Identification of genome constitution of Oryza malampuzhaensis, O. minuta,and O. punctata by multicolor genomic in situ hybridization

Multicolor genomic in situ hybridization (McGISH) was applied to identify the genomic constitution of three tetraploid species (2n = 4x = 48) in the Oryza officinalis complex of the genus Oryza, i.e. Oryza malam-puzhaensis, Oryza minuta, and Oryza punctata. The genomic probes used were from three diploids, i.e. Oryza officinalis (CC), Oryza eichingeri (CC) and Oryza punctata (BB), respectively. The results indicated that all three tetraploids are allotetraploid with the genomic constitution of BBCC, and among them the genome constitution of O. malampuzhaensis was verified for the first time. Restoration of the independent taxonomic status of O. malampuzhaensis is suggested. One pair of satellite chromosomes belonging to the B genome was identified in O. malampuzhaensis, but no such satellite chromosomes were found in either O. minuta or the tetraploid O. punctata. The average chromosome length of the C genome was found to be slightly larger than that of the B-genome chromosomes of O. minuta, but not in the tetraploids O. punctata and O. malampuzhaensis. McGISH also revealed that the B genome of O. minuta and the B genome of diploid O. punctata showed clear differentiation from each other. Therefore, the suggestion was proposed that the B genome in diploid O. punctata was not the source of the B genome of O. minuta. The present results proved that multicolor GISH had high resolution in identifying the genomic constitution of polyploid Oryza species. Received: 14 February 2000 / Accepted: 13 November 2000     

Polymorphism and phylogenetic relationships among species in the genus Oryza as determined by analysis of nuclear RFLPs

Summary Ninety-three accessions representing 21 species from the genus Oryza were examined for restriction fragment length polymorphism. The majority (78%) of the accessions, for which five individuals were tested, were found to be monomorphic. Most of the polymorphic accessions segregated for only one or two probes and appeared to be mixed pure lines. For most of the Oryza species tested, the majority of the genetic variation (83%) was found between accessions from different species with only 17% between accessions within species. Tetraploid species were found to have, on average, nearly 50% more alleles (unique fragments) per individual than diploid species reflecting the allopolyploid nature of their genomes.Classification of Oryza species based on RFLPs matches remarkably well previous classifications based on morphology, hybridization and isozymes. In the current study, four species complexes could be identified corresponding to those proposed by Vaughan (1989): the O. ridleyi complex, the O. meyeriana complex, the O. officinalis complex and the O. sativa complex. Within the O. sativa complex, accessions of O. rufipogon from Asia (including O. nivara) and perennial forms of O. rufipogon from Australia clustered together with accessions of cultivated rice O. sativa. Surprisingly, indica and japonica (the two major subspecies of cultivated rice) showed closer affinity with different accessions of wild O. Rufipogon than to each other, supporting a hypothesis of independent domestication events for these two types of rice. Australian annual wild rice O. meridionalis (previously classified as O. rufipogon) was clearly distinct from all other O. rufipogon accessions supporting its recent reclassification as O. meridionalis (Ng et al. 1981). Using genetic relatedness as a criterion, it was possible to identify the closest living diploid relatives of the currently known tetraploid rice species. Results from these analyses suggest that BBCC tetraploids (O. malampuzhaensis, O. punctata and O. minuta) are either of independent origins or have experienced introgression from sympatric C-genome diploid rice species. CCDD tetraploid species from America (O. latifolia, O. alta and O. grandiglumis) may be of ancient origin since they show a closer affinity to each other than to any known diploid species. Their closest living diploid relatives belong to C genome (O. eichingeri) and E genome (O. Australiensis) species. Comparisons among African, Australian and Asian rice species suggest that Oryza species in Africa and Australia are of polyphyletic origin and probably migrated to these regions at different times in the past.Finally, on a practical note, the majority of probes used in this study detected polymorphism between cultivated rice and its wild relatives. Hence, RFLP markers and maps based on such markers are likely to be very useful in monitoring and aiding introgression of genes from wild rice into modern cultivars.     

Phylogeny and species delimitation of the C‐genome diploid species in Oryza

Abstract The diploid Oryza species with C‐genome type possesses abundant genes useful for rice improvement and provides parental donors of many tetraploid species with the C‐genome (BBCC, CCDD). Despite extensive studies, the phylogenetic relationship among the C‐genome species and the taxonomic status of some taxa remain controversial. In this study, we reconstructed the phylogeny of three diploid species with C‐genome (Oryza officinalis, O. rhizomatis, and O. eichingeri) based on sequences of 68 nuclear single‐copy genes. We obtained a fully resolved phylogenetic tree, clearly indicating the sister relationship of O. officinalis and O. rhizomatis, with O. eichingeri being the more divergent lineage. Incongruent phylogenies of the C‐genome species found in previous studies might result from lineage sorting, introgression/hybridization and limited number of genetic markers used. We further applied a recently developed Bayesian species delimitation method to investigate the species status of the Sri Lankan and African O. eichingeri. Analyses of two datasets (68 genes with a single sample, and 10 genes with multiple samples) support the distinct species status of the Sri Lankan and African O. eichingeri. In addition, we evaluated the impact of the number of sampled individuals and loci on species delimitation. Our simulation suggests that sampling multiple individuals is critically important for species delimitation, particularly for closely related species.     

Molecular diversity in the primary and secondary gene pools of genus Oryza

The objective of the present investigation was to assess the genetic relationships among the species of Oryza that belong to the primary gene pool (sativa complex) and the secondary gene pool (officinalis complex) using three marker systems such as RAPDs, ISSRs and SSRs. A total of 432 clear and reproducible bands were amplified from 18 RAPD primers; 113 bands were detected from 8 ISSR primers and 78 alleles were found to be amplified across the Oryza species from 13 SSR primer pairs. All the three dendrograms constructed, using UPGMA from the genetic similarity matrices based on the three marker data sets, were similar in their groupings. In all the three trees, two accessions of Oryza sativa formed an exclusive group indicating its genomic differentiation from its wild ancestors through the process of domestication. Distinctness between the wild species of the sativa and officinalis complexes was evident in all the trees derived from different markers. The groupings obtained among the species of the sativa complex were in perfect concordance with the species relationships established through classical crossability and cytogenetic analysis. This study has brought out some information on the species relationship between the diploid and tetraploid genomes of the officinalis complex possessing BB, CC and DD genomes. The higher level of similarity observed between the species possessing C and D genomes supports the view of many earlier authors that these two genomes might have originated from a single hybridization event. The results of this study also show that the diploid species possessing C genomes such as Oryza officinalis, Oryza rhizomatis and Oryza eichingeri are distinct from their allotetraploid counterparts possessing BBCC and CCDD genomes indicating a wider genomic differentiation in their evolutionary process.     

Differentiation and inter-genomic relationships among C, E and D genomes in the Oryzaofficinalis complex (Poaceae) as revealed by multicolor genomic in situ hybridization

The multicolor genomic in situ hybridization (McGISH) method was used to study differentiation and relationships among the C, D and E genomes in the officinalis complex of the genus Oryza. The chromosomes of Oryza alta (CCDD genomes) were hybridized with labelled probes of the C genome (from diploid Oryza eichingeri and Oryza officinalis) and the E genome (from Oryza australiensis) simultaneously. By adjusting the post-hybri- dization washing stringency in a gradual series, differentiation between the genomes was detected according to the homology between the target genomes and the probes. The McGISH results indicate that the C, D and E genomes share a substantial amount of similar sequences, and differentiation between the D and C genomes of O. alta is less than that between the E genome and each of the C and D genomes. The differentiation within the C genomes of the diploid species (O. officinalis and O. eichingeri) and the C genome of O. alta was clearly discerned by McGISH, suggesting strongly that neither O. officinalis nor O. eichingeri was the direct C-genome donor of O. alta. The evidence of the GISH results also indicates that the E genome was considerably differentiated from the C and D genomes. Therefore, the E genome should not be the direct donor of O. alta; on the contrary, the E genome is closer to the C than to the D genome. McGISH is an efficient method in revealing the relationships among the genomes in question, particularly under the gradual stringent-washing condition. Received: 14 February 2000 / Accepted: 14 November 2000     

A genome-specific repetitive DNA sequence from Oryza eichingeri: characterization,localization, and introgression to O. sativa

In the course of transferring the brown planthopper resistance from a diploid, CC-genome wild rice species, Oryza eichingeri (IRGC acc. 105159 and 105163), to the cultivated rice variety 02428, we have isolated many alien addition and introgression lines. The O. eichingeri chromatin in some of these lines has previously been identified using genomic in situ hybridization and molecular-marker analysis. Here we cloned a tandemly repetitive DNA sequence from O. eichingeri IRGC acc105163, and detected it in 25 introgression lines. This repetitive DNA sequence showed high specificity to the rice CC genome, but was absent from all the four tetraploid species with BBCC or CCDD genomes. The monomer in this repetitive DNA sequence is 325–366-bp long, with a copy number of about 5,000 per 1 C of the O. eichingeri genome, showing 88% homology to a repetitive DNA sequence isolated from Oryza officinalis (2n=2x=24, CC). Fluorescent in situ hybridization revealed 11 signals distributed over eight O. eichingeri chromosomes, mostly in terminal or subterminal regions. Received: 28 November 2000 / Accepted: 3 April 2001     

Isolation of a new retrotransposon-like DNA sequence and its use in analysis of diversity within the Oryza officinalis

To better understand the genetic diversity of the wild relatives of rice (Oryza sativa L.) in the O. officinalis species complex repetitive DNA markers were obtained from the diploid species of this complex. One cloned sequence from O. eichingeri gave intense hybridization signals with all species of the O. officinalis complex. This 242 bp clone, named pOe.49, has a copy number from 0.9 to 4.0 × 10⁴ in diploid species of this complex. Analysis of the primary structure and database searches revealed homology of pOe.49 to a number of sequences representing part of the integrase coding domain of retroviruses and gypsy-like retrotransposons. Sequencing of specific PCR products confirmed that pOe.49 is part of a gypsy-like retrotransposon. RFLP analysis was used to study the genomic organisation of pOe.49 among 30 accessions of the O. officinalis complex using 10 restriction enzymes. Diversity analysis based on 120 polymorphic fragments obtained from the RFLP assay grouped the O. officinalis complex accessions by genome, species and eco-geographic groups. The results suggest that, with further characterization, this retrotransposon-like DNA sequence may be useful for phylogenetic analysis of species in the O. officinalis complex. This revised version was published online in August 2006 with corrections to the Cover Date.     

Two new genomes in the Oryza complex identified on the basis of molecular divergence analysis using total genomic DNA hybridization

The genus Oryza to which cultivated rice belongs has 24 species (2n = 24 or 48), representing seven genomes (AA, BB, CC, EE, FF, BBCC and CCDD). The genomic constitution of five of these species is unknown. These five species have been grouped into two species complexes, the tetraploid ridleyi complex (O. ridleyi, O.␣longiglumis) and the diploid meyeriana complex (O.␣granulata, O. meyeriana, O. indandamanica). To evaluate the genomic structure of these species in terms of divergence at the molecular level vis-à-vis other known genomes of Oryza, we used the total genomic DNA hybridization approach. Total genomic DNA (after restriction digestion) of 79 accessions of 23 Oryza species, 6 related genera, 5 outgroup taxa (2 monocots, 3 dicots) and 6 F₁s and BC₁s derived from crosses of O.␣sativa with wild species were hybridized individually with ³²P-labeled total genomic DNA from 12 Oryza species: O. ridleyi, O. longiglumis, O. granulata, O.␣meyeriana, O. brachyantha, O. punctata, O. officinalis, O. eichingeri, O. alta, O. latifolia, O. australiensis, and O.␣sativa. The labeled genomic DNAs representing the ridleyi and meyeriana complexes cross-hybridized best to all the accessions of their respective species, less to those representing other genomes of Oryza and related genera, and least to outgroup taxa. In general, the hybridization differential measured in terms of signal intensities was >50-fold under conditions that permit detection of 70–75% homologous sequences, both in the presence and in the absence of O. sativa DNA as competitor. In contrast, when total DNAs representing other Oryza genomes were used as probes, species of the O.␣ridleyi and O.␣meyeriana complexes did not show any significant cross-hybridization (<5%). These results demonstrate that the genome(s) of both of these complexes are highly diverged and distinct from all other known genomes of Oryza. We, therefore, propose new genomic designations for these two species complexes: GG for the diploid O. meyeriana complex and HHJJ for the allotetraploid O. ridleyi complex. The results also suggest that the uniqueness of these genomes is not restricted to species-specific highly repetitive DNA sequences, but also applies to dispersed sequences present in single or low to moderate copy numbers. Furthermore these appear to share relatively more genome-specific repeat sequences between themselves than with other genomes of rice. The study also demonstrates the potential of total genomic DNA hybridization as a simple but powerful tool, complementary to existing approaches, for ascertaining the genomic makeup of an organism. Received: 26 July 1996 / Accepted: 17 September 1996     

Genetic diversity and phylogenetic relationship as revealed by inter simple sequence repeat (ISSR) polymorphism in the genus Oryza

Inter simple sequence repeat (ISSR) polymorphism was used to determine genetic diversity and phylogenetic relationships in Oryza. Forty two genotypes including 17 wild species, representing AA,BB,CC,EE,FF,GG,BBCC,CCDD, and HHJJgenomes, two cultivated species, Oryza sativa (AA) and Oryza glaberrima (AA), and three related genera, Porteresia coarctata, Leersia and Rhynchoryza subulata, were used in ISSR analysis. A total of 30 ISSR primers were screened representing di-, tri-, tetra- and penta-nucleotide repeats, of which 11 polymorphic and informative patterns were selected to determine the genetic diversity. The consensus tree constructed using binary data from banding patterns generated by ISSR-PCR clustered 42 genotypes according to their respective genomes. ISSR analysis suggests that the genus Oryza may have evolved following a polyphyletic pathway; Oryza brachyantha (FF genome) is the most divergent species in Oryza and Oryza australiensis (EE genome) does not fall under the Officinalis complex. DNA profiles based on ISSR markers have revealed potential diagnostic fingerprints for various species and genomes, and also for individual accessions/cultivars. Additionally ISSR revealed 87 putative genome/species-specific molecular markers for eight of the nine genomes of Oryza. The ISSR markers are thus useful in the fingerprinting of cultivated and wild species germplasm, and in understanding the evolutionary relationships of Oryza. Received: 23 August 1999 / Accepted: 10 November 1999     

Phylogeny and species delimitation of the C-genome diploid species in Oryza

The diploid Oryza species with C-genome type possesses abundant genes useful for rice improvement and provides parental donors of many tetraploid species with the C-genome (BBCC,CCDD).Despite extensive studies,the phylogenetic relationship among the C-genome species and the taxonomic status of some taxa remain controversial.In this study,we reconstructed the phylogeny of three diploid species with C-genome (Oryza officinalis,O.rhizomatis,and O.eichingeri) based on sequences of 68 nuclear single-copy genes.We obtained a fully resolved phylogenetic tree,clearly indicating the sister relationship of O.officinalis and O.rhizomatis,with O.eichingeri being the more divergent lineage.Incongruent phylogenies of the C-genome species found in previous studies might result from lineage sorting,introgression/hybridization and limited number of genetic markers used.We further applied a recently developed Bayesian species delimitation method to investigate the species status of the Sri Lankan and African O.eichingeri.Analyses of two datasets (68 genes with a single sample,and 10 genes with multiple samples) support the distinct species status of the Sri Lankan and African O.eichingeri.In addition,we evaluated the impact of the number of sampled individuals and loci on species delimitation.Our simulation suggests that sampling multiple individuals is critically important for species delimitation,particularly for closely related species.     

Two new genomes in the Oryza complex identified on the basis of molecular divergence analysis using total genomic DNA hybridization

The genus Oryza to which cultivated rice belongs has 24 species (2n?=?24 or 48), representing seven genomes (AA, BB, CC, EE, FF, BBCC and CCDD). The genomic constitution of five of these species is unknown. These five species have been grouped into two species complexes, the tetraploid ridleyi complex (O. ridleyi, O.?longiglumis) and the diploid meyeriana complex (O.?granulata, O. meyeriana, O. indandamanica). To evaluate the genomic structure of these species in terms of divergence at the molecular level vis-à-vis other known genomes of Oryza, we used the total genomic DNA hybridization approach. Total genomic DNA (after restriction digestion) of 79 accessions of 23 Oryza species, 6 related genera, 5 outgroup taxa (2 monocots, 3 dicots) and 6 F₁s and BC₁s derived from crosses of O.?sativa with wild species were hybridized individually with ³²P-labeled total genomic DNA from 12 Oryza species: O. ridleyi, O.?longiglumis, O. granulata, O.?meyeriana, O. brachyantha, O. punctata, O. officinalis, O. eichingeri, O. alta, O. latifolia, O. australiensis, and O.?sativa. The labeled genomic DNAs representing the ridleyi and meyeriana complexes cross-hybridized best to all the accessions of their respective species, less to those representing other genomes of Oryza and related genera, and least to outgroup taxa. In general, the hybridization differential measured in terms of signal intensities was >50-fold under conditions that permit detection of 70–75% homologous sequences, both in the presence and in the absence of O. sativa DNA as competitor. In contrast, when total DNAs representing other Oryza genomes were used as probes, species of the O.?ridleyi and O.?meyeriana complexes did not show any significant cross-hybridization (<5%). These results demonstrate that the genome(s) of both of these complexes are highly diverged and distinct from all other known genomes of Oryza. We, therefore, propose new genomic designations for these two species complexes: GG for the diploid O. meyeriana complex and HHJJ for the allotetraploid O. ridleyi complex. The results also suggest that the uniqueness of these genomes is not restricted to species-specific highly repetitive DNA sequences, but also applies to dispersed sequences present in single or low to moderate copy numbers. Furthermore these appear to share relatively more genome-specific repeat sequences between themselves than with other genomes of rice. The study also demonstrates the potential of total genomic DNA hybridization as a simple but powerful tool, complementary to existing approaches, for ascertaining the genomic makeup of an organism.     

A comparative study of genetic relationships among the AA-genome<Emphasis Type="Italic"> Oryza</Emphasis> species using RAPD and SSR markers

In order to estimate genetic relationships of the AA-genome Oryza species, RAPD and SSR analyses were performed with 45 accessions, including 13 cultivated varieties (eight Oryza sativa and five Oryza glaberrima) and 32 wild accessions (nine Oryza rufipogon, seven Oryza nivara, three Oryza glumaepatula, four Oryza longistaminata, six Oryza barthii, and three Oryza meridionalis). A total of 181 clear and repeatable bands were amplified from 27 selected RAPD primers, and 101 alleles were detected from 29 SSR primer pairs. The dendrogram constructed using UPGMA from a genetic-similarity matrix based on the RAPD data supported the clustering of distinct five groups with a few exceptions: O. rufipogon/O. nivara/O. meridionalis, O. barthii/O. glaberrima, O. glumaepatula, O. sativa and O. longistaminata. The dendrogram based on the SSR analysis showed a more-complicated genetic variation pattern, but the O. longistaminata and O. barthii/O. glaberrima accessions were consistently separated from all other accessions, indicating significant differentiation of the African AA-genome Oryza species. For accessions in the O. rufipogon/O. nivara/O. sativa complex, it is apparent that geographical isolation has played an important role in differentiation of the Asian AA-genome Oryza taxa. It is also demonstrated from this study that both RAPD and SSR analyses are powerful methods for detecting polymorphisms among the different AA-genome Oryza accessions. However, the RAPD analysis provides a more-informative result in terms of the overall genetic relationships at the species level compared to the SSR analysis. The SSR analysis effectively reveals diminutive variation among accessions or individuals within the same species, given approximately the same number of primers or primer-pairs used in the studies.Communicated by Q. Zhang     

Phylogenetic relationships among Oryza species revealed by AFLP markers

 The genus Oryza to which cultivated rice belongs has 22 wild species. Seventy-seven accessions of 23 Oryza species, five related genera, and three outgroup taxa were fingerprinted using amplified fragment length polymorphism (AFLP). A total of 1191 polymorphic markers were obtained using five AFLP primer combinations. AFLP data were analyzed to study species relationships using different clustering algorithms, and the resulting phenograms were tested for stability and robustness. The findings suggest a common ancestry to the genus Oryza. Moreover, the results demonstrate that: (1) evolution in Oryza has followed a polyphyletic path wherein multiple lineages underwent independent divergence after separation early in the evolution from a common ancestor/pool of related taxa; (2) newly assigned genomes, GG for O. meyeriana and HHJJ for O. ridleyi complexes, are among the most diverged in the genus; (3) CCDD tetraploids have a relatively ancient origin among the Officinalis complex; (4) O. malampuzhaensis, O. indandamanica, O. alta, and O. grandiglumis are diverged enough to deserve species status; (5) O. officinalis and O. eichingeri (CC) are putative progenitors of O. minuta ^* O. malampuzhaensis and tetraploid O. punctata, respectively, (6) O. brachyantha is most diverged species in the genus. AFLP is reliable molecular technique and provides one of the most informative approaches to ascertain genetic relationships in Oryza, which may also be true for other related species/organisms. Received: 1 July 1998 / Accepted: 2 November 1998     

Genetic relationship of Porteresia coarctata Tateoka using molecular markers

ABSTRACT

Twenty-one species belonging to Oryza, including wild rices, were compared with a tetraploid (2n=48) halophytic wild rice relative, Porteresia coarctata Tateoka (=Oryza coarctata) for the genetic relatedness using AFLP and RAPD markers. Diploid and tetraploid groups were clearly separated except in the case of a few species where the clustering was unique and different. The molecular analysis has helped in positioning Porteresia in the vicinity of other wild rice species, and to better understand the pattern of species differentiation in Oryza. From our study, O. australiensis seems to be related to P. coarctata; thus, O. australiensis may be an effective “bridge” species in transferring genetic traits from P. coarctata to O. sativa. The usefulness of molecular marker systems for studying polymorphism and classification, and in clarifying genetic relationships between wild species has been confirmed.     

Diversity in the Integrase Coding Domain of a gypsy-like Retrotransposon Among Wild Relatives of Rice in the Oryza officinalis Complex

The Oryza officinalis complex is a genetically diverse, tertiary genepool of rice. We analyzed part of the primary structure of the integrase coding domain (ICD) of a gypsy-like retrotransposon from species of the O. officinalis species complex. PCR was performed with degenerate primers that hybridized to conserved sequences in the integrase genes of gypsy-type retrotransposons, using total DNA from different species of the O. officinalis complex as templates. Cloning and sequencing of the PCR products showed that the amplified fragments are highly homologous to each other (75–90%) and belong to one family of retrotransposons that is related to the previously studied RIRE-2 element from rice. Two main subfamilies of 292 and 351 bp were distinguished. Analysis of primary sequence data supports previous reports that sequence divergence during vertical transmission has been the major influence on the evolution of gypsy-type retrotransposons in Oryza species. Based on sequence data phylogenetic relationships among species of the O. officinalis complex were estimated. The data suggests that O. eichingeri is more closely related to the ancestral species of the complex. This revised version was published online in July 2006 with corrections to the Cover Date.     

SUB1A‐dependent and ‐independent mechanisms are involved in the flooding tolerance of wild rice species

Crop tolerance to flooding is an important agronomic trait. Although rice (Oryza sativa) is considered a flood‐tolerant crop, only limited cultivars display tolerance to prolonged submergence, which is largely attributed to the presence of the SUB1A gene. Wild Oryza species have the potential to unveil adaptive mechanisms and shed light on the basis of submergence tolerance traits. In this study, we screened 109 Oryza genotypes belonging to different rice genome groups for flooding tolerance. Oryza nivara and Oryza rufipogon accessions, belonging to the A‐genome group, together with Oryza sativa, showed a wide range of submergence responses, and the tolerance‐related SUB1A‐1 and the intolerance‐related SUB1A‐2 alleles were found in tolerant and sensitive accessions, respectively. Flooding‐tolerant accessions of Oryza rhizomatis and Oryza eichingeri, belonging to the C‐genome group, were also identified. Interestingly, SUB1A was absent in these species, which possess a SUB1 orthologue with high similarity to O. sativa SUB1C. The expression patterns of submergence‐induced genes in these rice genotypes indicated limited induction of anaerobic genes, with classical anaerobic proteins poorly induced in O. rhizomatis under submergence. The results indicated that SUB1A‐1 is not essential to confer submergence tolerance in the wild rice genotypes belonging to the C‐genome group, which show instead a SUB1A‐independent response to submergence.     

Phylogenetic analysis of Oryza species, based on simple sequence repeats and their flanking nucleotide sequences from the mitochondrial and chloroplast genomes

Simple sequence repeats (SSR) and their flanking regions in the mitochondrial and chloroplast genomes were sequenced in order to reveal DNA sequence variation. This information was used to gain new insights into phylogenetic relationships among species in the genus Oryza. Seven mitochondrial and five chloroplast SSR loci equal to or longer than ten mononucleotide repeats were chosen from known rice mitochondrial and chloroplast genome sequences. A total of 50 accessions of Oryza that represented six different diploid genomes and three different allopolyploid genomes of Oryza species were analyzed. Many base substitutions and deletions/insertions were identified in the SSR loci as well as their flanking regions. Of mononucleotide SSR, G (or C) repeats were more variable than A (or T) repeats. Results obtained by chloroplast and mitochondrial SSR analyses showed similar phylogenetic relationships among species, although chloroplast SSR were more informative because of their higher sequence diversity. The CC genome is suggested to be the maternal parent for the two BBCC genome species (O. punctata and O. minuta) and the CCDD species O. latifolia, based on the high level of sequence conservation between the diploid CC genome species and these allotetraploid species. This is the first report of phylogenetic analysis among plant species, based on mitochondrial and chloroplast SSR and their flanking sequences.     

A tourist element in the 5'-flanking region of the catalase gene CatA reveals evolutionary relationships among Oryza species with various genome types

Tourist-OsaCatA, a transposable element, was found in the 5′-flanking region of the rice gene CatA. The characteristics of this element are similar to those of the other Tourist elements so far found in Oryza sativa. PCR and sequence analyses of 37 accessions of 18 species revealed that all the Oryza species examined, except for one accession, have either a full-length or a partial Tourist element at this locus. Unlike the Tourist elements previously reported, this Tourist element is found in all four Oryza species complexes in the Oryzeae tribe. All AA genome Oryza species, except O. longistaminata, contain the full-length Tourist element. O. longistaminata and the species of the O. officinalis, O. meyeriana and O. ridleyi complexes contain the partial element. A phylogenetic tree of Oryza species based on the nucleotide sequences of these Tourist elements was constructed. The O. longistaminata accessions were placed near the neighboring cluster of the officinalis complex. We propose that the ancestor of O. longistaminata and that of other species with the AA genome diverged, and the ancestor(s) of the O. officinalis, O. ridleyi and O. meyeriana complexes then diverged from the ancestor of O. longistaminata in the course of the evolution of the Oryza species. The Tourist elements associated with CatA and its orthologs thus provide useful tools for examining evolutionary relationships among Oryza species. Received: 12 March 1999 / Accepted: 7 July 1999     

Allozyme variation and population genetic structure of common wild rice Oryza rufipogon Griff. in China

In order to determine the genetic diversity and genetic structure of populations in common wild rice Oryza rufipogon, an endangered species, allozyme diversity was analyzed using 22 loci in 607 individuals of 21 natural populations from the Guangxi, Guangdong, Hainan, Yunnan, Hunan, Jiangxi and Fujian provinces in China. The populations studied showed a moderate allozyme variability (A=1.33, P=22.7%, Ho=0.033 and He=0.068), which was relatively high for the genus Oryza. The levels of genetic diversity for Guangxi and Guangdong were significantly higher than those for the other regions, and thus South China appeared to be the center of genetic diversity of O. rufipogon in China. A moderate genetic differentiation (F_ST=0.310, I=0.964) was found among the populations studied. Interestingly, the pattern of population differentiation does not correspond to geographic distance. An estimate of the outcrossing rate (t=0.324) suggests that the species has a typical mixed-mating system. The deficit of heterozygotes (F=0.511) indicates that some inbreeding may have taken place in outcrossing asexual populations because of intra-clone outcrossing events and ”isolation by distance” as a result of human disturbance. In order to predict the long-term genetic survival of fragmented populations, further studies on gene flow among the remaining populations and the genetic effects of fragmentation are proposed. Finally, some implications for the conservation of endangered species are suggested. Received: 22 June 1999 / Accepted: 20 December 1999     

A study on population genetic structure of Oryza meyeriana (Zoll. et Mor. ex Steud.) Baill. from Yunnan and its in situ conservation significance

In order to determine genetic diversity ofOryza meyeriana (Zoll. et Mor. ex Steud.) Baill., 12 enzyme systems encoded by 17 loci were electrophoretically analyzed in 164 individuals of seven populations from Simao Prefecture, Yunnan Province, China. In comparison with those seed plants with the same life history and breeding systems, as well as the other species in the genusOryza, the species shows rather low levels of genetic diversity (A = 1.1,P = 8.0 %, Ho = 0.004 and He = 0.015) within populations and high genetic differentiation among populations. F_st was up to 0. 649, suggesting that 64. 9% of total genetic variability exists among populations. Considering high genetic differentiation among populations from a limited geographic region, most of the populations of the species are worth being protected, and therefore, great natural protection regions should theoretically be established in which a great deal of populations should be involved for developingin situ conservation management. Meanwhile, some priory localities forin situ conservation ofO. meyerzana in Yunnan Province, were proposed. Project supported by the Grant of the President of the Chinese Academy of Sciences.