不同种植方式下温度升高对水稻产量及同化物转运的影响

【目的】气候变暖对水稻生产系统的影响备受关注,研究不同种植方式下,水稻产量及其形成对气候变化的响应规律,为水稻种植区划、栽培措施和品种调整提供依据。【方法】 2017—2018年以南粳9108和南粳46为供试品种,模拟机插秧移栽和机械化直播2种种植方式,以常温（NT）为对照,于始穗期进行中度升温（平均增加2℃,MT）和极端高温胁迫（平均增加5℃,HT）,研究不同种植方式下温度升高对不同水稻品种的产量及其构成、同化物转运、光合生产特性的影响。【结果】在中度升温和极端高温胁迫下,南粳9108和南粳46产量降幅均为移栽<直播,长生育期品种南粳46产量降幅较小。穗干物重增长速率表现为NT>MT>HT,水稻茎叶向穗的干物质转运量、转运率均随着温度升高而递减,且南粳9108下降趋势大于南粳46。穗后21 d至成熟期,剑叶SPAD值总体随着温度的升高而增加,差异达极显著水平;剑叶净光合速率穗后14—21 d均以极端高温胁迫处理下最小,而到穗后35 d以极端高温胁迫处理下最大。剑叶气孔导度、蒸腾速率均呈NT>MT>HT趋势,生育后期差异更显著。通径分析表明,产量各构成因子对产量的影响程度为结实率>千粒重>穗数>每穗粒数,温度处理对产量各构成因子的影响都表现为负效应,且以结实率影响最大（-0.819）。相关分析表明,不同种植方式下受中度升温、极端高温胁迫后,成熟期干物质总重量、茎叶干物质转运量与产量构成因子（穗数除外）,一、二次枝梗籽粒结实率都呈极显著正相关。【结论】始穗期2—5℃升温均显著降低粳稻结实率,从而导致水稻产量降低。从光合物质特性究其原因是由于温度升高降低了干物质向穗的转运率和穗干物质积累速率,从而导致生育后期水稻剑叶SPAD值增加,延长叶片持绿时间,抑制“源”向“库”转移。从气候变暖应对措施来看,选择采用移栽种植方式和长生育期品种易于表现出对极端高温胁迫逆境较好的抗性。     

不同类型水稻品种产量和氮素吸收利用对大气CO2浓度升高响应的差异

目的 探明不同类型水稻品种产量和氮素吸收利用对FACE(大气CO₂浓度增高)响应的差异。方法 以常规粳稻、杂交籼稻、常规籼稻共6个品种为供试材料,研究FACE对不同类型水稻产量、氮素吸收利用的影响。结果 1）FACE处理极显著提高了水稻产量,平均增加24.17%, 常规籼稻增幅最大,FACE和对照均以杂交籼稻最高;2）FACE处理显著增加了单位面积穗数,常规粳稻增幅最大,并显著增加了杂交籼稻和常规籼稻每穗粒数;3）FACE处理显著提高了成熟期吸氮量和氮素籽粒生产效率,成熟期吸氮量平均增加21.23%,杂交籼稻增幅最大, FACE和对照均以常规籼稻最高;氮素籽粒生产效率平均增加7.33%,杂交籼稻增幅最大,FACE和对照均以杂交籼稻最高。成熟期吸氮量对产量促进作用略大于成熟期氮素籽粒生产效率;4）FACE处理降低了植株含氮率,成熟期平均下降0.105个百分点,常规粳稻降幅最大。FACE处理极显著提高植株干物质量,成熟期平均增加23.95%,常规籼稻增幅最大;FACE处理显著提高常规籼稻和杂交籼稻成熟期单穗吸氮量,分别增加10.79%、13.93%,但常规粳稻下降了9.60%;FACE处理显著提高了成熟期群体吸氮强度,平均增加22.29%,杂交籼稻增幅最大。FACE处理对水稻全生育期天数无显著影响;FACE处理显著提高茎鞘、叶片、穗各器官吸氮量,叶片增幅最大,平均增加51.86%,杂交籼稻增幅最大;FACE处理显著提高了不同生育阶段吸氮量,抽穗-成熟阶段增幅最大,平均增加108.90%,杂交籼稻增幅最大;5）植株干物质量、单穗吸氮量、吸氮强度、穗吸氮量、抽穗-成熟阶段吸氮量对成熟期总吸氮量的促进作用分别大于植株含氮率、单位面积穗数、生育天数、茎鞘叶吸氮量、移栽-分蘖和分蘖-抽穗阶段吸氮量;6）FACE处理显著提高了氮肥偏生产力,降低了每百千克籽粒需氮量,前者平均增加24.16%,常规籼稻增加最多;后者平均降低4.7%,常规籼稻降幅最大。结论 FACE处理可显著提高水稻产量和氮素吸收利用效率,但品种间差异较大。     

江苏近年育成粳稻新品种/系的稻瘟病抗性基因及穗颈瘟抗性分析

【目的】明确水稻品种携带的抗稻瘟病基育种应用价值,是利用抗病基因培育抗病品种控制病害流行的重要前期工作。【方法】利用功能标记分析了14个抗稻瘟病基因在江苏近年育成的195个粳稻新品种/系中的分布情况,并对其中158个品种和17份携带抗稻瘟病基因Pigm的高世代回交株系进行穗颈瘟接种鉴定。【结果】大多数品种携带2~5个抗病基因,但所有品种均不含有Pigm基因;Pib、Pita和Pikh基因在供试品种中的分布频率较高,均在45%以上,其余基因均在30%以内;Pid3、Pid2、Pia、Pb1在新育成品种中的出现频率明显高于审定品种。测试品种对穗颈瘟的抗性主要与3个基因显著相关,贡献率由高至低依次为Pia、Pi3/5/i和Pita;其中,Pia或Pi3/5/i与Pita间的聚合效应均显著高于各基因单独存在时的抗病效应,且以Pia和Pita间的聚合效应最强,携带该基因组合的所有品种对穗颈瘟均表现抗至高抗水平抗性。回交导入Pigm基因的所有17份株系对穗颈瘟的抗性均显著高于各自轮回亲本,且均达到了抗病以上水平。【结论】抗病基因Pigm及基因组合“Pia+Pita”在江苏粳稻抗穗颈瘟育种中具有重要的育种应用价值。     

Effects of post-silking water deficit on the leaf photosynthesis and senescence of waxy maize

Waxy maize is widely cultivated under rainfed conditions and frequently suffers water shortage during the late growth stage. In this study, a pot trial was conducted to examine the effects of post-silking drought on leaf photosynthesis and senescence and its influence on grain yield. Two waxy maize hybrids, Suyunuo 5(SYN5) and Yunuo 7(YN7), were grown under the control and drought(soil moisture content was 70–80% and 50–60%, respectively) conditions after silking in 2016 and 2017. The decrease in yield was 11.1 and 15.4% for YN7 and SYN5, respectively, owing to the decreased grain weight and number. Post-silking dry matter accumulation was reduced by 27.2% in YN7 and 26.3% in SYN5. The contribution rate of pre-silking photoassimilates transferred to grain yield was increased by 15.6% in YN7 and 10.2% in SYN5, respectively. Post-silking drought increased the malondialdehyde content, but decreased the contents of water, soluble protein, chlorophyll, and carotenoid in the leaves. The weakened activities of enzymes involved in photosynthesis(ribulose-1,5-bisphosphate carboxylase and phosphoenolpyruvate carboxylase) and antioxidant system(catalase, superoxide dismutase and peroxidase) reduced the photosynthetic rate(P_n) and accelerated leaf senescence. The correlation results indicated that reduced Pn and catalase activity and increased malondialdehyde content under drought conditions induced the decrease of post-silking photoassimilates deposition, ultimately resulted in the grain yield loss.     

RGB1 Regulates Rice Panicle Architecture and Grain Filling Through Monitoring Cytokinin Level in Inflorescence Meristem and Grain Abscisic Acid Level During Filling Stage

正RGB1 regulated not only rice panicle architecture but also the grain filling process. Suppression of RGB1 expression resulted in a denser panicle and smaller grain size and weight, which was largely due to the lower endogenous cytokinin (CK) level caused by the increased expression of cytokinin oxidase genes in the inflorescence meristem. Suppression of RGB1 expression also significantly delayed the grain development and reduced the starch accumulation rate through reducing grain abscisic acid(ABA) accumulation during early filling stage. Exogenous ABA can partially rescue the detrimental effects of suppression of RGB1 expression on starch accumulation and grain weight.     

小麦高分子量谷蛋白亚基缺失品质效应研究进展

高分子量谷蛋白亚基（high-molecular-weight glutenin subunits,HMW-GS）是小麦籽粒贮藏蛋白的重要组成成分,其数量和质量与品质密切相关。聚合优质HMW-GS可改良强筋小麦制品面包品质,相反HMW-GS缺失可能在弱筋小麦制品饼干、糕点或其他特色食品品质改良上具有重要应用价值。本文从小麦HMW-GS缺失的类型和机制、贮藏蛋白组分和蛋白体发育、面粉和面团品质效应以及食品加工品质改良等方面进行了综述,分析了当前小麦HMW-GS缺失研究利用中存在的问题,并对未来研究方向进行了展望。     

Characteristics of grain quality and starch fine structure of japonica rice kernels following preharvest sprouting

Preharvest sprouting (PHS) is one of the most serious defects that impacts rice production and grain quality. Knowledge about the effects of PHS on the eating and cooking quality (ECQ) of milled rice is limited. Here, we selected four japonica rice varieties to study the influences of PHS on grain quality. The results showed that PHS strongly led to poor grain appearance and the development of small starch granules whose surfaces were eroded. Analysis of starch fine structure revealed that PHS resulted in amylose (AM) degradation; in particular, PHS caused a decrease in the content of long AM chains. Moreover, PHS led to a decrease in the content of short amylopectin (AP) chains in the varieties Yandao 815 (YD815), Wuyugeng 27 (WY27) and Yangeng 13 (YG13), while the variety Sidao 785 (SD785) displayed the opposite trend. We propose that the main reasons for the decrease in starch crystallinity and the pasting profiles of the germinated rice were due to both the tendency of the AM content to decrease and the degree of this decrease in the content of the different AM chains along with changes in AP and other major components. All these changes caused by PHS led to a decrease in both ECQ and palatability of milled rice.     

水稻着丝粒特异组蛋白CENH3抗体的制备与应用

【目的】着丝粒是真核生物染色体的基本功能元件之一,其功能是在细胞有丝分裂和减数分裂时期精确地调控染色体配对和分离并维持染色体的稳定。着丝粒结构是由DNA和蛋白质形成的一种复合体。着丝粒特异组蛋白(centromere-specific histone H3,CENH3)是功能着丝粒是否具有活性的最基本特征。所以制备CENH3的相关抗体是进行着丝粒结构与功能研究的前提条件之一。【方法】通过设计短肽进行兔免疫实验,制备了水稻着丝粒特异组蛋白CENH3兔源抗体,利用ELISA和蛋白免疫荧光(immunofluorescence,IF)等检测方法对抗体有效性进行了鉴定。【结果】ELISA检测显示制备的CENH3抗体有效稀释度为1:40万,并且蛋白免疫荧光信号在水稻体细胞每条染色体的着丝粒区域均能检测到。同时,该抗体也可以应用于玉米等其他物种。通过染色质免疫沉淀(ChIP)技术获得与CENH3相结合的DNA分子,并进行PCR扩增和FISH定位分析,结果显示相应的Ch IP-DNA位于水稻功能着丝粒区域。【结论】本研究制备的水稻CENH3兔源抗体能满足着丝粒研究中相关实验的要求,可进一步应用于着丝粒的结构与功能研究。     

水分与氮素及其互作对水稻产量和水肥利用效率的影响研究进展

了解水分、氮素及其互作对水稻产量与水、氮利用效率的影响,对协同提高水稻产量与水氮利用效率有重要意义。本文概述了水稻节水灌溉技术、氮肥利用效率与氮肥施用技术、水分与氮素对水稻产量及水氮利用效率的耦合效应、作物-土壤关系及水氮调控机制等方面取得的进展;讨论了存在的问题,这些问题包括:高产水稻作物与土壤的水氮互作效应尚不明确;高产水稻水氮耦合与高效利用的分子机理不清楚;协同提高水稻产量与水氮利用效率的调控途径尚未掌握。针对这些问题,建议今后重点研究:高产水稻作物与土壤的水氮互作效应及其机制;水氮互作调控水稻吸收利用水分和氮素的生理与分子机理;协同提高水稻产量和水氮利用效率的调控途径与关键技术。