Effects of Plant Density and Nitrogen Application Rate on Grain Yield and Nitrogen Uptake of Super Hybrid Rice

The nitrogen uptake, yield and its components for two super-high-yielding hybrid rice combinations, Guodao 6 and Eryou 7954 were investigated under different plant densities （15, 18, and 21 plants/m^2） and different nitrogen application rates （120, 150, 180, and 210 kg/hm^2）. The experiment was conducted on loam soil during 2004-2006 at the experimental farm of the China National Rice Research Institute in Hangzhou, China. In these years, the two hybrid rice cleady showed higher yield at a plant density of 15 plants/m^2 with a nitrogen application rate of 180 kg/hm^2. Guodao 6 produced an average grain yield of 10 215.6 kg/hm^2 across the three years, while the yield of Eryou 7954 was 9 633.0 kg/hm^2. With fewer plants per unit-area and larger plants in the plots, the two hybrid rice produced more panicles per plant in three years. The highest nitrogen uptake of the two hybrid rice was at a plant density of 15 plants/m^2 with a nitrogen application rate of 180 kg/hm^2. Further increasing nitrogen application rate was not advantageous for nitrogen uptake in super-high-yielding rice under the same plant density.

Comparison of agronomic performance between inter-sub-specific hybrid and inbred japonica rice under different mechanical transplanting methods

Mechanical transplanting has been applied to rice cultivation to save labor costs and ease labor shortages in Asian countries, especially in China. However, little information is available related to the characteristics of agronomic performance when comparing inter-sub-specific hybrid rice(IHR) and inbred japonica rice(IJR) under mechanical transplanting method. In 2013 and 2014, field experiments were conducted using IHR(Yongyou 2640) and IJR(Wuyunjing 24) under two cultivation patterns, that is, pot seedlings mechanically transplanted(PS) and carpet seedlings mechanically transplanted(CS). Grain yield, yield components, leaf area index(LAI), leaf area duration(LAD), aboveground biomass, crop growth rate(CGR), nitrogen(N) uptake, and N accumulation were investigated. When compared with CS, PS displayed significantly increased grain yield for both varieties because the larger sink size allowed higher N accumulation from panicle initiation to maturity. Moreover, total aboveground biomass under PS increased significantly compared with that under CS; that is, higher photosynthetic productivity resulted from a greater LAI and higher LAD during the grain filling stage. Higher N absorption capacity in the middle and late growth periods resulted in significantly enhanced total N uptake under PS. When compared with IJR for both treatments, IHR generated 75.2% more grain yield. However, the characteristics creating high yield of IHR were different from those of IJR. Greater aboveground biomass production as well as higher N uptake and accumulation created higher grain yield in IHR than in IJR. These results suggest higher yield could be achieved using PS with IHR, attributing to exploit both yield superiority and productive potential.

Hybrid rice achievements, development and prospect in China

This article reviews the history and progress of hybrid rice development. Hybrid rice research was initiated back in 1964, and commercialized in 1976. Three-line and two-line system hybrid rice were developed in 1974 and 1995, respectively. Research on super hybrid rice, which was first launched by Ministry of Agriculture, China in 1996, is discussed, and the great progress of super hybrid rice had been achieved with a new yield record by 15.4 t ha^-1 in the 6.84 ha demonstration location in Xupu, Hunan Province, China in 2014. And the mechanism of heterosis, the techniques of hybrid seed production and the modern field managements in hybrid rice over the past decades are also discussed. Additionally, this article dealt with the intellectual property protection（IPR） and development of hybrid rice seed industry in China. Major factors that constrain hybrid rice development are analyzed and possible solutions to this problems are proposed. Finally, the authors present methods to further increase production yield, and propose an improvement for breeding super high-yielding hybrid rice based on these methods.

Breeding of New Japonica-indica Hybrid Rice Combination Chunyou 284

Chunyou 284 is a medium- japonica hybrid combination,as well as an indica-japonica subspecific hyrbid with super-high yield,which was developed from Chunjiang 23A,a thermo-sensitive CMS line with very early anthesis time,and C84,an indica-japonica intermediate type restorer line with wide compatibility.This combination has the advantages of high yield potential,early maturity,excellent comprehensive agronomic traits and wide adaptability.It was approved by Jiangsu Provincial Crop Variety Approval Committee in June,2018.The breeding process,main characteristics,cultivation techniques and seed production points of the combination were introduced.

Proteomic Analysis of the Response of Liangyoupeijiu(Super High-Yield Hybrid Rice) Seedlings to Cold Stress

Liangyoupeijiu is a super high-yield hybrid rice. Despite its advantages with respect to yield and grain quality, it is sensitive to cold, which keeps it from being widely cultivated. We subjected Liangyoupeijiu seedlings to 4 ℃ cold treatment, then extracted the leaf proteins. After 2-D gel electrophoresis separation and matrix-assisted laser desorption/ionization time-of-flight mass spectrometry analysis, a series of differentially displayed proteins were identified. Some metabolism-associated proteins were found among the downregulated proteins, such as carbamoyl phosphate synthetase, transketolase 1, dihydrolipoamide dehydrogenase and glyceraldehyde 3-phosphate dehydrogenase. The upregulated proteins included both stress-resistance proteins such as nucleoside diphosphate kinase I and proteins that are negative for rice growth, such as FtsH-like protein, plastid fusion and/or translocation factor （Pftf） and actin. Our results indicate that cold may inhibit Liangyoupeijiu growth through decreasing metabolic activity and damaging cell structure.

杂交水稻新组合卓两优1126百亩片单产17.79 t/hm^(2)超高产栽培技术

卓两优1126是湖南杂交水稻研究中心和湖南农业大学用小粒不育系卓201S与大粒恢复系R1126选配而成的强优势新组合。该组合株叶形态好,剑叶挺直,穗层相对较低,根系发达,穗大粒多,结实率高,稻米品质好,具有优异的抗倒伏能力和较大的高产潜力。同时,该组合的小粒型不育系可进行轻简机械化制种,实现杂交水稻种子生产全程机械化,降低种子成本,促进水稻生产方式转型。2023年卓两优1126在云南省蒙自市进行百亩超高产攻关示范,平均单产达17.79 t/hm^(2)。本文详细阐述了卓两优1126百亩片单产17.79 t/hm^(2)超高产栽培技术,并提出栽培种植过程中获取高产的关键措施。

超高产优质早熟籼粳杂交稻浙优915的选育与栽培技术

高产与优质是水稻产业的关键性目标,然而这2个性状存在明显的矛盾,运用常规育种技术在同一品种上集聚2个性状非常困难。本研究团队采用分子育种技术与籼粳杂种优势利用方法相结合,成功选育出超高产优质早熟籼粳杂交稻浙优915。该品种在区域试验和生产试验中,表现出超高产潜力。稻米品质符合食用稻部标三等,评价指标中除碱消值外,其余指标符合部标一等。全生育期为146.5~156.5 d,比嘉优5号早熟0.3~0.9 d。2023年通过国家品种审定,适宜在浙江、上海、安徽、湖北、苏南等南方粳稻种植区推广应用。根据浙优915品种特性,提出提高有效穗数和增加每穗粒数的关键性高产栽培技术。

水稻小粒不育系新组合卓两优1126的高产特征

[目的]挖掘杂交水稻产量潜力,培育超高产品种,既是一道科学难题,也是“藏粮于技”安全战略。本研究旨在解析小粒不育系卓201S配组的杂交稻卓两优1126高产形成规律,为优质高效超级杂交稻培育提供理论支撑。[方法]2022年选用小粒不育系新组合卓两优1126和对照品种超级稻两优培九、Y两优900和湘两优900为试验材料,在湖南省隆回县统一高产栽培,系统比较卓两优1126与其他3个超级杂交稻产量及其产量构成、干物质积累、根系发育和抗倒性,探究小粒不育系新组合卓两优1126高产特征。[结果]卓两优1126产量极显著高于对照,较超级杂交稻第1期代表品种两优培九增产35.07%,较超级杂交稻第4期代表品种Y两优900增产17.84%,较超级杂交稻新代表品种湘两优900增产14.52%。卓两优1126产量的提高主要原因是在保持稳定千粒重和结实率基础上,通过平衡有效穗数与每穗粒数使群体总颖花数显著提升。与对照相比,卓两优1126单茎地上部干质量、根干质量和根冠比均极显著高于对照,表明卓两优1126根系具有显著的生长优势,能够很好地协调植株地下和地上部分的生长,有助于超高产的形成。卓两优1126株高适中,基部3节间总长和穗下节间长度都极显著高于对照,但基部第2节间的弯曲力矩和抗折力与湘两优900的差异未达到显著水平,卓两优1126在增加株高的同时保持了较强的抗倒性。卓两优1126耐低氮,稻米品质综合评级为部标优质2级,极端高温下较对照Y两优1928增产5.53%。[结论]卓两优1126在保持稳定的千粒重和结实率基础上,通过平衡有效穗数与每穗粒数使群体总颖花数显著提升,从而实现超高产。卓两优1126亲本间粒型存在显著差异,可以实现父母本混播混收的全程机械化制种,降低种子生产成本。另外,小粒型不育系千粒重仅为常规不育系的1/2,在制种产量保持不变的前提下,单位制种面积的杂交稻种子粒数比普通不育系多1倍,大幅降低杂交稻的用种成本。因此,以卓两优1126为代表的“小粒种高产稻”模式,能为解决杂交水稻当前困境提供新思路,是新的发展方向。

福建两系杂交稻制种安全高产的精细气候适宜性区划

利用福建省67个国家气象观测站1971-2020年气象资料以及地理信息资料、两系杂交稻制种基地调查资料,构建了两系杂交稻制种育性转换敏感期气候风险模型与风险等级指标、扬花授粉期天气综合危害指数模型与等级指标两个安全期气候区划指标,选择不育系育性转换起点温度23℃开展研究,基于两系杂交稻制种气候适宜性分区等级标准,采用多层复合方法,开展基于GIS的福建省两系杂交稻制种安全高产精细气候适宜性区划。结果表明:育性敏感期安排在7月上旬-下旬、7月中旬-8月上旬,扬花授粉期安排在8月上旬-中旬,适宜区分布在福建北部、西南部等县市海拔300m以下的区域,次适宜区分布在福建北部、西南部等县市海拔300-500m的区域;育性敏感期安排在7月下旬-8月中旬、8月上旬-下旬,扬花授粉期8月下旬-9月上旬,适宜区分布在福建北部、西南部等县市海拔400m以下的区域,次适宜区分布在福建北部、西南部等县市海拔400-500m的区域;育性敏感期安排在7月上旬-8月下旬,扬花授粉期安排在8月上旬-9月上旬,低适宜区分布在海拔500-1000m的区域,不适宜区分布在海拔1000m以上区域。

优质高产籼粳杂交稻嘉禾优7245的选育及制种技术

嘉禾优7245是中国水稻研究所联合嘉兴市农业科学研究院等多家单位,以嘉禾212A(长粒型粳稻三系不育系)为母本与中恢7245(中籼迟熟型恢复系)为父本选育的三系杂交水稻新组合。该组合具有高产、优质、抗倒伏等优势,于2017年7月通过国家审定(国审稻20170064),2020—2022年先后通过了广西壮族自治区(桂审稻2020220号)、广西壮族自治区晚稻(桂审稻2022093号)、江西省(赣审稻20210016)的品种审定,2022年通过福建省:(闽)引种〔2022〕第1号的引种备案,适宜在长江中下游地区作中、晚稻种植。文章介绍了嘉禾优7245的选育过程、特征特性、高产栽培及制种技术等。

优质高产籼粳杂交稻嘉丰优3号的选育及制种技术

嘉丰优3号是嘉兴市农业科学研究院联合中国水稻研究所、浙江可得丰种业有限公司,以嘉禾112A(长粒型粳稻三系不育系)为母本与G1143(中籼迟熟型恢复系)为父本选育的三系杂交水稻新组合。该组合具有高产、优质、中抗稻瘟病等优势,于2021年4月通过浙江审定(浙审稻2021019),2021—2023年先后通过了江西省[(赣)引种〔2021〕第001号]、安徽省(皖引稻2021066)、福建省[(闽)引种〔2022〕第1号]、湖北省(鄂引种2022055)的引种备案,适宜在长江中下游地区作中稻种植。文章介绍了嘉丰优3号的选育过程、特征特性、高产栽培及制种技术等。

高产三系杂交中稻荃优9的选育及栽培制种技术

荃优9是长沙碧盈农业科技有限公司与安徽荃银高科种业股份有限公司合作选育的籼型三系杂交中稻迟熟组合,以籼型细胞质雄性不育系荃9311A为母本、R1833为父本配组选育而成,具有产量高、生育期适中、广适性、抗倒伏等特点。2022年通过湖南省农作物品种审定。介绍了荃优9选育的具体过程,以及该品种在区域试验中农艺性状表现,并对其丰产栽培技术和高产制种技术进行了探究,以期为推广应用提供数据支撑。

优质高产早熟杂交水稻新组合广8优1090的选育与应用

【目的】选育优质高产早熟杂交水稻品种,满足贵州省中高海拔地区水稻生产的需要。【方法】安顺市农业科学院、广东省农业科学院水稻研究所及广西兆和种业有限公司联合,选用水稻不育系广8A与恢复系安恢1090组配,经6年12代定向育种,成功育成优质高产早熟籼型三系杂交稻广8优1090。2022年通过贵州省农作物品种审定委员会审定(审定编号:黔审稻20220017)。【结果】广8优1090在贵州省2020—2021年杂交水稻早熟组区域试验中,2年平均产量10118.7 kg/hm^(2),比对照(香早优2017)增产8.21%,2年累计增产点占78.6%;平均生育期158.2 d,较对照晚1.9 d。2021年生产试验平均产量9482.7 kg/hm^(2),比对照(香早优2017)增产9.45%,增产点率100.0%。广8优1090的出糙率79.6%,精米率69.9%,整精米率62.5%,粒长6.8 mm,长宽比3.4,垩白粒率25%,垩白度6.7%,胶稠度82 mm,直链淀粉14.4%,碱消值4.5,透明度1级;食味综合评分80.19分,优于对照(80.0分)。【结论】广8优1090高产稳产、耐冷性强、熟期早、食味好,适合在贵州省中高海拔地区种植。

组合式气象灾害下江汉平原杂交水稻的产量和品质表现

2020年湖北省中稻前期经历连续晴日高温天气,随之又遭遇了长时间低温寡照天气,探讨这种组合式灾害天气条件下产量和品质的变化,是评估水稻产业化生产中气象灾害及其风险控制的重要方法。试验选取现行主推品种荃优华占、全两优鄂丰丝苗、Y两优1号、晶两优华占、兆优6377、Y两优900和隆两优华占共7个品种,采用2期播种,分别经历了高温(C1)和低温寡照(C2),测定了其产量和品质相关指标随播期及其天气条件的变化。结果表明,所有水稻品种在高温和低温寡照条件下产量和品质均受到影响,不同品种所受影响程度不同。产量方面,荃优华占和Y两优1号在C1下产量显著低于C2,Y两优900在C1下产量显著高于C2(P<0.05),其余品种在不同播期间无显著差异;品质方面,与C1相比,C2下绝大部分品种的整精米率、垩白度、垩白粒率等品质指标显著降低;通过对比相关品种在正常天气条件下的产量和品质表现可知,全两优鄂丰丝苗、晶两优华占、兆优6377和隆两优华占对高温和低温寡照均有较好的耐受性;荃优华占、Y两优900对高温、低温寡照均比较敏感。组合式气象灾害依据类型各有其特点,低温寡照灾害的危害有可能超越高温热害的危害。

优质高产杂交水稻新品种赛两优658的选育及推广应用

赛两优658是安徽赛诺种业有限公司用不育系赛15S和恢复系R658配组杂交育成的籼型两系杂交水稻新组合。该品种于2019—2020年期间参加福建科力企业水稻联合体区域试验及生产试验,区试两年平均产量9827.91 kg/hm^(2),较对照品种F优498增产3.73%。生产试验平均产量9963.46 kg/hm^(2),较对照增产4.86%,稻米品质优,2019年和2020年经检测分别达《食用稻品种品质》标准优质2级和优质3级。试验中综合表现优异,并于2021年通过国家审定,编号为国审稻20210086。该文主要介绍了赛两优658的选育过程及杂交水稻新品种推广应用的意义、策略和方法。

两系杂交水稻新组合F两优658选育及高产栽培技术

F两优658是安徽赛诺种业有限公司利用两系不育系F168S与恢复系R658配组并经过多年多点比较试验选育而成的两系杂交水稻新组合。该组合株型紧凑,株高适中,丰产性好,适宜在长江上游地区种植。2022年F两优658通过国家农作物品种审定委员会审定,审定编号为国审稻20220052。本文详细阐述了F两优658的选育过程、高产栽培技术及其种子生产技术,以期为水稻种植户提供参考。

三系杂交稻“华浙优1561”高产制种技术要点

“华浙优1561”是由广西壮族自治区农业科学院水稻研究所联合中国水稻研究所和浙江勿忘农种业股份有限公司共同选育的优质杂交稻品种。“华浙优1561”属于多穗小粒型品种,分蘖力中等、产量高、抗褐飞虱。“华浙优1561”在稻米品质上表现突出:糙米率83.0%、整精米率65.7%、垩白度0.4%、透明度1级、碱消值7.0级、胶稠度72 mm、直链淀粉含量17.5%、粒长7.3 mm、长宽比3.3、垩白粒率3%,达到《食用稻品种品质》(NY/T53-01)优质一等食用长粒形籼稻品种品质规定要求。2020年“华浙优1561”通过广西壮族自治区农作物品种审定委员会审定,在广西北部、中部和南部稻作区可作早、晚稻种植。文章主要介绍了三系杂交水稻“华浙优1561”的高产制种技术要点,通过科学的制种技术和精细的栽培管理提高该品种的制种产量和品质,为水稻生产提供有力支持。

诚优13在宁化县种植表现及优质高产栽培技术

诚优13是杭州众诚农业科技有限公司育成的籼粳杂交稻新品种,2022年通过福建省引种备案。2020—2022年在福建省宁化县试种、示范,表现生育期适中、适应性广、抗逆性强、产量高、米质优等优点。总结了诚优13在宁化县种植表现及高产栽培技术要点。

野香优7008在泉州市种植表现及高产栽培技术

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