东北地区杂草稻与栽培稻的遗传多样性及籼粳分化

利用88对籼粳特异性分子标记对收集于我国东北三省的35份杂草稻和36份栽培稻遗传基础及籼粳分化进行研究,结果表明上述标记能够高效地鉴别稻属资源的籼粳属性,共检测到156个等位基因,平均有效等位基因(Na)为1.773。遗传多样性分析表明,东北地区杂草稻多样性水平略高于当地栽培稻,其中杂草稻的等位基因数(Na)、杂合度(He)、基因多样性(Hsk)以及多态性信息含量(PIC)分别为1.659、0.006、0.076和0.085,而东北栽培稻分别为1.557、0.004、0.060和0.067。遗传结构和聚类分析结果表明,东北地区杂草稻与栽培稻具有较近的亲缘关系,均存在一定程度的籼粳分化。进一步对籼粳血缘进行相对量化分析发现,杂草稻的籼型基因型频率(F_i=0.050)略高于当地栽培稻(F_i=0.043)。东北三省籼型基因型频率变化趋势为:辽宁杂草稻(0.062)辽宁栽培稻(0.058)吉林栽培稻(0.048)黑龙江杂草稻(0.041)吉林杂草稻(0.024)黑龙江栽培稻(0.020)。     

辽宁和江苏两省杂草稻植物性状多样性

辽宁和江苏两省是我国杂草稻(Oryza sativa f. spontanea)发生最为严重的地区之一, 为明确两省杂草稻识别特征和类型, 我们在两省14个市29个样点采集样品, 与当地栽培水稻品种一并在南京种植, 观测了营养生长期和生殖生长期的23个植物性状。结果表明, 两省杂草稻在营养生长期的1月株高、1月和2月分蘖数, 在生殖生长期的果皮色、谷粒长/宽比、百粒重、落粒性、秆硬度、剑叶宽、剑叶长、有效穗数、50%黄熟、50%黄熟–50%抽穗和全黄熟等性状与相应的当地栽培稻存在差异;主成分1和主成分2组成的二维散点图(累计贡献率达43.24%)也显示出两省杂草稻间以及与栽培稻间的差异性。采用欧氏距离对两省杂草稻进行系统聚类可以将杂草稻分为籼型和粳型。其中辽宁省杂草稻全部聚在粳型类群中, 它们又可细分为两类; 江苏省杂草稻既有粳型, 又有籼型, 其中粳型与辽宁省杂草稻聚在粳型类群中, 籼型又可分为3类。这6个类群分别具有如下突出特点: 第1类为强落粒、粒轻、秆矮、早熟、偏粳等; 第2类为无芒、穗多、强休眠、剑叶窄、偏粳等; 第3类为长芒、弱分蘖、穗少、弱落粒、偏粳等; 第4类为硬秆、剑叶宽、迟熟、强休眠、偏籼等; 第5类为红果皮、粒长、软秆、粒重、偏籼等; 第6类为无芒、株高、穗长、剑叶长、偏籼等。上述杂草稻的形态学指标和类型的研究将为两省开展杂草稻危害防治工作提供理论依据。     

普通野生稻和亚洲栽培稻线粒体DNA的RFLP分析

通过７个探针、１７种内切酶探针组合对１１８份普通野生稻和７６份亚洲栽培稻的线粒体ＤＮＡ（ｍｔＤＮＡ）ＲＦＬＰ分析表明,籼粳分化是亚洲栽培稻线粒体基因组分化的主流,７６个栽培稻中,３６个品种ｍｔＤＮＡ为籼型,４０个品种ｍｔＤＮＡ为粳型。普通野生稻ｍｔＤＮＡ以籼型为主（８６份）,粳型较少（７份）,１份类型难以确定,还有２４份没有籼粳分化。     

普通野生稻和亚洲栽培稻线粒体DNA的RFPL分析

通过７个探针、１７种内切酶探针组合对１１８份普通野生稻和７６份亚洲栽培稻的线粒体ＤＮＡ（ｍｔＤＮＡ）ＲＦＬＰ分析表明,籼粳分化是亚洲栽培稻线粒体基因组分的主流,７６个栽培稻中,３６个品种ｍｔＤＮＡ为籼型,４０个品种ｍｔＤＮＡ为粳型。普通野生稻ｍｔＤＮＡ以籼型为主（８６份）,粳型较少（７份）,１份类型难以确定,还有２４份没有籼粳分化。     

中国普通野生稻遗传分化的RAPD研究

多数学者已认定亚洲栽培稻（ＯｒｙｚａｓａｔｉｖａＬ．）的祖先是普通野生稻（Ｏ．ｒｕｆｉｐｏｇｏｎ）。然而栽培稻的籼、粳分化是发生在驯化之前还是在驯化之后,也即普通野生稻是否存在籼、粳分化的问题,是十几年来稻作起源研究中争论的热点之一。Ｓｅｃｏｎｄ［１］用多个同工酶位点的分析结果得出结论,普通野生稻在驯化为栽培稻之前就已经发生了籼、粳分化,即有籼型普通野生稻和粳型普通野生稻之分。Ｍｏｒｉｓｈｉｍａ和Ｇａｄｒｉｎａｂ［２］用２４个形态和生理性状及１２个同工酶位点和杂交亲合力等方法证明普通野生稻没有发…     

基于叶绿体基因多样性的中国水稻起源进化研究

针对目前亚洲栽培稻起源地和进化途径学说众多、分歧巨大的现状,本研究选择原产中国的98份亚洲栽培稻和125份普通野生稻为材料,对叶绿体中atpA序列、rps16内含子序列、trnP-rpl33间隔区、trnG-trnfM序列、trnT-trnL间隔区序列的五段高突变序列进行测序,利用生物信息学方法进行比对分析,绘制Network网络图,构建系统发育树。结果表明,普通野生稻的Indel和SNP数目均比亚洲栽培稻多,序列多样性丰富;基于单倍型的Network网络图和系统发育树可将所有参试材料归为3个类群,类群I主要为粳稻与普通野生稻,类群II主要为籼稻,类群III主要为普通野生稻,而类群II和类群III亲缘关系较近,提示粳、籼两个亚种可能由偏粳、偏籼的普通野生稻分别进化而来,支持二次起源学说;所有与亚洲栽培稻亲缘关系较近的普通野生稻均来源于华南地区,支持华南地区为我国亚洲栽培稻起源中心的论点。     

光敏核不育水稻农垦58S与其衍生不育系的叶绿体DNA的比较

扩增了光敏核不育系农垦58S及从它衍生出来的5个两用核不育系叶绿体DNA的ORF（open reading frame）100、ORF29-TrnC^GCA、rps16（ribosomal proteins16）基因内含子和TrnT^UGU-TrnL^UAA（tRNA^Thr（UGU）-tRNA^-Leu（UAA）等4个片段,并测定了其序列。研究结果表明,粳型光敏核不系农垦58S的叶绿体为粳型。农垦58S衍生的核不育系中,粳型核不育系7001S以及3个籼型核不育系1103S、培矮64S和广占63S的叶绿体DNA为粳型,与选育者提供的细胞质系谱一致。籼型核不育系W6154S的叶绿体DNA为籼型,与选育者提供的细胞质系谱不一致,推断选育者在选育过程中更换过细胞质（曾用不育系作过父本）。5个粳型叶绿体DNA的rps16基因内含子和TrnT^UGU-TrnL^UAA间区的序列相互之间有1-2个单核苷酸的变异。     

水稻同工酶基因多样性及非随机组合现象的研究

通过对６８０份栽培稻、８８份中国纯合普通野生稻的同工酶基因多样性和非随机组合现象的研究发现：（１）籼稻的多样性大于粳稻,对中国而言,普通野生稻大于籼稻,籼稻大于粳稻。（２）东南亚品种的非随机组合值很低,分化较低。基因多样性（Ｈ）、基因型频率（Ｆ）很高,是一个多样性中心。（３）南亚品种多样性和东南亚差不多,非随机组合值偏低,分化较差。但Ａｕｓ稻多样性很小,非随机组合值较高,分化较彻底。（４）除中国云南以外的中国其它品种籼粳分化最彻底,多样性很小。中国云南粳稻多样最小,籼稻多样性近中,非随机组合值和中国的其它品种接近,从同工酶上看,中国云南不像是一个多样性中心。但发现和Ｅｓｔ－２座位相关的非随机组合值很低。（５）籼粳交后代材料非随机组合值低,多样性偏高,推测籼粳交在水稻籼粳分化过程中起着很大的作用,有降低分化程度,增加多样性的作用。（６）中国普通野生稻非随机组合值很小,多数座位间不显著。可见,野生稻的分化是很小的。（７）广亲和品种与Ｅｓｔ－２相关的非随机组合值很低,全部不显著,但其余的组合都较高。与中国云南品种的非随机组合值结果十分类似。     

贵州地方水稻种质资源籼-粳遗传分化的InDel分子标记研究

本研究利用36对InDel分子标记引物对贵州地方水稻种质的籼-粳遗传分化和亲缘关系进行分析,结果表明,82份贵州地方栽培稻中49份为粳稻,33份为籼稻,贵州地方栽培稻“禾”品种主要属于粳稻,而“谷”品种主要为籼稻。基于Nei氏遗传距离的亲缘关系分析表明在粳稻群体和籼稻群体中均存在与野生稻亲缘关系近的品种,其中的粳稻品种与野生稻的遗传关系比之籼稻品种近。而基于MCMC算法的遗传结构分析揭示了贵州地方籼稻品种中存在较为复杂的遗传结构。分子变异分析显示,粳稻和籼稻品种的遗传变异主要来自亚种内,遗传多样性分析表明其亚种内籼稻品种的遗传多样性略高于粳稻品种。研究结果揭示了贵州省黔东南地区栽培稻种质资源的籼-粳分化程度、遗传关系及其遗传多样性。     

中国栽培稻的起源与演化

中国栽培稻起源地主要有4种假说:华南起源说、云南起源说、长江中下游说和长江中游-淮河上游说。对其进行了简要概括,并进行评述:目前没有一种假说能完全符合水稻起源的4个条件,此外有些学者提出水稻的多起源中心;从分子生物学角度综述了栽培稻籼粳分化研究进展,主要有两个起源说:一源论和二次(或多次)起源论,大量研究支持籼稻和粳稻多起源论;从古DNA、水稻落粒性与驯化、植硅石等方面探讨栽培稻起源演化的研究方法。旨在能为水稻的起源演化研究提供有价值的参考。     

Single-seeded InDel fingerprints in rice:An effective tool for indica-japonica rice classification and evolutionary studies

Asian cultivated rice(Oryza sativa L.),an important cereal crop worldwide,was domesticated from its wild ancestor 8000 years ago.During its long-term cultivation and evolution under diverse agroecological conditions, Asian cultivated rice has differentiated into indica and japonica subspecies.An effective method is required to identify rice germplasm for its indica and japonica features,which is essential in rice genetic improvements.We developed a protocol that combined DNA extraction from a single rice seed and the insertion/deletion(InDel) molecular fingerprint to determine the indica and japonica features of rice germplasm.We analyzed a set of rice germplasm,including 166 Asian rice varieties,two African rice varieties,30 accessions of wild rice species,and 42 weedy rice accessions,using the single-seeded InDel fingerprints(SSIF).The results show that the SSIF method can efficiently determine the indica and japonica features of the rice germplasm.Further analyses revealed significant indica and japonica differentiation in most Asian rice varieties and weedy rice accessions.In contrast,African rice varieties and nearly all the wild rice accessions did not exhibit such differentiation.The pattern of cultivated and wild rice samples illustrated by the SSIF supports our previous hypothesis that indica and japonica differentiation occurred after rice domestication under different agroecological conditions.In addition,the divergent pattern of rice cultivars and weedy rice accessions suggests the possibility of an endoferal origin(from crop)of the weedy rice included in the present study.     

Genetic characterization of weedy rice (Oryza sativa L.) based on morpho-physiology, isozymes and RAPD markers

 Weedy rice (Oryza sativa L.) is an important resource for breeding and for studying the evolution of rice. The present study was carried out to identify the genetic basis of the weedy rices distributed in various countries of the world. One hundred and fifty two strains of weedy rice collected from Bangladesh, Brazil, Bhutan, China, India, Japan, Korea, Nepal, Thailand and the USA were tested for variations in six morpho-physiological characteristics and in 14 isozyme loci. Twenty six weedy strains selected from the above materials were assayed for the Est-10 locus, six RAPD loci of the nuclear genome, and one chloroplast locus. From the results of multivariate analysis based on the morpho-physiological characteristics and the isozymes, weedy rice strains were classified into indica and japonica types, and each type was further divided into forms resembling cultivated and wild rice. Thus, four groups designated as I, II, III and IV were identified. Weedy strains of group I (indica-type similar to cultivars) were distributed mostly in temperate countries, group II (indica-type similar to wild rice) in tropical countries, group III (japonica-type similar to cultivars) in Bhutan and Korea, group IV ( japonica-type similar to wild rice) in China and Korea. In group I, classified as indica, several strains showed japonica-specific RAPD markers, while some others had japonica cytoplasm with indica-specific RAPD markers in a heterozygous state at several loci. One weedy strain belonging to group II showed a wild rice-specific allele at the Est-10 locus. However, in groups III and IV, no variation was ound either for the markers on Est-10 or for the RAPD loci tested. Judging from this study, weedy rice of group I might have originated at least partly from gene flow between indica and japonica, whereas that of group II most probably originated from gene flow between wild and cultivated indica rice. Weedy rice of group III is thought to have originated from old rice cultivars which had reverted to a weedy form, and that of group IV from gene flow between japonica cultivars and wild rice having japonica backgrounds. Received: 2 May 1996 / Accepted: 30 August 1996     

Population genomics identifies the origin and signatures of selection of Korean weedy rice

Weedy rice is the same biological species as cultivated rice (Oryza sativa); it is also a noxious weed infesting rice fields worldwide. Its formation and population‐selective or ‐adaptive signatures are poorly understood. In this study, we investigated the phylogenetics, population structure and signatures of selection of Korean weedy rice by determining the whole genomes of 30 weedy rice, 30 landrace rice and ten wild rice samples. The phylogenetic tree and results of ancestry inference study clearly showed that the genetic distance of Korean weedy rice was far from the wild rice and near with cultivated rice. Furthermore, 537 genes showed evidence of recent positive or divergent selection, consistent with some adaptive traits. This study indicates that Korean weedy rice originated from hybridization of modern indica/indica or japonica/japonica rather than wild rice. Moreover, weedy rice is not only a notorious weed in rice fields, but also contains many untapped valuable traits or haplotypes that may be a useful genetic resource for improving cultivated rice.     

Genome re-sequencing suggested a weedy rice origin from domesticated indica-japonica hybridization: a case study from southern China

Main conclusion

Whole-genome re-sequencing of weedy rice from southern China reveals that weedy rice can originate from hybridization of domesticated indica and japonica rice.

Abstract

Weedy rice (Oryza sativa f. spontanea Rosh.), which harbors phenotypes of both wild and domesticated rice, has become one of the most notorious weeds in rice fields worldwide. While its formation is poorly understood, massive amounts of rice genomic data may provide new insights into this issue. In this study, we determined genomes of three weedy rice samples from the lower Yangtze region, China, and investigated their phylogenetics, population structure and chromosomal admixture patterns. The phylogenetic tree and principle component analysis based on 46,005 SNPs with 126 other Oryza accessions suggested that the three weedy rice accessions were intermediate between japonica and indica rice. An ancestry inference study further demonstrated that weedy rice had two dominant genomic components (temperate japonica and indica). This strongly suggests that weedy rice originated from indica-japonica hybridization. Furthermore, 22,443 novel fixed single nucleotide polymorphisms were detected in the weedy genomes and could have been generated after indica-japonica hybridization for environmental adaptation.     

Evidences of introgression from cultivated rice to Oryza rufipogon (Poaceae) populations based on SSR fingerprinting: implications for wild rice differentiation and conservation

Crop-to-wild introgression may play an important role in evolution of wild species. Asian cultivated rice (Oryza sativa L.) is of a particular concern because of its cross-compatibility with the wild ancestor, O. rufipogon Griff. The distribution of cultivated rice and O. rufipogon populations is extensively sympatric, particularly in Asia where many wild populations are surrounded by rice fields. Consequently, gene flow from cultivated rice may have a potential to alter genetic composition of wild rice populations in close proximity. In this study, we estimated introgression of cultivated rice with O. rufipogon based on analyses of 139 rice varieties (86 indica and 53 japonica ecotypes) and 336 wild individuals from 11 O. rufipogon populations in China. DNA fingerprinting based on 17 selected rice simple sequence repeat (SSR) primer pairs was adopted to measure allelic frequencies in rice varieties and O. rufipogon samples, and to estimate genetic associations between wild and cultivated rice through cluster analysis. We detected consanguinity of cultivated rice in O. rufipogon populations according to the admixture model of the STRUCTURE program. The analyses showedz that four wild rice populations, DX-P1, DX-P2, GZ-P2, and HL-P, contained some rare alleles that were commonly found in the rice varieties examined. In addition, the four wild rice populations that scattered among the rice varieties in the cluster analysis showed a closer affinity to the cultivars than the other wild populations. This finding supports the contention of substantial gene flow from crop to wild species when these species occur close to each other. The introgressive populations had slightly higher genetic diversity than those that were isolated from rice. Crop-to-wild introgression may have accumulative impacts on genetic variations in wild populations, leading to significant differentiation in wild species. Therefore, effective measure should be taken to avoid considerable introgression from cultivated rice, which may influence the effective in-situ conservation of wild rice species.     

Genetic variation and possible origins of weedy rice found in California

Control of weeds in cultivated crops is a pivotal component in successful crop production allowing higher yield and higher quality. In rice‐growing regions worldwide, weedy rice (Oryza sativa f. spontanea Rosh.) is a weed related to cultivated rice which infests rice fields. With populations across the globe evolving a suite of phenotypic traits characteristic of weeds and of cultivated rice, varying hypotheses exist on the origin of weedy rice. Here, we investigated the genetic diversity and possible origin of weedy rice in California using 98 simple sequence repeat (SSR) markers and an Rc gene‐specific marker. By employing phylogenetic clustering analysis, we show that four to five genetically distinct biotypes of weedy rice exist in California. Analysis of population structure and genetic distance among individuals reveals diverse evolutionary origins of California weedy rice biotypes, with ancestry derived from indica, aus, and japonica cultivated rice as well as possible contributions from weedy rice from the southern United States and wild rice. Because this diverse parentage primarily consists of weedy, wild, and cultivated rice not found in California, most existing weedy rice biotypes likely originated outside California.     

A chloroplast variation map generated using whole genome re‐sequencing of Korean landrace rice reveals phylogenetic relationships among Oryza sativa subspecies

Although the overall structure of the chloroplast genome is generally conserved, several sequence variations have been identified that are valuable for plant population and evolutionary studies. Here, we constructed a chloroplast variation map of 30 landrace rice strains of Korean origin, using the Oryza rufipogon chloroplast genome (GenBank: NC_017835 ) as a reference. Differential distribution of single‐nucleotide polymorphisms and INDELs across the rice chloroplast genome is suggestive of a region‐specific variation. Population structure clustering revealed the existence of two clear subgroups (indica and japonica) and an admixture group (aus). Phylogenetic analysis of the 30 landrace rice strains and six rice chloroplast references suggested and supported independent evolution of O. sativa indica and japonica. Interestingly, two aus type accessions, which were thought to be indica type, shared a closer relationship with the japonica type. One hypothesis is that ‘Korean aus’ was intentionally introduced and may have obtained japonica chloroplasts during cultivation. We also calculated the nucleotide diversity of 30 accessions and compared the results to six rice chloroplast references. These data demonstrated that although nucleotide diversity is low in all strains tested, aus and indica have a higher nucleotide diversity than japonica.     

All roads lead to weediness: Patterns of genomic divergence reveal extensive recurrent weedy rice origins from South Asian Oryza

Weedy rice (Oryza spp.), a weedy relative of cultivated rice (O. sativa), infests and persists in cultivated rice fields worldwide. Many weedy rice populations have evolved similar adaptive traits, considered part of the ‘agricultural weed syndrome’, making this an ideal model to study the genetic basis of parallel evolution. Understanding parallel evolution hinges on accurate knowledge of the genetic background and origins of existing weedy rice groups. Using population structure analyses of South Asian and US weedy rice, we show that weeds in South Asia have highly heterogeneous genetic backgrounds, with ancestry contributions both from cultivated varieties (aus and indica) and wild rice. Moreover, the two main groups of weedy rice in the USA, which are also related to aus and indica cultivars, constitute a separate origin from that of Asian weeds. Weedy rice populations in South Asia largely converge on presence of red pericarps and awns and on ease of shattering. Genomewide divergence scans between weed groups from the USA and South Asia, and their crop relatives are enriched for loci involved in metabolic processes. Some candidate genes related to iconic weedy traits and competitiveness are highly divergent between some weed‐crop pairs, but are not shared among all weed‐crop comparisons. Our results show that weedy rice is an extreme example of recurrent evolution, and suggest that most populations are evolving their weedy traits through different genetic mechanisms.     

Better performance of germination in hyperosmotic solutions in conspecific weedy rice than cultivated rice

Weeds and crops that grow together often confront similar types of environmental stress, especially drought stress. Weedy rice (Oryza sativa f. spontanea) and cultivated rice (O. sativa L.) provide a unique pair consisting of a weed and a conspecific model crop that can be used to study the drought tolerance of plants across a large distributional range. The investigation on weedy rice's damage to paddy fields showed that it was more serious in dry direct seeding than water direct seeding. Compared with water direct seeding, the seeds of cultivated rice and weedy rice in dry direct seeding will absorb water and germinate under the condition of insufficient soil moisture. Our hypothesis is that weedy rice seeds have evolved stronger germination ability than coexisting cultivated rice under water stress, so that they can obtain more growth space in the early stage in dry direct seeding and thus obtain higher fitness. Seeds of weedy rice populations and coexisting rice cultivars were collected from 61 sites across China and were germinated with 20% polyethylene glycol‐6000 to simulate drought stress. Two drought response indices, which assessed germination rate and germination index, plus one germination stress tolerance index, indicated significantly greater drought tolerance in weedy rice populations than in coexisting rice cultivars (P < 0.01). Drought tolerance for the three indexes were indica weedy rice > indica rice cultivars, japonica weedy rice > japonica rice cultivars, and indica weedy rice > japonica rice cultivars. These results indicate that weedy rice populations show stronger drought stress tolerance than coexisting rice cultivars at various sites, specifically during the seed germination period. Furthermore, Pearson's correlation found that drought response of weedy rice populations and coexisting rice cultivars were significantly different with these environmental factors: latitude, altitude, annual mean precipitation, mean annual temperature, mean precipitation in the sowing month, mean temperature in the sowing month, and sowing methods. Weedy rice shows different patterns of drought tolerance variation across geographical (latitude and altitude) and environmental (precipitation) gradients compared to coexisting rice cultivars. This study suggests that weedy rice might have evolved new drought tolerance and could provide a useful source of genetic resources for improving drought tolerance of crop cultivars and breeding direct seeded cultivars to reduce the usage of seeds in direct seeding.     

Comparison of the genetic diversity of common wild rice (Oryza rufipogon Griff.) and cultivated rice (O. sativa L.) using RFLP markers

Forty fourth single-copy RFLP markers were used to evaluate the genetic diversity of 122 accessions of common wild rice (CWR, Oryza rufipogon Griff.) and 75 entries of cultivated rice (Oryza sativa L. ) from more than ten Asian countries. A comparison of the parameters showing genetic diversity, including the percentage of polymorphic loci (P), the average number of alleles per locus (A), the number of genotypes (Ng), the average heterozygosity (Ho) and the average genetic multiplicity (Hs) of CWR and indica and japonica subspecies of cultivated rice from different countries and regions, indicated that CWR from China possesses the highest genetic diversity, followed by CWR from South Asia and Southeast Asia. The genetic diversity of CWR from India is the second highest. Although the average gene diversity (Hs)of the South Asian CWR is higher than that of the Southeast Asian CWR, its percentage of polymorphic loci (P), number of alleles (Na) and number of genotypes (Ng) are all smaller. It was also found that the genetic diversity of cultivated rice is obviously lower than that of CWR. At the 44 loci investigated, the number of polymorphic loci of cultivated rice is only 3/4 that of CWR, while the number of alleles, 60%, and the number of genotypes is about 1/2 that of CWR. Of the two subspecies studied, the genetic diversity of indica is higher than that of japonica. The average heterozygosity of the Chinese CWR is the highest among all the entries studied. The average heterozygosity of CWR is about two-times that of cultivated rice. It is suggested that during the course of evolution from wild rice to cultivated rice, many alleles were lost through natural and human selection, leading to the lower heterozygosity and genetic diversity of the cultivated rice. Received: 19 May 1999 / Accepted: 26 April 2000