Adventitious roots inGlycine subg.Glycine (Leguminosae): Morphological and taxonomic indicators of the B genome

Adventitious roots were observed on 3 wild perennialGlycine species, in short-poddedG. clandestina, G. latifolia and mostG. tabacina (2x, 4x, 6x), while other species lacked adventitious roots. This suggests that the adventitious roots trait is associated with B genome species. Intra- and interspecific F₁ hybrids reveal that adventitious roots apparently are inherited recessively. The presence of adventitious roots or short-poddedG. clandestina, coupled with infertility with longer-poddedG. clandestina, and enzymatic and leaflet morphology differences between the twoG. clandestina subgroups, supports segregation of the short-podded form as a separate taxon.     

Intersubgeneric hybridization of soybeans with a wild perennial species,Glycine clandestina Wendl

Summary The exploitation of wild perennial species of subgenus Glycine has been formidable in soybean breeding programs because of extremely poor crossability and an early pod abortion. The combination of gibberellic acid application to hybridized gynoecia and improved seed culture media formulations resulted in a new intersubgeneric hybrid between Glycine max (L.) Merr. (2n=40) and G. clandestina Wendt. (2n=40). Of the 31 immature seeds cultured, 1 regenerated 21 plants through organogenesis while the remaining 30 failed to germinate. All the regenerated plants were similar morphologically, carried expected 2n=40, possessed hybrid isozyme patterns and were completely sterile. Complete absence of chromosome pairing was observed in 40.9% sporocytes. The occurrence of 1 to 6 loosely paired rod bivalents suggests some possibilities of allosyndetic pairing. Hybrid plants set aborted pods after backcrossing to G. max.     

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.     

The genomic relationship between Glycine max (L.) Merr. and G. soja Sieb. and Zucc. as revealed by pachytene chromosome analysis

Summary This study was conducted with the objective of determining the genomic relationship between cultivated soybean (Glycine max) and wild soybean (G. soja) of the subgenus Soja, genus Glycine. Observations on cross-ability rate, hybrid viability, meiotic chromosome pairing, and pollen fertility in F ₁ hybrids of G. max × G. soja and reciprocals elucidated that both species hybridized readily and set mature putative hybrid pods, generated vigorous F₁ plants, had a majority of sporocytes that showed 18II + 1IV chromosome association at diakinesis and metaphase I, and had a pollen fertility that ranged from 49.2% to 53.3%. A quadrivalent was often associated with the nucleolus, suggesting that one of the chromosomes involved in the interchange is a satellited chromosome. Thus, G. max and G. soja genetic stocks used in this study have been differentiated by a reciprocal translocation. Pachytene analysis of F₁ hybrids helped construct chromosome maps based on chromosome length and euchromatin and heterochromatin distribution. Chromosomes were numbered in descending order of 1–20. Pachytene chromosomes in soybean showed heterochromatin distribution on either side of the centromeres. Pachytene analysis revealed small structural differences for chromosomes 6 and 11 which were not detected at diakinesis and metaphase I. This study suggests that G. max and G. soja carry similar genomes and validates the previously assigned genome symbol GG.Research supported in part by the Illinois Agricultural Experiment Station and U.S. Department of Agriculture Competitive Research Grant (85-CRCR-1-1616)     

Distribution of rDNA loci in the genus Glycine Willd.

The objective of this study was to examine the distribution of rDNA loci in the genus Glycine Willd. by fluorescent in situ hybridization (FISH) using the internal transcribed spacer (ITS) region of nuclear ribosomal DNA as a probe. The hybridized rDNA probe produced two distinct yellow signals on reddish chromosomes representing two NORs in 16 diploid (2n=40) species. Aneudiploid (2n=38) and aneutetraploid (2n=78) Glycine tomentella Hayata also exhibited two rDNA sites. However, the probe hybridized with four chromosomes as evidenced by four signals in two diploid species (Glycine curvata Tind. and Glycine cyrtoloba Tind.) and tetraploid (2n=80) G. tabacina (Labill.) Benth. and G. tomentella. Synthesized amphiploids (2n=80) of Glycine canescens F. J. Herm. (2n=40) and the 40-chromosome G. tomentella also showed four signals. This study demonstrates that the distribution of the rDNA gene in the 16 Glycine species studied is highly conserved and that silence of the rDNA locus may be attributed to amphiplasty during diploidization and speciation. Received: 10 October 2000 / Accepted: 6 December 2000     

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     

HYBRIDIZATION IN THE GENUS GLYCINE SUBGENUS GLYCINE WILLD. (LEGUMINOSAE,PAPILIONOIDEAE)

The genus Glycine is composed of two subgenera, Glycine and Soja. Soja includes the cultivated soybean, G. max, and its wild annual counterpart G. soja, while Glycine includes seven wild perennial species. Hybridization was carried out within and between wild perennial species of the subgenus Glycine. The success rate (pods set/flowers crossed) was 11% for intraspecific and 8% for interspecific crosses. A total of 220 F₁ hybrids was examined morphologically and cytologically where possible. Hybrids within G. canescens (2n = 40) and G. latifolia (2n = 40) were fertile as expected. Glycine clandestina (2n = 40) was morphologically separable into at least three groups, which produced fertile hybrids within each group. One cross between two groups gave vegetatively vigorous but sterile hybrids. The majority of crosses within G. tabacina (2n = 80) were fertile, except that extremely narrow-leaved forms gave sterile hybrids in combination with more usual forms. Sterility was also encountered in G. tomentella when aneuploids (2n = 78) from New South Wales, Australia, were crossed with tetraploids (2n = 80) from either Queensland, Australia, or Taiwan; crosses between the latter two populations resulted in seedling lethality. Cytological behavior of sterile hybrids followed a similar pattern, whether at the diploid or tetraploid level. The frequency of chromosome pairing was approximately half that expected if genomes showed full pairing homology. Bivalent disjunction at anaphase I was usually followed by precocious division of the majority of univalents. Telophase I and II were characterized by lagging chromosomes and micronuclei, so that resulting pollen was misshapen and sterile. Chromosome pairing data from sterile intraspecific hybrids at the tetraploid level may indicate a polyphyletic origin of tetraploids, whereby different diploid populations were involved in their formation. Similarly, chromosome pairing in sterile intraspecific diploid hybrids may indicate that the various diploid groups arose independently of one another. Both 40- and 80-chromosome forms are fully diploidized, however, and if they are of ancient origin, divergence since that time could have resulted in the chromosomal differentiation which becomes apparent when intraspecific hybridization is effected. Diploid (2n = 40) interspecific hybrids G. falcata × G. canescens, and G. falcata × G. tomentella grew poorly and did not reach flowering stage. Diploid (2n = 40) crosses between G. latifolia and G. tomentella produced inviable seedlings. Tetraploid (2n = 80) hybrids between G. tomentella and G. tabacina were vegetatively vigorous but sterile owing to low chromosome pairing at meiosis, indicating little pairing homology between the two species. Diploid hybrids between G. canescens and G. clandestina, however, showed almost complete chromosome pairing at diakinesis and partial fertility. Although morphologically distinct, these two species have not diverged sufficiently to prevent hybridization and possible gene exchange through recombination. Self compatibility, perennial growth habit, and geographic isolation have favored divergence among Glycine populations to the point that gene exchange appears no longer possible in many cases. Internal isolating mechanisms have been shown to operate at various levels of plant development from hybrid lethality at seedling stage, to failure of seed-set in sterile but vegetatively vigorous hybrids.     

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.     

Fertile progeny of a hybridization between soybean [Glycine max (L.) Merr.] and G. tomentella Hayata

Summary A colchicine-doubled F₁ hybrid (2n=118) of a cross between PI 360841 (Glycine max) (2n=40) x PI 378708 (G. tomentella) (2n=78), propagated by shoot cuttings since January 1984, produced approximately 100 F₂ seed during October 1988. One-fourth of the F₂ plants or their F₃ progeny have been analyzed for chromosome number, pollen viability, pubescence tip morphology, seed coat color, and isoenzyme variation. Without exception, all plants evaluated possessed the chromosome number of the G. max parent (2n=40). Most F₂ plants demonstrated a high level of fertility, although 2 of 24 plants had low pollen viability and had large numbers of fleshy pods. One F₂ plant possessed sharp pubescence tip morphology, whereas all others were blunt-tipped. All evaluated F₂ and F₃ plants expressed the malate dehydrogenase and diaphorase isoenzyme patterns of the G. max parent and the endopeptidase isoenzyme pattern of the G. tomentella parent. Mobility variants were observed among progeny for the isoenzymes phosphoglucomutase, aconitase, and phosphoglucoisomerase. This study suggests that the G. Tomentella chromosome complement has been eliminated after genetic exchange and/or modification has taken place between the genomes.Journal Paper No. J-13776 of the Iowa Agriculture and Home Economics Experiment Station, Ames, IA, USA, Project 2763     

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.     

Genomic relationships among diploid wild perennial species of the genus Glycine Willd. subgenus Glycine revealed by crossability,meiotic chromosome pairing and seed protein electrophoresis

Summary The nomenclature of species beased on classical taxonomy can be verified from cytogenetic, biochemical and molecular studies. The objective of the study presented here was to provide further information on genomic affinities among species of the genus Glycine Willd. based on crossability, meiotic chromosome pairing of F₁ hybrids and seed-protein profiles. Meiotic chromosome pairing data revealed no genomic similarity between G. microphylla (BB) and G. falcata (FF), nor between G. tomentella (2n = 38; EE) and G. microphylla (BB). Despite morphological similarity between G. cyrtoloba (CC) and G. curvata no F₁ hybrid was obtained, although 748 flowers were pollinated. The seed-protein banding patterns showed G. latrobeana to be closer to the A-genome species than to others. Based on these results we assign genome symbol A₃A₃ to G. latrobeana. Likewise, G. curvata was allotted the designation C₁C₁ because the seed-protein banding patterns of G. curvata and G. cyrtoloba are similar. The genome designations of Glycine species based on cytogenetic investigations may be further extended by results obtained from biochemical and molecular approaches.Research supported in part by the Illinois Agricultural Experiment Station and US Department of Agriculture Competitive Research Grant 88-37231-4100     

Genetic structure of Glycine canescens,a perennial relative of soybean

Summary Allozyme variation as detected by starch gel electrophoresis was used to assess the extent and spatial organization of genetic variation across the entire range of Glycine canescens sensu lato. Eleven enzyme systems were assayed in 116 accessions of this taxon and 102 alleles were detected at a total of 31 loci. Eighty-one percent of loci were polymorphic. Most of this variation occurred between and very little within accessions. Three major groupings were detected. These groupings (groups 1, 2, and 3) also differed with respect to mean seed size and their geographic distribution. A further ten accessions stood out from these distinct groups. These accessions were most closely related to group 3 but were variable among themselves. In general, they were collected from highly dissected terrain, often in the remote interior of the continent. A final group of 18 problematic accessions (group X), originally tentatively identified as G. canescens on morphological grounds, was shown to be isozymically distinct from this species and was reclassified as one form of the polytypic species G. clandestina.     

Glycine mosaic virus: a comovirus from Australian native Glycine species

Two strains of a virus designated Glycine mosaic virus (GMV) were found in Glycine clandestina and G. tabacina, legumes indigenous to Australia and the western Pacific region. When transmitted by sap inoculation, GMV infected mostly leguminous species, and caused mosaic and mottling symptoms. The virus was not found naturally in soybean G. max, but it infected all of the 21 cultivars tested. GMV has isometric particles of c. 28 nm diameter, and produces three components with sedimentation coefficients of 60 S (top), 103 S (middle), and 130 S (bottom). Both middle and bottom components are required for infectivity. The virions contain two major proteins with molecular weights of c. 21 500 and 42 000. GMV produces large aggregates of particles in the cytoplasm of the mesophyll cells of pea Pisum sativum, and also induces amorphous membrane-bound bodies and cytoplasmic vesicles. The type strain (from New South Wales) reacts with antisera to Echtes Ackerbohnenmosaik, broad bean stain, and a Californian isolate of squash mosaic virus. The GW strain (from Queensland) reacts with all of the latter antisera, as well as with antisera to cowpea mosaic virus (Sb and Ark strains), bean pod mottle, and red clover mottle viruses, and is serologically related to, but not identical with, the type strain. These properties clearly establish GMV as a new member of the comovirus group.     

Plant regeneration from leaf explants of Glycine clandestina Wendl

Fully fertile plants with the expected chromosome number 2n=40 were regenerated from excised leaf sections of Glycine clandestina. Shoots formed directly on the explants through organogenesis. Utilizing the same media and procedures fully fertile plants were also regenerated from cotyledon and hypocotyl tissue of the same G. clandestina accession. We were not successful in regenerating plants from root tissue of G. clandestina.Abbreviations 6-BA 6-Benzyladenine - FAA Formalin - NAA Naphthalenacetic acid - IAA Indoleacetic acid - Na₂EDTA Disodium salt Ethylenediamine tetraacetic acid - Fe-NaEDTA Ferric-Sodium salt Ethylenediamine tetraacetic acid     

Variation in the DNA Content of Glycine Species

Nuclei were isolated from cotyledons of a range of accessionsfrom 14 species of Glycine. These were stained with ethidiumbromide and the relative fluorescence for each genotype wasmeasured by flow cytometry. The DNA content was estimated bycomparison of relative fluorescence with that from nuclei fromseedling leaves of Allium cepa, whose DNA content has been calculatedpreviously by chemical assay. The 4C amounts for diploid Glycineranged from 3.80 to 6.59 pg. Two groups of diploid species appearedfrom the analysis. The first consisted of species with amountsranging from 3.80 to 5.16 pg and included G. canescens (AA),G. argyrea (A₁ A₁), G. clandestina (A²A²), G. microphylla(BB),G. latifolia (B₁B₁), G. tabacina 2n=40 (B²B²), G. tomentella2n=38 (EE) and 2n=40 (DD), G. max and G. soja (GG), G. arenariaand G. latrobeana. A second group had higher DNA contents rangingfrom 5.27 to 6.59 pg, and consisted of G. curvata, G. cyrtoloba(CC), and G. falcata (FF). The polyploid species, G. tabacina2n=80 (AABB, BBB¹B¹), G. tomentella 2n=78 and 2n=80 (AAEE andDDEE, respectively) contained amounts approximating to the sumsof the respective parental diploid species thought to have givenrise to these allotetraploids. Intraspecific variation was detectedin the DNA content of G. canescens. Within the overall distributionof DNA amounts found in A genome species, each genome containeda range of DNA contents specific to that species. This phenomenonwas also detected amongst B genome species.     

Wide hybridization between Brazilian soybean cultivars and wild perennial relatives

Employing a different culture strategy, we obtained a greatly improved frequency of embryo rescue in intersubgeneric soybean hybrids. Successful crosses were obtained in 31 different genotype combinations between nine Brazilian soybean lines as the female parents and 12 accessions from Glycine canescens, G. microphylla, G. tabacina and G. tomentella. The hybrid pod retention rate dropped to about 10% during the first 8 days after pollination and stayed largely unchanged up to the 20th day. Immature harvested seeds fell into three size groups: Group 1, smaller than 1.3 mm (mostly empty seed coats); Group 2, 1.9–5.0 mm; Group 3, larger than 5 mm (from selfing). A total of 90 putative hybrid embryos were rescued using a highly enriched B5 medium to nourish the newly dissected embryos. The growing embryos were then placed in a high osmotic, modified B5 medium to induce maturation and dormancy. Schenk and Hildebrandt medium was used to germinate the dormant, partially dehydrated, physiologically mature embryos. Approximately 37% of the rescued embryos developed into plantlets in vitro, and approximately 8% grew into mature plants in the greenhouse. Morphological, cytological and isoenzyme patterns confirmed the hybrid status of all seven mature plants, all of which were generated using G. tomentella G 9943 as the paternal parent. It was observed that all soybean lines crossed with G 9943 were capable of producing mature hybrid plants. There was no correlation between the initial size of Group 2 seeds and plant survival rate. The hybrids were cloned by grafting and treated with colchicine. One of the treated plants displayed chromosome doubling.     

Spontaneous hybridization between a male-sterile oilseed rape and two weeds

Spontaneous interspecific hybrids were produced under natural conditions (pollination by wind and bees) between a male-sterile cybrid Brassica napus (AACC, 2n = 38) and two weeds Brassica adpressa (AdAd, 2n = 14) and Raphanus raphanistrum (RrRr, 2n = 18). After characterization by chromosome counts and isozyme analyses, we observed 512 and 3 734 inter-specific seeds per m² for the B. napus-B. adpressa and B. napus-R. raphanistrum trials respectively. Most of the hybrids studied had the expected triploid structure (ACX). In order to quantify the frequency of allosyndesis between the genomes involved in the hybrids, their meiotic behavior was compared to a haploid of B. napus (AC). For the B. napus-B. adpressa hybrids, we concluded that probably no allosyndesis occurred between the two parental genomes, and that genetic factors regulating homoeologous chromosome pairing were carried by the B. adpressa genome. For the B. napus-R. raphanistrum hybrids, high chromosome pairing and the presence of multivalents (in 9.16% of the pollen mother cells) indicate that recombination is possible between chromosomes of different genomes. Pollen fertility of the hybrids ranged from 0 to 30%. Blackleg inoculation tests were performed on the three parental species and on the interspecific hybrids. BC₁ production with the weeds and with rapeseed was attempted. Results are discussed in regard to the risk assessment of transgenic rapeseed cultivation, F₁ hybrid rapeseed variety production, and rapeseed improvement.     

Wide hybridization in Brassica

Summary Crosses were made to obtain interspecific hybrids between B. fruticulosa (wild species , 2n = 16) × B. campestris (cultivar , 2n = 20). Although many pollen grains germinated and their tubes entered the style, only about 30% of the ovules received pollen tubes. Fertilized ovules aborted at various stages of development. A few hybrid seeds resulted from hand pollinations in the field, and they showed poor germination and seedling establishment. The in vitro culture of ovaries, ovules, and seeds increased the frequency of obtaining hybrid seeds and plants: the most effective method was ovary culture followed by ovule culture. The hybrid nature of the plants was confirmed through morphological, cytological, and electrophoretic studies. A meiotic analysis of F₁ hybrids (2n = 18) showed that they had 0–5 bivalents and were completely pollen sterile. Electrophoretic analysis of leaf esterases and acid phosphatases of F₁ hybrids revealed bands derived from each parent. Induced amphidiploids of F₁ hybrids contained mostly bivalents, and had about 50% fertile pollen.     

Phylogenetic relationships of the chloroplast genomes in the genus Glycine inferred from four intergenic spacer sequences

The nucleotide sequences of four intergenic spacer regions of chloroplast DNA, atpB-rbcL, trnS-trnG, rps11-rpl36, and rps3-rpl16, were analyzed in the genus Glycine. Phylogenetic analysis based on the sequence data using Neonotonia wightii as the outgroup generated trees supporting the classification of two subgenera, Soja and Glycine, and three plastome groups in the subgenus Glycine. The results were consistent with the presence of diversified chloroplast genomes within tetraploid plants of G. tabacina and G. tomentella, as well as with a close relationship between G. tomentella and G. dolichocarpa that had been suggested based on morphological analyses. Little sequence variation was found in the subgenus Soja, suggesting that G. soja rapidly expanded its distribution in East Asia. The analysis also showed that the differentiation into three plastome groups in the subgenus Glycine occurred in the early stages of its evolution, after the two subgenera diverged.     

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.