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.     

稻属不同染色体组着丝粒BAC克隆的分离和鉴定

着丝粒在真核生物有丝分裂和减数分裂染色体正常的分离和传递中起着重要的作用。通过构建5个稻属二倍体野生种的基因组BAC文库, 采用菌落杂交和FISH技术, 筛选和鉴定了各染色体组着丝粒克隆, 并且分析了这些克隆在不同基因组间的共杂交情况, 结果表明: (1) C染色体组的野生种O. officinalis 和F染色体组的野生种O. brachyantha具有各自着丝粒特异的卫星DNA序列, 并且O. brachyantha着丝粒还具有特异的逆转座子序列; (2) A、B和E染色体组的野生稻O. glaberrima、O. punctata和O. australiensis着丝粒区域都含有与栽培稻着丝粒重复序列CentO和CRR同源的序列; (3) C染色体组野生稻O. officinalis的2条体细胞染色体着丝粒具有CentO的同源序列, 同时也发现其所有着丝粒区域都包含栽培稻CRR的同源序列。这些结果对克隆稻属不同染色体组的着丝粒序列、研究不同染色体组间着丝粒的进化关系和稻属不同着丝粒DNA序列与功能之间的关系均具有重要意义。     

Expression of CENH3 alleles in synthesized allopolyploid Oryza species

Synthesized allopolyploids are valuable materials for comparative analyses of two or more distinct genomes,such as the expression changes(activation,inactivation or differential expression)of orthologous genes following allopolyploidization.CENH3 is a centromerespecific histone H3 variant and has been regarded as a central component in kinetochore formation and centromere function.In this study,interspecific hybrids of Oryza genus(AA × CC,AA × CCDD)and their backcross progenies were produced,and the genome constitutions were identified as AC,ACC,ACD,AACD,or AA(CD)by Genomic in situ hybridization(GISH).We further cloned and sequenced the CENH3 genes from O.sativa(AA),O.officinalis(CC)and O.latifolia(CCDD).Sequencing of RT-PCR products revealed that CENH3_C2 and CENH3_D,the two CENH3 alleles from O.latifolia,showed polymophism in several sites,while CENH3_C2 and CENH3_C1 from O.officinalis were different at only two amino acids positions.Moreover,we found that the CENH3 genes from both parents are expressed in interspecific hybrids and their progenies.Specifically,based on our cDNA sequencing data,the ratio of expression level between CENH3_A and CENH3_C1 was approximately 1 in AC and 0.5 in ACC genomes,respectively.As a result,the CENH3 expression patterns shed more light on the inter-coordination between varied centromeric DNA sequences and highly conserved kinetochore protein in synthesized allopolyploids of Oryza genus.     

Simple sequence repeat analyses of interspecific hybrids and MAALs of <Emphasis Type="Italic">Oryza </Emphasis><Emphasis Type="Italic">officinalis</Emphasis> and <Emphasis Type="Italic">Oryza sativa</Emphasis>

Wild rice is a valuable resource for the genetic improvement of cultivated rice (Oryza sativa L., AA genome). Molecular markers are important tools for monitoring gene introgression from wild rice into cultivated rice. In this study, Simple sequence repeat (SSR) markers were used to analyze interspecific hybrids of O. sativa-O. officinalis (CC genome), the backcrossing progenies and the parent plants. Results showed that most of the SSR primers (335 out of 396, 84.6%) developed in cultivated rice successfully amplified products from DNA samples of wild rice O. officinalis. The polymorphism ratio of SSR bands between O. sativa and O. officinalis was as high as 93.9%, indicating differences between the two species with respect to SSRs. When the SSR markers were applied in the interspecific hybrids, only a portion of SSR primers amplified O. officinalis-specific bands in the F(1) hybrid (52.5%), BC(1) (52.5%), and MAALs (37.0%); a number of the bands disappeared. Of the 124 SSR loci that detected officinalis-specific bands in MAAL plants, 96 (77.4%) showed synteny between the A and C-genomes, and 20 (16.1%) showed duplication in the C-genome. Sequencing analysis revealed that indels, substitution and duplication contribute to the diversity of SSR loci between the genomes of O. sativa and O. officinalis.     

Polymorphisms and evolutionary history of retrotransposon insertions in rice promoters

Retrotransposons are ubiquitous in higher plant genomes. The presence or absence of retrotransposons in whole genome and high throughput genomic sequence (HTGS) from cultivated and wild rice was investigated to understand the organization and evolution of retrotransposon insertions in promoter regions. Approximately half of the Oryza sativa subsp. japonica 'Nipponbare' promoters with retrotransposons conserved in Oryza sativa subsp. indica '93-11' and four wild rice species showed higher sequence conservation in retrotransposon than nonretrotransposon regions. We further investigated, in detail, the evolutionary dynamics of five retrotransposons in the promoter regions of 95 rice genotypes. Our data suggest that four of five insertions (Rp2-Rp5) occurred in the ancestor of AA genome, while the other insertion (Rp1) predates the ancestral divergence of Oryza officinalis (CC genome). Four retrotransposons (Rp2-Rp5) were present in 52% (Rp2), 29% (Rp3), 53% (Rp4), and 43% (Rp5) of the rice genotypes with AA genome type, and the fifth retrotransposon (Rp1) was present in 95% of the rice genotypes with AA, BBCC, or CC genome types. Furthermore, most of these retrotransposons were found to evolve slower than flanking promoter regions, suggesting a role in promoter function for regulating downstream genes.     

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.     

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.     

Identification of Chromosomes from Multiple Rice Genomes Using a Universal Molecular Cytogenetic Marker System

To develop reliable techniques for chromosome identification is critical for cytogenetic research, especially for genomes with a large number and smaller-sized chromosomes. An efficient approach using bacterial artificial chromosome （BAC） clones as molecular cytological markers has been developed for many organisms. Herein, we present a set of chromosomal arm-specific molecular cytological markers derived from the gene-enriched regions of the sequenced rice genome. All these markers are able to generate very strong signals on the pachytene chromosomes of Oryza sativa L. （AA genome） when used as fluorescence in situ hybridization （FISH） probes. We further probed those markers to the pachytene chromosomes of O. punctata （BB genome） and O. officinalis （CC genome） and also got very strong signals on the relevant pachytene chromosomes. The signal position of each marker on the related chromosomes from the three different rice genomes was pretty much stable, which enabled us to identify different chromosomes among various rice genomes. We also constructed the karyotype for both O. punctata and O. officinalis with the BB and CC genomes, respectively, by analysis of 10 pachytene cells anchored by these chromosomal arm-specific markers.     

Dynamic nucleotide-binding site and leucine-rich repeat-encoding genes in the grass family

The proper use of resistance genes (R genes) requires a comprehensive understanding of their genomics and evolution. We analyzed genes encoding nucleotide-binding sites and leucine-rich repeats in the genomes of rice (Oryza sativa), maize (Zea mays), sorghum (Sorghum bicolor), and Brachypodium distachyon. Frequent deletions and translocations of R genes generated prevalent presence/absence polymorphism between different accessions/species. The deletions were caused by unequal crossover, homologous repair, nonhomologous repair, or other unknown mechanisms. R gene loci identified from different genomes were mapped onto the chromosomes of rice cv Nipponbare using comparative genomics, resulting in an integrated map of 495 R loci. Sequence analysis of R genes from the partially sequenced genomes of an African rice cultivar and 10 wild accessions suggested that there are many additional R gene lineages in the AA genome of Oryza. The R genes with chimeric structures (termed type I R genes) are diverse in different rice accessions but only account for 5.8% of all R genes in the Nipponbare genome. In contrast, the vast majority of R genes in the rice genome are type II R genes, which are highly conserved in different accessions. Surprisingly, pseudogene-causing mutations in some type II lineages are often conserved, indicating that their conservations were not due to their functions. Functional R genes cloned from rice so far have more type II R genes than type I R genes, but type I R genes are predicted to contribute considerable diversity in wild species. Type I R genes tend to reduce the microsynteny of their flanking regions significantly more than type II R genes, and their flanking regions have slightly but significantly lower G/C content than those of type II R genes.     

Targeted analysis of orthologous phytochrome A regions of the sorghum,maize, and rice genomes using comparative gene-island sequencing

A "gene-island" sequencing strategy has been developed that expedites the targeted acquisition of orthologous gene sequences from related species for comparative genome analysis. A 152-kb bacterial artificial chromosome (BAC) clone from sorghum (Sorghum bicolor) encoding phytochrome A (PHYA) was fully sequenced, revealing 16 open reading frames with a gene density similar to many regions of the rice (Oryza sativa) genome. The sequences of genes in the orthologous region of the maize (Zea mays) and rice genomes were obtained using the gene-island sequencing method. BAC clones containing the orthologous maize and rice PHYA genes were identified, sheared, subcloned, and probed with the sorghum PHYA-containing BAC DNA. Sequence analysis revealed that approximately 75% of the cross-hybridizing subclones contained sequences orthologous to those within the sorghum PHYA BAC and less than 25% contained repetitive and/or BAC vector DNA sequences. The complete sequence of four genes, including up to 1 kb of their promoter regions, was identified in the maize PHYA BAC. Nine orthologous gene sequences were identified in the rice PHYA BAC. Sequence comparison of the orthologous sorghum and maize genes aided in the identification of exons and conserved regulatory sequences flanking each open reading frame. Within genomic regions where micro-colinearity of genes is absolutely conserved, gene-island sequencing is a particularly useful tool for comparative analysis of genomes between related species.     

Bph3在栽培稻和药用野生稻中的BAC-FISH比较物理定位

用栽培稻(Oryza sativa L.)遗传图第四连锁群中与抗褐稻虱基因Bph3紧密连锁的RFLP标记RZ69及筛选出来的BAC克隆38J9作探针,对药用野生稻(O.officinalis Well ex Watt)和栽培稻荧光原位杂交,供试标记RZ69及38J9均被定位于药用野生稻和栽培稻第4染色体的短臂上,药用野生稻杂交信号的百分距分别为22.12±3.44和20.00±5.40,而栽培稻均为0.在栽培稻中,信号检出率相应地为6.29%和56.10%,在药用野生稻中则为6.14%和50.00%.BAC克隆和RFLP标记探针杂交信号的百分距十分接近,说明在栽培稻和野生稻中RFLP标记RZ69都在同一BAC克隆的大插入片段中.由此推知,药用野生稻与抗性基因Bph3的同源顺序就在第4染色体信号出现的相应位置.在未封阻的情况下,药用野生稻的BAC杂交在多条染色体上具有信号,这表明它和栽培稻的Cot-1 DNA重复顺序也在一定程度上具有同源性.药用野生稻第4染色体是根据栽培稻与药用野生稻的比较遗传图选用与Gm-6连锁的RG214通过FISH确定的.讨论了栽培稻BAC克隆对药用野生稻比较原位杂交物理作图的可行性问题.     

Long-range and targeted ectopic recombination between the two homeologous chromosomes 11 and 12 in Oryza species

Whole genome duplication (WGD) and subsequent evolution of gene pairs have been shown to have shaped the present day genomes of most, if not all, plants and to have played an essential role in the evolution of many eukaryotic genomes. Analysis of the rice (Oryza sativa ssp. japonica) genome sequence suggested an ancestral WGD ～50-70 Ma common to all cereals and a segmental duplication between chromosomes 11 and 12 as recently as 5 Ma. More recent studies based on coding sequences have demonstrated that gene conversion is responsible for the high sequence conservation which suggested such a recent duplication. We previously showed that gene conversion has been a recurrent process throughout the Oryza genus and in closely related species and that orthologous duplicated regions are also highly conserved in other cereal genomes. We have extended these studies to compare megabase regions of genomic (coding and noncoding) sequences between two cultivated (O. sativa, Oryza glaberrima) and one wild (Oryza brachyantha) rice species using a novel approach of topological incongruency. The high levels of intraspecies conservation of both gene and nongene sequences, particularly in O. brachyantha, indicate long-range conversion events less than 4 Ma in all three species. These observations demonstrate megabase-scale conversion initiated within a highly rearranged region located at ～2.1 Mb from the chromosome termini and emphasize the importance of gene conversion in cereal genome evolution.     

New insights into <Emphasis Type="Italic">Oryza</Emphasis> genome evolution: high gene colinearity and differential retrotransposon amplification

An ∼247-kb genomic region from FF genome of wild rice Oryza brachyantha, possessing the smallest Oryza genome, was compared to the orthologous ∼450-kb region from AA genome, O. sativa L. ssp. japonica. 37 of 38 genes in the orthologous regions are shared between japonica and O. brachyantha. Analyses of nucleotide substitution in coding regions suggest the two genomes diverged ∼10 million years ago. Comparisons of transposable elements (TEs) reveal that the density of DNA TEs in O. brachyantha is comparable to O. sativa; however, the density of RNA TEs is dramatically lower. The genomic fraction of RNA TEs in japonica is two times greater than in O. brachyantha. Differences, particularly in RNA TEs, in this region and in BAC end sequences from five wild and two cultivated Oryza species explain major genome size differences between sativa and brachyantha. Gene expression analyses of three ObDREB1 genes in the sequenced region indicate orthologous genes retain similar expression patterns following cold stress. Our results demonstrate that size and number of RNA TEs play a major role in genomic differentiation and evolution in Oryza. Additionally, distantly related O. brachyantha shares colinearity with O. sativa, offering opportunities to use comparative genomics to explore the genetic diversity of wild species to improve cultivated rice. Electronic supplementary material The online version of this article (doi:) contains supplementary material, which is available to authorized users. Data deposition: Sequence data from this article were deposited with GenBank Library under accession number DQ810282. Shibo Zhang and Yong Qiang Gu contributed equally to the work     

Cloning and characterization of repetitive DNA sequences from genomes of Oryza minuta and Oryza australiensis

The value of genome-specific repetitive DNA sequences for use as molecular markers in studying genome differentiation was investigated. Five repetitive DNA sequences from wild species of rice were cloned. Four of the clones, pOm1, pOm4, pOmA536, and pOmPB10, were isolated from Oryza minuta accession 101141 (BBCC genomes), and one clone, pOa237, was isolated from Oryza australiensis accession 100882 (EE genome). Southern blot hybridization to different rice genomes showed strong hybridization of all five clones to O. minuta genomic DNA and no cross hybridization to genomic DNA from Oryza sativa (AA genome). The pOm1 and pOmA536 sequences showed cross hybridization only to all of the wild rice species containing the C genome. However, the pOm4, pOmPB10, and pOa237 sequences showed cross hybridization to O. australiensis genomic DNA in addition to showing hybridization to the O. minuta genomic DNA.     

Rate and polarity of gene fusion and fission in Oryza sativa and Arabidopsis thaliana

Eukaryotic gene fusion and fission events are mechanistically more complicated than in prokaryotes, and their quantitative contributions to genome evolution are still poorly understood. We have identified all differentially composite or split genes in 2 fully sequenced plant genomes, Oryza sativa and Arabidopsis thaliana. Out of 10,172 orthologous gene pairs, 60 (0.6% of the total) revealed a verified fusion or fission event in either lineage after the divergence of O. sativa and A. thaliana. Polarizing these events by outgroup comparison revealed differences in the rate of gene fission but not of gene fusion in the rice and Arabidopsis lineages. Gene fission occurred at a higher rate than gene fusion in the O. sativa lineage and was furthermore more common in rice than in Arabidopsis. Nucleotide insertion bias has promoted gene fission in the O. sativa lineage, consistent with its generally longer nucleotide sequences than A. thaliana in selectively neutral regions, and with the abundance of transposable elements in rice. The divergence time of monocots and dicots (140-200 Myr) indicates that gene fusion/fission events occur at an average rate of 1x10(-11) to 2x10(-11) events per gene per year, approximately 100-fold slower than the average per site nuclear nucleotide substitution rate in these lineages. Gene fusion and fission are thus rare and slow processes in higher plant genomes; they should be of utility to address deeper evolutionary relationships among plants--and the relationship of plants to other eukaryotic lineages--where sequence-based phylogenies provide equivocal or conflicting results.     

A novel repetitive DNA sequence in the genus Oryza

Summary Repetitive DNA sequences in the genus Oryza (rice) represent a large fraction of the nuclear DNA. The isolation and characterization of major repetitive DNA sequences will lead to a better understanding of rice genome organization and evolution. Here we report the characterization of a novel repetitive sequence, CC-1, from the CC genome. This repetitive sequence is present as long tandem arrays with a repeat unit 194 bp in length in the CC-diploid genome but 172 bp in length in the BBCC and CCDD tetraploid genomes. This repetitive sequence is also present, though at lower copy numbers, in the AA and BB genomes, but is absent in the EE and FF genomes. Hybridization experiments revealed considerable differences both in copy numbers and in restriction fragment patterns of CC-1 both between and within rice species. The results support the hypothesis that the CC genome is more closely related to the AA genome than to the BB genome, and most distantly related to the EE and FF genomes.     

重复DNA顺序pRRD9在稻属中的拷贝数测定

本文应用狭缝印渍杂交方法,把水稻基因组总DNA和含水稻中度重复顺序片段的质粒(pRRD9)DNA分别转移到尼龙膜上形成狭缝印渍、然后用~(32)P标记的 pRRD9插入片段进行杂交、根据各狭缝印渍的放射性强度,测定水稻(Oryza)一些栽培种和野生种基因组中重复DNA顺序的拷贝数,并就拷贝数与水稻进化关系及基因组型的联系进行讨论.     

A new comprehensive annotation of leucine-rich repeat-containing receptors in rice

Oryza sativa (rice) plays an essential food security role for more than half of the world’s population. Obtaining crops with high levels of disease resistance is a major challenge for breeders, especially today, given the urgent need for agriculture to be more sustainable. Plant resistance genes are mainly encoded by three large leucine-rich repeat (LRR)-containing receptor (LRR-CR) families: the LRR-receptor-like kinase (LRR-RLK), LRR-receptor-like protein (LRR-RLP) and nucleotide-binding LRR receptor (NLR). Using lrrprofiler , a pipeline that we developed to annotate and classify these proteins, we compared three publicly available annotations of the rice Nipponbare reference genome. The extended discrepancies that we observed for LRR-CR gene models led us to perform an in-depth manual curation of their annotations while paying special attention to nonsense mutations. We then transferred this manually curated annotation to Kitaake, a cultivar that is closely related to Nipponbare, using an optimized strategy. Here, we discuss the breakthrough achieved by manual curation when comparing genomes and, in addition to ‘functional’ and ‘structural’ annotations, we propose that the community adopts this approach, which we call ‘comprehensive’ annotation. The resulting data are crucial for further studies on the natural variability and evolution of LRR-CR genes in order to promote their use in breeding future resilient varieties.     

水稻两个frr基因的结构、转录特性及同源性分析

对水稻中两个核糖体再循环因子同源基因OsfrrA和OsfrrB进行了鉴定与分析.这两个单拷贝基因分别位于水稻的4号和7号染色体上,且在细胞器基因组中未发现同源序列.它们在不同组织中的转录特性及其蛋白质产物的N端特征提示其翻译产物会被各自转运并分别定位于线粒体和叶绿体中,而序列上的保守性及构成性的表达则表明它们在植物生长中扮演着重要的角色.它们与其它原核及真核RRF之间在基因结构及编码序列上的异同为内共生学说提供了新的证据,也揭示了RRF在分子进化研究方面所具有的潜在价值.