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.     

Genetic variation in Oryza species detected by MITE-AFLP

MITE-AFLP markers were successfully used to study the genetic variation and species relationship in Oryza species. Analysis of 53 accessions of Oryza species with seven MITE-AFLP primer combinations detected a total of 250 polymorphic fragments. High polymorphism was detected within and between Oryza species. 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 genetic distances (GDs) between species were higher than those within species and the GDs in O. sativa complex were higher than those in O. officinalis complex. The phylogenetic tree recognized two major groups at 62% genetic similarity; group I consists of all AA genome species of the O. sativa complex, and group II consists of BB-, CC-, EE- and BBCC genome species of the O. officinalis complex. Therefore, this study demonstrated that the MITE-AFLP technique provide a tool for studying the genetic variation and species relationship in Oryza species.     

Patterns of sequence divergence and evolution of the S orthologous regions between Asian and African cultivated rice species

A strong postzygotic reproductive barrier separates the recently diverged Asian and African cultivated rice species, Oryza sativa and O. glaberrima. Recently a model of genetic incompatibilities between three adjacent loci: S(1)A, S(1) and S(1)B (called together the S(1) regions) interacting epistatically, was postulated to cause the allelic elimination of female gametes in interspecific hybrids. Two candidate factors for the S(1) locus (including a putative F-box gene) were proposed, but candidates for S(1)A and S(1)B remained undetermined. Here, to better understand the basis of the evolution of regions involved in reproductive isolation, we studied the genic and structural changes accumulated in the S(1) regions between orthologous sequences. First, we established an 813 kb genomic sequence in O. glaberrima, covering completely the S(1)A, S(1) and the majority of the S(1)B regions, and compared it with the orthologous regions of O. sativa. An overall strong structural conservation was observed, with the exception of three isolated regions of disturbed collinearity: (1) a local invasion of transposable elements around a putative F-box gene within S(1), (2) the multiple duplication and subsequent divergence of the same F-box gene within S(1)A, (3) an interspecific chromosomal inversion in S(1)B, which restricts recombination in our O. sativa×O. glaberrima crosses. Beside these few structural variations, a uniform conservative pattern of coding sequence divergence was found all along the S(1) regions. Hence, the S(1) regions have undergone no drastic variation in their recent divergence and evolution between O. sativa and O. glaberrima, suggesting that a small accumulation of genic changes, following a Bateson-Dobzhansky-Muller (BDM) model, might be involved in the establishment of the sterility barrier. In this context, genetic incompatibilities involving the duplicated F-box genes as putative candidates, and a possible strengthening step involving the chromosomal inversion might participate to the reproductive barrier between Asian and African rice 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。     

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.     

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.     

The molecular basis of white pericarps in African domesticated rice: novel mutations at the Rc gene

Repeated phenotypic evolution can occur at both the inter- and intraspecific level and is especially prominent in domesticated plants, where artificial selection has favoured the same traits in many different species and varieties. The question of whether repeated evolution reflects changes at the same or different genes in each lineage can now be addressed using the domestication and improvement genes that have been identified in a variety of crops. Here, we document the genetic basis of nonpigmented ('white') pericarps in domesticated African rice (Oryza glaberrima) and compare it with the known genetic basis of the same trait in domesticated Asian rice (Oryza sativa). In some cases, white pericarps in African rice are apparently caused by unique mutations at the Rc gene, which also controls pericarp colour variation in Asian rice. In one case, white pericarps appear to reflect changes at a different gene or potentially a cis-regulatory region.     

Diversification of the rice Waxy gene by insertion of mobile DNA elements into introns.

The waxy (wx) gene of Oryza glaberrima was cloned, and its nucleotide sequence was determined. A waxy mutant of O. glaberrima showing a glutinous phenotype was found to contain a substitution mutation generating a termination codon in the coding region of the wx gene. The Wx sequence of O. glaberrima was different from that of Oryza sativa by substitutions and insertions/deletions, among which only a few substitutions occurred in several exons not to severely alter the amino acid sequence of the Wx protein. The most striking difference observed in introns was a 139-bp deletion (or insertion) in intron 10 of O. glaberrima (or O. sativa). In O. sativa, 125 bp of the 139-bp sequence was flanked by direct repeats of a 14-bp sequence. A sequence homologous to the 125-bp sequence was found in the region preceding exon 2; this sequence was also flanked by direct repeats of another 14-bp sequence. This result and the observation that the 125-bp sequence was interspersed in rice genomes indicate that they are SINEs (short interspersed elements) in the plant system. We also identified a DNA sequence with long terminal inverted repeats in intron 13 of both O. glaberrima and O. sativa. This sequence was present in multiple copies in rice genomes, suggesting that it is a transposable element. These results obtained suggest that mobile DNA elements have diversified the rice Waxy gene by inserting into introns, each of which may originally have a length of about 100 bp.     

Evolutionary relationships among rice species with AA genome based on SINE insertion analysis

Previous studies based on morphological and molecular markers indicated that there are two cultivated and five wild rice species within the Oryza genus with the AA genome. In the cultivated rice species, Oryza sativa, a retroposon named p-SINE1 has been identified. Some of the p-SINE1 members characterized previously showed interspecific insertion polymorphisms in the species with the AA genome. In this study, we identified new p-SINE1 members showing interspecific insertion polymorphisms from representative strains of four wild rice species with the AA genome: O. barthii, O. glumaepatula, O. longistaminata, and O. meridionalis. Some of these members were present only in strains of one species, whereas the others were present in strains of two or more species. The p-SINE1 insertion patterns in the strains of the Asian and African cultivated rice species O. sativa and O. glaberrima were very similar to those of the Asian and African wild rice species O. rufipogon and O. barthii, respectively. This is consistent with the previous hypothesis that O. sativa and O. glaberrima are derived from specific wild rice species. Phylogenetic analysis based on the p-SINE1 insertion patterns showed that the strains of each of the five wild rice species formed a cluster. The strains of O. longistaminata appear to be distantly related to those of O. meridionalis. The strains of these two species appear to be distantly related to those of three other species, O. rufipogon, O. barthii and O. glumaepatula. The latter three species are closely related to one another with O. barthii and O. glumaepatula being most closely related. A phylogenetic tree including a hypothetical ancestor with all loci empty for p-SINE1 insertion showed that the strains of O. longistaminata are related most closely to the hypothetical ancestor. This indicates that O. longistaminata and O. meridionalis diverged early on, whereas the other species diverged relatively recently, and suggests that the Oryza genus with AA genome might have originated in Africa, rather than in Asia.     

Characterization of a plant SINE, p-SINE1, in rice genomes.

We have previously found that a short interspersed element (SINE), named p-SINE1, is present in the Waxy gene of Oryza sativa in two copies. Here, we cloned five members of p-SINE1 located at other loci in O. sativa and determined their nucleotide sequences. These sequences had a T-rich pyrimidine tract at their defined 3' end and were flanked by direct repeats of a sequence of mostly 14-15 bp long like p-SINE1s in the Waxy gene. The consensus sequence derived from total seven members of p-SINE1 was 123 bp in length and had an internal promoter region for RNA polymerase III. The 5'-half region of the sequence was partially homologous to the tRNA-related block of rabbit C family, one of SINEs in the animal system. Two of the seven p-SINE1 members were not present in the corresponding loci in African rice, Oryza glaberrima, and may thus be available for classification of some rice strains. Comparison of the nucleotide sequences of the Waxy gene between O. sativa and O. glaberrima showed that base substitutions have frequently occurred in a p-SINE1 member (p-SINE1-r1) and a transposable element Tnr1 also present in the Waxy gene, suggesting that these elements, which appear as repetitive sequences in the rice chromosome, tend to acquire base substitutions at a higher frequency than do unique sequences.     

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.     

QTL detection for rice grain quality traits using an interspecific backcross population derived from cultivated Asian (O. sativa L.) and African (O. glaberrima S.) rice.

An interspecific advanced backcross population derived from a cross between Oryza sativa "V20A" (a popular male-sterile line used in Chinese rice hybrids) and Oryza glaberrima (accession IRGC No. 103544 from Mali) was used to identify quantitative trait loci (QTL) associated with grain quality and grain morphology. A total of 308 BC3F1 hybrid families were evaluated for 16 grain-related traits under field conditions in Changsha, China, and the same families were evaluated for RFLP and SSR marker segregation at Cornell University (Ithaca, N.Y.). Eleven QTL associated with seven traits were detected in six chromosomal regions, with the favorable allele coming from O. glaberrima at eight loci. Favorable O. glaberrima alleles were associated with improvements in grain shape and appearance, resulting in an increase in kernel length, transgressive variation for thinner grains, and increased length to width ratio. Oryza glaberrima alleles at other loci were associated with potential improvements in crude protein content and brown rice yield. These results suggested that genes from O. glaberrima may be useful in improving specific grain quality characteristics in high-yielding O. sativa hybrid cultivars.     

Sex-independent transmission ratio distortion system responsible for reproductive barriers between Asian and African rice species

* A sex-independent transmission ratio distortion (siTRD) system detected in the interspecific cross in rice was analyzed in order to understand its significance in reproductive barriers. The S(1) gene, derived from African rice Oryza glaberrima, induced preferential abortion of both male and female gametes possessing its allelic alternative (), from Asian rice O. sativa, only in the heterozygote. * The siTRD was characterized by resolving it into mTRD and fTRD occurring through male and female gametes, respectively, cytological analysis of gametophyte development, and mapping of the S(1) locus using near-isogenic lines. The allelic distribution of the S(1) locus in Asian and African rice species complexes was also analyzed. * The siTRD system involved at least two components affecting male and female gametogeneses, respectively, including a modifier(s) that enhances fTRD. The chromosomal location of the major component causing the mTRD was delimited within an approx. 40 kb region. The S(1) locus induced hybrid sterility in any pairwise combination between Asian and African rice species complexes. * The allelic state of the S(1) locus has diverged between Asian and African rice species complexes, suggesting that the TRD system has a significant role in the reproductive barriers in rice.     

Subspecies-specific intron length polymorphism markers reveal clear genetic differentiation in common wild rice （Oryza rufipogon L.） in relation to the domestication of cultivated rice （O. sativa L.）

It is generally accepted that Oryza rufipogon is the progenitor of Asian cultivated rice （O. sativa）. However, how the two subspecies of O. sativa （indica and japonica） were domesticated has long been debated. To investigate the genetic differentiation in O. rufipogon in relation to the domestication of O. sativa, we developed 57 subspecies-specific intron length polymorphism （SSILP） markers by comparison between 10 indica cultivars and 10 japonica cultivars and defined a standard indica rice and a standard japonica rice based on these SSILP markers. Using these SSILP markers to genotype 73 O. rufipogon accessions, we found that the indica alleles and japonica alleles of the SSILP markers were predominant in the O. rufipogon accessions, suggesting that SSILPs were highly conserved during the evolution of O. sativa. Cluster analysis based on these markers yielded a dendrogram consisting of two distinct groups： one group （Group I） comprises all the O. rufipogon accesions from tropical （South and Southeast） Asia as well as the standard indica rice; the other group （Group II） comprises all the O. rufipogon accessions from Southern China as well as the standard japonica rice. Further analysis showed that the two groups have significantly higher frequencies of indica alleles and japonica alleles, respectively. These results support the hypothesis that indica rice and japonica rice were domesticated from the O. rufipogon of tropical Asia and from that of Southern China, respectively, and suggest that the indica-japonica differentiation should have formed in O. rufipogon long before the beginning of domestication. Furthermore, with an O. glaberrima accession as an outgroup, it is suggested that the indica-japonica differentiation in O. ruffpogon might occur after its speciation from other AA-genome species.     

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.     

A new MITE family,Pangrangja, in Gramineae species

The miniature inverted-repeat transposable element (MITE) is a type of class II transposon. We have isolated a new MITE, Pangrangja, from the species Oryza. Although Pangrangja elements are present in a number of Gramineae species, they are more prevalent in A genome Oryza species, Triticum, Aegilops, Hordeum, and Tripsacum. The Pangrangja has a 16 bp terminal inverted repeat (TIR) and conserved trinucleotides 5'-TTG-3' and 5'-AAA-3' at both ends. The TIR starts with 5'-CAGT-3', similar to the MITEs of the Emigrant family. The sequences between TIRs are very AT-rich and vary in length from 161 bp in A genome Oryza species to 513 bp in Hordeum vulgare. While the size and sequence of Pangrangia elements are conserved in the A genome Oryza species, there is some sequence variation in other plants. In an analysis of the mobile history of Oryza sativa, eight RESites (related to empty sites) were found and grouped into three types depending on the presence or absence of the conserved trinucleotides 5'-TTG-3' and 5'-AAA-3'. Since one of the RESites showed a perfect palindromic 22 bp sequence into which 180 bp of the Pangrangja element was inserted, the possible role of secondary structure of the palindromic sequences is discussed. We also suggest that as Pangrangja MITE-AFLP has been successful in many different Gramineae, Pangrangja elements may be useful in the genomic analysis of grasses.     

Conservation and purifying selection of transcribed genes located in a rice centromere

Recombination is strongly suppressed in centromeric regions. In chromosomal regions with suppressed recombination, deleterious mutations can easily accumulate and cause degeneration of genes and genomes. Surprisingly, the centromere of chromosome8 (Cen8) of rice (Oryza sativa) contains several transcribed genes. However, it remains unclear as to what selective forces drive the evolution and existence of transcribed genes in Cen8. Sequencing of orthologous Cen8 regions from two additional Oryza species, Oryza glaberrima and Oryza brachyantha, which diverged from O. sativa 1 and 10 million years ago, respectively, revealed a set of seven transcribed Cen8 genes conserved across all three species. Chromatin immunoprecipitation analysis with the centromere-specific histone CENH3 confirmed that the sequenced orthologous regions are part of the functional centromere. All seven Cen8 genes have undergone purifying selection, representing a striking phenomenon of active gene survival within a recombination-free zone over a long evolutionary time. The coding sequences of the Cen8 genes showed sequence divergence and mutation rates that were significantly reduced from those of genes located on the chromosome arms. This suggests that Oryza has a mechanism to maintain the fidelity and functionality of Cen8 genes, even when embedded in a sea of repetitive sequences and transposable elements.     

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.     

2012年第11期《遗传》封面说明

作物的驯化是人类从开始种植和储存的野生作物中选择优良性状,使之形态特征适应于农业生产方向进化的过程,因此,大部分种子作物驯化后在落粒性、种子休眠和植株形态等方面都出现了相似的变化。水稻是研究谷类作物驯化的良好模式生物。稻属包含2种栽培稻,分别为亚洲栽培稻(Oryza sativa L.)和非洲栽培稻(O. glaberrima Steud.),其中亚洲栽培稻遍布全世界,包含两个主要亚种,粳稻亚种(O. sativa L. ssp. japonica)和籼稻亚种(O. sativa L. ssp. indica)。稻属丰富的近缘种和广泛的地域分布非常有利于研究确定现代栽培稻的驯化地域。此外,水稻基因组较小、具高质量精细图谱,加上功能基因研究上的进展,也为深入开展水稻驯化进程研究奠定了基础。详见本期第XX-XX页区树俊,汪鸿儒,储成才“亚洲栽培稻主要驯化性状研究进展”,对水稻关键驯化性状研究进行的比较全面的综述。封面图中央是选取23株AA基因组的亚洲栽培稻及其近缘野生稻,利用水稻驯化过程中受到选择的控制稻壳颜色基因Bh4上下游各50 kb中的SNP位点所构建的进化树;图外从左下至右下沿顺时针方向,反映的是水稻驯化过程中稻壳颜色、谷粒形状、穗型的变化趋势。 区树俊,汪鸿儒,储成才（绘图：区树俊）     

Phylogenetic Analysis of AA-genome Oryza Species (Poaceae) Based on Chloroplast, Mitochondrial, and Nuclear DNA Sequences

Species in the genus Oryza (Poaceae) contain 10 genomic types and are distributed in pan-tropics of the world. To explore phylogenetic relationships of Oryza species having the AA-genome, DNA sequences of the chloroplast trnL intron and trnL-trnF spacer, mitochondrial nad1 intron 2, and nuclear internal transcribed spacer were analyzed, based on materials from 6 cultivated (O. sativa and O. glaberrima) and 13 wild accessions, in addition to a CC-genome species (O. officinalis) that was used as an outgroup. Analyses of the combined sequence data set from different sources provide a much better resolution of the AA-genome species than the individual data set, indicating the limitation of a single gene in phylogenetic reconstruction. The phylogeny based on the combined data set demonstrated an apparent grouping of the AA-genome Oryza species that was well associated with their geographic origin, although the Australian O. meridionalis showed its affinity with the African species. The geographic pattern of the phylogenetic relationship was probably attributed to the frequent genetic exchange and introgression among the AA-genome species from the same continents. In addition, Asian cultivated rice O. sativa showed its close relation to O. rufipogon and O. nivara, whereas African cultivated rice O. glaberrima was closely linked to O. barthii and O. longistaminata, indicating the independent domestication of the two cultivated species in different geographic locations.