The Dynamic Change of Soil Microorganism and Enzyme Activity in the Whole Procreative Process of the Tarim Island Cotton

对塔里木海岛棉生育全程土壤微生物与酶活性的动态变化进行了检测,测试结果表明：（1）塔河种业高产海岛棉田土壤养分比塔河滩地高出6.58%~37.42%,特别是全钾、速效钾比塔河滩地高出29.02%~37.42%。（2）微生物数量变化呈现如下变化趋势：细菌类群在夏季有生长高峰,秋季略有回升;真菌在春季存在生长高峰,夏季处于低谷,秋季生物活性开始回升;放线菌生长高峰位于夏季,春秋季处于低谷。在土壤微生物区系构成中,细菌占据绝对优势,暗示土壤养分的转化主要靠细菌完成。（3）塔河种业高产海岛棉田土壤酶中的过氧化氢酶、     

金龟子绿僵菌CQMa421对棉蚜、绿盲蝽的田间防效

棉花是我国重要的经济作物, 虫害严重制约了棉花生产, 造成棉农的经济损失。目前, 化学杀虫剂仍是防治棉花虫害的主要手段, 长期使用化学杀虫剂导致棉蚜Aphis gossypii、绿盲蝽Apolygus lucorum产生抗药性, 降低防治效果。本研究使用80亿孢子/mL金龟子绿僵菌CQMa421可分散油悬浮剂防治棉蚜、绿盲蝽, 室内生测结果表明, 金龟子绿僵菌CQMa421能有效侵染棉蚜和绿盲蝽, 随着浓度的升高, 对棉蚜和绿盲蝽的毒力增强。〖JP+2〗田间试验结果表明, 该药剂能有效控制棉花主要害虫棉蚜和绿盲蝽。采用1 200 mL/hm2用量, 药后14 d对棉蚜的防效达94.42%; 采用1 350 mL/hm2用量, 药后14 d对绿盲蝽的防效分别达到87.25%(新疆), 91.62%(湖北)。     

新疆南疆机采棉品种株型结构与产量性状的相关性

【目的】分析不同类型陆地棉品种的株型结构及产量性状,研究高产优质机采棉品种的株型结构与产量结构的特点,为棉花结构育种提供理论参考。【方法】测试不同机采棉品种的株型结构性状及产量结构相关指标,利用差异显著性分析、相关分析等统计方法,研究几种机采棉品种的株型性状、产量结构性状及其相关性特点。【结果】籽棉产量与株高、主茎节间长、果枝数、果节数存在正相关但不显著,与果枝始节高度呈负相关;株高与果枝始节高存在显著正相关,与主茎节间长度呈极显著相关; 17N11株型为塔型结构,其底部主茎叶片保留完整、籽棉产量、株高最高,而17N13主茎叶片数最多,17N5则具有最小的叶片脱落率;在棉花株型结构的共性方面,棉花果枝角度具有由上至下呈增大趋势,而变异能力则呈现与之相反的趋势(上部＞中部＞下部)。棉花主茎叶大小具有由上部至下部减小的趋势,变异能力亦呈现与之相反的趋势(下部＞中部＞上部)。【结论】株型结构具备中、上部果枝夹角较小(上部＜32.0°,中部＜50.0°),主茎叶总面积高于320 cm²,下部主茎叶片脱落率低于20%的机采棉品种产量优势显著,中上部果枝夹角、主茎叶总面积、下部主茎叶片脱落率可作为株型育种后代材料选择依据。     

有机肥替代化肥对棉花生长发育和产量的影响

【目的】研究不同有机肥替代化肥对棉花生长发育和产量的影响。【方法】以陇棉3号为试材,采用田间随机区组排列试验,研究有机肥与化肥不同配施比例对棉花生育期、营养器官和生殖器官干重、叶面积指数、花铃期光合速率、产量及其构成的影响。【结果】不同有机肥替代化肥延长了棉花生育期2～6 d,且用生物有机肥替代40%化肥的情况延长生育期的时间最长。各处理的叶面积指数从苗期到花铃期上升,花铃期升至最大,随后在吐絮期下降。在花铃期和吐絮期,6个处理中T5处理的叶面积指数最大。施用有机肥对棉花花铃期的光合速率无显著影响。普通有机肥和生物有机肥替代化肥能够获得与常规施肥相应的产量。而生物有机肥替代40%化肥显著增加了绒长、籽棉产量和皮棉产量。【结论】棉花生产过程中可以用生物有机肥来替代化肥,达到减用化肥、增产增效的效果。     

棉蚜茧蜂对不同品种、不同生育期棉花的趋性行为反应

【目的】研究棉蚜茧蜂对不同品种、不同生育期棉花的趋性行为反应,为了解天敌昆虫与寄主之间关系,利用棉蚜茧蜂对棉蚜等害虫进行防控。【方法】以生产上大面积种植的GK-12(对照为泗棉3号)、新棉33B(亲本为新棉33)和SGK321(亲本为石远321)等3组棉花品种为材料,于棉花7叶期、现蕾前期和现蕾期,设计无虫棉植株、被棉蚜为害后剔除虫体的植株以及棉蚜+有虫株等3种不同处理,借助“Y”型嗅觉仪,检测棉蚜茧蜂在棉花不同生育期对这3种不同处理的趋性。【结果】棉蚜茧蜂无法识别健康的常规棉和转基因棉花植株;对不含棉蚜的被害棉来说,转基因棉对棉蚜茧蜂更具吸引力。而对含有棉蚜的有害棉来说,除7叶期GK12、新棉33B和现蕾期GK12这3组处理外,其他各组的转基因棉对棉蚜茧蜂均具较强的吸引作用。【结论】两类不同的棉花品种对棉蚜茧蜂不存在排斥性,棉蚜为害转基因棉花后更能吸引棉蚜茧蜂。     

棉种介电分选的试验研究

介电分选是一种新型的种子分选方法,具有结构简单、适应性强、分选效果好和可按种子活力进行分级的特点.电导率是反映种子活力的一个重要指标,分选电压是影响介电分选效果的一个重要因素,为了探讨电导率与分选电压之间的关系,介绍了棉种介电分选的原理,并在不同的分选电压条件下对棉种电导率进行了测定,同一条件下重复测定5次,所得数据用DPS统计软件进行分析处理.结果表明,分选电压对棉种电导率有影响,且回归效果显著.     

化学打顶对阿拉尔垦区主栽品种光合冠层的影响

化学打顶是指利用植物生长调节剂来打破作物顶端优势,进而保障作物的正常生长和生产。本文为探究化学打顶对作物的影响,利用摇钱素和棉花打顶剂处理新陆中70和新陆中82不同品种,同时测定不同化学打顶剂处理条件下,棉花的净光合速率、气孔导度、蒸腾速率、胞间CO₂浓度及棉花冠层叶面积指数指标。研究发现：不同化学打顶处理条件下,与人工打顶相比化学打顶的棉花的五种指标变化均不明显,但新陆中70和新陆中82品种的净光合速率平均值与对照相比分别高出3 μmol/(m2.s)和2 μmol/(m2.s),且冠层叶面积指数值比人工打顶的略高。试验结果表明化学打顶处理后没有造成棉花疯长,提高了光能利用率,进而增加作物群体的光合作用。     

光子陆地棉种质资源主要性状的遗传评价

以102份光子陆地棉材料为母本,分别与遗传标准系TM-1杂交,获得102个F₁群体。采用随机区组设计,设置3个重复,对光子陆地棉材料主要性状进行遗传评价。结果表明,调查的11个性状表型差异均较大,材料间产量性状(株高、果枝数、铃数、铃重、衣分和子指)差异大于纤维品质性状(纤维长度、纤维强度、马克隆值、整齐度和伸长率),特别是衣分、铃数等性状差异更明显; 除果枝数、马克隆值、伸长率以外,光子亲本群体其他性状的平均值都小于F₁群体。而亲本群体所有性状的变异系数均大于F₁,不同光子材料的杂种优势有很大差别,中亲优势和超亲优势也有很大的差别,有些种质某些性状的中亲、超亲优势为负值,其后代性状表现劣势; 纤维品质性状的中亲、超亲优势与毛子程度均呈负相关,而产量性状的中亲、超亲优势与毛子程度均呈正相关,说明可利用光子材料杂种优势改良纤维品质,而其后代产量性状的杂种优势利用受到限制; SSR分子标记遗传相似系数与各个性状的中亲、超亲优势的相关都不显著,说明在光子材料的育种中,杂种优势是不能通过亲本之间的遗传背景相似程度来预测的。     

Cotton Chemical Topping by Applying DPC in Different Cotton-Growing Regions

[Objective] The objective of this study was to investigate the stability and universality of cotton chemical topping by applying mepiquat chloride (1,1-dimethyl-piperidinium chloride, DPC) in different cotton-growing regions. [Method] Field experiments were conducted in 2018 at 10 locations in the Yellow River basin (Hejian and Handan, Hebei province; Dezhou and Wudi, Shandong province), the Yangtze River basin (Dafeng, Jiangsu province; Huanggang, Hubei province), and Xinjiang area (Shihezi location I and loacation II, northern Xinjiang and Luntai and Shaya, southern Xinjiang). Local cultivars/lines were used, and the experiments were performed using a randomized complete block design with three or four replicates. Accompanied with typical DPC multi-application in each location, chemical topping was conducted at 10 days before manual topping (T1) or at the same time with manual topping (T2) by applying four dosages of DPC (0, 90, 180, 270 g·hm^－2), manual topping was used as the first control and non-topping as the second control. [Result] The time of chemical topping significantly affected cotton plant height (except for the results in Handan, Dezhou and Wudi) and the number of fruit branches (except for the results in Dafeng and Huanggang). It was observed that earlier chemical topping would result in lower cotton plant height and a fewer fruit branches. In Hejian and Shihezi location I, the average plant height across DPC chemical topping at T1 stage was not only lower than that of T2 stage but also 3.3 cm and 4.6 cm lower than that of manual topping, respectively. In most locations, chemical topping at T1 stage increased around two fruit branches per plant compared with manual topping, while in T2 stage the increased fruit branches per plant ranged from 2.3 to 7.7. Also, we found that a higher dosage of DPC resulted in shorter plant height (except for that in Huanggang). In some locations, plant heights of chemical topping with 180 g·hm^－2 or 270 g·hm^－2 DPC were even shorter than that of manual topping. The number of fruit branches per plant of 0 g·hm^－2 DPC increased by 2.4-8.3 compared with manual topping. However, chemical topping with 90-270 g·hm^－2 DPC significantly reduced the number of fruit branches compared with 0 g·hm^－2 DPC. There were no significant differences in the number of fruit branches among three DPC dosages (90, 180, and 270 g·hm^－2). In Handan, seed cotton yield of chemical topping at T2 stage was significantly lower than that of manual topping due to the decreased boll number, which is possibly associated with the high temperature and drought weather after chemical topping. While at other locations, most treatments of chemical topping by using DPC did not produce significant effects on yield. In addition, chemical topping by using DPC did not delay cotton maturity, characterized by their similar boll-opening rate and the first harvest rate to those of manual topping before spraying harvest aids. [Conclusion] Cotton chemical topping with DPC is more stable and universal across different cotton-growing regions. We suggest that 90-180 g·hm^－2 DPC could be used at the same time with manual topping for cotton chemical topping.     

陆地棉转录因子GhNAC78基因的特征及功能分析

本实验室从陆地棉中克隆得到GhNAC78,分析了其基因特征及功能。该基因cDNA全长为937 bp,开放阅读框为876bp,编码291个氨基酸,隶属于NAM转录因子亚家族。体外转录激活实验表明,GhNAC78具有转录激活活性。上游启动子区1537 bp序列的生物信息学分析可知其包含多种激素、胁迫和光响应元件,表明GhNAC78广泛地参与植物生长发育和胁迫响应的调控。荧光定量结果显示,GhNAC78在棉花叶片衰老过程中高调表达,推测其参与叶片衰老的调控。