水稻根系遗传育种研究进展

根系作为水稻(Oryza sativa)植株的重要组成部分,在水稻生长发育过程中发挥多种作用,包括植物的固定、水分和营养物质的获取以及氨基酸和激素的生物合成等,其形态结构和生理功能与水稻产量和稻米品质以及抗性等密切相关。目前,通过遗传及生化等诸多手段,已挖掘到较多水稻根系QTLs与控制基因。该文综述了水稻根系QTL和基因的研究进展,并对未来根系研究进行展望,以期为进一步克隆水稻根系基因和完善水稻理想株型模型提供参考。     

水稻根系遗传育种研究进展

根系作为水稻(Oryza sativa)植株的重要组成部分, 在水稻生长发育过程中发挥多种作用, 包括植物的固定、水分和营养物质的获取以及氨基酸和激素的生物合成等, 其形态结构和生理功能与水稻产量和稻米品质以及抗性等密切相关。目前, 通过遗传及生化等诸多手段, 已挖掘到较多水稻根系QTLs与控制基因。该文综述了水稻根系QTL和基因的研究进展, 并对未来根系研究进行展望, 以期为进一步克隆水稻根系基因和完善水稻理想株型模型提供参考。     

水稻抗白叶枯病基因的鉴定、定位和克隆进展

由水稻黄单胞菌水稻变种Xoo引起的水稻白叶枯病是全球性的重要病害之一。已有31个水稻白叶枯抗性基因被鉴定并报道,其中18个被定位到染色体上,5个被克隆。简要综述了水稻白叶枯抗性基因的鉴定、定位和克隆的进展,并讨论了合理利用抗性基因防治白叶枯病的前景。     

水稻抗白叶枯病基因及其应用研究进展

由黄单胞菌水稻变种Xanthomonas oryzae pv.Oryzae（Xoo）引起的白叶枯病是水稻重要病害之一。目前,已有37个水稻白叶枯抗性基因被鉴定并报道,其中28个被定位到染色体上,7个被克隆。本文简要综述了水稻白叶枯抗性基因的鉴定、定位和克隆的进展,并讨论了合理利用抗性基因防治白叶枯病的前景。     

水稻CesA4基因启动子与GUS基因融合表达

目的:利用GUS报告基因,研究水稻CesA4基因在水稻组织和器官的定位.方法:克隆水稻的CesA4基因的启动子并用GUS组织化学染色检测启动子与GUS基因融合表达情况.结果:成功克隆了水稻的CesA4基因的启动子,并发现水稻的CesA4基因在水稻的根、茎、叶、鞘、穗的纤维均有表达.结论:通过将水稻CesA4基因的启动子与GUS基因融合来分析水稻此基因的表达部位,是一种简便和有效方法.     

水稻耐冷相关基因克隆研究进展

全球约有一半的人口以稻米为主食,然而,大多数栽培水稻品种(尤其是籼稻品种)的耐冷性不强,易受冷害(冰点以上低温危害)。采用分子育种方法培育耐冷水稻新品种是提高水稻耐冷性、减轻冷害的措施之一,对水稻耐冷相关基因进行定位与克隆是水稻耐冷分子育种的重要环节。介绍了以东乡野生稻为研究对象的耐冷相关基因定位以及以栽培稻为研究对象的OsDREB1A与OSISAP1等耐冷相关基因的克隆,并指出了今后该领域研究的重点。     

水稻短根突变体Osksr5的遗传分析和基因定位

水稻根系对其生长、发育及产量等起着至关重要的作用。该研究从甲基磺酸乙酯（ethyl methane sulfonate,EMS）诱变的籼稻Kasalath突变体库中筛选到1个根系变短的突变体,命名为Osksr5（Oryza sativa kasalath short root 5）,该突变体植株具体表现为主根、不定根和侧根都明显变短,不定根的数目相对减少,株高与野生型相比也明显矮小。遗传分析结果表明,该突变性状由1对隐性核基因控制。利用图位克隆技术将OsKSR5基因定位在第1染色体的STS（sequence tagged site）分子标记33027k和33471k,物理距离约为444 kb。对OsKSR5基因的定位为进一步克隆该基因和阐明水稻根系发育的分子机理奠定了基础。     

稻瘟菌无毒基因研究进展

稻瘟菌是引起水稻稻瘟病的病原物。水稻与稻瘟菌间存在广泛而特异的相互作用,是研究寄主与病原物互作的重要模式系统。本文对稻瘟菌与水稻互作最重要的激发子―无毒基因的研究现状进行了概括,讨论了无毒基因的定位、克隆方法以及已克隆无毒基因的功能及进化研究,同时对今后无毒基因研究的重要方向进行了探讨,为深入理解无毒基因的功能及与水稻可能的互作关系奠定了基础。     

水稻白叶枯病抗性基因Xa21的分子生物学研究进展

由黄单胞杆菌水稻致病变种Xanthomonas oryzae pv.oryzae(Xoo)引起的白叶枯病是水稻重要细菌性病害之一。迄今,已有7个水稻白叶枯病抗性基因被克隆。Xa21是第一个被克隆的白叶枯病抗性基因,因具有广谱抗性而受到广泛的关注。对Xa21的发现、定位及克隆、表达特征、编码产物XA21的生化特性、作用与调控以及XA21介导的免疫反应模式等方面的研究结果进行综述,并对今后的研究方向进行展望。     

水稻广谱抗稻瘟病基因研究进展

稻瘟病是水稻生产中的最严重病害之一,由于稻瘟菌小种的高度变异性,垂直抗性基因难以持续控制稻瘟病的危害,因此,克隆和利用广谱持久抗瘟基因被认为是解决稻瘟病问题最经济有效的策略。本文从广谱抗源的筛选与利用,广谱抗瘟基因的定位、克隆与应用等方面对水稻广谱抗稻瘟病基因研究取得的进展进行了概述,并介绍了广谱抗性分子机理的最新研究进展。基于国内外稻瘟病抗性基因研究的现状及趋势,以及我国丰富的抗瘟水稻种质资源,克隆越来越多的广谱抗瘟基因具有重要的理论与应用价值。     

Molecular diversity, structure and domestication of grasses

Map-based cloning has been considered problematic for isolating quantitative trait loci (QTLs) due to the confounding phenotypic effects of environment and other QTLs. However, five recent studies, all in plants, have succeeded in cloning QTLs using map-based methods. We review the important features of these studies and evaluate the prospects for broader application of the techniques. Successful map-based cloning requires that QTLs represent single genes that can be isolated in near-isogenic lines, and that genotypes can be unambiguously inferred by progeny testing. In plants or animals for which map-based cloning of genes with discrete phenotypes is feasible, the modified procedures required for QTLs should not be limiting in most cases. The choice between map-based cloning and alternative methods will depend on details of the species and traits being studied.     

Gene identification using rice genome sequences

Identifying useful gene(s) is one of the most important objectives of plant geneticists. Various strategies can be used, which are based on the characteristics of plant reproduction and available technology. Rice is the first model crop whose whole genome sequence has been reported. In addition, information on the whole genome sequences of two important rice subspecies (japonica and indica rice) is also available. Rice is a self-pollinating crop and methods of artificial crossing are relatively easy to perform; such methods enable the production of numerous seeds for genetic analyses. Based on these features, a map-based cloning (i.e., positional cloning) strategy has been successfully applied over the last decade to identify rice genes. Recently, advanced next-generation sequencing (NGS) technology was used to ascertain the genome sequences of individual plants, opening up a new strategy for gene identification. This strategy has been used successfully to identify the genes responsible for certain qualitative traits in rice. However, to identify the gene(s) involved in a quantitative trait, a map-based cloning strategy is still required after quantitative trait loci analysis using NGS technology. In this review, we discuss both map-based cloning (which is still the primary strategy used to identify rice genes) and NGS-based strategies.     

水稻长日照开花因子Lfm1的图位克隆

开花期是水稻最重要的农艺性状之一,水稻的花期决定着水稻的地区适应性和最终产量。人工选择使水稻从短日照向长日照、低纬度向高纬度扩张,因此水稻已逐渐进化出适应长日照条件下的开花调控机制。目前,虽然鉴定了一些影响水稻长日照的开花基因如SDG724、RFT1、EHD4、DTH2,但是挖掘水稻长日照开花基因还十分有限。本研究通过筛选水稻突变体库,获得一批在长日照下花期有显著差异的突变体材料,其中一份突变体lfm1(late-flowering mutant1),在长日照条件下开花延迟,在短日照条件下开花时间正常。通过图位克隆,将Lfm1基因初定位至第8染色体端粒附近。进一步的精细定位将Lfm1基因定位于分子标记8-0.269和与8-0.283之间,范围为12 kb,该区域包括3个候选基因。经测序分析发现,在突变体lfm1中,LOC_Os08g01420基因的第六外显子2800处缺失9个碱基,突变体lfm1等位于已报道的突变体ehd3。在适度(中日照条件下,~12 h/12 h)的光照条件下,突变体lfm1表现为穗粒数增多,生育期略延长,具有应用于生产的潜力。Lfm1基因的克隆为培育适应不同生态区域的水稻材料提供了重要的基因资源。     

Identification, isolation and pyramiding of quantitative trait loci for rice breeding

Many agronomically important traits are governed by several genes known as quantitative trait loci (QTLs). The identification of important, QTL-controlled agricultural traits has been difficult because of their complex inheritance; however, completion of the rice genomic sequence has facilitated the cloning of QTLs and their pyramiding for breeding. Because QTLs are derived from natural variation, the use of a wider range of variations such as that found in wild species is important. In addition, Introgression Lines (ILs) developed from wild species in combination with Marker Assisted Selection should facilitate efficient gene identification. This review describes recent developments in rice QTL analysis including mapping, cloning and pyramiding QTLs.     

Genetic and molecular dissection of quantitative traits in rice

Recent progress in the generation of a molecular genetic map and markers for rice has made possible a new phase of mapping individual genes associated with complex traits. This type of analysis is often referred to as quantitative trait locus (QTL) analysis. Increasing numbers of QTL analyses are providing enormous amounts of information about QTLs, such as the numbers of loci involved, their chromosomal locations and gene effects. Clarification of genetic bases of complex traits has a big impact not only on fundamental research on rice plant development, but it also has practical benefits for rice breeding. In this review, we summarize recent progress of QTL analysis of several complex traits in rice. A strategy for positional cloning of genes at QTLs is also discussed.     

小麦根系特征对干旱胁迫的响应

干旱胁迫时, 小麦(Triticum aestivum)根系率先产生应激响应, 同时向地上部发出信号, 诱导地上部发生生理反应, 从而提高植株抗旱能力。根系构型包括平面几何性状和立体几何结构(即拓扑构型), 具有遗传稳定性和可塑性。干旱胁迫影响根系理化特性, 如根源化学信号、根系细胞酶类和根系渗透作用的响应。根系通过调整其解剖学结构和水分吸收动力等来适应干旱胁迫。该文从根系构型、理化特性和解剖学结构3个方面, 系统阐述了小麦根系特征对干旱胁迫的响应, 并探讨了其与干旱胁迫的关系和当前研究中存在的问题, 以期为相关研究提供参考。     

小麦根系特征对干旱胁迫的响应

干旱胁迫时, 小麦(Triticum aestivum)根系率先产生应激响应, 同时向地上部发出信号, 诱导地上部发生生理反应, 从而提高植株抗旱能力。根系构型包括平面几何性状和立体几何结构(即拓扑构型), 具有遗传稳定性和可塑性。干旱胁迫影响根系理化特性, 如根源化学信号、根系细胞酶类和根系渗透作用的响应。根系通过调整其解剖学结构和水分吸收动力等来适应干旱胁迫。该文从根系构型、理化特性和解剖学结构3个方面, 系统阐述了小麦根系特征对干旱胁迫的响应, 并探讨了其与干旱胁迫的关系和当前研究中存在的问题, 以期为相关研究提供参考。