Xinjiang Agricultural Sciences ›› 2023, Vol. 60 ›› Issue (9): 2081-2090.DOI: 10.6048/j.issn.1001-4330.2023.09.001
• Crop Genetics and Breeding·Germplasm Resources·Molecular Genetics·Soil Fertilizer • Previous Articles Next Articles
WANG Peng(), ZHENG Kai, ZHAO Jieyin, GAO Wenju, LONG Yilei, CHEN Quanjia, QU Yanying()
Received:
2023-01-18
Online:
2023-09-20
Published:
2023-09-19
Correspondence author:
QU Yanying(1962-), female, Urumqi XinJiang, Doctorate student supervisor, Research Direction: Cotton Breeding Genetic,(E-mail)Supported by:
王朋(), 郑凯, 赵杰银, 高文举, 龙遗磊, 陈全家, 曲延英()
通讯作者:
曲延英(1962-),女,新疆乌鲁木齐人,教授,博士,硕士生/博士生导师,研究方向为作物遗传育种,(E-mail)作者简介:
王朋(1994-),男,新疆乌鲁木齐人,硕士研究生,研究方向为作物遗传育种,(E-mail)1120964149@qq.com
基金资助:
CLC Number:
WANG Peng, ZHENG Kai, ZHAO Jieyin, GAO Wenju, LONG Yilei, CHEN Quanjia, QU Yanying. Evaluation and index screening of heat resistance of Gossypium hirsutum germplasm resources[J]. Xinjiang Agricultural Sciences, 2023, 60(9): 2081-2090.
王朋, 郑凯, 赵杰银, 高文举, 龙遗磊, 陈全家, 曲延英. 陆地棉种质资源材料的耐热性评价及指标筛选[J]. 新疆农业科学, 2023, 60(9): 2081-2090.
Add to citation manager EndNote|Ris|BibTeX
URL: http://www.xjnykx.com/EN/10.6048/j.issn.1001-4330.2023.09.001
编号 Number | 中国棉花 品种(系) Chinese cotton varieties(series) | 编号 Number | 巴基斯坦 棉花品种(系) Pakistan cotton varieties(series) |
---|---|---|---|
1 | 鲁棉10-221 | 11 | DEBAL |
2 | 新陆早42号 | 12 | JR NIBGE-8 |
3 | 新陆早26号 | 13 | CIM-343 |
4 | 中棉49号 | 14 | Cyto-515 |
5 | 辽5856 | 15 | MNH1026 |
6 | 中棉所35号 | 16 | AA933 |
7 | 新陆中24号 | 17 | Tipo |
8 | 晋棉10号 | 18 | Cyto-179 |
9 | 新陆早49号 | 19 | MNH1016 |
10 | Z112 | 20 | GHAURi-1 |
21 | Cyto-608 | ||
22 | CIM-616 | ||
23 | BAHAR-2017 | ||
24 | CIM-602 |
Tab.1 Names of varieties (lines) from different Gossypium hirsutum
编号 Number | 中国棉花 品种(系) Chinese cotton varieties(series) | 编号 Number | 巴基斯坦 棉花品种(系) Pakistan cotton varieties(series) |
---|---|---|---|
1 | 鲁棉10-221 | 11 | DEBAL |
2 | 新陆早42号 | 12 | JR NIBGE-8 |
3 | 新陆早26号 | 13 | CIM-343 |
4 | 中棉49号 | 14 | Cyto-515 |
5 | 辽5856 | 15 | MNH1026 |
6 | 中棉所35号 | 16 | AA933 |
7 | 新陆中24号 | 17 | Tipo |
8 | 晋棉10号 | 18 | Cyto-179 |
9 | 新陆早49号 | 19 | MNH1016 |
10 | Z112 | 20 | GHAURi-1 |
21 | Cyto-608 | ||
22 | CIM-616 | ||
23 | BAHAR-2017 | ||
24 | CIM-602 |
年份地点 Year and location | 性状 Trait | 平均值 Mean | 标准偏差 Standard deviation | 最小值 Minimum | 最大值 Maximum | 偏度 Skewness | 峰度 Kutosis | 变异系数 Coefficient of variation |
---|---|---|---|---|---|---|---|---|
2018年中国 新疆沙湾 Shawan 2018 | 株高 | 72.82 | 11.45 | 49.67 | 91.33 | -0.10 | -1.09 | 15.72 |
籽棉产量 | 105.40 | 9.38 | 83.65 | 122.47 | -0.10 | -0.20 | 8.90 | |
单铃重 | 5.27 | 0.45 | 4.33 | 6.13 | -0.19 | -0.36 | 8.54 | |
皮棉产量 | 42.94 | 6.27 | 30.80 | 55.56 | -0.03 | -0.57 | 14.60 | |
衣分 | 40.66 | 4.05 | 32.02 | 50.33 | 0.39 | 0.53 | 9.96 | |
2018年巴基斯坦 费萨拉巴德 Pakistan 2018 | 株高 | 68.57 | 14.57 | 45.90 | 115.23 | 1.21 | 2.02 | 21.25 |
籽棉产量 | 38.17 | 7.67 | 25.23 | 56.27 | 0.14 | -0.47 | 20.09 | |
单铃重 | 2.01 | 0.38 | 1.36 | 2.98 | 0.18 | 0.03 | 18.91 | |
皮棉产量 | 16.27 | 4.08 | 10.00 | 25.10 | 0.31 | -0.73 | 25.08 | |
衣分 | 42.85 | 7.86 | 29.15 | 59.15 | 0.43 | -0.35 | 18.34 | |
2020年中国 新疆沙湾 Shawan 2020 | 株高 | 73.14 | 11.74 | 49.67 | 90.67 | -0.14 | -1.11 | 16.05 |
籽棉产量 | 100.21 | 7.85 | 82.80 | 114.90 | 0.03 | -0.45 | 7.78 | |
单铃重 | 5.35 | 0.51 | 4.42 | 5.89 | 0.15 | -1.18 | 10.10 | |
皮棉产量 | 41.90 | 5.59 | 33.30 | 56.55 | 0.40 | -0.59 | 16.49 | |
衣分 | 43.50 | 3.99 | 36.45 | 53.20 | 0.33 | -0.31 | 11.91 |
Tab.2 Descriptive statistical analysis of agronomic traits of 24 Gossypium hirsutum varieties(%)
年份地点 Year and location | 性状 Trait | 平均值 Mean | 标准偏差 Standard deviation | 最小值 Minimum | 最大值 Maximum | 偏度 Skewness | 峰度 Kutosis | 变异系数 Coefficient of variation |
---|---|---|---|---|---|---|---|---|
2018年中国 新疆沙湾 Shawan 2018 | 株高 | 72.82 | 11.45 | 49.67 | 91.33 | -0.10 | -1.09 | 15.72 |
籽棉产量 | 105.40 | 9.38 | 83.65 | 122.47 | -0.10 | -0.20 | 8.90 | |
单铃重 | 5.27 | 0.45 | 4.33 | 6.13 | -0.19 | -0.36 | 8.54 | |
皮棉产量 | 42.94 | 6.27 | 30.80 | 55.56 | -0.03 | -0.57 | 14.60 | |
衣分 | 40.66 | 4.05 | 32.02 | 50.33 | 0.39 | 0.53 | 9.96 | |
2018年巴基斯坦 费萨拉巴德 Pakistan 2018 | 株高 | 68.57 | 14.57 | 45.90 | 115.23 | 1.21 | 2.02 | 21.25 |
籽棉产量 | 38.17 | 7.67 | 25.23 | 56.27 | 0.14 | -0.47 | 20.09 | |
单铃重 | 2.01 | 0.38 | 1.36 | 2.98 | 0.18 | 0.03 | 18.91 | |
皮棉产量 | 16.27 | 4.08 | 10.00 | 25.10 | 0.31 | -0.73 | 25.08 | |
衣分 | 42.85 | 7.86 | 29.15 | 59.15 | 0.43 | -0.35 | 18.34 | |
2020年中国 新疆沙湾 Shawan 2020 | 株高 | 73.14 | 11.74 | 49.67 | 90.67 | -0.14 | -1.11 | 16.05 |
籽棉产量 | 100.21 | 7.85 | 82.80 | 114.90 | 0.03 | -0.45 | 7.78 | |
单铃重 | 5.35 | 0.51 | 4.42 | 5.89 | 0.15 | -1.18 | 10.10 | |
皮棉产量 | 41.90 | 5.59 | 33.30 | 56.55 | 0.40 | -0.59 | 16.49 | |
衣分 | 43.50 | 3.99 | 36.45 | 53.20 | 0.33 | -0.31 | 11.91 |
材料 Material | 株高 Plant height(%) | 籽棉产量 Seed cotton yield(%) | 单铃重 Single bell weight(%) | 皮棉产量 Lint cotton yield(%) | 衣分 Lint percentage(%) | 排名 Ranking |
---|---|---|---|---|---|---|
Cyto-179 | 6.85 | -53.67 | -53.67 | -30.09 | 51.27 | 1 |
BAHAR-2017 | -35.95 | -59.95 | -59.95 | -37.87 | 55.12 | 2 |
鲁棉10-221 Lumian 10-221 | -8.50 | -53.32 | -53.32 | -52.78 | 1.15 | 3 |
JRNIBGE-8 | 46.29 | -53.69 | -53.69 | -58.56 | -10.43 | 4 |
MNH1026 | -30.29 | -58.36 | -58.36 | -55.32 | 7.26 | 5 |
Cyto-608 | -37.32 | -60.79 | -60.79 | -53.99 | 17.38 | 6 |
晋棉10号 Jimian 10 | 6.51 | -60.39 | -60.39 | -57.28 | 7.85 | 7 |
CIM-343 | -28.51 | -59.46 | -59.46 | -60.43 | -2.35 | 8 |
Cyto-515 | 1.24 | -58.53 | -58.53 | -63.09 | -10.97 | 9 |
辽5856 Liao5856 | 7.20 | -64.50 | -64.50 | -54.09 | 29.30 | 10 |
新陆早42号 Xinluzao 42 | 23.01 | -61.03 | -61.03 | -59.85 | 3.18 | 11 |
CIM-602 | -20.28 | -58.98 | -58.98 | -67.59 | -20.85 | 12 |
DEBAL | -4.89 | -64.45 | -64.45 | -60.36 | 11.54 | 13 |
AA933 | -16.10 | -59.67 | -59.67 | -69.72 | -24.83 | 14 |
新陆早26号 Xinluzao 26 | 43.22 | -65.30 | -65.30 | -64.99 | 0.90 | 15 |
Z112 | 16.37 | -65.13 | -65.13 | -65.83 | -2.00 | 16 |
MNH1016 | 32.45 | -66.83 | -66.83 | -65.22 | 4.99 | 17 |
Tipo | -3.20 | -67.93 | -67.93 | -64.38 | 11.08 | 18 |
CIM-616 | -40.66 | -65.51 | -65.51 | -74.23 | -25.29 | 19 |
新陆早49号 Xinluzao 49 | -12.71 | -71.03 | -71.03 | -72.91 | -6.53 | 20 |
GHAURi-1 | -15.19 | -73.51 | -73.51 | -70.74 | 10.34 | 21 |
新陆中24号 Xinluzhong 24 | 9.33 | -75.48 | -75.48 | -70.40 | 20.54 | 22 |
中棉所35号 Zhongmiansuo 35 | -2.82 | -75.21 | -75.21 | -71.80 | 14.15 | 23 |
中棉49号 Zhongmian 49 | -23.15 | -76.01 | -76.01 | -76.20 | -0.83 | 24 |
Tab.3 Average percentage change of 24 Gossypium hirsutum resource materials in 2018 and 2020
材料 Material | 株高 Plant height(%) | 籽棉产量 Seed cotton yield(%) | 单铃重 Single bell weight(%) | 皮棉产量 Lint cotton yield(%) | 衣分 Lint percentage(%) | 排名 Ranking |
---|---|---|---|---|---|---|
Cyto-179 | 6.85 | -53.67 | -53.67 | -30.09 | 51.27 | 1 |
BAHAR-2017 | -35.95 | -59.95 | -59.95 | -37.87 | 55.12 | 2 |
鲁棉10-221 Lumian 10-221 | -8.50 | -53.32 | -53.32 | -52.78 | 1.15 | 3 |
JRNIBGE-8 | 46.29 | -53.69 | -53.69 | -58.56 | -10.43 | 4 |
MNH1026 | -30.29 | -58.36 | -58.36 | -55.32 | 7.26 | 5 |
Cyto-608 | -37.32 | -60.79 | -60.79 | -53.99 | 17.38 | 6 |
晋棉10号 Jimian 10 | 6.51 | -60.39 | -60.39 | -57.28 | 7.85 | 7 |
CIM-343 | -28.51 | -59.46 | -59.46 | -60.43 | -2.35 | 8 |
Cyto-515 | 1.24 | -58.53 | -58.53 | -63.09 | -10.97 | 9 |
辽5856 Liao5856 | 7.20 | -64.50 | -64.50 | -54.09 | 29.30 | 10 |
新陆早42号 Xinluzao 42 | 23.01 | -61.03 | -61.03 | -59.85 | 3.18 | 11 |
CIM-602 | -20.28 | -58.98 | -58.98 | -67.59 | -20.85 | 12 |
DEBAL | -4.89 | -64.45 | -64.45 | -60.36 | 11.54 | 13 |
AA933 | -16.10 | -59.67 | -59.67 | -69.72 | -24.83 | 14 |
新陆早26号 Xinluzao 26 | 43.22 | -65.30 | -65.30 | -64.99 | 0.90 | 15 |
Z112 | 16.37 | -65.13 | -65.13 | -65.83 | -2.00 | 16 |
MNH1016 | 32.45 | -66.83 | -66.83 | -65.22 | 4.99 | 17 |
Tipo | -3.20 | -67.93 | -67.93 | -64.38 | 11.08 | 18 |
CIM-616 | -40.66 | -65.51 | -65.51 | -74.23 | -25.29 | 19 |
新陆早49号 Xinluzao 49 | -12.71 | -71.03 | -71.03 | -72.91 | -6.53 | 20 |
GHAURi-1 | -15.19 | -73.51 | -73.51 | -70.74 | 10.34 | 21 |
新陆中24号 Xinluzhong 24 | 9.33 | -75.48 | -75.48 | -70.40 | 20.54 | 22 |
中棉所35号 Zhongmiansuo 35 | -2.82 | -75.21 | -75.21 | -71.80 | 14.15 | 23 |
中棉49号 Zhongmian 49 | -23.15 | -76.01 | -76.01 | -76.20 | -0.83 | 24 |
Fig.5 Changes of physiological indexes of Gossypium.hirsutum heat-resistant extreme material under 40℃ stress Note:* and ** refer to the different significance at P<0.05 and P<0.01 levels
[1] | Saleem M A, Malik W, Qayyum A, et al. Impact of heat stress responsive factors on growth and physiology of cotton (Gossypium hirsutum L.)[J]. Molecular Biology Reports, 2021, 48(11). |
[2] |
Chen Y, Wang H, Hu W, et al. Combined elevated temperature and soil waterlogging stresses inhibit cell elongation by altering osmolyte composition of the developing cotton (Gossypium hirsutum L.) fiber[J]. Plant Science, 2017, 256:196-207.
DOI URL |
[3] |
Chen Y, Chen B, Wang H, et al. Combined elevated temperature and soil waterlogging stresses limit fibre biomass accumulation and fibre quality formation by disrupting protein activity during cotton fibre development[J]. Functional Plant Biology, 2019, 46(8):715-724.
DOI PMID |
[4] |
Cottee N S, Tan D K Y, Bange M P, et al. Multi-level determination of heat tolerance in cotton (Gossypium hirsutum L.) under field conditions[J]. Crop Science, 2010, 50(6):2553-2564.
DOI URL |
[5] |
Song G, Wang M, Zeng B, et al. Anther response to high-temperature stress during development and pollen thermotolerance heterosis as revealed by pollen tube growth and in vitro pollen vigor analysis in Gossypium hirsutum[J]. Planta, 2015, 241(5):1271-1285.
DOI URL |
[6] |
Min L, Li Y, Hu Q, et al. Sugar and auxin signaling pathways respond to high-temperature stress during anther development as revealed by transcript profiling analysis in cotton[J]. Plant Physiology, 2014, 164(3):1293-1308.
DOI PMID |
[7] |
Pettigrew W T. The effect of higher temperatures on cotton lint yield production and fiber quality[J]. Crop Science, 2008, 48(1):278-285.
DOI URL |
[8] |
马益赞, 闵玲, 张献龙. 棉花响应高温机理及耐高温种质资源研究[J]. 植物遗传资源学报, 2022, 23(1):29-39.
DOI |
MA Yizan, MIN Ling, ZHANG Xianlong. Progress and Prospect of Researches in Mechanism of High Temperature Stress Response and Development of High Temperature Tolerant Germplasms of Cotton[J]. Journal of Plant Genetic Resources, 2022, 23(1):29-39.
DOI |
|
[9] | Rishi P., Singh P V., Vara Prasad K, et al. Influence of High Temperature and Breeding for Heat Tolerance in Cotton: A Review[J]. Advances in Agronomy, 2007, 93:313-385. |
[10] | 何小艳, 朱红芳, 李晓锋, 等. 高温和淹水胁迫对不结球白菜生长发育的影响[J]. 上海农业学报, 2021, 37(2):38-45. |
HE Xiaoyan, ZHU Hongfang, LI Xiaofeng, et al. Effects of high temperature and waterlogging stress on the growth and development of non-heading Chinese cabbage[J]. Shanghai Journal of Agriculture, 2021, 37(2):38-45. | |
[11] | 范蓉, 郭亚萍, 赵柯柯, 等. 旱、盐胁迫下棉花3个转录因子基因的表达与生理指标相关性分析[J]. 生物学杂志, 2021, 38(4):86-91. |
FAN Rong, GUO Yaping, ZHAO Keke, et al. Correlation analysis between the expression of three transcription factor genes and physiological indicators in cotton under drought and salt stress[J]. Journal of Biology, 2021, 38(4):86-91. | |
[12] | 杨敏文. 快速测定植物叶片叶绿素含量方法的探讨[J]. 光谱实验室, 2002,(4):478-481. |
YANG Minwen. Discussion on the rapid determination method of plant leaf chlorophyll content[J]. Spectroscopy Laboratory, 2002,(4):478-481. | |
[13] | 李春红, 姚兴东, 鞠宝韬, 等. 不同基因型大豆耐荫性分析及其鉴定指标的筛选[J]. 中国农业科学, 2014, 47(15):2927-2939. |
LI Chunhong, YAO Xingdong, JU Baotao, et al. Analysis of Different Genotypes of Soybean Shade Tolerance and Screening of Identification Indexes[J]. Scientia Agricultura Sinica, 2014, 47(15):2927-2939. | |
[14] | 姜梦辉, 孙丰磊, 杨阳, 等. 棉花陆海重组自交系群体花铃期抗旱性鉴定及评价[J]. 干旱区研究, 2020, 37(6):1635-1643. |
JIANG Menghui, SUN Fenglei, YANG Yang, et al. Identification and Evaluation of Drought Resistance of Cotton Land-sea Recombinant Inbred Lines at Flowering and Boll Stage[J]. Arid Zone Research, 2020, 37(6):1635-1643. | |
[15] | 胡启瑞, 宋桂成, 王雪姣, 等. 高温对陆地棉花粉萌发及棉铃发育的影响[J]. 新疆农业大学学报, 2017, 40(1):1-7. |
HU Qirui, SONG Guicheng, WANG Xuejiao, et al. The effect of high temperature on the germination of Gossypium hirsutum flour and the development of cotton bolls[J]. Journal of Xinjiang Agricultural University, 2017, 40(1):1-7. | |
[16] | 孔令双. 马铃薯种质资源的耐热性分析及鉴定[D]. 杨凌: 西北农林科技大学, 2021. |
KONG Lingshuan. Analysis and Identification of Heat Tolerance of Potato Germplasm Resources[D]. Yangling: Northwest A&F University, 2021. | |
[17] | 周永海. 甜瓜种质资源耐热性评价及外源物质对热胁迫的缓解效应[D]. 杨凌: 西北农林科技大学, 2021. |
ZHOU Yonghai. Evaluation of heat tolerance of melon germplasm resources and mitigation effects of exogenous substances on heat stress[D]. Yangling: Northwest A&F University, 2021. | |
[18] |
李敏, 苏慧, 李阳阳, 等. 黄淮海麦区小麦耐热性分析及其鉴定指标的筛选[J]. 中国农业科学, 2021, 54(16):3381-3393.
DOI |
LI Min, SU Hui, LI Yangyang, et al. Analysis of Heat Tolerance of Wheat in Huanghuaihai Wheat Region and Screening of Identification Indexes[J]. Scientia Agricultura Sinica, 2021, 54(16):3381-3393.
DOI |
|
[19] | Hu Q, Wang W, Lu Q, et al. Abnormal anther development leads to lower spikelet fertility in rice (Oryza sativa L.) under high temperature during the panicle initiation stage[J]. BMC Plant Biology, 2021, 21(1). |
[20] | 杨杰, 韩登旭, 阿布来提·阿布拉, 等. 新疆自然高温环境下玉米自交系开花期耐热性鉴定与评价[J]. 西北植物学报, 2021, 41(8):1380-1390. |
YANG Jie, HAN Dengxu, Abulaiti Abula, et al. Identification and Evaluation of Heat Tolerance of Maize Inbred Lines in Flowering Period under Natural High Temperature Environment in Xinjiang[J]. Acta Botanica Sinica, 2021, 41(8):1380-1390. | |
[21] | 徐如强, 孙其信, 张树榛. 春小麦耐热性的筛选方法与指标[J]. 华北农学报, 1997, 12(3): 22-29. |
XU Ruqiang, SUN Qixin, ZHANG Shuzhen. Screening methods and indices of heat tolerance in spring wheat[J]. Acta Agriculturae Boreali-Sinica, 1997, 12(3): 22-29. | |
[22] | 陈希勇, 孙其信, 孙长征. 春小麦耐热性表现及其评价[J]. 中国农业大学学报, 2000, 5(1): 43-49. |
CHEN Xiyong, SUN Qixin, SUN Changzheng. Performance and evaluation of spring wheat heat tolerance[J]. Journal of China Agricultural University, 2000, 5(1): 43-49. | |
[23] | 耿晓丽, 张月伶, 臧新山, 等. 北方冬麦区与黄淮北片优良小麦品种 (系)耐热性评价[J]. 麦类作物学报, 2017, 36(2): 172-181. |
GENG Xiaoli, ZHANG Yueling, ZANG Xinshan, et al. Evaluation the thermotolerance of the wheat (Triticum aestivum L.) cultivars and advanced lines collected from the northern china and north area of Huanghuai Winter Wheat regions[J]. Journal of Triticeae Crops, 2017, 36(2): 172-181. | |
[24] | 吾甫尔·阿不都, 巴哈古丽·先木西, 彭华, 等. 棉花种质资源耐热性鉴定及高温胁迫对光合特性的影响[J]. 中国棉花, 2015, 42(2):32-34. |
Wupuer Abudu, Bahaguli Xianmuxi, PENG Hua, et al. Identification of heat tolerance of cotton germplasm resources and the effect of high temperature stress on photosynthetic characteristics[J]. China Cotton, 2015, 42(2):32-34. | |
[25] |
任茂, 张文英. 棉花品种耐热性分析及鉴定指标筛选[J]. 核农学报, 2018, 32(4):788-794.
DOI |
REN Mao, ZHANG Wenying. Analysis of Heat Tolerance of Cotton Varieties and Screening of Identification Indexes[J]. Journal of Nuclear Agriculture, 2018, 32(4):788-794. | |
[26] |
刘少卿, 孙君灵, 何守朴, 等. 不同棉花种质资源耐热性苗期鉴定[J]. 核农学报, 2013, 27(7):1029-1040.
DOI |
LIU Shaoqing, SUN Junling, HE Shoupu, et al. Identification of heat tolerance of different cotton germplasm resources at seedling stage[J]. Journal of Nuclear Agriculture, 2013, 27(7):1029-1040. | |
[27] | 赵冰雪, 张永春, 周琳, 等. 月季高温胁迫研究进展[J]. 北方园艺, 2021,(10):124-131. |
ZHAO Bingxue, ZHANG Yongchun, ZHOU Lin, et al. Research progress of rose high temperature stress[J]. Northern Horticulture, 2021,(10):124-131. | |
[28] | 凌瑞, 戴中武, 代晓雨, 等. 8个绣球品种耐热性综合评价与耐热指标筛选[J]. 热带作物学报, 2021, 42(8):2209-2218. |
LING Rui, DAI Zhongwu, DAI Xiaoyu, et al. Comprehensive evaluation of heat resistance and selection of heat resistance indexes of 8 hydrangea varieties[J]. Chinese Journal of Tropical Crops, 2021, 42(8):2209-2218. |
[1] | Wang Tianling, Hou Xianfei, Shi Junjie, Sun Quanxi, Jia Donghai, Gu Yuanguo, Shan Shihua, Miao Haocui, Li Qiang. Genetic diversity analysis of 67 creeping peanut germplasm resources [J]. Xinjiang Agricultural Sciences, 2024, 61(1): 42-54. |
[2] | BAI Shijian, HU Jinge, LI Shuai, XUE Feng, ZHANG Wen, PAN Xubing, WEI Dengpan, ZHAO Ronghua, CAI Junshe. Effects of two cultivation modes on the cluster region micro-environment,berry development and quality of marselan grape in turpan-hami basin [J]. Xinjiang Agricultural Sciences, 2024, 61(1): 79-91. |
[3] | OUYANG Danhua, ZHAO Kang, SONG Dongbo, LIU Ziqing, GUO Wangzhen, LIU Yan, GU Aixing, Azhatiguli Maimaitituer, Alikaerjiang Amaier. Identification and comprehensive analysis of Verticillium wilt resistance in 35 cotton strains [J]. Xinjiang Agricultural Sciences, 2024, 61(1): 9-18. |
[4] | MA Qingshan, DU Xiao, TAO Zhixin, HAN Wanli, LONG Yilei, AI Xiantao, HU Shoulin. Identification and analysis of machine-picked agronomic characters of Gossypium hirsutum resource materials [J]. Xinjiang Agricultural Sciences, 2023, 60(8): 1830-1839. |
[5] | ZHAO Lianjia, LI Gan, XU Lin, YAN Guorong, LIU Ning, WANG Fan, DENG Chaohong, Abudukeyoumu Abudurezike, WANG Cong, WANG Wei. Analysis of the main characters of soybean varieties in Xinjiang and their correlation with yield [J]. Xinjiang Agricultural Sciences, 2023, 60(7): 1663-1670. |
[6] | GENG Feifei, MENG Chaomin, QING Guixia, ZHOU Jiamin, ZHANG Fuhou, LIU Fengju. Cloning and expression analysis of phosphorus efficient gene GhMYB4 in Gossypium hirsutum L. [J]. Xinjiang Agricultural Sciences, 2023, 60(6): 1406-1412. |
[7] | HUANG Qiannan, Maerheba Aisibaier, ZOU Hui, WANG Cairong, Ailimaimaiti Kuerban, SUN Na, LEI Junjie. Genetic diversity of main agronomic traits in Xinjiang winter wheat germplasm resources [J]. Xinjiang Agricultural Sciences, 2023, 60(5): 1050-1058. |
[8] | SANG Zhiwei, LIANG Yajun, GONG Zhaolong, ZHENG Juyun, WANG Junduo, LI Xueyuan, CHEN Quanjia. Analysis of mechanical harvesting characters of germplasm resources of different upland cotton [J]. Xinjiang Agricultural Sciences, 2023, 60(5): 1088-1098. |
[9] | LU Tao, ZENG Qingtao, ZHANG Wen, WANG Wenbo, WANG Zhengyang, YANG Rui, SUN Yuyan. Comprehensive evaluation of cotton yield and quality by principal component analysis and grey correlation analysis [J]. Xinjiang Agricultural Sciences, 2023, 60(5): 1099-1109. |
[10] | LI Shuo, WANG Juan, Nigary Yadikar, ZHU Jinfang, FENG Zuoshan, Parhat Ainiwaer. Functional components changes of different apricot cultivars in different development stages [J]. Xinjiang Agricultural Sciences, 2023, 60(5): 1200-1207. |
[11] | DU Hongyan, PANG Shengqun, MA Haixiang, JI Xuehua. Correlation and path analysis of agronomic traits of processing tomato early maturity mutants [J]. Xinjiang Agricultural Sciences, 2023, 60(4): 943-950. |
[12] | YANG ZHi, DONG Mengyi, WANG Zhenlei, YAN Fenfen, WU Cuiyun, WANG Jiurui, LIU Mengjun, LIN Minjuan. TPA Method was Used to Analyze the Texture and Split of F1 Fruit of Jujube Hybrid [J]. Xinjiang Agricultural Sciences, 2023, 60(3): 608-615. |
[13] | MA Xu, ZHAO Ying, HAN Wei, WU Shengli, HAN Xiaoyan. Principal Component Analysis and Cluster Analysis of Amino Acids in Seabuckthorn Fruit [J]. Xinjiang Agricultural Sciences, 2023, 60(2): 378-388. |
[14] | HOU Zhixiong, JING Changqing, CHEN Chen, WANG Gongxin, GUO Wenzhang, ZHAO Weikang. Spatiotemporal Variation of Vegetation Coverage of Natural Grassland in Northern Xinjiang in Recent 20 Years and Its Relationship with Meteorological Factors [J]. Xinjiang Agricultural Sciences, 2023, 60(2): 464-471. |
[15] | WEN Jia, HUANG Chenjue, JI Zihan, LI Libei, FENG Zhen, YU Shuxun. Association analysis of dynamic plant height trait using SSR marker in Gossypium hirsutum L. [J]. Xinjiang Agricultural Sciences, 2023, 60(12): 2892-2901. |
Viewed | ||||||
Full text |
|
|||||
Abstract |
|
|||||