广东省国标优质杂交稻育种进展

整理了2002～2007年共6年12季的广东省杂交稻区试资料,分析了2002年后广东省国标优质杂交稻的育种状况,以及国标优质杂交稻育种中存在的突出问题.     

外源油菜素甾酮处理水稻对褐飞虱取食和产卵选择性等行为的影响

为了解经油菜素甾酮处理后水稻对褐飞虱Nilaparvata lugens的抗性,通过在水稻培养液中添加不同浓度的油菜素甾酮,观察水稻对褐飞虱取食和产卵、若虫生长发育、羽化等行为的影响,评估油菜素甾酮在水稻抗虫防御反应中的作用。结果表明,水稻培养液中的油菜素甾酮可被水稻有效吸收并产生生理活性。经0.01～10μmol/L油菜素甾酮处理后水稻叶片弯曲程度均显著增加,其叶角分别为对照的3.3～11.0倍。褐飞虱取食和产卵嗜好性与油菜素甾酮处理浓度密切相关,经较低浓度0.005～0.05μmol/L油菜素甾酮处理的水稻能显著降低褐飞虱雌成虫的取食和产卵嗜好性,其产卵量为对照的35.0%～73.9%;而较高浓度0.1～5μmol/L油菜素甾酮处理则增加褐飞虱雌成虫的取食和产卵嗜好性,其产卵量为对照的1.3～1.8倍。0.01、1、5、10μmol/L油菜素甾酮处理的水稻显著降低褐飞虱若虫的羽化率,为对照的32.5%～53.3%。0.1～10μmol/L油菜素甾酮处理显著缩短褐飞虱若虫发育历期,仅为对照的94.1%～96.9%。褐飞虱若虫存活数和初羽化雌成虫体重分别仅在0.1、10μmol/L油菜素甾酮处理下显著降低。表明油菜素甾酮处理水稻可对水稻抗虫防御反应产生影响,其具有作为生态功能分子用于褐飞虱田间防控的潜力。     

半干旱栽培稻田不同秸秆覆盖材料的产量效应

采用田间观测的方法,分析了不同覆盖材料对半干旱栽培条件下杂交水稻田间茎蘖数、干物质积累和土壤水分的影响,探讨了不同覆盖材料的产量效应。结果表明:(1)在川西北丘陵旱区进行秸秆覆盖有利于增加非灌溉期田间土壤贮水量,提高田间茎蘖数;秸秆腐烂所释放的养分,缓解了稻田磷钾供应相对不足的现状,有效提高了杂交稻的结实率、有效穗数和千粒重;覆盖处理稻田0~0.5 m土层贮水量较不覆盖处理增加2%~13%,田间茎蘖数增加4%~15%,有效穗数增加4%~8%,结实率增加3%~7%,千粒重增加0.6%~1.7%。(2)在灌溉水源没有保证的丘陵旱区,将半干旱栽培与秸秆覆盖相结合,可有效提高杂交水稻产量。冈优725和D优363实收产量平均值在油菜荚壳覆盖、麦草覆盖和麦糠覆盖处理下分别较对照增加10.2%、7.0%和7.7%。     

水稻内生细菌B196的鉴定及其对水稻纹枯病的防治作用

从水稻体内分离得到的细菌菌株B196对水稻纹枯病菌Rhizoctonia solani的生长有较强抑制作用.通过形态学和生理生化鉴定及16S rDNA序列分析,将菌株B196鉴定为巨大芽孢杆菌Bacillus megaterium.采用浸种和喷雾的方法将菌株B196接种到水稻植株后,均能在稻株体内回收到该菌株,表明菌株B196能在水稻体内定殖.菌株B196对水稻纹枯病的盆栽和田间防效分别为64.29%和55.13%.     

野生稻与栽培稻的杂种后代对褐稻虱的抗性机制初探

为了开拓抗虫基因源,培育抗性稳定的水稻抗虫品种,采用感虫的栽培稻雄性不育株为母本,以高抗褐稻虱的野生稻为父本进行有性杂交。通过用改良的苗期群体筛选法,对其后代进行抗性鉴定,证实其抗性可以遗传,已成功地获得了抗褐稻虱的杂种后代。并根据飞虱在抗虫植株上的生存率、群体建立、蜜露量和稻株的受害级别等指标与感虫对照种TN1上的差异显著性作比较,综合评定杂种后代对褐稻虱的抗性机制。结果表明,测试的N482(A)/101392组合的F_5、F_6、F_7和H_4等几个后代对褐稻虱的抗性机制均为抗生性。     

转hrf1基因水稻对稻曲病抗性分析

用注射接种法测定9个转hrf1基因水稻品系对稻曲病的抗性,结果表明B12-2m、B12、HTRP2和NJH12转基因系对稻曲病的抗性有显著提高,其中NJH12对稻曲病的抗性表现最突出。在江苏南京和安徽潜山两地的田间测定结果显示NJH12对稻曲病的抗性表现明显,与对照相比防效提高65%以上。用RT-PCR测定抗病转基因系中防卫基因的表达,在抗病转基因系中,Ospr1a、Ospr1b和PAL等防卫反应基因的表达明显增强。转hrf1基因水稻可能通过诱导防卫反应基因的表达提高水稻对稻曲病的抗性。     

中国水稻害虫治理对策的演变及其展望

本文简要回顾了中国水稻害虫的变迁、相应的对策演变,从中了解、总结害虫发生与人类治虫对策之间的因果渊源,指出只有师法自然、通过生态工程实施生态治理技术才能持续双赢。     

8个WRKY转录因子在水稻叶片生长和抗病过程中的表达分析

 WRKY是植物体内最大的转录因子家族之一, 其成员在植物生长发育和抗逆过程中发挥重要作用。为了解水稻WRKY的功能, 本研究利用蛋白质免疫印迹(western blotting, WB)技术, 检测了8个WRKY转录因子在水稻叶片生长和Xa21介导的抗白叶枯病过程中的表达丰度变化。结果表明:OsWRKY12、43、55和86在苗期表达量较低, 随叶片的生长表达逐步增加;OsWRKY50和84在苗期叶片中的表达量相对较高, 成熟期下降;未检测到OsWRKY40/64和52在叶片中的表达。在Xa21介导的白叶枯病抗性反应中, OsWRKY40/64、50和52受白叶枯病菌诱导表达, OsWRKY84受侵染后表达量上调, OsWRKY12、43、55和86在抗病过程中没有检测到表达丰度的变化。进一步比较这些转录因子在抗、感和对照(Mock)反应中的表达, 发现抗、感反应间蛋白质的表达变化是相似的。研究结果提示:OsWRKY12、43、55和86可能在叶片正常生长中发挥作用;OsWRKY40/64和52可能在水稻-白叶枯病菌互作过程中发挥作用;OsWRKY50和84则在叶片生长和抗白叶枯病过程中都有一定的功能。     

Allelopathy in crop/weed interactions--an update

Since varietal differences in allelopathy of crops against weeds were discovered in the 1970s, much research has documented the potential that allelopathic crops offer for integrated weed management with substantially reduced herbicide rates. Research groups worldwide have identified several crop species possessing potent allelopathic interference mediated by root exudation of allelochemicals. Rice, wheat, barley and sorghum have attracted most attention. Past research focused on germplasm screening for elite allelopathic cultivars and the identification of the allelochemicals involved. Based on this, traditional breeding efforts were initiated in rice and wheat to breed agronomically acceptable, weed-suppressive cultivars with improved allelopathic interference. Promising suppressive crosses are under investigation. Molecular approaches have elucidated the genetics of allelopathy by QTL mapping which associated the trait in rice and wheat with several chromosomes and suggested the involvement of several allelochemicals. Potentially important compounds that are constitutively secreted from roots have been identified in all crop species under investigation. Biosynthesis and exudation of these metabolites follow a distinct temporal pattern and can be induced by biotic and abiotic factors. The current state of knowledge suggests that allelopathy involves fluctuating mixtures of allelochemicals and their metabolites as regulated by genotype and developmental stage of the producing plant, environment, cultivation and signalling effects, as well as the chemical or microbial turnover of compounds in the rhizosphere. Functional genomics is being applied to identify genes involved in biosynthesis of several identified allelochemicals, providing the potential to improve allelopathy by molecular breeding. The dynamics of crop allelopathy, inducible processes and plant signalling is gaining growing attention; however, future research should also consider allelochemical release mechanisms, persistence, selectivity and modes of action, as well as consequences of improved crop allelopathy on plant physiology, the environment and management strategies. Creation of weed-suppressive cultivars with improved allelopathic interference is still a challenge, but traditional breeding or biotechnology should pave the way.