Impact of Three Isolates of Cercosporidium personatum (Berk. Et M.A Curt.), a Pathogen of Late Leaf Spot, on Defoliation and Yield in Groundnut (Arachis hypogaea L.) under Controlled Conditions

Late leaf spot caused by Cercosporidium personatum is one of the most widespread groundnut leaf diseases. Along with early leaf spot and rust, it is one of the main fungal diseases hampering groundnut production worldwide. Late leaf spot accounts for significant yield losses throughout the world where groundnuts are grown. This reduction in yield caused by the disease could result in yield losses of between 50% and 70%. In Burkina Faso, the disease is present throughout the country, with incidence varying according to region and season. Could the variability in the incidence of the disease be linked to the nature of the isolates or to the conditions from each agro-ecological zone? In this study, the aim was to assess the capacity of three isolates from three agroclimatic zones of the country to defoliate and reduce groundnut yield. To this end, three isolates of Cercosporidium personatum (Berk. Et M.A Curt.) were collected in these zones and evaluated on three contrasting groundnut varieties. A split-splot design was used for the experiment. Isolates were prepared from samples collected in farmers’ fields. After incubation in the laboratory, leaf spots showing good sporulation were scraped off with a scalpel after immersing the leaves in distilled water. Inoculations were carried out under controlled environment. After inoculation with the isolate, the percentage of defoliation and the reduction in yield of these varieties were then evaluated. Inoculation was carried out from the 30th day after sowing with Cercosporidium personatum spore suspensions at 105 spores/ml. The study showed that the percentage of defoliation (P = 0.0001) and the reduction in yield (P = 0.0001) were significant. The study revealed that, whatever the variety, isolate I3TF from the Upper Basins region in the South Sudanese zone caused the greatest defoliation and the greatest reduction in yield. The variety TS32-1, regardless of the isolate used for the treatment, recorded the best yield. The variety PC79-79, regardless of the isolate used for the treatment, recorded the lowest percentage of defoliation. The highest defoliation recorded under the effect of the isolates was of the order of 72.20%;the highest yield reduction was of the order of 87.20% compared with the water control.

Influence of <i>Pterocarpus erinaceus</i>Poir. on the Growth and Yields of Groundnut (<i>Arachis hypogea</i>L.) in Agroforestry Parks in the Districts of Tenghory and Kataba 1 (Bignona Department, Lower Casamance)

In Lower Casamance, Pterocarpus erinaceus occupies a very important place in agroforestry parks. It is often grown in association with the most important cash crop of the area, groundnut (Arachis hypogea L.). Thus, the objective of this study is to contribute to a better understanding of the interactions between trees and groundnut cultivation in agroforestry parks in Lower Casamance. To this end, in each of the two districts (Tenghory and Kataba 1) three Pterocarpus erinaceus trees were selected in three separate communes. For each P. erinaceus tree selected and following each of the four cardinal directions, three situations were defined: at R/2, at 1.5 R and at 2 R from the trunk, with R the radius of the crown. Thus, 12 yield squares were installed around each selected tree, for a total of 72 yield squares installed in the two districts. The parameters measured were the height of the peanut plants, the number of pods produced per plant, and the yield in flakes and pods. The results show that geographical orientation significantly influenced plant height (p = 0.004) but not the number of pods/plant (p = 0.6). As for the distance to the trunk of Pterocarpus erinaceus, it induced a significant variation in the number of pods/plant (p = 0.009) but did not induce a significant effect on the other parameters. Yields varied between 1.56 Tons M S /ha and 2.02 Tons M S /ha for the hay, and between 1.03 Tons M S /ha and 1.45 Tons M S/ha for the pods. The results of this study constitute a useful source of information for a better management of the productivity of the agroforestry parks of the department of Bignona.

Effect of Gamma Irradiation on Morpho-Agronomic Characteristics of Groundnut (<i>Arachis hypogaea</i>L.)

Induced mutation in plant improvement has been used in several crops to generate new sources of genetic variations. A study was conducted to determine the effect of different doses of gamma irradiation on different morpho-agronomic characteristics. Agronomic traits that were analyzed included: grain yield, number of pods/plant, number of seeds/plant and weight of 100 seeds and numbers of days to 50% flowering. Morphometric characterisation of the descriptive data included plant height, stem diameter, number of leaves/plant, leaflet length, leaflet width and number of ramification/ plant. Groundnut seeds were treated with various doses of gamma rays (100, 200, 400 and 600 Gy). Among the various dose treatments, gamma rays treatment at 100 Gy resulted in a higher increase of grain yield and other morpho-agronomic parameters especially for the JL24 variety. In fact the gamma irradiation at 100 Gy increased significantly grain yield by 14% for JL24, and 4 % for JL12. The number of pods per plant was increased by 2% for JL12 and 37% for JL24. For the number of seeds per plant, there was a significant increase of 8% for JL12, and 62% for JL24 at 100 Gy. A similar trend was observed for the JL24 at 200 Gy dose. Higher doses of gamma rays (400 and 600 Gy) reduced significantly plant growth and grain yield. The usefulness of the mutants identified in a groundnut breeding program is discussed.

盐胁迫下氮素对花生种子萌发和种子际细菌菌群结构的调控

【目的】盐胁迫影响花生种子萌发和植株生长,阐明盐胁迫下适量施肥提高种子萌发率和花生产量的内在调控机制,并解析该过程与种子际土壤细菌菌群结构的关系,为通过改良种子际土壤微生物环境,提高花生出苗健苗率、耐盐抗逆性和花生生产能力提供理论和技术依据。【方法】以耐盐花生品种(花育25号,HY25)为试验材料,设置3个氮素水平0、90和180 kg/hm^(2),采用盆栽试验和高通量测序技术,阐明氮肥施用对盐胁迫下花生种子际微生物菌群结构、花生发芽出苗和产量的影响。【结果】施加氮肥可有效提高花生种子在盐胁迫下的发芽率和最终产量,并以施氮量90 kg/hm^(2)最适。16S rRNA测序分析显示,种子际的土壤细菌以变形菌门(Proteobacteria)、放线菌门(Actinobacteria)、厚壁菌门(Firmicutes)、酸杆菌门(Acidobacteria)、拟杆菌门(Bacteroidetes)、绿弯菌门(Chloroflexi)及芽孢杆菌门(Gemmatimonadetes)等为优势菌门。在属水平上,盐胁迫虽然提高了有益菌属拟杆菌属(Bacteroides)的相对丰度,但同时导致有害的链球菌属(Streptococcus)增多,最终降低了有益菌属芽孢杆菌属(Bacillus)、鞘脂单胞菌属(Sphingomonas)和溶杆菌属(Lysobacter)的相对丰度。盐胁迫下施氮可以显著改善种子际的土壤微环境,提高有益菌属拟杆菌属、芽孢杆菌属、鞘脂单胞菌属的相对丰度,对土壤修复和地力提升有一定的帮助,同时还能增强花生抗逆性。【结论】盐胁迫下适量施氮可提高种子际有益菌属的相对丰度,从而提高花生种子的发芽率和耐盐性,最终促进盐胁迫下的花生增产。

花生分子标记辅助育种研究进展与展望

花生是重要的食用植物油和植物蛋白来源,高产优质抗病是花生新品种选育的主要目标。目前生产上大面积推广的优良品种主要以传统杂交育种技术选育而成,育种周期长、效率低、成本高。分子标记辅助选择可显著提高育种的精准性和效率。高密度的基因型数据是花生产量、品质、抗病性状QTL定位和开发分子标记的基础。2019年我国花生骨干亲本狮头企和伏花生以及美国匍匐型花生品种Tifrunner的基因组序列相继公布,极大推动了花生重要农艺性状的分子标记开发和应用。近年来,花生籽仁油酸含量、脂肪含量等品质性状,根结线虫病、锈病、叶斑病、青枯病等抗病性状,以及荚果、籽仁大小等产量组成性状的分子标记相继被开发。利用分子标记辅助育种,成功选育出了高油酸且高含油量、高油酸且抗病花生新品种或新种质。未来花生分子标记的开发利用需要重视优异野生种质资源的表型精准鉴定,建立高通量表型及基因型检测平台,以及全基因组选择技术策略的应用。

不同播种方式下高油酸花生生长性状及产量的表现

以高油酸花生(Arachis hypogaea L.)品种中花215、中花28和中花34为试验材料,采用小区试验对比的方法研究不同播种方式(单粒播种、双粒播种、单双粒间播)对高油酸花生生长性状及产量的影响。结果表明,不同播种方式对高油酸花生生长性状及产量均产生一定影响,单粒播种更有利于花生单株生长发育,相比其他两种播种方式,能显著提高叶片SPAD值、单株结果数、单株生产力和干果产量;单双粒间播和双粒播种的干果产量无显著差异;3个高油酸品种单粒播种的经济效益最高,单双粒间播次之,双粒播种最低;相同播种方式下,中花215的产量和经济效益最高,中花34次之,中花28最低。

花生产量相关性状与气象因子多环境相关性分析

花生(Arachis hypogea L.)是重要的经济和油料作物,提高花生产量对保障油料安全和农民增收具有积极作用。2013—2016年,本研究利用11个花生品种共77环境的花生产量相关性状数据和气象数据,分析了花生产量相关性状与气象因子的相关性。研究发现,主茎高和侧枝长与平均气温、全生育期光照时数、平均昼夜温差和平均风速极显著相关;分枝数与全生育期≥10℃活动积温和平均昼夜温差极显著相关;单株结果数和单株饱果数与全生育期光照时数和全生育期降水量极显著相关;荚果产量与全生育期≥10℃活动积温、全生育期降水量、平均昼夜温差和平均气温极显著相关。本研究对指导各地规划花生种植期、提高花生产量具有重要指导意义。

壳寡糖对旱薄地花生叶片衰老及产量和品质的影响

在旱薄地条件下,以小花生品种‘花育20号’(HY20)和大花生品种‘花育22号’(HY22)为实验材料,研究叶面喷施不同浓度壳寡糖[0mg·kg-1(T0)、50mg·kg-1(T1)、100mg·kg-1(T2)、200mg·kg-1(T3)]对叶片衰老、荚果产量和籽仁品质的影响。结果表明:(1)壳寡糖处理均显著提高了旱薄地花生饱果期叶片叶绿素含量和保护酶(SOD、POD、CAT)活性,降低了MDA含量,并显著提高了2个品种的单株结果数、饱果率和荚果产量。(2)壳寡糖处理降低了HY20的籽仁蛋白质含量却提高了其脂肪含量,但提高了HY22的籽仁蛋白质和脂肪含量,且T1处理对HY20的油酸/亚油酸(O/L)比值提高幅度较大,而T2处理对HY22的O/L值提高幅度较大。研究认为,在生产实际中用50mg·kg-1壳寡糖叶面喷施品种‘花育20号’(HY20)、用100mg·kg-1壳寡糖叶面喷施品种‘花育22号’(HY22)时,2个品种的籽仁产量、蛋白质和脂肪产量均最高,可达到花生生产的高产优质高效。

施氮量对不同类型花生品种衰老特性和产量的影响

为了探讨花生高产的适宜施氮量,在大田高产条件下,以珍珠豆型花生品种白沙1016和普通型花生品种花育17为材料,研究了施氮量对不同类型花生品种衰老特性和产量的影响。结果表明,两花生品种叶片叶绿素含量和光合速率、SOD和CAT活性均随着施氮量的增加而增加,MDA含量随施氮量的增加而降低,只是白沙1016品种在施氮超过135kg/hm2后上述指标增加或降低不显著,说明增施氮肥可以延缓花生叶片的衰老。在一定施氮量范围内,两花生品种有效荚果数随着施氮量的增加而增加,千克果数随着施氮量的增加而降低,导致荚果产量随着施氮量的增加而增加(珍珠豆型花生品种白沙1016施氮在0-90kg/hm2、普通型花生品种花育17在0-135kg/hm2范围内),但是超过此范围后再增加施氮量反而导致有效荚果数下降、千克果数增多、荚果产量下降。

基于产量的花生基因型耐湿涝性综合评价

在大田条件下,利用塑料膜遮挡雨水,从花生营养生长末期开始分别进行短期湿涝(10d)和长期湿涝(88d)以及正常灌溉处理,以测定18个花生基因型的籽仁产量,再计算相对产量、耐湿涝系数和耐湿涝指数,进而分类评价花生基因型对湿涝反应的差异。结果表明:(1)花生对湿涝的反应,因湿涝长短和基因型而异。短、长期湿涝导致一些基因型减产(2.5%～48.6%),另一些基因型增产(5.5%～56.7%)。其中7个品种均减产,5个均增产,5个只适应长期湿涝,1个只适应短期湿涝。(2)根据长、短期耐湿涝系数差异可将基因型划分为7类;采用聚类分析并结合湿涝产量和耐湿涝系数,则划分为6类。结果认为,以耐湿涝指数作为综合评价指标有失偏颇。(3)已获得多个优异耐性基因型,可用于深入研究目标基因和选育耐湿涝性品种。

施钾对花生积累氮素来源和产量的影响

利用盆栽试验和15N示踪技术,研究了不同施钾量对花生吸收土壤氮、肥料氮、根瘤固氮量及比例和产量的影响。结果表明,不同施钾处理花生氮素均主要积累在籽仁中,但随着施钾量的增大,花生各器官中茎的含氮量增加幅度最大,果壳的含氮量增加幅度最小。适当增施钾肥可以提高各器官含氮量和15N丰度、氮素和15N积累量,促进花生植株对3种氮源的吸收利用,尤其对籽仁生物量(经济产量)的影响最大。吸收土壤氮的比例在38.29%～45.10%之间,吸收肥料氮的比例在12.37%～13.40%之间,吸收大气氮的比例在42.53%～48.31%之间。适量增施钾肥提高了吸收肥料氮和根瘤固氮的比例,降低了吸收土壤氮的比例,提高了肥料氮的利用率,但过量施钾效果降低。

不同生育期花生叶片蛋白质含量及氮代谢相关酶活性分析

以5个珍珠豆型花生(Arachis hypogaea Linn.)品种(系)‘汕E’(‘Shan E’)、‘汕G’(‘Shan G’)、‘TH’、‘TJ’和‘泉花7号’(‘Quanhua No.7’)为研究对象,分析了花针期、结荚期和饱果期花生叶片中可溶性蛋白质含量及硝酸还原酶(NR)、谷氨酰胺合成酶(GS)和谷氨酸脱氢酶(GDH)活性的变化趋势,并比较了5个品种(系)荚果和秆产量的差异。结果表明:在3个生育期内,5个花生品种(系)叶片可溶性蛋白质含量和GDH活性的变化趋势基本一致,而NR和GS活性的变化趋势则有差异。其中,可溶性蛋白质含量均呈"低—高—低"的变化趋势,在结荚期最高;GDH活性均逐渐升高,至饱果期达最高;‘泉花7号’叶片NR活性呈"高—低—高"的变化趋势,而其他4个品种(系)叶片NR活性均逐渐降低;‘汕E’、‘TJ’和‘泉花7号’叶片GS活性呈逐渐降低趋势,而‘汕G’和‘TH’叶片GS活性呈"低—高—低"的变化趋势。总体上看,5个品种(系)中,‘汕G’和‘泉花7号’叶片的可溶性蛋白质含量及NR和GDH活性、‘汕E’叶片的NR和GS活性以及‘TH’叶片的GDH活性均较高。5个品种(系)的2个产量指标(单株荚果鲜质量和单株秆鲜质量)均有明显差异,总体上看,‘汕G’、‘泉花7号’和‘TH’的2个产量指标均较高,而‘汕E’和‘TJ’的2个产量指标均较低。综合分析结果显示:‘汕G’和‘泉花7号’叶片可溶性蛋白质含量及NR和GDH活性均相对较高,其荚果和秆产量也均较高,表明花生荚果和秆产量与不同生育期叶片氮代谢水平有一定关系。

花生钙营养效应及其与磷协同吸收特征

为了挖掘土壤耕作对花生钙素的供应能力,基于三个典型棕壤土大田耕作试验,研究了免耕、浅耕、深耕和深松下花生钙营养效应及其与磷协同吸收特征。结果表明:(1)深耕和浅耕花生荚果及植株地上部(茎、叶、针)的钙吸收量比免耕和深松增加12.8%~41.8%。(2)耕作措施下土壤钙供给与植株钙吸收并非呈直线关系,土壤交换性钙低于临界值2.7g/kg时,植株钙吸收量随着土壤交换性钙增加而显著增加。(3)花生对钙(Ca^(2+))与磷(H_2PO_4^-/HPO_4^(2-))吸收呈显著正相关关系,且荚果钙与磷的协同吸收效应大于植株地上部分。(4)花生钙吸收量每增加10kg/hm^2,荚果产量增加610kg/hm^2,粗蛋白增加108kg/hm^2。总之,通过耕翻20~30cm措施可维持适宜的土壤交换性钙含量,有利于花生对钙磷的协同吸收,促进花生产量、品质的提高。

干旱胁迫对花生生育中后期根系生长特征的影响

花生是较耐旱的经济和油料作物，长期少雨或季节性干旱是限制花生产量提高的重要环境因子，也是花生收获前黄曲霉素感染的重要因素。根系是植物吸水的主要器官，不同土壤水分状况下植物的根系构型可能会表现出显著差异，进而影响植物根系吸收养分和水分的能力。研究不同土壤水分状况下花生根系形态的发育特征与抗旱性的关系对进一步理解花生的水分吸收、运输、利用和散失机制以及培育抗旱性花生具有非常重要的作用。为明确不同抗旱性花生品种的根系形态发育特征，探讨其根系形态发育特征对不同土壤水分状况的响应机制，在防雨棚旱池内进行土柱栽培试验，研究抗旱型花生品种“花育22号”和干旱敏感型花生品种“花育23号”生育中后期根系生长特征及其对干旱胁迫的响应。设置正常供水和中度干旱胁迫（分别控制土壤含水量为田间持水量的80％～85％和45％～50％）2个水分处理，分别在花针期、结荚期和饱果期进行取样，根长、根表面积和体积扫描后通过WinRhizoProVision5．0a程序进行分析；收获时测定产量和抗旱系数（干旱胁迫处理与正常供水处理下产量之比）。结果表明，“花育22号”具：行较高的产量和抗旱系数，“花育23号”对干旱胁迫的适应性小于“花育22号”。抗旱型品种“花育22号”具有较大的根系生物量、总根长和根系表面积，且深层土壤内根系表面积和体积大于“花育23号”。与正常供水处理相比，干旱胁迫显著降低2个品种花针期的根系总根长、根系总表面积和总体积，对结荚期和饱果期根系性状无显著影响；干旱胁迫增加2个品种生育中后期40cm以下土层内的根长密度分布比例、根系表面积和体积，怛“花育23号”各根系性状增加幅度小于“花育22号”。干旱胁迫处理下20～40cm和40cm以下土层内根系表面积和体积分别与总根长、总表面积和总体积呈显著或极显著正相关，而正常供水处理下0～20cm土层内根暴表面积和体积与整体根系性状表现极显著正相关。总体而言，具有较大根系和深层土壤内较多的根系分布是抗旱型花生的主要根系分布特征：土壤水分亏缺条件下，花生主要通过增加深层土壤内根长、根系表面积和体积等形态特性调节植株对水分的利用。

种衣剂拌种和地膜覆盖对花生成苗与产量的影响

种衣剂拌种和出苗期盖膜均能明显提高花生成苗率、百果重和荚果产量等,二者具有一定的正向互作效应。在酸性红壤条件下,出苗期盖膜与全生育期盖膜处理比较,单株饱果数、百果重、百仁重等性状值均较高,花生增产15.8%。

施磷对花生根系生长发育和产量的影响

采用盆栽方式,研究了施磷对花生根系生长发育和产量的影响。结果表明,花生出苗45d后根系干物重、根系活力、根瘤数和根瘤鲜重逐渐增大,在出苗后85d(饱果初期)达到最大值,以后逐渐降低。增施磷肥有利于提高花生根系干物重、根系活力、根瘤数和根瘤鲜重,最终提高了荚果产量、生物产量和经济系数。

花生结荚期施用油菜素内酯对同化物调配及荚果产量的效应

本文研究了在花生结荚期,用油菜素内酯处理果针,结果表明:油菜素内酯能调配茎枝叶中的同化物向荚果中运输和积累,使结荚率和饱果率升高,从而能提高花生经济产量。

长期连作对不同花生品种生长发育、产量与品质的影响

花生是中国重要的油料作物和经济作物,连作障碍已成为花生产业发展面临的突出问题。为解析长期连作对不同花生品种生长发育、产量及内在品质的影响,笔者对7个不同花生品种在3年连作地块和10年连作地块的生长发育、产量与产量构成及品质相关指标进行测定分析。结果表明花生出苗率与出苗时间不受连作年限长短影响,且品种间差异不大,但其他形态性状指标、产量与产量构成以及品质指标均受连作年限影响,且不同品种对连作年限的敏感度表现各异。综合生长发育与产量及产量构成各项指标,‘花育19号’、‘花育20号’、‘花育34号’对长期连作最为敏感,‘花育30号’和‘花育33号’敏感度居中;‘花育26号’和‘花育50号’属于对长期连作的耐受品种。花生内在品质同样受连作年限影响,但品种间对连作年限的反应有所差异。

暗黑齿爪鳃金龟虫口密度与花生产量损失的关系

暗黑齿爪鳃金龟幼虫危害花生的空间格局,为以个体群为基本成分的聚集格局。其幼虫虫口密度与花生总果荚数呈不显著负相关,与果荚被害率和为害指数均呈极显著正相关,为花生产量呈极显著负相关。由此组建了花生产量损失率的预测模式和花生生长期卵、幼虫防治指标模型。

不同耕种模式对红壤旱坡地花生产量及降水利用的影响

通过定位监测方法,研究红壤旱坡地3种不同耕种模式对花生产量及降水利用的影响。结果表明:横沟+稻草覆盖的花生产量及降水利用效果最好,其中花生产量达到3 993.2 kg/hm2,降水有效利用率达74.69%,水分表观生物利用率和表观经济利用率分别为0.645 2和0.311 9 kg/m3,水分实际生物利用率和实际经济利用率分别为0.860 7和0.410 7 kg/m3;横沟+植物篱的效果次之;传统的顺坡耕种方式最差,不仅不利于花生产量的增加,而且还会加剧水土流失。因此,在生产中应尽量推广横沟+稻草覆盖的农作方式,以保证农业生产的可持续发展。