籼粳杂交稻穗部性状的遗传效应及其与环境互作

采用包括基因型与环境互作效应的加性显性加性×加性上位性遗传模型,分析了不同环境下籼粳杂交稻穗部性状的遗传特点.结果表明,除了主穗粒数的加性与环境互作和二次枝梗数的显性与环境互作不显著外,其他性状均存在显著和极显著的加性、显性、加性×加性上位性遗传效应及其与环境的互作效应,其中均以显性效应为主,显性与环境互作效应对枝梗性状的影响较为明显.遗传率分析表明,各性状的普通广义遗传率最大,互作遗传率也有一定作用.杂种优势预测表明,除了一次、二次枝梗数外,其他性状均表现正向的杂种优势,基因型与环境互作只影响杂种优势表达的程度,而不改变其方向.遗传效应预测值结果表明,IR6615837、IR6560085、明恢63和R6694个亲本可以明显改良杂交后代多数穗部性状,且环境影响程度较小,可作为优良亲本列于育种计划中.     

云南香型软米水稻资源农艺性状遗传效应研究

选取5份云南地方香型软米水稻种质资源和6份自育香型软米保持系按5×6不完全双列杂交设计(NCⅡ)配制成30个组合,采用加性-显性-上位性遗传模型,分析云南香型软米11个农艺性状的遗传效应。结果表明,云南香型软米多数农艺性状的遗传主要受加×加上位性效应、加性×环境效应、显性×环境效应的影响,还存在不同程度的加性效应和显性效应,单株产量受基因加性效应、显性效应、加×加上位性效应、加性×环境效应、显性×环境效应的影响;株高、有效穗的遗传率以普通狭义遗传率为主,其他性状的普通狭义遗传率和互作狭义遗传率均达极显著水平;产量构成性状之间存在不同类型和不同程度的遗传相关,多数性状之间以加×加上位性、加性×环境和显性×环境互作效应显著。     

基因型与环境互作对食用稻米重金属积累特性遗传的影响

采用包括种子、细胞质、母体植株三套遗传体系的种子数量性状的遗传模型和统计方法,分析了食用稻米汞、砷、铬、镉和铅等5个重金属积累特性遗传的基因型与环境互作．结果表明,5个重金属积累除了受制于种子、细胞质和母体植株三套遗传效应外,还明显受到基因型与环境互作效应的影响．在遗传主效应中,汞、铬和铅积累以母体植株显性效应及其与环境互作效应为主．砷和镉积累则以种子直接加性与环境互作效应和母体植株显性与环境互作效应为主,细胞质效应及其与环境互作效应对这2个重金属积累的影响也较为明显．     

籼粳杂交稻穗部性状的遗传效应及其与环境互作

采用包括基因型与环境互作效应的加性-显性-加性×加性上位性遗传模型,分析了不同环境下籼粳杂交稻穗部性状的遗传特点.结果表明,除了主穗粒数的加性与环境互作和二次枝梗数的显性与环境互作不显著外,其他性状均存在显著和极显著的加性、显性、加性×加性上位性遗传效应及其与环境的互作效应,其中均以显性效应为主,显性与环境互作效应对枝梗性状的影响较为明显.遗传率分析表明,各性状的普通广义遗传率最大,互作遗传率也有一定作用.杂种优势预测表明,除了一次、二次枝梗数外,其他性状均表现正向的杂种优势,基因型与环境互作只影响杂种优势表达的程度,而不改变其方向.遗传效应预测值结果表明,IR66158-37、IR65600-85、明恢63和R6694个亲本可以明显改良杂交后代多数穗部性状,且环境影响程度较小,可作为优良亲本列于育种计划中.     

烤烟主要农艺性状的遗传与相关分析

利用包括基因型与环境互作的加性-显性遗传模型,对14个烤烟品种(系)及其配制的41个杂交组合在4个环境下的7个农艺性状表现进行遗传分析。结果表明,株高、节距、腰叶宽主要受加性效应控制,叶数、腰叶长受显性×环境互作效应影响最大,茎围以加性×环境互作效应、显性×环境互作效应为主,产量以加性效应、显性×环境互作效应为主。适应当地生态条件的品种（系）具有较高的正向加性效应。许多组合的显性主效应及在各试验点的显性×环境互作效应在方向上不尽一致,杂交组合的选配宜针对特定的生态环境进行。性状相关分析表明,大多数成对性状的各项相关系数为正值,且多以加性遗传相关为主,可利用株高对产量进行间接选择。
     

不同环境条件下粳型杂交稻米碾磨品质性状的遗传效应分析

采用包括基因型×环境互作效应的种子遗传模型,对粳型杂交稻稻米碾磨品质性状进行了遗传研究.结果表明:各碾磨品质性状除了受制于种子直接效应、细胞质效应和母体效应等遗传主效应外,还明显受到各基因型×环境互作效应的影响.其中糙米率性状以遗传主效应为主,而精米率、整精米率性状以基因型×环境互作效应为主.在遗传主效应中,糙米率性状主要受种子直接加性效应、母体加性效应的控制;在基因型×环境互作效应中,精米率和整精米率性状都是以种子直接加性×环境互作效应和母体加性×环境互作效应为主,细胞质×环境互作效应也起着较为重要的作用.大部分稻米碾磨品质性状的狭义遗传率均较高,其中糙米率性状以普通狭义遗传率为主,而精米率和整精米率性状则以互作狭义遗传率为主.另外,根据性状的遗传效应预测值对各亲本的育种利用价值作了评价.     

不同环境下籼稻糙米重的发育遗传研究

采用包括遗传主效应和基因型与环境互作效应的数量性状发育遗传模型和统计分析方法 ,分析了籼稻(OryzasativaL .)稻米 4个发育时期糙米重的两年资料。结果表明 ,除了三倍体胚乳和二倍体母体植株基因的加性和显性主效应以及细胞质主效应可以控制不同稻米发育时期的糙米重量外 ,基因型与环境互作效应也可明显影响不同发育时期糙米重量。基因加性主效应和加性×环境互作效应在整个稻米灌浆过程中起着主要作用 ,对糙米重的选择可以取得良好的改良效果。条件方差分量分析结果表明 ,胚乳和母体植株中控制糙米重表现的基因在多数稻米发育时期均有新的表达 ,且以稻米发育早期为主 ,开花后第 1～ 7天是控制糙米重的基因表达最为活跃的时期 ,其次为开花后第 8～ 14天。一些基因只在个别发育时期间断表达 ,这在净细胞质主效应和净细胞质×环境互作效应以及净显性主效应上表现得尤为明显。稻米不同发育时期的遗传效应预测值表明 ,V2 0和作 5等亲本可以明显提高后代的糙米重量。     

不同环境下籼型杂交稻穗干物质重的发育遗传分析

选用穗干物质重性状差异较大的 4个籼型不育系 (A)和相应的保持系 (B)以及 5个籼型恢复系(R) ,按不完全双列杂交设计 (4× 5 ) ,配成一套亲本和F12个世代的遗传群体 .采用包括基因型×环境互作的加性 显性发育遗传模型 ,分析了两年的籼型杂交稻不同发育时期穗干物质重的遗传表现 .结果表明 ,穗干物质重的发育全过程均受到遗传主效应和基因型与环境互作效应的控制 .在穗干物质重发育的前、中期 (15d前 )主要由显性效应控制 ,显性效应基因的表达量最大 ,环境因素的正向影响也较明显 ,可通过采取适当的栽培管理措施为稻穗发育创造良好的环境条件 ,促进杂种优势潜力的充分发挥 ;在发育的中后期 (15d后 )加性效应转为主要作用 ,加性效应基因的表达也呈最活跃状态 ,这一时期对穗重进行遗传选择会获得较好的遗传进度 .     

加性-显性-母体效应及GE互作效应遗传模型的模拟比较

运用蒙特卡罗方法比较了8个亲本正反应的加性－显性－母体效应的全模型及缩减模型,当σ^2M和σ^2ME存在时,检测各项遗传方差分量的功效高达97％以上,如何存在σ^2M和σ^2ME而缩减模型未包括这两项效应时,除显性效应以外的各项方差分量都被高估。对于加性－显性模型,如果忽略了基因型与环境互作,σ^2ε和σ^2A将被高估。当母体效应和基因型与环境互作被忽略时,将显著地增加遗传效应预测值的方差。     

油用向日葵主要农艺性状的遗传效应及相关性研究

根据加性-显性与环境互作的遗传模型,对6个油用向日葵自交系及其配制的9个杂交组合在2个环境下的7个农艺性状表现进行遗传分析,揭示油用向日葵主要农艺性状遗传性质、规律以及主要农艺性状对含油率的贡献率。结果表明:株高、茎粗、盘径、百粒重、籽仁率和单盘粒重等6个遗传性状主要受加性和显性共同控制,结实率的遗传以加性、显性×环境互作效应为主,籽仁率、单盘粒重以加性、显性、显性×环境互作效应为主;性状间的各项遗传相关性多以加性遗传相关为主。百粒重的净效应对籽实含油率的加性遗传方差贡献率最高,结实率的净效应对籽实含油率的显性遗传方差贡献率最高,单盘粒重对籽实含油率的加性×环境互作遗传方差的贡献率最高。     

Conditional genetic effect of allelopathy in rice (<Emphasis Type="Italic">Oryza sativa</Emphasis> L.) under different environmental conditions

Five parental rice lines with varied levels of allelopathic potential were employed in a partial diallel crossing program to generate 10 F₁ hybrids. The allelopathic effects of the aqueous leaf extracts of the five rice parents and 10 F₁s grown under two different conditions were assessed at different growth stages using lettuce (Lactuca sativa L.) as a bioassay species. Conditional genetics of rice seedling allelopathy and its genotype × environment effects were analyzed by using additive–dominant developmental genetic models. The results showed that conditional additive and dominant effects expressed alternatively from 3- to 8-leaf stage of rice seedlings. The additive effects were significant in the 5|4, 6|5, and 8|7-leaf phases, whilst the dominance effects appeared to play an important role in the 4|3 and 7|6 leaf phases. The conditional narrow sense heritability was significant in the 5|4, 6|5, and 8|7 leaf phases, the broad sense heritability was pronounced among all the growth periods investigated, suggesting that selection for allelopathic activity should be performed during this three leaf phases in order to improve selection response.     

籼型三系杂交水稻地上部干物质重的发育遗传研究

采用数量性状的加性--显性发育遗传模型分析了按NCⅡ交配设计的两套籼型三系杂交水稻地上部干物质重的发育遗传规律．结果表明,在不同发育阶段,地上部干物质重以显性效应为主,控制地上部干物质重的加性效应基因几乎不表达,而显性效应基因在两年中的表达呈连续性,且在生长中期活动强度最大,环境和基因型互作会影响地上部干物质重加性效应基因的表达,而对显性效应基因表达的影响不明显,随着发育进程的推进,地上部干物质重杂种优势趋于减弱。     

水稻化感物质抑草作用机理的分子生物学研究

水稻化感作用是通过水稻植株体向环境中释放化感物质来实现的．水稻化感物质的主要抑草作用机理有：抑制杂草种子的发芽,影响激素平衡,破坏细胞膜系统的完整性,影响光合作用和呼吸作用,干扰对营养和水分的吸收,影响蛋白质合成和基因表达等．水稻化感作用是由多基因控制的,表现为数量性状．利用分子生物学技术和化感生物检测技术等研究手段检测到了多个水稻化感作用的主效应(QTLs)位点,但不同水稻化感种质其主效应QTLs位点明显不同．通过分子辅助选择和建立近等基因系的方法对检测到的QTLs作进一步的精细定位,最终实现水稻化感抑草有利基因的克隆是今后研究的重要方向。     

化感水稻种质资源鉴定及基因定位研究进展与展望

稻种资源化感作用的鉴定评价与深入研究是化感水稻品种选育的基础.本文概要介绍了化感水稻种质资源鉴定评价方法、化感作用生理生化机理以及化感特性遗传与基因定位方面的主要研究进展,并进一步讨论了水稻化感作用研究与利用的发展方向.     

西芹挥发物对黄瓜枯萎病菌的化感作用

将定量的西芹种子、8～10叶期的叶片、叶柄、鲜根分别置于玻璃真空干燥器的下部,将在PDA培养基上接种黄瓜枯萎病菌的培养皿置于干燥器的上部,密封,利用生长速率法研究了不同西芹离体材料挥发物对黄瓜枯萎病菌的化感作用(各处理材料重量分别为50、100、150、200g)。结果表明:西芹挥发物对黄瓜枯萎病菌有化感抑制作用,且化感效果随着浓度的增加而增加;重量为200g的西芹种子、叶片、叶柄、鲜根挥发物处理黄瓜枯萎病菌144h后,化感效果分别为9.3%、10.9%、12.2%、18.7%;西芹鲜根挥发物的化感作用最强,其次为叶柄,叶片和种子最弱。对共培养后接种黄瓜枯萎病菌的黄瓜幼苗进行病害调查,处理为200株的西芹挥发物化感抑制效果最好,至接菌11d其发病株数为64株,化感效果为15.8%;西芹挥发物浓度越高,其抑制发病的效果越好,抑病效果随着时间的延长而减弱。     

Distribution of Endogenous Gibberellins in Vegetative Shoots of Rice

Levels of endogenous gibberellins in rice seedlings (Oryza sativaL., cv. Nipponbare) were compared between young and old leavesat the 4- and 5-leaf stages. The levels of GA₁, GA₁₉ and GA₅₃were higher in the youngest leaf than in older leaves at the5-leaf stage, but they did not differ significantly betweenthe leaf sheath and the leaf blade. At the 4-leaf stage, thelevel of GA₁, was highest in the third leaf sheaths which containedyoung elongating tissues. These results indicate that gibberellinsare synthesized in young vegetative tissues to promote theirelongation growth. The levels of GA₁ in the youngest leaf sheathsof two cultivars of dwarf rice, Tan-ginbozu and Waito-C, wereapproximately 10% of that in the normal rice at the 5-leaf stage.This result could explain the retardation of shoot elongationin these dwarf cultivars. (Received February 15, 1995; Accepted June 1, 1995)     

Genomic analysis of allelopathic response to low nitrogen and barnyardgrass competition in rice (<Emphasis Type="Italic">Oryza sativa</Emphasis> L.)

To explore the molecular mechanism of allelopathic rice in response to low nitrogen (N) supply or accompanying weed stress, allelopathic rice PI 312777 and its counterpart Lemont were grown under low N supply or co-cultured with barnyardgrass [Echinochloa crus-galli (L.) Beauv.] in hydroponics. The suppression subtractive hybridization (SSH) technique was employed to isolate the up-regulated genes in the treated rice accession. The results indicated that the expression of the genes associated with N utilization was significantly up-regulated in allelopathic rice PI 312777, and the higher efficiency of N uptake and its utilization were also detected in PI 312777 than that in Lemont when the two rice accessions were exposed to low N supply. This result suggested that the allelopathic rice had higher ability to adapt to low N stress than its non-allelopathic counterpart. However, a different response was observed when the allelopathic rice was exposed to accompanying weed (barnyardgrass) co-cultured in full Hoagland solution (normal N supply). It showed that the expression of the genes associated with allelochemical synthesis and its detoxification were all up-regulated in the allelopathic rice when co-cultured with the target weed under normal N supply. The results suggested that the allelopathic rice should be a better competitor in the rice-weed co-culture system, which could be attributed to increasing de novo biosynthesis and detoxification of allelochemicals in rice, consequently resulting in enhanced allelopathic effect on the target and preventing the autotoxicity in this process. These findings suggested that the accompanying weed, barnyardgrass is not only the stressful factor, but also one of the triggers in activating allelopathy in rice. This implies that the allelopathic rice is sensible of the existing target in chemical communication.     

Separation of allelopathy from resource competition using rice/barnyardgrass mixed-cultures

Plant-plant interference is the combined effect of allelopathy, resource competition, and many other factors. Separating allelopathy from resource competition is almost impossible in natural systems but it is important to evaluate the relative contribution of each of the two mechanisms on plant interference. Research on allelopathy in natural and cultivated plant communities has been hindered in the absence of a reliable method that can separate allelopathic effect from resource competition. In this paper, the interactions between allelopathic rice accession PI312777, non-allelopathic rice accession Lemont and barnyardgrass were explored respectively by using a target (rice)-neighbor (barnyardgrass) mixed-culture in hydroponic system. The relative competitive intensity (RCI), the relative neighbor effect (RNE) and the competitive ratio (CR) were used to quantify the intensity of competition between each of the two different potentially allelopathic rice accessions and barnyardgrass. Use of hydroponic culture system enabled us to exclude any uncontrolled factors that might operate in the soil and we were able to separate allelopathy from resource competition between each rice accession and barnyardgrass. The RCI and RNE values showed that the plant-plant interaction was positive (facilitation) for PI312777 but that was negative (competition) for Lemont and barnyardgrass in rice/barnyardgrass mixed-cultures. The CR values showed that one PI312777 plant was more competitive than 2 barnyardgrass plants. The allelopathic effects of PI312777 were much more intense than the resource competition in rice/barnyardgrass mixed cultures. The reverse was true for Lemont. These results demonstrate that the allelopathic effect of PI312777 was predominant in rice/barnyardgrass mixed-cultures. The most significant result of our study is the discovery of an experimental design, target-neighbor mixed-culture in combination with competition indices, can successfully separate allelopathic effects from competition.     

应用差异蛋白质组学方法分析作物化感作用的分子机理

试验旨在分析运用分子标记技术(QTL)和差异蛋白组学技术研究作物化感作用分子机理的差异性。首先运用差异蛋白组学技术探讨在生物胁迫(稗草)下水稻化感作用潜力变化的内在分子机理。分别用稗草和水稻的根系分泌物培养切自一株5叶龄化感水稻P I312777植株并经恢复的2个分蘖。7d后,提取处理和对照相同叶位叶片的全蛋白质并进行双向电泳,每张电泳胶片上获得800多个电泳胶点,其中差异表达的蛋白质点有4个。采用M ALD I-TOF-M S对各差异蛋白质点进行肽质量指纹图谱分析,经过SW ISS-PROT数据库查询,结果表明化感水稻P I312777在稗草胁迫下的特异蛋白分别与苯丙氨酸氨解酶(PAL)、硫还原型蛋白(T rx-m)、3-羟基-3-甲基戊二酰辅酶A还原酶(HM GR)和过氧化物酶(POD)相匹配。根据编码以上4个差异蛋白质的DNA序列,发现编码以上4个差异蛋白的基因分别位于水稻染色体4、7、8和12上的特定克隆位点,这就是与化感作用相关基因。前人也运用QTL方法开展作物化感作用的分子机理研究,但由于所采用的供体材料、受体植物及对表型性状的评价方法等的不同,定位结果存在较大的差异。综合比较两种方法后认为,运用差异蛋白组学技术分析水稻化感作用的分子机理,比QTL技术更加直接和深入。因为比较胁迫处理和对照植物组织的2-DE图谱将能鉴定出由表达候选基因编码的胁迫蛋白质,氨基酸残基序列的测定将揭示那些功能与胁迫性状密切相关的蛋白质,这种编码的基因就是兼具功能与表达的候选基因。