水稻种质资源芽期耐冷性的鉴定与评价

对新收集的879份水稻种质资源进行了水稻芽期耐冷性的鉴定与评价,从中筛选出芽期耐冷性极强的水稻种质资源39份,均为贵州地方粳稻品种.供试粳稻品种61.23%具有强芽期耐冷性(3级),而籼稻品种只有13.77%具有强芽期耐冷性(3级 ),粳稻品种的芽期耐冷性显著强于籼稻品种.无论籼稻,还是粳稻,贵州地方稻种的芽期耐冷性显著强于来自其他地区的品种,从贵州地方稻种中挖掘极强耐冷种质资源的潜力较大 .     

中国水稻微核心种质不同生育时期耐冷性鉴定及其相关分析

以204份中国水稻微核心种质为试验材料,进行了水稻发芽期、芽期、幼苗期、孕穗期等耐冷性鉴定及其相关性分析。结果表明,水稻各生育时期耐冷性在籼粳亚种间、各种质之间存在明显的差异。粳稻种质的耐冷性明显强于籼稻种质,但籼稻种质中也存在耐冷性较强的种质。高阳淀稻大红芒、肥东塘稻、木樨球、卫国、兴国、山酒谷、中花8号等粳稻种质和包选21号、红米三担白、寸谷糯、红谷等籼稻种质在水稻各生育时期均表现较强的耐冷性,在水稻耐冷性育种及耐冷基因发掘研究中应加以利用。自然低温和冷水胁迫下水稻结实率与低温下发芽率呈显著或极显著正相关,而与死苗率呈显著负相关,即低温下发芽期耐冷性和芽期耐冷性强的水稻种质一般表现为较强的孕穗期耐冷性。认为低温下发芽率和芽期低温处理后的死苗率可以作为孕穗期耐冷性早期鉴定的间接指标。     

中国水稻微核心种质不同生育时期耐冷性鉴定及其相关分析

以204份中国水稻微核心种质为试验材料,进行了水稻发芽期、芽期、幼苗期、孕穗期等耐冷性鉴定及其相关性分析。结果表明,水稻各生育时期耐冷性在籼粳亚种间、各种质之间存在明显的差异。粳稻种质的耐冷性明显强于籼稻种质,但籼稻种质中也存在耐冷性较强的种质。高阳淀稻大红芒、肥东塘稻、木樨球、卫国、兴国、山酒谷、中花8号等粳稻种质和包选21号、红米三担白、寸谷糯、红谷等籼稻种质在水稻各生育时期均表现较强的耐冷性,在水稻耐冷性育种及耐冷基因发掘研究中应加以利用。自然低温和冷水胁迫下水稻结实率与低温下发芽率呈显著或极显著正相关,而与死苗率呈显著负相关,即低温下发芽期耐冷性和芽期耐冷性强的水稻种质一般表现为较强的孕穗期耐冷性。认为低温下发芽率和芽期低温处理后的死苗率可以作为孕穗期耐冷性早期鉴定的间接指标。     

粳稻芽期耐冷性鉴定方法研究

利用22个粳稻品种,在不同低温胁迫、不同处理天数下进行水稻芽期耐冷性鉴定,并提出了适合于粳稻芽期耐冷性的鉴定方法.研究结果表明,在低温胁迫和不同天数的处理中,以2℃/6d低温胁迫下的22个粳稻品种死苗率的方差和变异范围表现为最大,并且死苗率的分布比较合理,据此认为该低温胁迫对于粳稻芽期耐冷性鉴定是比较合适的胁迫条件.在2℃/6d低温胁迫下,靖粳7号、辐优1号、合系15、沈农15、东农422、滇系1号等品种芽期耐冷性属3级,为强耐冷性品种;云南省粳稻品种的芽期耐冷性普遍好于东北三省的粳稻品种.     

普通野生稻染色体片段代换系的孕穗期耐冷性研究

为筛选出在苗期和孕穗期都具有强耐冷性的种质以供水稻耐冷研究与育种利用,本研究利用人工低温胁迫的方法,对20份苗期耐冷的普通野生稻染色体片段代换系进行了孕穗期耐冷性鉴定评价。结果表明:(1)在20份代换系材料中,孕穗期耐冷性表现强(3级)、中(5级)和弱(7级)级别的材料为2份、15份和3份,分别占供试材料的10%、75%和15%;(2)水稻苗期和孕穗期的耐冷性呈显著正相关(p0.05),所鉴定出的2份抗性3级材料(DC907和DC866)不但可以作为苗期耐冷性抗源,同时也可以作为孕穗期耐寒性抗源;(3)可溶性蛋白、可溶性糖、游离氨基酸、脯氨酸、丙二醛和超氧化物歧化酶等各项生理指标与相对结实率之间均无显著的相关关系,因此均不适宜作为孕穗期耐冷性的鉴定评价指标。     

人工环境鉴定小豆芽苗期耐冷性研究

对来自中国北京187份、天津33份、河北25份、山西16份、山东6份、河南1份、安徽1份、江苏22份、四川2份、陕西3份、辽宁18份、吉林33份、黑龙江5份,日本31份和韩国1份共384份小豆种质资源进行发芽期耐冷性鉴定,并以31份资源和18个品种为试验材料,进行三叶期耐冷性鉴定研究.结果表明:筛选出发芽期耐冷性较好(耐冷指数>0.80)的资源31份;在三叶期低温8～5℃胁迫7d,资源G-I-34、JN95-0和E0064等表现出较强的耐冷性.采用三叶期低温8～5℃胁迫7d,只统计生长正常苗的方法进行小豆苗期耐冷性鉴定评价是可行的;小豆发芽期与三叶期耐冷性存在差异;苗期持续耐冷性存在差异.     

基于引物扩增受阻突变技术开发水稻耐冷基因CTB4a特异性分子标记

水稻(Oryza sativa)作为热带与亚热带起源的作物对低温敏感.对水稻种质进行耐冷性鉴定,能筛选出耐冷性强的种质,发展耐冷基因分子标记,能够有效鉴别种质中耐冷基因的基因型.本研究使用芽期4℃低温处理10d对41份水稻材料进行芽期耐冷鉴定,对品种的芽期耐冷能力进行评价,获得了参试材料中除了'昆明小白谷'之外的芽期耐冷性最强的品种'南特号'.对已克隆的耐冷基因CTB4a开发分子标记,能够辅助选择水稻的耐冷育种.水稻孕穗期耐冷基因CTB4a来源于'昆明小白谷',能够影响水稻抵抗低温的能力.参照公布的CTB4a序列信息,从中挑选出序列中的作用位点SNP(单核苷酸多态性,single nucleotide polymorphism),结合引物扩增受阻突变技术(Penta-primer amplification refractory mutation system,PARMS),用Primer 6.0设计引物,建立CTB4a基因荧光分子标记GM-CTB4a,使用荧光分子标记GM-CTB4a对41份水稻品种进行鉴定,使用酶标仪在'昆明小白谷'中检测到利用标记扩增产物中包含'昆明小白谷'特异SNP、T碱基引物携带的FAM荧光信号,在另外40份品种的扩增产物中检测到包含作用位点的C碱基引物携带的HEX荧光信号.本研究利用设计的分子标记,鉴定了 41份水稻品种的耐冷性和基因型.比对分析耐冷性和基因型鉴定结果,说明我们开发的分子标记GM-CTB4a特异性较强,具有实际应用价值.研究结果为利用水稻孕穗期耐冷基因CTB4a培育强耐冷水稻品种奠定坚实基础.     

人工环境鉴定小豆芽苗期耐冷性研究

对来自中国北京187份、天津33份、河北25份、山西16份、山东6份、河南1份、安徽1份、江苏22份、四川2份、陕西3份、辽宁18份、吉林33份、黑龙江5份,日本31份和韩国1份共384份小豆种质资源进行发芽期耐冷性鉴定,并以31份资源和18个品种为试验材料,进行三叶期耐冷性鉴定研究。结果表明：筛选出发芽期耐冷性较好（ 耐冷指数＞0.80）的资源31份;在三叶期低温8～5℃胁迫7d,资源G-I-34、JN95-0和E0064等表现出较强的耐冷性。采用三叶期低温8～5℃胁迫7d,只统计生长正常苗的方法进行小豆苗期耐冷性鉴定评价是可行的;小豆发芽期与三叶期耐冷性存在差异;苗期持续耐冷性存在差异。     

水稻抗冷性与不同生长阶段的关系

从国际水稻研究所种质库取得50个水稻品种,其中包括粳型品种12个,釉稻18个,爪哇型品种10个,釉×粳杂种3个,以及野生稻7个。在芽期、苗期、移栽期、孕穗期、开花期,进行了耐冷性的测定。结果指出,在不同的水稻类型中,其耐冷性的次序为:粳稻>爪哇型>秈稻>野生稻。从本实验所采用的有限量的品种来看,在苗期粳型品种的耐冷性比其它类型好;在开花期某些爪哇型品种比粳型品种好;在芽期和苗期之间,以及在芽期和开花期之间,其耐冷性有明显的正相关。在其它时期之间未找到这种相关性。这指出,在特殊地区的低温发生时期的一定生育阶段中,进行筛选是必要的。     

人工海水胁迫下小麦种质资源的耐盐性筛选与鉴定

利用人工配制的海水筛选耐盐性较好的小麦品种,为沿海滩涂地区的小麦耐盐育种提供重要信息。本研究利用人工海水处理的方法,对363份小麦种质资源进行了芽期耐盐性初步鉴定,筛选出芽期耐盐性为1级的小麦种质28份。进一步对芽期耐盐性较好的48份小麦种质进行了苗期耐盐性鉴定,并对其耐盐指标进行隶属值模糊评价分析,从中鉴定出了2个苗期耐盐性较强的小麦种质,分别为淮麦31和红壳洋麦。依据来源的不同,发现小麦种质资源的芽期耐盐性大小依次为地方品种>育成品种>国外引进品种。小麦芽期与苗期的耐盐性相关分析表明,二者相关性极低(r=-0.0051)。     

盐胁迫下不同水稻种质形态指标与耐盐性的相关分析

选用中国、韩国和国际水稻研究所(IRRI)不同耐盐能力的籼、粳、爪哇稻16份为材料进行芽期和苗期试验。随着NaCl浓度增加,种子开始发芽的时间推迟、发芽过程延长、发芽率降低;品种的发芽率能有效地指示其芽期耐盐能力。NaCl浓度对许多苗期形态指标有显影响,其中叶片盐害指数能反映品种的苗期耐盐能力;随着NaCl处理时间的增长,叶片盐害指数与NaCl浓度间的相关性越来越大。同一品种在芽期的耐盐能力和苗期表现不一致,两的相关系数很低。     

Gene expression of the biosynthetic enzymes and biosynthesis of starch during Rice Grain development

Amylose and amylopectin are determinants of the physicochemical properties for starch and grain quality in rice. Their biosynthesis is catalyzed by the interplay of ADP-glucose pyrophosphorylase (AGPase), granule-bound starch synthase (GBSS), soluble starch synthase (SSS), a starch branching enzyme (SBE), and a starch debranching enzyme (SDE). In this study, the genes for these enzymes were highly expressed 7 to 28 days after flowering during grain development, and their expression closely matched increases in both starch content and grain weight Among all the tested cultivars, amylose contents in the rice grains remained essentially constant throughout their development The AGPase gene was highly expressed in the high-yield cultivars of both glutinous and non-glutinous rice. The SSS gene was actively expressed when mature GBSS mRNA decreased. Genes responsible for amylopectin biosynthesis were simultaneously expressed in the late stage of grain development. We have now demonstrated that the expression patterns of starch biosynthetic genes differ between glutinous and non-glutinous rice, and between Tongil (a Japonica/ Indica hybrid) and Japonica types.     

广西地方稻种资源核心种质构建和遗传多样性分析

以丁颖分类体系分组原则与组内逐层聚类取样方法,对8609份广西地方栽培稻资源表型数据信息进行分析,通过对表型保留比例等评价指标的多重比较确定核心种质总体取样比例,构建出占总体样本5%(414份)的广西地方栽培稻资源初级核心种质。初级核心种质能代表总体遗传变异的89%。用34对SSR分子标记对初级核心种质进行遗传多样性分析,结果表明:广西地方栽培稻资源有较高的遗传多样性(等位基因数A为4.91,Nei’s多样性指数为0.574)。就Nei’s遗传多样性指数而言,粳稻高于籼稻,晚稻高于早稻,水稻高于陆稻,糯稻高于粘稻;来自桂中的稻种资源具有最高的遗传多样性。研究最终利用SSR数据,把414份初级核心种质压缩50%后形成209份核心种质,核心种质基因保留比例达到98%以上,有效代表了广西地方栽培稻资源多样性水平。     

Genetic architecture of aluminum tolerance in rice (Oryza sativa) determined through genome-wide association analysis and QTL mapping

Aluminum (Al) toxicity is a primary limitation to crop productivity on acid soils, and rice has been demonstrated to be significantly more Al tolerant than other cereal crops. However, the mechanisms of rice Al tolerance are largely unknown, and no genes underlying natural variation have been reported. We screened 383 diverse rice accessions, conducted a genome-wide association (GWA) study, and conducted QTL mapping in two bi-parental populations using three estimates of Al tolerance based on root growth. Subpopulation structure explained 57% of the phenotypic variation, and the mean Al tolerance in Japonica was twice that of Indica. Forty-eight regions associated with Al tolerance were identified by GWA analysis, most of which were subpopulation-specific. Four of these regions co-localized with a priori candidate genes, and two highly significant regions co-localized with previously identified QTLs. Three regions corresponding to induced Al-sensitive rice mutants (ART1, STAR2, Nrat1) were identified through bi-parental QTL mapping or GWA to be involved in natural variation for Al tolerance. Haplotype analysis around the Nrat1 gene identified susceptible and tolerant haplotypes explaining 40% of the Al tolerance variation within the aus subpopulation, and sequence analysis of Nrat1 identified a trio of non-synonymous mutations predictive of Al sensitivity in our diversity panel. GWA analysis discovered more phenotype-genotype associations and provided higher resolution, but QTL mapping identified critical rare and/or subpopulation-specific alleles not detected by GWA analysis. Mapping using Indica/Japonica populations identified QTLs associated with transgressive variation where alleles from a susceptible aus or indica parent enhanced Al tolerance in a tolerant Japonica background. This work supports the hypothesis that selectively introgressing alleles across subpopulations is an efficient approach for trait enhancement in plant breeding programs and demonstrates the fundamental importance of subpopulation in interpreting and manipulating the genetics of complex traits in rice.     

长江三角洲主要超级稻CH4排放特征及其与植株生长特性的关系

采用盆栽试验研究了长江三角洲14个主要超级稻品种(6个粳型超级稻和8个籼型杂交超级稻)CH₄排放特征及其与植株生长特性之间的关系.结果表明: 粳型和籼型超级稻全生育期CH₄排放均呈双峰模式,排放峰值分别出现在分蘖盛期和孕穗期.粳型超级稻的平均CH₄排放总量比籼型超级稻高37.6%(P<0.01),品种间排放差异主要出现在生长后期.虽然两种类型超级稻的CH₄排放总量均与最大叶面积呈显著正相关,但CH₄排放与其他生长特性的关系因品种类型而异.在株高上,粳型超级稻CH₄排放总量与株高呈显著正相关,而籼型超级稻的相关不显著.在生产力上,籼型超级稻CH₄排放总量与其总生物量、籽粒产量和收获指数呈显著负相关,而粳型超级稻的相关不显著.籼型超级稻CH₄排放量低主要是由于其根系生物量显著高于粳型超级稻.     

施氮对水稻植株和颖果发育及稻米品质的影响

以'扬稻6号'和'粳稻941'为材料,在施氮总量相同条件下分别设置低分蘖肥高孕穗肥和高分蘖肥低孕穗肥2个施氮处理,通过盆栽试验研究施氮量和施氮时期对水稻植株生长、颖果发育和稻米品质的影响.结果表明:水稻植株鲜重、干重、分蘖数和株高随分蘖期氮肥用量增加而增加;增加孕穗期氮肥用量比例能显著提高抽穗期水稻剑叶和颖果光合速率、颖壳叶绿素含量、呼吸速率、颖果CAT及SOD活性;增加孕穗期氮肥用量还能提高水稻籽粒出糙率、精米率、整精米率,降低稻米垩白率,改善稻米的碾米品质和营养品质.因此,增加分蘖期施氮比例能促进水稻植株生长,而提高孕穗期施氮量则有利于水稻颖果发育和稻米品质改善.     

长江三角洲主要超级稻CH4排放特征及其与植株生长特性的关系

采用盆栽试验研究了长江三角洲14个主要超级稻品种(6个粳型超级稻和8个籼型杂交超级稻)CH₄排放特征及其与植株生长特性之间的关系.结果表明: 粳型和籼型超级稻全生育期CH₄排放均呈双峰模式,排放峰值分别出现在分蘖盛期和孕穗期.粳型超级稻的平均CH₄排放总量比籼型超级稻高37.6%(P<0.01),品种间排放差异主要出现在生长后期.虽然两种类型超级稻的CH₄排放总量均与最大叶面积呈显著正相关,但CH₄排放与其他生长特性的关系因品种类型而异.在株高上,粳型超级稻CH₄排放总量与株高呈显著正相关,而籼型超级稻的相关不显著.在生产力上,籼型超级稻CH₄排放总量与其总生物量、籽粒产量和收获指数呈显著负相关,而粳型超级稻的相关不显著.籼型超级稻CH₄排放量低主要是由于其根系生物量显著高于粳型超级稻.     

Identification and pyramiding of QTLs for cold tolerance at the bud bursting and the seedling stages by use of single segment substitution lines in rice (<Emphasis Type="Italic">Oryza sativa</Emphasis> L.)

Cold stress is one of the main constraints in rice production, and damage from cold can occur at different developmental stages in rice. Understanding the genetic basis of cold tolerance is the key for breeding cold-tolerant variety. In this study, we used single segment substitution lines (SSSLs) derived from a cross between cold-tolerant japonica variety “Nan-yang-zhan” and a popular indica variety “Hua-jing-xian 74” to detect and pyramid QTLs for cold tolerance at the bud bursting and the seedling stages. Evaluation of cold tolerance of these SSSLs and their recurrent parent helped identify two cold-tolerant QTLs (qCTBB-5 and qCTBB-6) at the bud bursting stage and two cold-tolerant QTLs (qCTS-6 and qCTS-12) at the seedling stage. The SSSLs carrying these QTLs showed stronger cold tolerance than their recurrent parent HJX74 did in three independent experiments. The qCTBB-6 and qCTS-6 were mapped to the same chromosomal region. QTL pyramiding was performed by intercrossing of SSSLs carrying the respective QTLs for cold tolerance at the bud bursting stage and the seedling stage and marker-assisted selection (MAS). The selected pyramiding line SC1-1 with different cold-tolerant QTLs showed cumulative effects on cold tolerance. Our results suggest that different genes (QTLs) control cold tolerance at bud bursting and seedling stages, and pyramiding of stable expression QTLs for cold tolerance at different developmental stages through MAS is a good strategy to prevent cold damage in rice.