夏玉米产量时空变化及气候年型分析

定量分析夏玉米同一品种产量及产量构成要素时空变化,探讨造成产量时空差异的气候年型组合变化特征。基于2004～2013年夏玉米种植区郑单958多点田间试验数据分析表明,夏玉米区域平均产量为9 055 kg/hm~2,年际差为1 635 kg/hm~2,变幅为18.1%;地点差4 258 kg/hm~2,变幅为47.1%。夏玉米区域平均千粒重为313 g,年际变幅为13.1%;地点变幅为27.8%。夏玉米区域平均穗粒数为479,年际变幅为18.0%,地点变幅为38.7%。千粒重的增加导致夏玉米产量显著增加。穗粒数显著降低和时空差异大是造成产量波动和时空差异变幅大的主要原因。夏玉米产量和产量构成要素,低产点受各气候要素变化的影响显著;平产点受温度和日最高温度大于33℃的天数影响显著;高产点受降水影响显著。     

吉林省西部地区滴灌条件下宜机械粒收玉米品种筛选

确定宜机械粒收的玉米品种是构建吉林省西部旱作补灌区玉米丰产增效技术模式的重要内容之一。2018年和2019年在吉林省西部地区开展滴灌条件下宜机械粒收玉米品种的筛选试验,测定38个玉米品种的收获子粒含水率和产量,并按玉米子粒含水率和产量水平采用双向平均法作图进行品种分类。结果表明,本研究初步筛选出5个滴灌条件下宜机械粒收玉米品种,分别是迪卡159、福莱77,稷秾108、吉农大889和优迪919。根据品种综合性状分析,吉农大889较优,其次为迪卡159,可以作为适宜吉林省西部滴灌条件下丰产高效栽培的推荐品种。     

玉米脱粒破碎率关键影响因子及其最优预测模型研究

子粒破碎率高是当前中国玉米机械收获子粒的重要限制因素,解析破碎率变化原因,建立其简便预测模型是需要解决的重要问题。本文采集7个玉米品种在3个种植密度下组合的果穗,在不同子粒含水率梯度条件下开展单穗脱粒试验。种植密度在6万～9万株/hm2范围内对子粒破碎率没有影响,品种、子粒的含水率、抗侧压碎力和穿刺强度等的影响均达到统计显著水平。品种对破碎率变化的偏贡献率为12.7%,且品种的偏贡献率子粒含水率的偏贡献率抗侧压碎力的偏贡献率穿刺强度的偏贡献率,种植密度的偏贡献率接近于零。破碎率的最优预测因子是穿刺强度,预测模型:破碎率=10.25×0.990穿刺强度,满足破碎率不高于5%约束的穿刺强度值不得低于60 MPa。研究结果可为玉米破碎率预测、宜机收玉米新品种培育与鉴定、脱粒机具设计与制造提供数据支撑和技术参考。     

秸秆还田对东北半干旱区玉米‖花生轮作系统土壤水热特性及作物产量的影响

以东北半干旱区玉米‖花生轮作系统为研究对象,试验设传统玉米单作、花生单作、不同秸秆还田量下(30%、60%和100%)玉米‖花生轮作5个处理。通过连续3年田间定位试验,研究玉米秸秆不同还田量对农田土壤水热特性、产量及土地当量比(LER)的影响。结果表明,与传统单作相比,秸秆还田处理玉米区播前0～40 cm土壤平均含水量提高了1.9%～3.9%,花生区提高了11.0%～13.9%;成熟期,秸秆还田花生区0:00～8:00平均地温比传统单作提高了0.2℃～1.1℃,10:00～22:00平均地温较传统单作降低了0.5℃～1.0℃。2016年和2017年玉米‖花生轮作系统LER为1.05～1.16,2018年各处理LER均小于1。吉林半干旱区玉米‖花生轮作系统进行秸秆还田改善了作物播前的土壤水分状况,但对于作物产量的影响在不同年份有所差异。     

水分和盐胁迫下小麦种子萌发相关性状的QTL定位

小麦萌发期对水分和盐胁迫敏感,对该时期水分和盐胁迫下种子萌发性状进行QTL定位具有重要的意义。本研究以小麦“泰农18×临麦6号” RIL群体为材料,以20%PEG-6000溶液和100 mmol·L^-1 NaCl溶液分别模拟水分和盐胁迫环境,对种子萌发期10个性状进行了QTL定位。结果表明,在正常、水分胁迫和盐胁迫3种不同处理下各性状变异较大。相关分析表明,抗旱和耐盐可能是两个独立遗传的性状,胚芽鞘长可以作为节水抗旱的鉴定指标。3种处理下共检测到10个萌发相关性状的103个QTL,其中,17个为相对高频QTL（RHF-QTL）,分布在7条染色体（1A、3A、3B、4B、7A、7B和7D）上,平均贡献率为7.55%~15.97%。这些RHF-QTL形成4个QTL簇（QTL cluster,QC）,分布在3A、7A和7D染色体上。其中,7A染色体上的QC2包括3个RHF-QTLs（ QSdw-7A.1、 QGf-7A.1和 QGi-7A.1）,均与小麦耐盐性相关;7D染色体上的QC3包括2个RHF-QTLs（ QGi-7D.1、 QGdrc-7D.1）,均与小麦节水抗旱性相关。这2个QCs增加效应均来自母本泰农18。本研究获得的RHF-QTLs和QCs,可为小麦萌发期节水抗旱和耐盐分子标记辅助选择提供理论和技术支持。     

生物有机肥部分替代化肥对日光温室黄瓜产量、品质及肥料利用率的影响

采用随机区组试验,设5个处理:不施肥(CK)、当地常规施肥(100CF)、100%常规施肥+生物有机肥(100CF+SF)、90%常规施肥+生物有机肥(90CF+SF)、80%常规施肥+生物有机肥(80CF+SF),研究生物有机肥部分替代化肥对黄瓜产量及产出投入比、品质、养分分配及肥料利用率的影响。结果表明,从植株不同部位对氮磷钾的分配率来看,茎叶分配率最高,果实次之,根最少。与单施化肥的常规施肥处理相比,减少普通化肥20%的施用量同时配施400 kg · (667 m~2)~(-1)生物有机肥效果较好,可增加单瓜质量和黄瓜产量,降低黄瓜果实硝酸盐含量,提高可溶性糖、可溶性蛋白的含量,改善产品品质,提高氮、磷、钾肥利用率。     

不同种植方式对大跨度外覆盖大棚番茄群体微环境及植株生长与产量和品质的影响

以番茄品种罗拉为试材,设置5个处理,分别为:CK,定植密度33 300株·hm~(-2),留6穗果;T1,49 500株·hm~(-2),留4穗果;T2,66 000株·hm~(-2),留3穗果;T3,49 500株·hm~(-2),单株留2穗果与留6穗果相间;T4,66 000株·hm~(~(-2)),单株留2穗果与留4穗果相间,研究不同种植密度和留果方式对外保温覆盖大棚内番茄植株生长、产量、品质、群体微环境的影响。结果表明:T2和T1处理生育期平均温度、温度适宜度较高;T1和T3处理摘心前的叶片SPAD值显著高于对照;T1、T2处理的前期产量和总产量均显著高于对照;VC、可滴定酸、可溶性糖、番茄红素等果实品质以T1处理最优。综合产量、品质以及大棚内的温湿度和光照适宜度,T1处理种植风险较小,是外保温覆盖大棚中较为合适的种植方式。     

Diversity,plant growth-promoting traits,and biocontrol potential of fungal endophytes of Sorghum bicolor

The diversity of fungal endophytes in Sorghum bicolor was investigated in samples collected from 10 different geographical regions of Karnataka state, India. A total of 360 endophytes were isolated from leaf, stem, and root tissues and were assigned to 26 fungal species based on morphology and molecular characterization using ITS sequences. All the endophytes belonged to the phylum Ascomycota. The diversity (Shannon H, 2.57; Simpson_1-D, 0.92) and species richness (Margalef's, 4.68; Menhinick, 3.61) were found to be higher for the endophytes isolated from leaf tissues. The species evenness of the endophytic assemblage was strongly influenced by tissue type, followed by geographical location. The biocontrol potential of isolated endophytes was evaluated against economically destructive sorghum grain mould pathogens such as Fusarium thapsinum, Epicoccum sorghinum, Alternaria alternata, and Curvularia lunata using the dual culture method. Biocontrol potential was exhibited by 26 endophytic isolates, of which Trichoderma asperellum recorded broad-spectrum activity against target pathogens, followed by E. nigrum and A. longipes. Most (82%) endophytes showed plant growth-promoting traits. Biosynthesis of indole-3-acetic acid (IAA) was observed in 84% of isolates, and phosphate solubilization, siderophore production, and cellulase activity was observed in 69%, 23%, and 27% of isolates, respectively. Seeds treated with T. asperellum exhibited a significantly higher seed vigour index (2096), germination percentage (94%), and yield under greenhouse and field conditions. The results were substantiated by the confocal microscopy analysis, which clearly demonstrated the colonization of treated endophyte in root tissues. The present study reveals an ecofriendly approach to explore T. asperellum in sorghum disease management.     

Quantitative trait loci mapping for yield-related traits under low and high planting densities in maize (Zea mays)

Average maize yield per hectare has increased significantly because of the improvement in high-density tolerance, but little attention has been paid to the genetic mechanism of grain yield response to high planting density. Here, we used a population of 301 recombinant inbred lines (RILs) derived from the cross YE478 × 08–641 to detect quantitative trait loci (QTLs) for 16 yield-related traits under two planting densities (57,000 and 114,000 plants per ha) across four environments. These yield-related traits responded differently to high-density stress. A total of 110 QTLs were observed for these traits: 33 QTLs only under low planting density, 50 QTLs under high planting density and 27 QTLs across both densities. Only two major QTLs, qCD6 and qWKEL2-2, were identified across low- and high-density treatments. Seven environmentally stable QTLs were also observed containing qED6, qWKEL3, qRN3-3, qRN7-2, qRN9-2 and qRN10 across both densities, as well as qRN9-1 under low density. In addition, 16 and eight pairs of loci with epistasis interaction (EPI) were detected under low and high planting densities, respectively. Additionally, nine and 17 loci showed QTL × environment interaction (QEI) under low- and high-density conditions, respectively. These interactions are of lesser importance than the main QTL effects. We also observed 26 pleiotropic QTL clusters, and the hotspot region 3.08 concentrated nine QTLs, suggesting its great importance for maize yield. These findings suggested that multiple minor QTLs, loci with EPI and QEI, pleiotropy and the complex network of “crosstalk” among them for yield-related traits were greatly influenced by plant density, which increases our understanding of the genetic mechanism of yield-related traits for high-density tolerance.     

边界线分析法评价小麦/西瓜/玉米间作体系产量的限制因子

本研究旨在分析小麦/西瓜/玉米间作体系限制作物产量的关键因子,为该体系的优化提供科学依据。采用农户调研的方式,对河北省曲周县的小麦/西瓜/玉米间作模式展开调查,主要调研内容是小麦和玉米的播种量、养分投入量和产量以及西瓜的养分投入量和产量,应用边界线分析方法评价小麦/西瓜/玉米间作高产体系的限制因子。结果表明,限制小麦产量的关键因子为小麦播种量,贡献率达17.8%,而养分投入量的贡献率分别为:P₂O₅ 12.5%、K₂O 11.7%、N 8.0%。限制西瓜产量的关键因子为钾肥投入量,贡献率达15.8%,N、P₂O₅的贡献率分别为14.2%和11.8%。限制玉米产量的关键因子为氮肥投入量,贡献率达20.6%,其他因子的贡献率分别为:K₂O 14.2%,P₂O₅ 11.5%,播种密度9.2%。因此,在小麦/西瓜/玉米间作体系中,应适当调控小麦播量,优化西瓜的钾肥和玉米的氮肥投入量,促进该间作模式的产量优势。