subgenusMelanocrommyum show the most distinct spectrum of all the other analyzed representatives, less marked differences were found in the case of the representatives of the subgenusAllium.     

Differentiation of two hemp nettle species (<Emphasis Type="Italic">Galeopsis bifida</Emphasis> Boenn. and <Emphasis Type="Italic">G. tetrahit</Emphasis> L.) inferred from morphological characters and DNA markers

Two species of the genus Galeopsis L., G. tetrahit L. and G. bifida Boenn. (family Lamiaceae), are problematic to distinguish often wrongly recognized, and treated by some taxonomists as a single species. Morphological diagnostical characters of these species are variable and partly overlap. Species independence of G. tetrahit and G. bifida was evaluated and their diagnostic characters verified using ISSR and RAPD markers. A total of 57 ISSR and 28 RAPD fragments were obtained providing distinct subdivision of the accessions examined into two groups. Analysis of molecular data using the neighbor-joining method showed that the accessions studied fell into two clades in the same way as demonstrated by the analysis of 20 morphological characters using single linkage method. These results suggest that G. tetrahit and G. bifida are distinct species. The morphological characters were found to be more variable compared to the molecular markers, although the combined of these characters provided differentiation of the species.     

Wood and stem anatomy of Misodendraceae: Systematic and ecological conclusions

The wood anatomy of the monogeneric South American family of epiparasites, Misodendraceae, contains numerous peculiarities. In the four species of the subgenusAngelopogon the cambium is virtually inactive in ray areas. In three of those species, a second ring of fascicular areas (“bundles”) forms in the pith only well after the initiation of the outer ring. Fibers occur in fascicular areas in paired strands (sheathed by crystalliferous parenchyma), as the background tissue, or may be absent, depending on the species; rays consist wholly of fibers or are composed of thin-walled cells, depending on the species. In the subgenusMisodendron (seven species), the cambium is active in fascicular areas and interfascicular areas equally; it contributes fibers to potential ray areas and to fascicular areas. If occurrence of these fibers is a criterion, the subgenusMisodendron may be considered rayless (except forM. gayanum, in which fibers occur only in rays). Growth rings are present in all species. Vessel elements are extremely short and narrow, numerous per mm², and pores are markedly grouped; all these are highly xeromorphic features appropriate to a parasite in an extreme climatic zone. In subgenusAngelopogon, lateral wall pitting of vessels consists of laterally much-widened pits, an appearance falsely resembling helical bands of primary xylem vessels. In subgenusMisodendron, pits on vessels are alternate or scalariformlike. The difference in vessel pitting between the two subgenera may relate to wood parenchymatization. Perforation plates are simple. Pits have wide apertures inM. angulatum andM. recurvum. Pith is sclerenchymatous in subgenusMisodendron but composed of thin-walled cells in which vessel strands occur in subgenusAngelopogon. Because of the numerous specific characteristics which correspond to the taxonomic system for the family, a key to species based on wood anatomy is given. New names must be employed for both subgenera for nomenclatural reasons; thus the combinationM. subgenusAngelopogon (=M. subgenusEumyzodendron) is coined. Wood anatomy of Misodendraceae is similar to that ofPsittacanthus and other Loranthaceae, disregarding the unique features found inMisodendron.     

Polymorphism of the IPK1 gene among members of the genus Glycine

The structural polymorphism of the IPK1 gene involved in the biosynthesis of phytic acid was studied in 30 samples from three species of the genus Glycine (G. max, G. soja, and G. gracilis). Single nucleotide polymorphisms in the sequences of the first and the second introns of the IPK1 gene were found, differences in the length of microsatellite loci located in intron 2 were demonstrated, and a total of six polymorphic variants were identified. Data on the distribution of the identified alleles among the samples from the working set and the analysis and discussion of these data are given.