RAPD, RFLP and SSLP analyses of phylogenetic relationships between cultivated and wild species of rice.

RAPD, RFLP, nuclear SSLP and chloroplast SSLP analyses were carried out to clarify the phylogenetic relationships among A-genome species of rice. In total, 12 cultivars of Oryza sativa (4 Japonica, 3 Javanica and 5 Indica), one cultivar of O. glaberrima, and 17 wild accessions (12 O. rufipogon, 2 O. glumaepatula, 1 O. longistaminata, 1 O. meridionalis and 1 O. barthii) were used. Their banding patterns were scored and compared to evaluate the similarity between accessions. Genetic differentiation within and between taxa was examined based on the average similarity indices. Except for chloroplast SSLP analysis, the average similarities were higher within O. sativa than within O. rufipogon, and O. sativa Indica had greater intrasubspecific variation than Japonica and Javanica. Comparisons between cultivated and wild species showed that O. sativa was closely related to O. rufipogon, while O. glaberrima was closely related to O. barthii. This indicated that two cultivated species, O. sativa and O. glaberrima, originated from O. rufipogon and O. barthii, respectively. Domestication of O. sativa seemed to be diphyletic, since strong similarity was observed between O. sativa Japonica-Javanica and O. rufipogon from China and between O. sativa Indica and O. rufipogon from tropical Asia. In addition, dendrograms for RAPD, RFLP, and nuclear and chloroplast SSLP analyses were constructed to reveal the overall genetic relationships among A-genome species. In all analyses, O. sativa and O. glaberrima formed groups with O. rufipogon and O. barthii, respectively. However, their manners of clustering with other wild species were not the same. The results of RAPD and RFLP analyses indicate that O. glumaepatula was relatively close to the groups of O. sativa and O. glaberrima whereas O. longistaminata and O. meridionalis were highly differentiated from other A-genome species. On the other hand, clear interspecific relationships were not obtained by nuclear or chloroplast SSLP analyses.     

Genetic diversity and phylogenetic relationship in AA Oryza species as revealed by Rim2/Hipa CACTA transposon display

CACTA is a class 2 transposon, that is very abundantly present in plant genomes. Using Rim2/Hipa CACTA transposon display (hereafter Rim2/Hipa-TD), we analyzed several A-genome diploid Oryza species that have a high distribution of the CACTA motifs. High levels of polymorphism were detected within and between the Oryza species. The African taxa, O. glaberrima and O. barthii, both showed lower levels of polymorphism than the Asian taxa, O. sativa, O. rufipogon, and O. nivara. However, O. longistaminata, another African taxon, showed levels of polymorphism that were similar to the Asian taxa. The Latin American taxon, O. glumaepatula, and the Australian taxon, O. meridionalis, exhibited intermediate levels of polymorphism between those of the Asian and African taxa. The lowest level of polymorphism was observed in O. glaberrima (32.1%) and the highest level of polymorphism was observed in O. rufipogon (95.7%). The phylogenetic tree revealed three major groups at the genetic similarity level of 0.409. The first group consisted of three Asian taxa, O. sativa, O. rufipogon and O. nivara. The second group consisted of three African taxa, O. glaberrima, O. barthii, O. longistaminata, and an American taxon, O. glumaepatula. The third group contained an Australian taxon, O. meridionalis. The clustering patterns of these species matched well with their geographical origins. Rim2/Hipa-TD appears to be a useful marker system for studying the genetic diversity and species relationships among the AA diploid Oryza species.     

水稻CMS相关基因在稻属AA基因组中的分布及其单核苷酸多态性

水稻线粒体基因组嵌合基因orf79 和 orfH79分别被认为与BT-型和HL-型水稻CMS有关, 两者具有98%的同源性, 并且其DNA序列只存在4核苷酸的差异。对于这两个嵌合基因, 前者来源于栽培稻(Oryza. sativa L.), 而后者则来源于普通野生稻(O. rufipogon Griff.)。这意味着orf79/ orfH79可能在广泛分布于稻属AA基因组中。为了调查orf79/ orfH79在稻属物种中的分布和变异, 190份栽培稻品系[包括156份亚洲栽培稻(O. sativa var. landrace)和34份非洲栽培稻(O. glaberrima)]以及104份稻属AA基因组野生稻品系(包括O. rufipogon、O.nivara、O. glumaepatula、O. barthii、O. longistaminata和O. meridionalis 6个种), 被用于PCR扩增检测。31份具有控制粤泰A和笹锦A的特异片段的稻属AA基因组水稻品系被检测出。所有特异片段均被回收并测序, 基于DNA 序列的聚类结果显示31份水稻材料被分成了两组, 分别代表为BT-型和HL-型水稻不育细胞质组群。结果也进一步表明: HL-型水稻CMS胞质主要分布于一年生的O. nivara中; BT-型水稻CMS胞质可能来源于栽培稻变种或多年生野生稻O. rufipogon。     

Genetic variations of AA genome Oryza species measured by MITE-AFLP

MITEs (miniature inverted-repeat transposable elements) are the major transposable elements in Oryza species. We have applied the MITE-AFLP technique to study the genetic variation and species relationship in the AA-genome Oryza species. High polymorphism was detected within and between species. The genetic variation in the cultivated species, Oryza sativa and Oryza glaberrima, was comparatively lower than in their ancestral wild species. In comparison between geographical lineages of the AA genome species, African taxa, O. glaberrima and Oryza barthii, showed lower variation than the Asian taxa, O. sativa, Oryza rufipogon, and Oryza nivara, and Australian taxon Oryza meridionalis. However, another African taxon, Oryza longistaminata, showed high genetic variation. Species relationships were analyzed by the pattern of presence or absence of homologous fragments, because nucleotide sequences of the detected MITE-AFLP fragments revealed that the same fragments in different species shared very high sequence homology. The clustering pattern of the AA-genome species matched well with the geographical origins (Asian, African and Australian), and with the Australian taxon being distant to the others. Therefore, this study demonstrated that the MITE-AFLP technique is amenable for studying the genetic variation and species relationship in rice.     

Identification and characterization of Australian wild rice strains of Oryza meridionalis and Oryza rufipogon by SINE insertion polymorphism

Of the rice species with an AA genome, Oryza meridionalis has been identified in northern Australia as a species of the annual type, among those previously classified as Oryza perennis, Oryza rufipogon or Oryza nivara. This notion has, however, led to some confusion to determine which strains belong to O. meridionalis and how different these strains are from the O. rufipogon strains of the annual type. In this paper, we examined Australian wild rice strains for the presence or absence of p-SINE1 members, which have been used for identification of the strains of species with the AA genome, by PCR using primers that hybridize to the sequences flanking each p-SINE1 member. The rice strains examined include perennial and annual strains, which have previously been described as O. rufipogon. We found that all the annual strains and other strains, whose types have not been determined, have p-SINE1 members that are specifically present at the corresponding loci in the standard strains of O. meridionalis, but do not have those which are specifically present at the corresponding loci in the strains of the other species with the AA genome. The perennial strains, however, have p-SINE1 members that are specifically present at the corresponding loci in the standard O. rufipogon strains of either the annual or the perennial type, but do not have those which are specifically present at the corresponding loci in the strains of the other species with the AA genome, including O. meridionalis. These findings support the previous notion that O. meridionalis consists of the annual strains and is a distinct species from O. rufipogon. The p-SINE1 members used in this study appear to be very useful for classification of any wild rice strains of the AA-genome species, even when one has limited knowledge of morphology, taxonomy, physiology, and biochemistry of rice strains.     

Nuclear- and chloroplast-microsatellite variation in A-genome species of rice.

Simple sequence length polymorphism analysis was carried out to reveal microsatellite variation and to clarify the phylogenetic relationships among A-genome species of rice. Total DNA from 29 cultivars (23 Oryza sativa and 6 O. glaberrima) and 30 accessions of wild A-genome species (12 O. rufipogon, 5 O. glumaepatula, 2 O. longistaminata, 6 O. meridionalis, and 5 O. barthii) was used as a template for PCR to detect 24 nuclear and 10 chloroplast microsatellite loci. Microsatellite allelic diversity was examined based on amplified banding patterns. Microsatellites amplified clearly in all 59 accessions, with an average of 18.4 alleles per locus. The polymorphism information content (PIC) value ranged from 0.85 to 0.94, with an average of 0.89. At the species level, high average PIC values were observed in O. sativa (0.79) and O. rufipogon (0.80). For chloroplast microsatellites, the average number of alleles per locus and the average PIC value were 2.9 and 0.38, respectively. While the magnitude of diversity was much greater for nuclear microsatellites than for chloroplast microsatellites, they showed parallel patterns of differentiation for each taxonomic group. Using the ratio of common alleles (estimated as size of amplified fragments) as a similarity index, the average percentages of common microsatellite alleles were calculated between taxa. For both nuclear and chloroplast microsatellites, O. sativa showed the highest similarity values to O. rufipogon, and O. glaberrima was most similar to O. barthii. These data support previous evidence that these cultivars originated from the corresponding wild ancestral species.     

Polyphyletic origin of cultivated rice: based on the interspersion pattern of SINEs

The wild rice species Oryza rufipogon with wide intraspecific variation is thought to be the progenitor of the cultivated rice species Oryza sativa with two ecotypes, japonica and indica. To determine the origin of cultivated rice, subfamily members of the rice retroposon p-SINE1, which show insertion polymorphism in the O. sativa -O. rufipogon population, were identified and used to "bar code" each of 101 cultivated and wild rice strains based on the presence or absence of the p-SINE1 members at the respective loci. A phylogenetic tree constructed based on the bar codes given to the rice strains showed that O. sativa strains were classified into two groups corresponding to japonica and indica, whereas O. rufipogon strains were in four groups, in which annual O. rufipogon strains formed a single group, differing from the perennial O. rufipogon strains of the other three groups. Japonica strains were closely related to the O. rufipogon perennial strains of one group, and the indica strains were closely related to the O. rufipogon annual strains, indicating that O. sativa has been derived polyphyletically from O. rufipogon. The subfamily members of p-SINE1 constitute a powerful tool for studying the classification and relationship of rice strains, even when one has limited knowledge of morphology, taxonomy, physiology, and biochemistry of rice strains.     

Phylogenetic analysis of Oryza rufipogon strains and their relations to Oryza sativa strains by insertion polymorphism of rice SINEs

Oryza rufipogon, the progenitor of the cultivated rice species Oryza sativa, is known by its wide intraspecific variation. In this study, we performed phylogenetic analyses of O. rufipogon strains and their relationships to O. sativa strains by using 26 newly identified p-SINE1 members from O. rufipogon strains, in addition to 23 members previously identified from O. sativa strains. A total of 103 strains of O. rufipogon and O. sativa were examined for the presence and absence of each of the p-SINE1 members at respective loci by PCR with a pair of primers that hybridize to the regions flanking each p-SINE1 member. A phylogenetic tree constructed on the basis of the insertion polymorphism of p-SINE1 members showed that O. rufipogon and O. sativa strains are classified into three groups. The first group consisted of O. rufipogon perennial strains mostly from China and O. sativa ssp. japonica strains, which included javanica strains forming a distinct subgroup. The second group consisted of almost all the O. rufipogon annual strains, a few O. rufipogon perennial strains and O. sativa ssp. indica strains. These groupings, in addition to other results, support the previous notion that annual O. rufipogon originated in the O. rufipogon perennial population, and that O. sativa originated polyphyletically in the O. rufipogon populations. The third group consisted of the other perennial strains and intermediate-type strains of O. rufipogon, in which the intermediate-type strains are most closely related to a hypothetical ancestor with no p-SINE1 members at the respective loci and to those belonging to the other rice species with the AA genome. This suggests that O. rufipogon perennial strains are likely to have originated from the O. rufipogon intermediate-ecotype population.     

Chloroplast genome sequence confirms distinctness of Australian and Asian wild rice

Cultivated rice (Oryza sativa) is an AA genome Oryza species that was most likely domesticated from wild populations of O. rufipogon in Asia. O. rufipogon and O. meridionalis are the only AA genome species found within Australia and occur as widespread populations across northern Australia. The chloroplast genome sequence of O. rufipogon from Asia and Australia and O. meridionalis and O. australiensis (an Australian member of the genus very distant from O. sativa) was obtained by massively parallel sequencing and compared with the chloroplast genome sequence of domesticated O. sativa. Oryza australiensis differed in more than 850 sites single nucleotide polymorphism or indel from each of the other samples. The other wild rice species had only around 100 differences relative to cultivated rice. The chloroplast genomes of Australian O. rufipogon and O. meridionalis were closely related with only 32 differences. The Asian O. rufipogon chloroplast genome (with only 68 differences) was closer to O. sativa than the Australian taxa (both with more than 100 differences). The chloroplast sequences emphasize the genetic distinctness of the Australian populations and their potential as a source of novel rice germplasm. The Australian O. rufipogon may be a perennial form of O. meridionalis.     

Morphological studies of Asian rice and its related wild species and the recognition of a new Australian taxon

In order to clarify the taxonomy and the interrelationships among Asiatic cultivated rice, Oryza sativa , and its related wild species ( O. rufipogon, O. nivara and O . barthii ), 41 morphological characters were examined. Numerical taxonomic methods were used to analyse the data and to illustrate species relationships.
Distinctive differences among the materials studied suggest the retention of O. rufipogoon, O. nivara and O . sativa as three distinct species. The origin of O. sativa from O. nivara through domestication is discussed. An annual wild taxon from Australia, which had been classified as a form of O. nivara , is shown to be distinct from typical O. nivnra and is raised to specific rank. This species has been named O. meridionalis Ng.     

Variation in the loss of seed dormancy during after-ripening of wild and cultivated rice species

BACKGROUND AND AIMS: The aim of this paper was to verify the variation in the loss of seed dormancy during after-ripening and the interspecific and interpopulation variability in the degree of dormancy of seven wild and two cultivated rice species comprising 21 populations and two cultivars. METHODS: Four wild rice species from South America, Oryza glumaepatula, O. latifolia, O. grandiglumis and O. alta, and two O. sativa cultivars were tested in one experiment. In a second experiment, five wild species, O. punctata, O. eichingeri, O.rufipogon, O. latifolia and O. glumaepatula, and one cultivated species (O. glaberrima) were evaluated. Initial germination tests were performed soon after the seeds were harvested and subsequently at 2-month intervals, for a total of six storage periods in the first experiment and three in the second. All tests were conducted in the dark at a temperature of 27 degrees C. KEY RESULTS: Different patterns of after-ripening among populations within and between species were observed. CONCLUSIONS: The cultivated species (O. sativa and O. glaberrima) and, amongst the wild species, the tetraploids O. latifolia, O. grandiglumis and the diploids O. eichingeri and O. punctata, had weak dormancy, losing it completely 2 months after harvest, while O. rufipogon and O. glumaepatula exhibited pronounced dormancy. The latter showed different patterns of after-ripening between populations indigenous to the Amazon region and those originating in the Paraguay River system. Seeds of Solimoes (Amazon) and Japura origin showed weak dormancy whereas those of Paraguay origin showed deep dormancy. Ecological differences among natural habitats may be involved in such differentiation.     

UVB sensitivity and cyclobutane pyrimidine dimer (CPD) photolyase genotypes in cultivated and wild rice species.

We investigated the UVB-sensitivity in 12 rice strains belonging to two cultivated species (O. sativa and O. glaberrima) and three wild species (O. barthii, O. meridionalis and O. rufipogon) of rice possessing the AA genome, while focusing on the CPD photolyase activity and the genotypes of CPD photolyase. Although the UVB sensitivity, CPD photolyase activity, and CPD photolyase genotype varied widely among these rice species, the sensitivity to UVB radiation depended on the activity of the CPD photolyase, regardless of grass shape, habitat, or species. The rice strains examined here clearly divided into three groups based on the CPD photolyase activity, and the activity of the strains greatly depended on amino acid residues at positions 126 and 296, with the exception of the W1299 strain (O. meridionalis). The amino acid residues 126 and 296 of CPD photolyase in Sasanishiki strain (O. sativa), which showed higher enzymatic activity and more resistance to UVB, were glutamine (Gln) and Gln, respectively. An amino acid change at position 126 from Gln to arginine ("Nori"-type) in the photolyase led to a reduction of enzymatic activity. Additionally, an amino acid change at position 296 from Gln to histidine led to a further reduction in activity. The activity of the W1299 strain, which possesses a "Nori"-type CPD photolyase, was the highest among the strains examined here, and was similar to that of the Sasanishiki. The CPD photolyase of the W1299 contains ten amino acid substitutions, compared to Sasanishiki. The alterations in amino acid residues in the W1299 CPD photolyase compensated for the reduction in activity caused by the amino acid substitutions at positions 126. Knowledge of the activity of different CPD photolyase genotypes will be useful in developing improved rice cultivars.     

Evolutionary implications of substitution patterns in prolamin genes of Oryza glaberrima (African rice, Poaceae) and related species

Patterns of sequence variation of nuclear genes encoding 10-kDa and 16-kDa prolamin seed storage proteins were examined in Oryza glaberrima (African rice, Poaceae) and O. barthii and compared to available sequences for the genus to assess potential application of these gene families in evolutionary studies. Sequence variation among species in 10-kDa genes was very low. In contrast, the 16-kDa genes have undergone rapid evolution, displaying a larger number of length and point mutations that in some cases result in frame shift or produce truncated protein or pseudogenes. The proportion of nonsynonymous substitution is high in both genes. Although nonsynonymous mutations did not alter the overall profile of the protein, pronounced shifts in proportions of some amino acids were evident and could have systematic application. The data provide support for a proposed direct evolution of the Asian (O. sativa) and African rice from O. rufipogon and O. barthii, respectively. Patterns of amino acid frequencies of the 10-kDa genes show the distinctness of O. rufipogon and O. longistaminata from the other species. The study underscores the potential application of the prolamin genes as markers from the nuclear genome for evolutionary studies in grasses at different taxonomic levels.     

Characterization of Interspecific Hybrids Between Oryza sativa L. and Three Wild Rice Species of China by Genomic In Situ Hybridization

In the genus Oryza, interspecific hybrids are useful bridges for transferring the desired genes from wild species to cultivated rice （Oryza sativa L.）. In the present study, hybrids between O. sativa （AA genome） and three Chinese wild rices, namely O. rufipogon （AA genome）, O. officinalis （CC genome）, and O. meyeriana （GG genome）, were produced. Agricultural traits of the F1 hybrids surveyed were intermediate between their parents and appreciably resembled wild rice parents. Except for the O. sativa × O. rufipogon hybrid, the other F1 hybrids were completely sterile. Genomic in situ hybridization （GISH） was used for hybrid verification. Wild rice genomic DNAs were used as probes and cultivated rice DNA was used as a block. With the exception of O. rufipogon chromosomes, this method distinguished the other two wild rice and cultivated rice chromosomes at the stage of mitotic metaphase with different blocking ratios. The results suggest that a more distant phylogenetic relationship exists between O. meyeriana and O. sativa and that O. rufipogon and O. sativa share a high degree of sequence homology. The average mitotic chromosome length of O. officinalis and O. meyeriana was 1.25- and 1.51-fold that of O. sativa, respectively. 4＇,6＇-Diamidino- 2-phenylindole staining showed that the chromosomes of O. officinalis and O. meyeriana harbored more heterochromatin, suggesting that the C and G genomes were amplified with repetitive sequences compared with the A genome. Although chromocenters formed by chromatin compaction were detected with wild rice-specific signals corresponding to the C and G genomes in discrete domains of the F1 hybrid interphase nuclei, the size and number of O. meyeriana chromocenters were bigger and greater than those of O. officinalis. The present results provide an important understanding of the genomic relationships and a tool for the transfer of useful genes from three native wild rice species in China to cultivars.     

Ultrastructure of Oryza glumaepatula, a wild rice species endemic of tropical America

Orv'za gluniaepatula is a perennial wild rice species, endemic to tropical America, previously known as the Latin American race of Orrza rufipogon. In Costa Rica, it is found in the northern region of the country, mainly in the wetland of the Medio Queso River, Los Chiles, Alajuela. It is diploid, of AA type genome and because of its genetic relatedness to cultivated rice it is included in the O. saliva complex. We describe the ultrastructure of leaf blade, spikelet, ligule and auricles. Special emphasis is given to those traits of major taxonomic value for O. glumaepatula and to those characters that distinguish this species from O. rufipogon and O. sativa. O. glumaepatula has a leaf blade covered with tombstone-shaped, oblong and spheroid epicuticular wax papillae. It has diamond-shaped stomata surrounded by spherical papillae, rows of zipper-like silica cells, bulky prickle trichomes of ca. 40 microm in length and small hirsute trichomes of ca. 32 tpm in length. The central vein is covered with large, globular papillae of ca. 146 microm in length, a characteristic that distinguishes this species from O. rufipogon and O. sativa. The border of the leaf blade exhibits a row of even-sized bulky prickle trichomes of ca. 42.5 microm in length. Auricles have attenuated trichomes of ca. 5.5 mm in length on the edges and small bicellular trichomes of 120 microm in length on the surface. The ligule has a large number of short attenuated trichomes on its surface of 100 microm in length. These latter two traits have important taxonomic value since they were found in O. glumaepatula but not found in O. sativa or in O. rufipogon. The spikelet has the typical morphology of the Oryza genus. Fertile lemmas have abundant spines, a trait shared with O. rufipogon but not with O. sativa. The sterile lemmas are wing-shaped with serrated borders, a characteristic that distinguishes this species from O. rufipogon and O. sativa. All the ultrastructure characters observed in O. glumaepatula from Costa Rica are also common to the specimens from Brazil.     

The Structural Features of Leaf Epidermis in Oryza and Their Systematic Significance

The rice genus (Oryza L. ) belongs to the grass family(Poaceae) and contains 24 annual or perennial species, including two cultivated rice species, i.e., the Asian rice ( O. sativa L. ) and African rice (O. glaberrima Steud. ), and 22 wild species distributed throughout the tropics of the world. Species in this genus have been extensively studied by scientists with different approaches, including morphological characterization and cytological and molecular investigations. The leaf epidermis is an important morphological character which has been studied for taxonomic identification and studies on systematic relationships of species, particularly in grasses. In this study, morphological features of the leaf epidermis of 23 rice species were observed through light microscopy. The results showed that some characters of the rice leaf epidermis had significant diversity between species and these characters were valuable for the identifying Oryza species, and for assessing systematic relationships in the genus. For example, O.schlechteri, O.ridleyi, O.longiglumis, O.granulata, and O. rneyeriana had elliptic stomatal complexes, whereas the other species had rhombic stomatal complexes. In most cases, papillae on the surface of the epidermis were variable in size and distribution between species. The size of papillae varied from small ( 1.5～4.4µm in diameter), medium-sized (9～18µm), to large (21～30µm) , and the pattern of papillary size and distribution were very useful for identification of rice species. In addition, the number and location of the small papillae in stomatal complexes were particularly different between species. Based on the following combinations of leaf-epidermic characters, i.e., the size and distribution of papillae on the abaxial surface of the epidermis, the number and location of the small papillae in stomatal complexes, and the shape of stomatal complexes, the 23 studied Oryza species could be divided into three major groups. The first group comprises O.longiglumis, O.ridleyi, O.meyeriana, and O.granulata. In these species, neither large nor medium-sized papillae, in some cases extremely rare small papillae, were found on the surfaces of epidermis, and there were no small papillae found in stomatal complexes. All species in the first group had elliptic stomatal complexes. The second group consists of O.brachyantha, diploid and tetraploid O.officinalis, O.minuta, O.eichingeri, O. punctata, O.latifolia, O.alta, O.grandiglumis, O.rhizomatis, and O.australiensis. In these species usually no large papillae were observed, but medium-sized and densely populated small papillae were found to cover the surface of epidermis, and at least four small papillae were found in stomatal complexes (in guard cells) of most species. The third group contains O.sativa, O.nivara, O.rufipogon, O.longistaminata, O. glumaepatula, O.meridionalis, O.barthii, O.glaberrima and O. schlechteri. The abaxial leaf epidermis of these species was usually covered with large papillae, medium-sized, and small papillae. In addition, more than 4 (usually 6～8 ) small papillae were found in guard cells or/and subsidiary cells of the stomatal complexes. Most species in the second and third groups had rhombic stomatal complexes. These results agree mostly with previous re-ports on the biosystematic studies of rice species by applying other methodologies.     

Origin,dispersal, cultivation and variation of rice

There are two cultivated and twenty-one wild species of genus Oryza. O. sativa, the Asian cultivated rice is grown all over the world. The African cultivated rice, O. glaberrima is grown on a small scale in West Africa. The genus Oryza probably originated about 130 million years ago in Gondwanaland and different species got distributed into different continents with the breakup of Gondwanaland. The cultivated species originated from a common ancestor with AA genome. Perennial and annual ancestors of O. sativa are O. rufipogon and O. nivara and those of O. glaberrima are O. longistaminata/, O. breviligulata and O. glaberrima probably domesticated in Niger river delta. Varieties of O. sativa are classified into six groups on the basis of genetic affinity. Widely known indica rices correspond to group I and japonicas to group VI. The so called javanica rices also belong to group VI and are designated as tropical japonicas in contrast to temperate japonicas grown in temperate climate. Indica and japonica rices had a polyphyletic origin. Indicas were probably domesticated in the foothills of Himalayas in Eastern India and japonicas somewhere in South China. The indica rices dispersed throughout the tropics and subtropics from India. The japonica rices moved northward from South China and became the temperate ecotype. They also moved southward to Southeast Asia and from there to West Africa and Brazil and became tropical ecotype. Rice is now grown between 55°N and 36°S latitudes. It is grown under diverse growing conditions such as irrigated, rainfed lowland, rainfed upland and floodprone ecosystems. Human selection and adaptation to diverse environments has resulted in numerous cultivars. It is estimated that about 120000 varieties of rice exist in the world. After the establishment of International Rice Research Institute in 1960, rice varietal improvement was intensified and high yielding varieties were developed. These varieties are now planted to 70% of world's riceland. Rice production doubled between 1966 and 1990 due to large scale adoption of these improved varieties. Rice production must increase by 60% by 2025 to feed the additional rice consumers. New tools of molecular and cellular biology such as anther culture, molecular marker aided selection and genetic engineering will play increasing role in rice improvement.     

8个野生稻种的叶片硅体研究

用强酸溶液分离8个野生稻种叶片中的硅体并用光学显微镜和电子扫描显微镜进行观测研究.结果显示,(1)叶片含有3种类型的硅体,即不规则硅体、哑铃形硅体和扇形硅体,前2种硅体不能作为属内分类的依据,但短药野生稻哑铃形硅体的表面纹饰独特,可作为识别该物种的特征.(2)同一个物种的扇形硅体变异很大,统计学表明它总以其中的某一种类型占有优势,紧穗野生稻和短舌野生稻中小型硅体占优势,药用野生稻和普通野生稻中约有一半为中型硅体,另一半为小型硅体,其余4种野生稻包括斑点野生稻、澳洲野生稻、展颖野生稻和短药野生稻中绝大多数为中型硅体,即野生稻的扇形硅体以中、小型为主.(3)根据扇面长/扇柄长的比值,将扇形硅体划分为长柄型、中间形和短柄型3种形态,依此对8个稻种的硅体分类.结果表明,斑点野生稻、药用野生稻、紧穗野生稻和澳洲野生稻以长柄型为优势;普通野生稻、短舌野生稻、展颖野生稻和短药野生稻则以中间型为主,且扇形硅体的扇面长/扇柄长的比值的大小与野生稻染色体组型或原产地有关.     

Genetic control of a transition from black to straw-white seed hull in rice domestication

The genetic mechanism involved in a transition from the black-colored seed hull of the ancestral wild rice (Oryza rufipogon and Oryza nivara) to the straw-white seed hull of cultivated rice (Oryza sativa) during grain ripening remains unknown. We report that the black hull of O. rufipogon was controlled by the Black hull4 (Bh4) gene, which was fine-mapped to an 8.8-kb region on rice chromosome 4 using a cross between O. rufipogon W1943 (black hull) and O. sativa indica cv Guangluai 4 (straw-white hull). Bh4 encodes an amino acid transporter. A 22-bp deletion within exon 3 of the bh4 variant disrupted the Bh4 function, leading to the straw-white hull in cultivated rice. Transgenic study indicated that Bh4 could restore the black pigment on hulls in cv Guangluai 4 and Kasalath. Bh4 sequence alignment of all taxa with the outgroup Oryza barthii showed that the wild rice maintained comparable levels of nucleotide diversity that were about 70 times higher than those in the cultivated rice. The results from the maximum likelihood Hudson-Kreitman-Aguade test suggested that the significant reduction in nucleotide diversity in rice cultivars could be caused by artificial selection. We propose that the straw-white hull was selected as an important visual phenotype of nonshattered grains during rice domestication.     

Two new SINE elements, p-SINE2 and p-SINE3, from rice

p-SINE1 was the first plant SINE element identified in the Waxy gene in Oryza sativa, and since then a large number of p-SINE1-family members have been identified from rice species with the AA or non-AA genome. In this paper, we report two new rice SINE elements, designated p-SINE2 and p-SINE3, which form distinct families from that of p-SINE1. Each of the two new elements is significantly homologous to p-SINE1 in their 5'-end regions with that of the polymerase III promoter (A box and B box), but not significantly homologous in the 3'-end regions, although they all have a T-rich tail at the 3' terminus. Despite the three elements sharing minimal homology in their 3'-end regions, the deduced RNA secondary structures of p-SINE1, p-SINE2 and p-SINE3 were found to be similar to one another, such that a stem-loop structure seen in the 3'-end region of each element is well conserved, suggesting that the structure has an important role on the p-SINE retroposition. These findings suggest that the three p-SINE elements originated from a common ancestor. Similar to members of the p-SINE1 family, the members of p-SINE2 or p-SINE3 are almost randomly dispersed in each of the 12 rice chromosomes, but appear to be preferentially inserted into gene-rich regions. The p-SINE2 members were present at respective loci not only in the strains of the species with the AA genome in the O. sativa complex, but also in those of other species with the BB, CC, DD, or EE genome in the O. officinalis complex. The p-SINE3 members were, however, only present in strains of species in the O. sativa complex. These findings suggest that p-SINE2 originated in an ancestral species with the AA, BB, CC, DD and EE genomes, like p-SINE1, whereas p-SINE3 originated in an ancestral strain of the species with the AA genome. The nucleotide sequences of p-SINE1 members are more divergent than those of p-SINE2 or p-SINE3, indicating that p-SINE1 is likely to be older than p-SINE2 and p-SINE3. This suggests that p-SINE2 and p-SINE3 have been derived from p-SINE1.