Late-maturity type of Yongyou japonica/indica hybrids series (LMYS) have shown great yield potential, and are being widely planted in the lower reaches of Yangtze River, China. Knowledge about suitable growing zone ...Late-maturity type of Yongyou japonica/indica hybrids series (LMYS) have shown great yield potential, and are being widely planted in the lower reaches of Yangtze River, China. Knowledge about suitable growing zone and evaluation of yield advantage is of practicall importance for LMYS in this region. Fifteen LMYS, two high-yielding inbred japonica check varieties (CK-J) and two high-yielding hybrid indica check varieties (CK-I) were grown at Xinghua (119.57°E, 33.05°N) of Lixiahe region, Yangzhou (119.25°E, 32.30°N)of Yanjiang region, Changshu (120.46°E, 31.41°N)of Taihu Lake region, and Ningbo (121.31°E, 29.45°N) of Ningshao Plain in 2013 and 2014. The results showed that maturity dates of the 15 were later than the secure maturity date at Xinghua and 6, 14 and 15 LMYS were mature before the secure maturity date at Yangzhou, Changshu and Ningbo, respectively. One variety was identified as high-yielding variety among LMYS (HYYS) at Yangzhou, 8 HYYS in 201:3 and 9 HYYS in 2014 at Changshu, 9 HYYS at Ningbo. HYYS here referred to the variety among LMYS that was mature before the secure maturity date and had at least 8% higher grain yield than both CK-J and CK-I at each experimental site. Grain yield of HYYS at each experimental site was about 12.0 t ha-1 or higher, and was significantly higher than CK varieties. High yield of HYYS was mainly attributed to larger sink size due to more spikelets per panicle. Plant height of HYYS was about 140 cm, and was significantly higher than check varieties. Significant positive correlations were recorded between duration from heading to maturity stage and grain yield, and also between whole growth periods and grain yield. HYYS had obvious advantage over check varieties in biomass accumulation and leaf area duration from heading to maturity stage. Comprehensive consideration about safe matudty and yield performance of LMYS at each experimental site, Taihu Lake region (representative site Changshu) and Ningshao Plain (representative site Ningbo) were thought suitable growing zones for LMYS in the lower reaches of Yangtze River. The main factors underlying high yield ofHYYS were larger sink size, higher plant height, longer duration from heading to maturity stage and whole growth periods, and higher biomass accumulation and leaf area duration during grain filling stage.展开更多
Thirty isolates of Magnaporthe grisea collected from 18 provinces/cities representing 21 pathotypes and 9 different lineages were inoculated to rice varieties with known resistance genes and some hybrid rices, convent...Thirty isolates of Magnaporthe grisea collected from 18 provinces/cities representing 21 pathotypes and 9 different lineages were inoculated to rice varieties with known resistance genes and some hybrid rices, conventional early indica and late japonica varieties cultivated recently in China. Virulence spectrum of the 30 isolates was very different, showing that they recognize numerous different resistance genes. Varieties also revealed very different resistance patterns showing that they carry different resistance genes or combinations of resistance genes. On the basis of comparisons with international differential varieties with known resistance genes, resistance genes in certain Chinese varieties could be speculated. The results indicated that some of them were resistant to most of the isolates tested and that they could be of interest as resistance sources for hybrid parents or to be planted in the field directly.展开更多
Chuanxiang No.2058 is a new combination of three-line late indica hybrid rice bred based on sterile line Chuanxiang 29A and restorer Qiannanhui No.2058. In order to promote its application, seed production techniques ...Chuanxiang No.2058 is a new combination of three-line late indica hybrid rice bred based on sterile line Chuanxiang 29A and restorer Qiannanhui No.2058. In order to promote its application, seed production techniques of Chuanxiang No.2058 were explored during 2009-2010. The research detailed the seed production tech- niques from selection of seed production bases, rational arrangement of sowing gap stage, seedling cultivation in different stages, scientific arrangement of male/female parents, management of fertilizer and water, adjustment of florescence, artificial pol- lination, comprehensive treatment of disease and pest damages, and timely control- ling of abnormal and poorly-qualified rice.展开更多
本研究旨在明确传统双季晚籼稻地区双季杂交晚粳稻超高产产量构成及其群体特征,阐明双季杂交晚粳稻超高产形成规律。以江西省上高县6.77 hm2连片双季杂交晚粳稻高产攻关示范方为依托,选用杂交粳稻甬优8号为材料,对中产(8.25~9.75 t hm...本研究旨在明确传统双季晚籼稻地区双季杂交晚粳稻超高产产量构成及其群体特征,阐明双季杂交晚粳稻超高产形成规律。以江西省上高县6.77 hm2连片双季杂交晚粳稻高产攻关示范方为依托,选用杂交粳稻甬优8号为材料,对中产(8.25~9.75 t hm–2)、高产(9.75~10.50 t hm–2)和超高产(>10.50 t hm–2)3个产量水平群体的产量构成及群体特征进行系统比较研究。结果表明,与中产、高产水平群体相比,超高产水平群体表现穗数足、穗型大、群体颖花量多(50 000×104 hm-2以上)的显著特点,但结实率和千粒重略低,差异不显著;群体茎蘖动态上,群体起点较高,可及时够苗;够苗后增长平缓,高峰苗数量较少、下降平缓,成穗率高(78.0%左右)。群体叶面积指数前期增长较缓,最大值出现在孕穗期,为8.0左右,此后下降缓慢,成熟期仍保持3.5以上;群体光合势生育前期较小,中、后期较大,抽穗至成熟期光合势为300×104 m2 d hm-2以上,总光合势为560×104 m2 d hm-2以上。拔节前干物质量积累速度较慢,拔节后积累速度较快,至抽穗期群体干物质量为10.5 t hm-2左右,抽穗后积累量亦高,成熟期干物质量达19.0 t hm-2左右,后期茎鞘物质转运率大于14.0%。超高产群体根量多、活力较强;植株吸氮能力强、成熟期氮素累积量高,氮素利用率40%以上。根据双季杂交晚粳稻超高产形成特征,我们探讨了培育双季晚粳稻超高产群体的关键栽培技术。展开更多
基金financed by the Special Program of Super Rice of Ministry of Agriculture, China (02318802013231)the National Public Services Sectors (Agricultural) Research Projects, China (201303102)+1 种基金the Major Scientific and Technological Projects, Bureau of Science and Technology of Ningbo, China (2013C11001)the Innovative Training Program of Yangzhou University, China (KYLX15_1371)
文摘Late-maturity type of Yongyou japonica/indica hybrids series (LMYS) have shown great yield potential, and are being widely planted in the lower reaches of Yangtze River, China. Knowledge about suitable growing zone and evaluation of yield advantage is of practicall importance for LMYS in this region. Fifteen LMYS, two high-yielding inbred japonica check varieties (CK-J) and two high-yielding hybrid indica check varieties (CK-I) were grown at Xinghua (119.57°E, 33.05°N) of Lixiahe region, Yangzhou (119.25°E, 32.30°N)of Yanjiang region, Changshu (120.46°E, 31.41°N)of Taihu Lake region, and Ningbo (121.31°E, 29.45°N) of Ningshao Plain in 2013 and 2014. The results showed that maturity dates of the 15 were later than the secure maturity date at Xinghua and 6, 14 and 15 LMYS were mature before the secure maturity date at Yangzhou, Changshu and Ningbo, respectively. One variety was identified as high-yielding variety among LMYS (HYYS) at Yangzhou, 8 HYYS in 201:3 and 9 HYYS in 2014 at Changshu, 9 HYYS at Ningbo. HYYS here referred to the variety among LMYS that was mature before the secure maturity date and had at least 8% higher grain yield than both CK-J and CK-I at each experimental site. Grain yield of HYYS at each experimental site was about 12.0 t ha-1 or higher, and was significantly higher than CK varieties. High yield of HYYS was mainly attributed to larger sink size due to more spikelets per panicle. Plant height of HYYS was about 140 cm, and was significantly higher than check varieties. Significant positive correlations were recorded between duration from heading to maturity stage and grain yield, and also between whole growth periods and grain yield. HYYS had obvious advantage over check varieties in biomass accumulation and leaf area duration from heading to maturity stage. Comprehensive consideration about safe matudty and yield performance of LMYS at each experimental site, Taihu Lake region (representative site Changshu) and Ningshao Plain (representative site Ningbo) were thought suitable growing zones for LMYS in the lower reaches of Yangtze River. The main factors underlying high yield ofHYYS were larger sink size, higher plant height, longer duration from heading to maturity stage and whole growth periods, and higher biomass accumulation and leaf area duration during grain filling stage.
文摘Thirty isolates of Magnaporthe grisea collected from 18 provinces/cities representing 21 pathotypes and 9 different lineages were inoculated to rice varieties with known resistance genes and some hybrid rices, conventional early indica and late japonica varieties cultivated recently in China. Virulence spectrum of the 30 isolates was very different, showing that they recognize numerous different resistance genes. Varieties also revealed very different resistance patterns showing that they carry different resistance genes or combinations of resistance genes. On the basis of comparisons with international differential varieties with known resistance genes, resistance genes in certain Chinese varieties could be speculated. The results indicated that some of them were resistant to most of the isolates tested and that they could be of interest as resistance sources for hybrid parents or to be planted in the field directly.
基金Supported by Guizhou Modern Agricultural(rice)Industry System(GZCYTX2014-06002)~~
文摘Chuanxiang No.2058 is a new combination of three-line late indica hybrid rice bred based on sterile line Chuanxiang 29A and restorer Qiannanhui No.2058. In order to promote its application, seed production techniques of Chuanxiang No.2058 were explored during 2009-2010. The research detailed the seed production tech- niques from selection of seed production bases, rational arrangement of sowing gap stage, seedling cultivation in different stages, scientific arrangement of male/female parents, management of fertilizer and water, adjustment of florescence, artificial pol- lination, comprehensive treatment of disease and pest damages, and timely control- ling of abnormal and poorly-qualified rice.
文摘本研究旨在明确传统双季晚籼稻地区双季杂交晚粳稻超高产产量构成及其群体特征,阐明双季杂交晚粳稻超高产形成规律。以江西省上高县6.77 hm2连片双季杂交晚粳稻高产攻关示范方为依托,选用杂交粳稻甬优8号为材料,对中产(8.25~9.75 t hm–2)、高产(9.75~10.50 t hm–2)和超高产(>10.50 t hm–2)3个产量水平群体的产量构成及群体特征进行系统比较研究。结果表明,与中产、高产水平群体相比,超高产水平群体表现穗数足、穗型大、群体颖花量多(50 000×104 hm-2以上)的显著特点,但结实率和千粒重略低,差异不显著;群体茎蘖动态上,群体起点较高,可及时够苗;够苗后增长平缓,高峰苗数量较少、下降平缓,成穗率高(78.0%左右)。群体叶面积指数前期增长较缓,最大值出现在孕穗期,为8.0左右,此后下降缓慢,成熟期仍保持3.5以上;群体光合势生育前期较小,中、后期较大,抽穗至成熟期光合势为300×104 m2 d hm-2以上,总光合势为560×104 m2 d hm-2以上。拔节前干物质量积累速度较慢,拔节后积累速度较快,至抽穗期群体干物质量为10.5 t hm-2左右,抽穗后积累量亦高,成熟期干物质量达19.0 t hm-2左右,后期茎鞘物质转运率大于14.0%。超高产群体根量多、活力较强;植株吸氮能力强、成熟期氮素累积量高,氮素利用率40%以上。根据双季杂交晚粳稻超高产形成特征,我们探讨了培育双季晚粳稻超高产群体的关键栽培技术。