水稻雄性不育系新露A的抽穗期基因型分析

水稻雄性不育系新露A是一个粳质籼核优质不育系, 其所配组合的抽穗期多数表现为超或偏早亲遗传. 本文利用抽穗期基因型明确的秋光(e1e1 e2e2 e3e3 Se-1eSe-1e)、越光(E1E1 E2E2 e3e3 Se-1eSe-1e)和日本晴(E1E1 e2e2 e3e3 Se-1nSe-1n)作测验品种, 分析了新露B的抽穗期基因型, 结果表明: 其抽穗期感光基因型为: e1e1 e2e2 e3e3     

Variation in heading date conceals quantitative trait loci for other traits of importance in breeding selection of rice

To identify quantitative trait loci (QTLs) associated with the primary target traits for selection in practical rice breeding programs, backcross inbred lines (BILs) derived from crosses between temperate japonica rice cultivars Nipponbare and Koshihikari were evaluated for 50 agronomic traits at six experimental fields located throughout Japan. Thirty-three of the 50 traits were significantly correlated with heading date. Using a linkage map including 647 single-nucleotide polymorphisms (SNPs), a total of 122 QTLs for 38 traits were mapped on all rice chromosomes except chromosomes 5 and 9. Fifty-eight of the 122 QTLs were detected near the heading date QTLs Hd16 and Hd17 and the remaining 64 QTLs were found in other chromosome regions. QTL analysis of 51 BILs having homozygous for the Koshihikari chromosome segments around Hd16 and Hd17 allowed us to detect 40 QTLs associated with 27 traits; 23 of these QTLs had not been detected in the original analysis. Among the 97 QTLs for the 30 traits measured in multiple environments, the genotype-by-environment interaction was significant for 44 QTLs and not significant for 53 QTLs. These results led us to propose a new selection strategy to improve agronomic performance in temperate japonica rice cultivars.     

Effect of VRN‐1 and PPD‐D1 genes on heading time in European bread wheat cultivars

The variation of the vernalization (VRN‐1) and photoperiod (PPD‐1) genes offers opportunities to adjust heading time and to maximize yield in crop species. The effect of these genes on heading time was studied based on a set of 245 predominantly spring cultivars of bread wheat from the main eco‐geographical regions of Europe. The genotypes were screened using previously published diagnostic molecular markers for detecting the dominant or recessive alleles of the major VRN‐1 loci such as: VRN‐A1, VRN‐B1, VRN‐D1 as well as PPD‐D1. We found that 91% of spring wheat cultivars contain the photoperiod sensitive PPD‐D1b allele. Photoperiod insensitive PPD‐D1a allele has been found mainly in southern region of Europe. For this region the monogenic control of vernalization by VRN‐B1 or VRN‐D1 dominant alleles is common, whereas in the remaining part of Europe, the combination of photoperiod sensitive PPD‐D1b allele with dominant VRN‐A1, VRN‐B1 and recessive vrn‐D1 alleles represents the most frequent genotype. Also, we revealed a significantly later (5–8 days) heading of the monogenically dominant genotypes at VRN‐B1 as compared to the digenic VRN‐A1 VRN‐B1 genotypes.     

Epistasis among the three major flowering time genes in rice: coordinate changes of photoperiod sensitivity,basic vegetative growth and optimum photoperiod

Flowering time is affected not only by photoperiod sensitivity (PS) but also by basic vegetative growth (BVG) and optimum photoperiod (OP), although their developmental and genetic relationships are not well understood. The present study was carried out in rice to examine to what extent these three developmental components are modified by the three flowering time genes, Se1 (= Hd1), Ef1 and e1 (= m-Ef1), which are known to contribute to flowering time in temperate and tropical regions of rice cultivation. Photoperiodic response curves were estimated under controlled conditions of different growth regimes, using eight near-isogenic lines possessing different combinations of the alleles at the three loci. The results showed that each of the components is greatly affected by the main effect of the genes, temperature and their epistasis, indicating that none of the three genes controls flowering time by altering any single component in PS, BVG or OP. Epistasis was detected more frequently among the three genes than reported before, suggesting that epistasis contributes to flowering time by changing PS, BVG and OP differently. The comparison of the nucleotide sequences suggested that Ef1 is the same as Early heading date 1 (Ehd1). Since the two genes Se1 (= Hd1) and Ef1 (= Ehd1) are known to up-regulate the rice homolog of Arabidopsis FT, it is suggested that the detected epistasis may respond to diverse environments by modulating the CO/FT system conserved in flowering plants.     

Development of a CAPS marker for the badh2.7 allele in Sri Lankan fragrant rice (Oryza sativa)

Fragrance in rice is caused by mutations in the badh2 (betaine aldehyde dehydrogenase) gene. It was previously reported that exons 1, 2, 7, 10, 13 and 14 of badh2 are hot spots for various mutations leading to fragrance in most aromatic rice. This study was carried out to sequence the 14th exon of badh2 gene of Sri Lankan aromatic rice varieties that lack the badh2.1 allele. The aims of the study were to predict the aberrant protein structure and to develop a functional DNA marker. In view of this, we sequenced the 14th exon of four traditional aromatic accessions and compared with a published sequence. Four accessions contained a nucleotide ‘G’ insertion in the 14th exon. This novel mutation can be classified as the badh2.7 allele. The predicted three‐dimensional protein structure of the mutant shows loss of part of the oligomerization and coenzyme binding domains, a change that is predicted to result in fragrance. A CAPS‐based novel marker, Bad2.7CAPS, was developed to identify varieties possessing this badh2.7 allele, and it can be utilized in rice breeding programmes.     

Fine mapping of qSS‐9, a major and stable quantitative trait locus,for seed storability in rice (Oryza sativa L.)

Seed storability in rice (Oryza sativa L.) is an important agronomic trait. We previously showed a quantitative trait locus of seed storability, qSS‐9, on chromosome 9 in a backcross population of ‘Koshihikari’ (japonica) / ‘Kasalath’ (indica) // ‘Koshihikari’. In this study, fine mapping of the chromosomal location of qSS‐9 was performed. Effect of ‘Kasalath’ allele of qSS‐9 was validated using a chromosome segment substitution line, SL36, which harboured the target quantitative trait loci (QTL) from ‘Kasalath’ in the genetic background of ‘Nipponbare’ under different ageing treatments in different environments. Subsequently, an F₂ population from a cross between ‘Nipponbare’ and SL36 was used for fine mapping of qSS‐9. Simultaneously, four subnear isogenic lines (sub‐NILs) that represented different recombination breakpoints across the qSS‐9 region were developed from F₃ progeny. Finally, the qSS‐9 locus was located between the Indel markers Y10 and Y13, which delimit a region of 147 kb in the ‘Nipponbare’ genome. These results provide a springboard for map‐based cloning of qSS‐9 and possibilities for breeding rice varieties with strong seed storability.     

Photoperiod insensitivity gene essential to the varieties grown in the northern limit region of paddy rice (Oryza sativa L.) cultivation

Summary The release of extremely early maturing varieties has made it possible to cultivate rice in Hokkaido (NL45-42°) in Japan, the northern limit region of paddy rice cultivation. Until then, rice cultivation in this region has been impracticable due to the climate condition, especially short summer and long-day more than 15 hours during summer. Experiment results confirmed that the success of rice cultivation in this area depends on raising photoperiod insensitivity varieties with short basic vegetative growth period. Moreover, in this study, the genetic factors controlling the photoperiod insensitivity of Hokkaido varieties were analyzed by using 8 kinds of tester lines for three loci, E1, E2, and E3, controlling photoperiod sensitivity. It was found out that all the varieties examined carry el, a photoperiod insensitivity allele of E1 locus, but as for the other loci, E2 and E3, the existence of plural alleles were recognized. We have already clarified that almost all the japonica-type varieties grown in Japan (except Hokkaido) and Taiwan carry E1 bringing about strong photoperiod sensitivity. Accordingly, it can be concluded that el is the gene essential to Hokkaido varieties: the interchange of E1 with e1 enabled rice cultivation under long-day condition.     

Development of gene-tagged markers for quantitative trait loci underlying rice yield components

Higher yields of rice have always been a predominant goal in rice breeding techniques. However, the inheritances of rice yield and its components are still unknown, and no information regarding suitable alleles can be directly provided for improving the rice yield level until three major quantitative trait loci (QTLs) have been cloned and functionally characterized. These QTLs contain Gn1a for grain number per panicle and GS3 and GW2 for grain weight. It has been proven that these three genes show a potential in improving the rice yield level. However, the distribution of suitable alleles on these three loci in rice cultivars and germ plasm are yet to be elucidated, this retards the progress of the utilization of suitable alleles in rice breeding techniques to produce higher yields. In the present study, we developed a set of gene-tagged markers based on the gene mutation sites Gn1a-M1 and Gn1a-M2 for Gn1a, GW2-HapI for GW2, and GS3-PstI for GS3. The results demonstrated that these STS markers could clearly differentiate between the different alleles at each gene locus. A survey of the allele distributions of the abovementioned three genes was performed with 156 cultivars. It was observed that the 5150-Gn1a allele was absent on the Gn1a locus and only two type alleles (Ha-Gn1a and Ko-Gn1a) were present, of which 54.3% indica and 21.5% japonica cultivars contained the Ha-Gn1a allele. Two alleles (MH-GS3 and ZS-GS3) were detected on the GS3 locus, and 48.6% indica and 9.9% japonica cultivars harbored the suitable allele MH-GS3. Further, all the cultivars contained the FA-GW2 allele on GW2, whereas the WY-GW2 allele was not found. These results further suggested that some of the alleles residing in the indica subspecies have introgressed into the japonica group with a very low frequency. The gene-tagged markers developed in the present study can be directly used as a tool for marker-aided selection (MAS) in rice breeding techniques to produce higher yields. Chang-Jie Yan and Song Yan contributed equally to this work.     

水稻突变群体的构建及功能基因组学

随着水稻基因组全序列的测定完成，功能基因组学已成为重点研究内容。功能基因组学主要研究生物有机体内各基因的生物学功能进而了解所有基因如何协调发挥作用完成一系列的生长发育过程。目前已经发展了多种分析鉴定基因功能的方法，其中最直接最有效的方法是构建饱和的基因突变群体，通过突变体分析鉴定基因功能。本文主要阐述了各种构建方法及其优缺点以及在功能基因分离鉴定上的应用。自发突变的频率极低，且自发突变基因的分离难度比较大，只能作为突变群体构建的辅助方法。利用EMS等化学诱变剂可以在短时间内构建大量点突变群体，并可用TILLING进行突变检测，但多位点的点突变使突变表型难以鉴定。由快中子等物理诱变也可以在短时间内构建大量缺失突变体，且可用Ddeteagene系统进行检测；但多基因缺失、多位点缺失和内含子缺失等使突变表型的分析可能无法进行。利用T—DNA、转座子和反转录转座子等构建插入突变体已经成为突变库构建的主要方法。T—DNA插入已成功应用于水稻大规模突变体的构建，但只限于转基因效率较高的品种；T—DNA在基因组中整合的复杂性以及转基因过程中由组织培养等引发的突变等，增加了突变体表型和分子分析的难度。Tos17是目前应用最为成功的反转录转座子，但多拷贝的插入使突变体的表型鉴定和分子鉴定较为困难，因为只有10％左右的突变性状是由Tos17插入引起的。理论上，Ac／Ds双因子系统是目前最理想的水稻插入突变库构建体系，Ds的单拷贝插入，大大方便了突变体的表型分析和分子鉴定；Ds的回复突变，可以验证突变表型是否由Ds插入引起；但在血转座酶驱动下Ds可能发生的多次跳动所形成的痕迹(footprint)也可能影响突变表型的分析。RNAi可以有效地使目标基因沉默，但并不是所有基因均可被RNAi沉默；对多因一效基因或同源性较高的基因家族，RNAi会同时作用这些基因，沉默表型很难鉴定。可见，每一种方法都有各自的优缺点，但不同的方法是可以互补的，通过各种方法是能够构建成理想的水稻突变库的。     

Responses to photoperiod before and after jointing in wheat substitution lines

It has been hypothesised that wheat yields may be increased by lengthening the duration of the stemelongation phase. This paper reports studies on the effects of chromosomes carrying major photoperiod genes (Ppd-A1, Ppd-B1, Ppd-D1) in different genetic backgrounds, on responses to photoperiod before and after jointing, when the onset of stem elongation occurs, and on number of grains per spike. A field experiment considered the effects of two photoperiods on Chinese Spring and 12 substitution lines, in which chromosomes 2A, 2B or 2D had been substituted by those from four contrasting cultivars. The phase from seedling emergence to jointing (EM-JO) was more responsive than that from jointing to anthesis (JO-ANT), but no relationship was found between the duration of these phases. EM-JO length affected leaf and spikelet number and consequently grains per spike, but this component was further influenced by JO-ANT duration. Our results confirmed that the phases are independent in sensitivity, supporting the hypothesis that genetic manipulation of phase duration could enhance yield, but no evidence was found of any particular Ppd allele being responsible for major responses to photoperiod during stem elongation. This revised version was published online in July 2006 with corrections to the Cover Date.     

A PCR-based DNA marker for detection of mutant and normal alleles of the Wx-D1 gene of wheat

To assist waxy wheat breeding a DNA marker was developed to discriminate mutant and normal alleles at the Wx‐D1 locus. This polymerase chain reaction‐based marker distinguishes the mutant from the normal allele by targeting the previously reported deletion basis of the mutant. The marker codominantly identifies the normal allele of the Wx‐D1 gene from the mutant allele originated from the Chinese landrace ‘Baihoumai’. However, attempts with a number of primer combinations targeting this deletion failed to amplify the corresponding fragment from an unrelated wheat line (NP150) that has a mutant null allele at the same locus. This indicates that NP150 has a different mutant allele from that of ‘Baihoumai’. This marker is a useful tool to identify wheat cultivars with mutant and normal alleles of the Wx‐D1 gene, and is used in marker‐assisted selection of the Wx‐D1 gene in our waxy wheat breeding programme.     

杂交水稻恢复系桂99的抽穗期基因及其效应分析

以基因型明确的抽穗期主基因近等基因系EG0~EG7、ER~LR、T65系列为测验系（TLs）,在江西南昌（28^o 36’ N）夏季自然高温长日（14 h/d）和人工遮光短日（10 h/d）,以及海南三亚（18^o 14’ N）旱季自然低温短日（11.6 h/d）处理条件下,对籼型杂交水稻恢复系桂99的抽穗期基因及其感温性和基因位点间的互作效应进行了分析。结果表明,桂99在E₁、E₂和E₃位点分别带有感光迟熟等位基因E₁、E₂和E₃,在Se-1位点带有非感光等位基因Se-1^e,在Ef-1位点带有早熟基因Ef-1,由此推断其抽穗期基因型为E₁E₁E₂E₂E₃E₃Se-1^eSe-1^eEf-1Ef-1。迟熟基因E₁、E₃与早熟基因Ef-1同时存在,E₁、E₃与Se-1^e基因位点间的互作使桂99农艺性状表现弱感光性。感光基因Se-1^u（或Se-1ⁿ）的存在能增强E位点感光迟熟基因的感光性,感光基因对“TLs×桂99”F₂植株抽穗的影响,是延长平均抽穗期,增加迟抽穗植株分布频率。分析了感温性对TLs抽穗期的影响,讨论了以桂99为恢复系配置的杂交水稻组合丰产性和广适性的遗传基础。     

Photoperiod sensitivity gene controlling heading date in rice cultivars in the northernmost region of Japan

Rice is grown in diverse environments at latitudes ranging from 53^°N to 40^°S. In Japan, Hokkaido is the northernmost rice cultivation region(42–45^°N latitude). Only extremely early maturing (heading) varieties that have extremely low photoperiod sensitivity are adapted to this area. Heading date is the most important trait in adaptation to this particular environment. Also, the efficient manipulation of heading date is a crucial component of rice improvement. To determine the genetic basis for heading date among cultivars grown in Hokkaido, the heading behaviour was analyzed. Clear segregations were observed. To estimate the photoperiod sensitivity of the genes involved, the cultivars and F₁ plants from crosses between the cultivars were grown under different daylength conditions. The results indicated that the genes controlling heading date are photoperiod sensitive, suggesting they play important roles in the northernmost rice cultivation regions in Japan, to which only cultivars with extremely low photoperiod sensitivity are adapted. This revised version was published online in August 2006 with corrections to the Cover Date.     

Identification,distribution and effects on agronomic traits of the semi-dwarfing <Emphasis Type="Italic">Rht</Emphasis> alleles in Bulgarian common wheat cultivars

Bulgarian common wheat cultivars released in the period 1925–2003 were studied using the gibberellic acid (GA) test and microsatellite analysis of the Xgwm261 locus on chromosome 2DS to identify the semi-dwarfing (Rht) genes. The old cultivars, isolated through selection from landraces, carried rare alleles (211- and 215-bp) at Xgwm261 locus, and those developed by hybridisation to foreign cultivars, carried the 165- and 174-bp alleles. Forty-two (55.3%) of 76 modern cultivars were GA-responsive. The 192-bp allele, diagnostic for Rht8, was observed in 64 (84.2%) modern cultivars, of which 37 carry Rht8 alone, and 27 possess a combination of Rht8 and a GA-insensitive allele viz. Rht-B1d (17); Rht-D1b (6) and Rht-B1b (4). The 174-bp allele is present in seven cultivars, only one of which is photoperiod-sensitive, and the rest are day-length insensitive. The 203-bp allele was found in six modern cultivars. Cultivars carrying the Rht8 allele are the most widespread and some of them have been cultivated for a long period. Cultivars with the `Saitama 27' allele (Rht-B1d) are the most productive and are second in distribution in the country. The recently observed trend for increasing the proportion of cultivars with GA-insensitive Rht genes is probably due to their combination with the 192-bp allele of Xgwm261 locus tightly linked to the Ppd-D1, to the break of the link between the 174-bp allele and ppd-D1, and to the introduction of other genes influencing flowering time.     

Development of AS‐PCR marker based on a key mutation confirmed by resequencing of Wx‐mp in Milky Princess and its application in japonica soft rice (Oryza sativa L.) breeding

Soft rice with low amylose content (AC) ranging by 5–15% is a unique type with special eating and appearance quality and has become popular in the rice market. We resequenced the Wx‐mp, a key allele from Milky Princess, a Japanese low AC variety, and found that the +473 mutation in exon 4 is the key mutation in both Wx‐mp and its ancestor allele, Wx‐mq from Milky Queen. Based on this functional mutation, an allele‐specific PCR (AS‐PCR) marker was developed and proven in a breeding population derived from a cross between a Chinese late variety Nan Keng 46 (Wx‐mp/Wx‐mp) and an early line Ning 63121(Wx‐b/Wx‐b). Based on the marker‐aided selection by our newly developed AS‐PCR marker for Wx‐mp and the known ST10 marker for Stvb‐i, a total of 12 Wx‐mp homozygotes were selected from 198 F₂ progenies, and four of them were immune to rice stripe virus (RSV) with averagely 11.3 days earlier heading than Nan Keng 46 without significant change in grain yield.     

Genome differentiation between Lycopersicon esculentum and L. pennellii as revealed by genomic in situ hybridization

The interaction between the Se1 and the Ef1 loci, which chiefly control the photoperiod sensitivity (PS) and the basic vegetative growth (BVG) period of rice (Oryza sativa L.) respectively, was investigated using four tester lines different in genotype for the two heading time loci from each other. The four tester lines were grown under 10, 13, 14, 15, and16h day lengths to estimate their BVG period and PS. The Taiwanese cultivar Taichung 65(T65), one of the tester lines, has an extremely long BVG period that has been considered to be conferred by a late heading-time allele ef1 at the Ef1 locus. Experimental results, however, showed that the extremely long BVG of T65was conferred not by a single effect ofef1 but by a complementary effect ofef1 and Se1-e, a photoperiod insensitivity allele, at theSe1 locus. It was also found that a complementary effect of a PS allele Se1-n at the Se1 locus and ef1stimulates the PS of rice. Gene analysis for heading time under an optimum daylength (10 h) as well as under natural day length confirmed the presence of the complementary effect of the two nonallelic genes on BVG, which was found only with homozygosity of both the genes. Based on these results and earlier reports on the Se1 locus, the roles of the Se1 andEf1 loci on the durations of pre-flowering developmental phases in rice were discussed. This revised version was published online in August 2006 with corrections to the Cover Date.     

Identification of a locus for asynchronous heading in rice, <Emphasis Type="Italic">Oryza sativa</Emphasis> L.

We have identified a locus for asynchronous heading in rice. The length of heading period in a plant was measured as the indicator of asynchronous heading in 98 backcross inbred lines (BILs). These lines were derived using a single-seed descent method from a backcross of (japonica Nipponbare/indica Kasalath)/Nipponbare, and we used this mapping population in quantitative trait locus (QTL) analysis. We located a single QTL related to asynchronous heading (qah7) in the region of R2401–C39 on chromosome 7, and its contribution to the total variation was 0.14 (r²), with the positive effect due to the Kasalath allele. A near isogenic line (NILah7) that carries a Kasalath chromosomal segment corresponding to qah7 in the Nipponbare genetic background was selected and analyzed to identify a locus for asynchronous heading. The length of heading period in NILah7 was significantly longer (P < 0.001) than that in Nipponbare.     

Deployment of cold tolerance loci from Oryza sativa ssp. Japonica cv. ‘Nipponbare’ in a high‐yielding Indica rice cultivar ‘93‐11’

Cold tolerance is a complex trait, and QTL pyramiding is required for rice breeding. In this study, a total of seven QTLs for cold tolerance in the Japonica rice variety ‘Nipponbare’ were identified in an F_2:3 population. A stably inherited major QTL, called qCTS11, was detected in the region adjacent to the centromere of chromosome 11. In a near‐isogenic line population, the QTL was further dissected into two linked loci, qCTS11.1 and qCTS11.2. Both of the homozygous alleles of qCTS11.1 and qCTS11.2 from ‘Nipponbare’ showed major positive effects on cold tolerance. Through pyramiding the linked QTLs in the cold‐sensitive Indica rice cultivar ‘93‐11’, we have developed a new elite, high‐yielding Indica variety with cold tolerance.     

The influence of a spring habit gene, Vrn-D1, on heading time in wheat

The adaptability of wheat cultivars to environmental conditions is known to be associated with a vernalization requirement, that is, spring/winter habit. To clarify the genetic effect of the spring habit gene, Vrn‐D1, on heading time in the field, recombinant inbred lines (RILs) with or without the Vrn‐D1 gene were produced from F₂ plants of the cross between ‘Nanbukomugi’ and ‘Nishikazekomugi’, non‐carrier and carrier cultivars of this gene, respectively. Using growth chambers with a controlled temperature and photoperiod, three components of heading time, i.e. vernalization requirement, photoperiodic sensitivity and narrow‐sense earliness (earliness per se), were evaluated in each RIL. RILs with the Vrn‐D1 gene (E lines) showed greatly reduced vernalization requirements and slightly shorter narrow‐sense earliness than RILs without Vrn‐D1 (L lines), although no difference in photoperiodic sensitivity was observed between the two groups. RILs were planted at four different sites in Japan and examined for their heading time in the field. E lines headed significantly earlier than L lines at all locations, indicating that the earliness of E lines is stable in various environmental conditions. These results indicated that spring habit caused by Vrn‐D1 gene, as well as narrow‐sense earliness, was responsible for heading time in the field.