浅谈水稻超高产育种的现状与前景

简要回顾了水稻超高产育种的历史进程,指出了提高单产是增加粮食产量的根本。结合我国水稻超高产育种经典理论内容与实践,分析了水稻超高产育种的现状,提出了通过籼粳稻杂交、光敏核不育和广亲和基因等途径实现水稻超高产育种的方法。     

施钾量对超高产早稻品种产量和稻米品质的影响

以超高产水稻品种陆两优996和淦鑫203为材料,在大田条件下研究了不同施钾量对其产量和稻米品质的影响。结果表明,施钾显著提高双季早稻有效穗数、每穗粒数和产量,增加生物产量、促进茎鞘物质运转,提高抽穗期剑叶的气-叶温差和颖花伤流量,降低抽穗后的根系活力衰退值。施钾量与倒1节间大维管束数、茎秆抗折力和稻米蛋白质含量显著正相关。施钾提高了陆两优996的垩白粒率和垩白度,但降低了淦鑫203的垩白粒率和垩白度。在本试验条件下,最适施钾量为180 kg/hm2。     

野生稻抗病虫基因的挖掘和利用

本文综合国内外文献,简要介绍了野生稻抗病虫基因发掘、定位、克隆及育种应用研究的进展,讨论了野生稻优异抗病虫基因在水稻育种中的应用前景。     

不同酶制剂对水稻秸秆和白酒糟混合青贮品质的影响

为研究不同酶制剂对水稻（Oryza sativa L.）秸秆和白酒糟（m︰m=1︰1）混合青贮品质的影响，设置CK（对照）、CEL（250 U·g^-1纤维素酶）和XYL（250 U·g^-1木聚糖酶）3个处理，青贮120 d后取样测定其青贮品质。结果表明：CEL处理的感官评定等级为良好；CEL和XYL处理的干物质、粗脂肪、钾和镁含量均显著高于CK（P<0.05），且CEL处理的粗蛋白和磷含量显著高于CK（P<0.05）；CEL和XYL处理的中性洗涤纤维、酸性洗涤纤维、木质素和纤维素含量均显著低于CK（P<0.05），且CEL处理显著低于XYL处理（P<0.05）；CEL和XYL处理30 h的养分消化率显著高于CK（P<0.05），且CEL处理48 h的养分消化率均显著高于CK（P<0.05）；CEL和XYL处理的饲用价值显著高于CK（P<0.05），且CEL处理显著高于XYL处理（P<0.05）。综上所述，添加纤维素酶、木聚糖酶能够提高水稻秸秆和白酒糟混合青贮的营养品质、养分消化率和饲用价值，且纤维素酶的添加效果优于木聚糖酶。     

干尖线虫病对不同水稻品种（系）产量相关性状的影响

[目的]该研究旨在了解干尖线虫病对不同水稻品种的影响。[方法]通过田间表型观察与室内考种试验，对自然发病状态下的4个常规粳稻品种（系）和粳稻恢复系 R161进行了观察和分析。[结果]不同水稻品种（系）被侵染后的症状存在差异，常规粳稻宁1707、宁1818、镇稻88和南粳9108被侵染后表现"干尖"和"小穗头"症状，粳稻恢复系R161只表现"干尖"，不表现"小穗头"症状，且"干尖"的位置不同，分别位于剑叶叶尖，整片剑叶及倒二叶。供试材料被水稻干尖线虫侵染后均能抽穗，但是株高、穗长、结实率和千粒重均受到不同程度的影响。此外，R161被干尖线虫侵染后，不同发病部位对水稻产量的影响不同，整片剑叶干枯扭曲的稻穗受影响最大。[结论]该研究为进一步阐明我国水稻干尖线虫病的危害规律和制定相应的防治措施提供依据。     

水稻高产、优质和氮高效协同的氮素调控研究

以超级粳稻‘新稻18号’为试验材料,大田条件下,研究不同施氮量(0、232.5、255.0、277.5、300.0、322.5和345.0kg/hm2纯氮水平)对水稻产量、品质及氮肥吸收利用效率的影响,以明确高产、优质和氮高效协同的适宜氮素水平。结果表明,随氮素水平提高,水稻产量、稻米品质和氮肥吸收利用效率均呈先增后降趋势。施氮量为255.0kg/hm2纯氮处理下,产量最高为9 878.11kg/hm2,稻米的糙米率、精米率和整精米率较高,分别为84.81%、72.85%和66.94%,垩白粒率和垩白度较低,分别10.00%和2.86%,氮肥吸收利用效率较高,为41.34%。低氮肥和高氮肥处理,产量、品质和氮肥利用效率相对较低。说明,在适宜的氮肥水平下,水稻高产、优质和氮高效可达到协同一致。     

生物炭表面水溶活性分子可以有效提高水稻的耐旱性

生物炭是一种可以改良土壤、增强作物产量和提升作物品质的新型农林废弃物再利用材料。本研究通过振荡方式制备生物炭浸提液,利用水培系统培养水稻幼苗,以20%PEG6000、300 mmol/L和500 mmol/L甘露醇模拟干旱胁迫,研究生物炭表面水溶活性分子对水稻幼苗抗旱性的影响。研究结果发现:生物炭浸提液可有效缓解干旱胁迫造成的水稻种子萌发和幼苗生长抑制,缓解叶绿素含量、鲜重及存活率的降低,同时可以降低体内的活性氧积累等。实时定量RT-PCR检测表明生物炭浸提液促进干旱胁迫响应标志基因的表达量。研究结果说明生物炭浸提液可以提高干旱胁迫下水稻幼苗的抗氧化能力,进一步提高水稻幼苗对干旱胁迫的耐受性。     

Genotype-by-environment interaction analysis of rice (Oryza spp.) yield in a floodplain ecosystem in West Africa

West Africa has large areas of river floodplains, most of which are not currently used for farmland. Rice (Oryza spp.) is a promising crop for farming in floodplains because of its high adaptability to a wide range of water environments. On the other hand, there is great variation in soil fertility and water availability even in a small area within a floodplain. Hence, we evaluated 27 rice genotypes in four fields in three years in a floodplain of the Northern Region of Ghana to investigate genotype × environment (G × E) interactions for rice yield and to identify stable, high-yielding genotypes. The genotypes consisted of O. sativa, O. glaberrima and New Rice for Africa (NERICA), and many were selected for their reported submergence resistance because of the anticipated submergence damage in the floodplain. There were large variations in yield, which ranged from 0.14 to 5.35 t ha⁻¹ depending on the location within a floodplain, genotype and year, and there were significant genotype, environment and G × E interaction effects on yield, accounting for 24.8%, 20.2%, and 28.2%, respectively, of the total variation. The results suggested that selection of suitable location with high soil fertility and low risk of submergence is necessary to achieve high yield in a floodplain. In addition, early sowing would be effective high-yielding crop management, which reduced the risk of submergence-induced damage just after sowing and secured sufficient growth duration to achieve high yield. Genotype IR42 showed the highest average yield among environments, but its yield stability was low. On the other hand, several genotypes including Amankwatia, a local aromatic cultivar adapted to irrigated and lowland environments, and IRBL9-W[RL], a blast-tolerant variety containing the Sub1 gene for submergence tolerance, showed high, stable yield. To put these results to practical use in other floodplain areas in West Africa, physiological mechanisms causing G × E interaction for rice yield should be further studied.     

Greenhouse gas implications of water reuse in the Upper Pumpanga River Integrated Irrigation System, Philippines

Enhancing water productivity is often recommended as a “soft option” in addressing the problem of increasing water scarcity. However, improving water productivity, particularly through water reuse, incurs additional investment and may result in increased greenhouse gas (GHG) emissions. In this study, we analysed the water productivity and GHG implications of water reuse through pumping groundwater and creek water, and compare this with gravity-fed canal irrigation in the Upper Pampanga River Integrated Irrigation System (UPRIIS) in the Philippines.Water productivity indicators show that water reuse contributes significantly to water productivity. For example, water productivity with respect to gross inflow (WP_gross) with water reuse (0.19 kg grain/m³) is 21% higher than without water reuse (0.15 kg grain/m³). However, there is a tradeoff between increasing water productivity and water reuse as water reuse increases GHG emissions. The estimated GHG emission from water reuse (pumping irrigation) is 1.47 times higher than without water reuse (gravity-fed canal irrigation). Given increasing concerns about climate change and the need to reduce carbon emissions, we recommend that a higher priority be given to water reuse only in areas where water scarcity is a serious issue.     

油菜水分胁迫的冠层表面温度特征及诊断研究

对油菜的冠层温度特征进行了研究,并在此基础上建立了油菜的冠气温差模型和CWSI模型。利用建立的CWSI模型对植株含水率进行预测,结果表明:油菜含水率预测值与实测值的平均相对误差小于9.2%;CWSI模型能够实现对油菜含水率的定性和定量分析。