Pyramiding the disease resistant genes to southern rust and stalk rot in maize(Zea mays L.) with marker-assisted selection

Southern corn rust(SCR) caused by Puccinia polysora Underw and maize stalk rot caused by Pythium inflatum Matthews(MSR-2) are two destructive diseases of maize(Zea mays L.) in China.Our previous studies indicated that maize inbred line Qi319 is highly resistant to SCR but susceptible to MSR-2,while inbred line 1145 is highly resistant to MSR-2 but susceptible to SCR.The SCR resistant gene(RppQ) in Qi319 and MSR-2 resistant gene(Rpi1) in 1145 have been mapped on chromosome 10 and 4 respectively.In this research,through marker-assisted selection(MAS) with the molecular markers,bnlg1937 tightly linked to Rpi1 and phi041 tightly linked to RppQ,pyramid breeding of the two kinds of disease resistant genes were carried out from the year of 2003 to 2007.Two homozygotic inbred lines of F5 generation,DR94-1-1-1 and DR36-1-1-1 were identified.MAS result suggested DR94-1-1-1 and DR36-1-1-1 contained the two resistance genes RppQ and Rpi1.Field inoculation tests confirmed their high resistance to the two diseases.In addition,field investigation indicated that the two selected inbred lines,particularly DR94-1-1-1,had excellent agronomic traits such as plant height,ear height and yield-relating traits including ear length,ear diameter,ear weight,kernels per ear,kernels per row and kernel weight per ear.The two selected inbred lines DR94-1-1-1 and DR36-1-1-1 can either be directly developed into commercial variety or used as immediate donors of SCR and MSR resistance breeding programs in maize.

Fine Mapping of RppP25, a Southern Rust Resistance Gene in Maize

Southern rust （Puccinia polysora Underw.） is a major disease that can cause severe yield losses in maize （Zea mays L.）. In our previous study, a major gene RppP25 that confers resistance to southern rust was identified in inbred line P25. Here, we report the fine mapping and candidate gene analysis of RppP25 from the near-isogenic line F939, which harbors RppP25 in the genetic background of the susceptible inbred line F349. The inheritance of resistance to southern rust was investigated in the BC1F1 and BC3F1 populations, which were derived from a cross between F939 and F349 （as the recurrent parent）. The 1：1 segregation ratio of resistance to susceptible plants in these two populations indicated that the resistance is controlled by a single dominant gene. Ten markers, including three simple sequence repeat （SSR） markers and seven insertion/deletion （InDel） markers, were developed in the RppP25 region. RppP25 was delimited to an interval between P091 and M271, with an estimated length of 40 kb based on the physical map of B73. In this region, a candidate gene was identified that was predicted to encode a putative nucleotide-binding site leucine-rich repeat （NBS-LRR） protein. Two co-segregated markers will aid in pyramiding diverse southern rust resistance alleles into elite materials, and thereby improve southern rust resistance worldwide.

Systematic dissection of disease resistance to southern corn rust by bulked-segregant and transcriptome analysis

Southern corn rust(SCR) is a destructive maize disease caused by Puccinia polysora Underw. To investigate the mechanism of SCR resistance in maize, a highly resistant inbred line, L119 A, and a highly susceptible line, Lx9801, were subjected to gene mapping and transcriptome analysis. Bulked-segregant analysis coupled with whole-genome sequencing revealed several quantitative trait loci(QTL) on chromosomes 1, 6, 8, and 10. A set of 25 genes, including two coiled-coil nucleotide-binding site leucine-rich repeat(CC-NBS-LRR) genes, were identified as candidate genes for a major-effect QTL on chromosome 10. To investigate the mechanism of SCR resistance in L119 A, RNA-seq of P. polysorainoculated and non-inoculated plants of L119 A and Lx9801 was performed. Unexpectedly, the number of differentially expressed genes in inoculated versus non-inoculated L119 A plants was about 10 times that of Lx9801, with only 29 common genes identified in both lines, suggesting extensive gene expression changes in the highly resistant but not in the susceptible line. Based on the transcriptome analysis, one of the CC-NBS-LRR candidate genes was confirmed to be upregulated in L119 A relative to Lx9801 independently of P. polysora inoculation. Gene Ontology and Kyoto Encyclopedia of Genes and Genomes analyses indicated that transcription factors, as well as genes involved in defense responses and metabolic processes, were dominantly enriched, with the phenylpropanoid biosynthesis pathway most specifically activated. Consistently, accumulation of phenylpropanoid-derived lignin, especially S lignin, was drastically increased in L119 A after P. polysora inoculation, but remained unchanged in Lx9801, suggesting a critical role of lignin in SCR resistance. A regulatory network of defense activation and metabolic change in SCR-resistant maize upon P. polysora infection is described.

QTL Mapping for Partial Resistance to Southern Corn Rust Using RILs of Tropical Sweet Corn

Southern corn rust is one of destructive diseases in maize caused by Puccinia polysora Undrew. A mapping population of tropical sweet corn recombinant inbred lines (RILs) derived from a cross between hA9104 and hA9035 inbred lines were set up to detect quantitative trait loci (QTLs) involved in partial resistance to southern corn rust. Eighty nine RILs were used to evaluate resistance levels using nine-point relative scale (1-9) at Sweet Seeds, Suwan Farm, Thailand include combined analysis. A genetic linkage map was constructed with 157 SSR markers, with a total length of 2123.1 cM, covering 10 chromosomes. Broad-sense heritability of individual location ranged from 0.76 and 0.82 and combined across locations was 0.87. Multiple QTL mapping (MQM) was applied for the identification of the QTLs. Fifteen QTLs were detected on chromosome 1, 2, 5, 6, 9 and 10 in both locations and combined across locations. QTLs on chromosome 1, 5 and 6 were contributed by alleles of resistant parent hA9104 while others were contributed by alleles from the susceptible parent, hA9035. Phenotypic variance of each QTL explained ranged from 6.1% to 41.8% with a total of 69.8% - 81.9%. QTL on chromosome 1, 6 and 10 were stable QTLs detected in both locations.

玉米南方锈病主效抗病QTL的鉴定和效应分析

以玉米南方锈病感病自交系Lx9801为母本、抗病自交系TY4为父本构建了含有165个家系的BC_(1)F_(4)群体,利用23K SNP芯片对亲本和BC_(1)F_(4)群体进行基因型分型,共筛选出4654个亲本间具有多态性的SNP标记,构建高密度的遗传连锁图谱,结合群体在3个环境下的抗性鉴定结果,共检测到6个QTL,可以解释3.93%~17.87%的表型变异。其中位于第6染色体上的qSCR6.01在3个环境中都检测到,可以解释最大17.87%的表型变异,是一个稳定的QTL。利用TY4与Lx9801组配的包含366个家系的BC1F5群体,对qSCR6.01进行精细定位,结合抗病区域内的标记开发和关键重组单株的抗性鉴定,将抗性位点定位在M2与M3标记之间,区间大小为4.09 Mb,此抗病位点暂被命名为RppT。

玉米南方锈病抗病育种研究进展

玉米是全世界也是我国种植范围最广、用途最多、总产量最高的作物,玉米生产对保障我国粮食安全具有重要意义。玉米南方锈病是由多堆柄锈菌(Puccinia polysora Underw.)引起的一种气传性真菌病害,主要发生在热带、亚热带玉米种植区。近年来,由于气候变化,该病害开始向高纬度地区蔓延,已逐渐成为我国黄淮海夏玉米区的主要病害,直接导致玉米籽粒品质变差、产量降低,对玉米生产造成严重威胁。目前,我国玉米生产上推广种植的玉米品种大多不抗玉米南方锈病,一旦南方锈病发生和流行,将会导致在短时间内大面积蔓延,而常规化学防治难以控制。因此,挖掘和利用玉米种质资源中的南方锈病抗性基因,进一步选育抗病品种是应对南方锈病为害最经济有效的技术途径。玉米资源中高抗南方锈病的种质较为匮乏,主要来自热带、亚热带,可直接利用的温带种质极少。与国外玉米种质相比,我国玉米种质中的高抗材料较少,主要来自农家种或含有热带血缘的P群材料,遗传基础狭窄。玉米南方锈病抗性基因的鉴定与克隆,对开展分子标记辅助育种、加快育种进程及抗病新品种选育具有重要促进作用,目前,已有多个南方锈病抗性基因被鉴定和克隆,为分子标记辅助选择育种奠定了基础。多年来,我国育种家利用有限的抗性种质资源,选育了多个抗南方锈病的优良玉米自交系,并成功育成抗病杂交种。近期,南方锈病病原菌基因组方面的研究揭示我国多堆柄锈菌群体已分化出高毒谱系,从而逃逸抗病基因的识别。因此,挖掘和利用抗性种质中蕴涵的丰富基因资源仍需进一步加强。本文概述了南方锈病的生物学特性及危害,系统梳理了南方锈病抗性种质资源鉴定、抗性基因定位与克隆,以及抗性品种选育的研究进展,并展望了玉米南方锈病未来研究方向,以期为玉米南方锈病防治和抗病品种选育提供参考。

不同药剂及施药技术对玉米南方锈病的防效研究

近年来,由多堆柄锈菌Puccinia polysora Underw.引起的玉米南方锈病在黄淮海玉米产区发生频率高、危害重。为明确玉米南方锈病的最佳防治时期,不同杀菌剂种类、施用剂量及防治次数对玉米南方锈病的防治效果,在大田条件下,以丙硫菌唑为供试杀菌剂,探讨了在玉米不同生育期防治及防治次数对玉米南方锈病的防效及对玉米产量的影响,同时研究了丙环唑、戊唑醇、氟环唑和丙硫菌唑4种杀菌剂不同使用剂量对玉米南方锈病的防效及对玉米产量的影响。结果表明,分别在玉米大喇叭口期、抽雄初期、吐丝期和灌浆期防治,以抽雄初期的防效最好(58.47%),挽回产量损失率最高(108.05%)。施药两次对玉米南方锈病的防治效果显著优于施药一次的防治效果。丙环唑、戊唑醇、氟环唑和丙硫菌唑4种杀菌剂对玉米南方锈病均有一定的防控效果,施药后14 d的防效均在85%以上,施药后28 d的防效呈明显下降趋势。4种杀菌剂防治玉米南方锈病,防效以氟环唑(1350 mL/h m^(2))和丙硫菌唑(1350 mL/h m^(2))最好,施药后14 d的防效分别为95.68%和95.57%;施药后28 d的防效分别为55.39%和60.27%。4种杀菌剂不同使用剂量的挽回产量损失率均在70%以上。从防治效果及挽回产量损失率等方面综合考虑,防治该病的最佳施药期为玉米抽雄初期,4种供试药剂均可在大田防治中推广应用。

玉米南方锈病研究进展

综述了玉米南方锈病(southern corn rust,SCR)的发生分布、病原特征、病原遗传结构、玉米抗病基因、防控措施方面的综合进展,分析了目前SCR研究中存在的问题,指出了今后应重视建立和优化综合防控体系,注重挖掘抗病基因、开发快速检测工具和筛选高效农药,以期为SCR的有效防治提供指导性策略。

植保无人飞机防治玉米南方锈病施药参数和防效探究

为了利用植保无人飞机有效防治玉米南方锈病,开展了施药液量和药剂筛选研究。试验结果表明:植保无人飞机在飞行高度2 m和飞行速度3 m/s条件下,施药液量为2 L/667m^(2)时,药液雾滴在玉米植株下三叶、棒三叶和上三叶上的沉积密度分别为91.72、57.75个/cm^(2)和13.42个/cm^(2),且施药液量增加到3 L/667m^(2)和4 L/667m^(2)时药液雾滴的沉积密度没有显著变化。施药液量为2、3 L/667m^(2)和4 L/667m^(2)时农药沉积利用率分别为52.59%、53.89%和57.88%。综合考虑作业效率,植保无人飞机施药防治玉米南方锈病的最佳施药液量为2 L/667m^(2)。在此施药条件下,喷施30%丙硫菌唑OD、20%丙环唑ME、32.5%苯甲·嘧菌酯SC和40%丙硫菌唑·戊唑醇SC 14 d后对玉米南方锈病的防治效果分别达到96.72%、70.68%、80.54%和69.71%。因此,植保无人飞机在飞行高度2 m,飞行速度3 m/s,作业行距5 m,施药液量2 L/667m^(2)时喷施30%丙硫菌唑OD、32.5%苯甲·嘧菌酯SC、20%丙环唑ME和40%丙硫菌唑·戊唑醇SC可有效防治玉米南方锈病。

4种生物制剂对玉米2种病害的田间防治效果

为有效防治玉米小斑病和玉米锈病,筛选有效防控的生物制剂,选用复合微生物菌剂(3种有效菌种:枯草芽孢杆菌+解淀粉芽孢杆菌+胶冻样类芽孢杆菌)20亿CFU/mL、微生物菌剂哈茨木霉粉剂5亿CFU/g、20%春雷霉素水分散粒剂和4%井冈霉素A水剂4种杀菌剂进行田间药效试验。结果表明,复合微生物菌剂(3种有效菌种:枯草芽孢杆菌+解淀粉芽孢杆菌+胶冻样类芽孢杆菌)对玉米田2种病害的田间防效最优,哈茨木霉粉剂5亿CFU/g对玉米小斑病的防效较好,20%春雷霉素水分散粒剂对玉米锈病的防效较理想。该研究结果可为玉米绿色生产提供参考。

46份黄淮海玉米新品种南方锈病抗性剖析

以河南省种业发展中心主持展示的46个玉米新品种为材料,通过田间南方锈病自然发病分析与接种鉴定分析比较,探讨46个玉米新品种抗南方锈病能力及对产量性状的影响。结果表明,在46份主推品种中,高抗(HR)品种2份,抗病(R)品种7份,中抗(MR)品种19份,感病(S)品种10份,高感(HS)品种8份,随着育种水平的提升,南方锈病抗性水平表现中抗以上品种逐年递增。穗粒重、产量与抗性水平呈正相关。其中,浚单678、名鼎26、航星708、浚单658、中科玉505、安玉706、现代959、金北516、中玉303、NK815、YD807、鑫农科898等品种南方锈病抗性和产量均较好。热带、亚热带血缘玉米材料具有较好的抗南方锈病性能,可以作为改良温带种质一个有效的抗原。

2021年黄淮地区夏玉米南方锈病流行因素分析及防控对策

黄淮地区是我国夏玉米重要产区,近年来由多堆柄锈菌Puccinia polysora Underw.引起的玉米南方锈病的发生与流行已成为黄淮地区玉米产量的主要限制因素,2021年玉米南方锈病在我国黄淮玉米产区大面积暴发流行,危害损失之严重历年罕见。本文介绍了2021年度黄淮地区玉米南方锈病的发生危害情况,分析了暴发流行的主要因素,并提出了今后的防控对策。

基于PCR和巢式PCR技术的玉米南方锈病早期检测

【目的】建立巢式PCR方法,快速检测处于病害潜育期的玉米叶片内的多堆柄锈菌(Puccinia polysora),为玉米南方锈病(southern corn rust)的预测和防治提供技术支持。【方法】根据多堆柄锈菌ITS区序列,在其变异区设计3条多堆柄锈菌特异性检测引物NX471-F、NX255-F和NX255-R,建立以NX471-F与真菌ITS区通用引物ITS4为外侧引物,NX255-F/NX255-R为内侧引物的巢式PCR。采用20μL扩增体系:Ex Taq DNA聚合酶(5 U·μL~(-1))0.15μL、10×Ex Taq Buffer(Mg~(2+)plus)2μL,d NTP Mixture(各2.5 mmol·L~(-1))1.6μL,上下游引物(10μmol·L~(-1))各0.3μL,DNA 1μL,14.65μL ddH_2O。扩增程序:利用外侧引物NX471-F/ITS4进行第一步PCR扩增,95℃预变性7 min;95℃变性30 s,55℃退火30 s,72℃延伸45 s,30个循环;72℃再延伸7 min。将扩增后的产物稀释20倍,取1μL用作第二步PCR的扩增模板,然后以内侧引物NX255-F/NX255-R进行第二步PCR扩增,95℃预变性7 min;95℃变性30 s,66℃退火30 s,72℃延伸26 s,30个循环;72℃再延伸7 min。同时选用内侧引物进行常规PCR扩增,扩增体系同巢式PCR,扩增程序除循环数为38,其余程序同巢式PCR的第二步PCR检测。在此条件下对多堆柄锈菌、高粱柄锈菌(Puccinia sorghi)、青杨叶锈病菌(Melampsora laricipopulina)和7种玉米常见病原菌进行特异性检测,对不同梯度多堆柄锈菌基因组DNA和3种人工接种病叶进行灵敏度检测。【结果】巢式PCR检测体系仅在检测多堆柄锈菌时,产生了255 bp的目的条带,其他菌株均未扩增出目的条带。巢式PCR检测体系对多堆柄锈基因组DNA的最低检测限为10 fg·μL~(-1),是常规PCR检测体系灵敏度的500倍。当1 g人工接种病叶含500—2.5×10~4个多堆柄锈菌夏孢子时,常规PCR和巢式PCR检出阳性率分别0和85.71%,巢式PCR可检测出的夏孢子个数最少为1 000个;当1 g人工接种病叶中含1—7个夏孢子堆时,常规PCR和巢式PCR检出阳性率分别76.19%和100%,常规PCR可检测出的夏孢子堆个数最少为2个,巢式PCR可检测出1个及以上夏孢子堆;当1 g人工接种病叶中含1—7个侵染点时,常规PCR和巢式PCR检出阳性率分别14.29%和66.67%,检测出的侵染点个数最少分别为6个和3个。【结论】成功建立了一种以NX471-F/ITS4为外侧引物,NX255-F/NX255-R为内侧引物的巢式PCR检测方法,可快速、高效、准确检测玉米叶片中潜伏期的多堆柄锈菌。

国家区试冬小麦品种在甘肃陇南的田间抗条锈病性评价

为精准评价冬小麦品种田间对条锈病的抗性,科学指导抗病育种和抗病材料的合理应用。在位于甘肃陇南不同生态区的甘肃省农业科学院植物保护研究所甘谷试验站和汪川良种场两地,于2017—2020年,对122个国家区域试验品种进行了连续3 a的成株期抗条锈病性评价。结果表明,有WJ18-1等19个品种3 a两地均表现抗病,且抗性表现稳定,占供试品种的15.57%;WJ18-494等49个品种具有慢条锈特性,占供试品种的40.16%。绝大多数品种表现出差异性,菌源、环境是主要原因。

玉米南方锈病的研究进展及防治对策研究

玉米南方锈病是由多堆柄锈菌(Puccinia polysora Underw.)引起的一种破坏性极强的气传性真菌病害,严重威胁玉米生产和粮食安全。近年,由于极端气候频发以及缺少抗锈种质资源,玉米南方锈病越来越严重。因此,深入了解玉米南方锈病暴发机制和有效防控至关重要。系统论述了玉米南方锈病在国内外的发生与危害、发病症状与发病规律、发病原因等情况,探讨了预防和治理南方锈病的措施,以实现玉米产量与品质的提高。

我国玉米南方锈病发生流行现状及绿色防控策略

玉米南方锈病是严重影响我国玉米生产的真菌病害.绿色防控作为新兴的建立在农田生态系统整体上的农业病虫害管理方式,近年来已成为研究和应用的热点.目前对玉米南方锈病的绿色防控技术已有使用,但较为零散不成体系.为系统了解玉米南方锈病绿色防控领域的研究现状和未来趋势,本文介绍了我国玉米南方锈病的发生状况,系统阐述了防控玉米南方锈病绿色防控手段,包括监测预警、抗病种质与基因、生态调控以及生物防治,并对玉米南方锈病潜在绿色防控手段进行展望,明确了绿色防控技术应用前景,以期对玉米南方锈病绿色防控体系的构建提供思路.

玉米南方锈病的发生规律及其防控策略

近几年来,南方锈病已成为绩溪县玉米主要病害之一,对玉米产量影响较大,中等发生年份一般减产10%~30%,重发生年份减产在50%以上。通过5年田间调查,对玉米南方锈病发生程度与品种、降雨日数、施肥量、田块类型等因素进行了相关性研究。结果发现,发病程度与上述因素密切相关,品种抗性差、降雨日多、偏施氮肥的田块发病重;种植密度大、排水性能差的田块发病重。基于此,本研究提出了以“品种选择、农业措施、药剂防治、统防统治”为核心的防控策略。

玉米P_(25)自交系抗锈病基因的遗传分析及SSR分子标记定位

以玉米南方型锈病免疫自交系P2 5和感病自交系F3 4 9及F1、F2 、B1和B2 为材料 ,采用主基因 多基因混合遗传模型研究了P2 5的抗病遗传规律。结果表明 :自交系P2 5的抗病基因为一主基因 ,表现为加性效应 ,没有检测出多基因 ,其在F2 、B1和B2 群体的遗传率分别为 81 88%、38 14 %和 5 5 1%。利用SSR分子标记技术 ,以组合P2 5×F3 4 9的F2 :3 家系作为构图群体 ,构建了玉米SSR遗传连锁图谱 ,并将玉米抗南方型锈病基因定位于 10号染色体上 ,与phi0 5 9标记的遗传距离为 5 8cM。

我国玉米南方锈病发生区域和玉米品种田间抗性的研究

通过对河南、山东、安徽等近20个省市的广泛调查以及有关田间发病记载数据的整理,明确了玉米南方锈病的准确发生地区。黄淮海夏玉米区以及海南省是当前我国玉米南方锈病发生的重点区域,病害对生产影响明显,其次为广西、广东等南方玉米区,西南玉米区局部有轻微发生,该区域主要发生的是普通锈病。汇总接种鉴定以及数年田间鉴定和国家玉米区域试验点记载的数据,获得了黄淮海夏玉米区47份推广品种对南方锈病的抗性水平情况,其中登海3号和天泰10号为高抗南方锈病品种,鲁单981、农大108、中科4号等14份也具有较好的田间抗性,但目前在该区域种植面积最大的郑单958和浚单20则属于高感品种。积极推广抗南方锈病品种是有效控制病害,减少生产损失的惟一选择。

玉米自交系CML470抗南方锈病基因的定位

南方锈病是我国玉米产区的主要病害,玉米抗病品种的利用是控制其为害的一条最为安全和经济的途径。但是,在我国当前的玉米育种中,所利用的玉米南方锈病基因多来自美国杂交种78599等。为寻找新的南方锈病抗病基因,本研究对CIMMYT自交系CML470的抗性进行了遗传分析。结果发现CML470的抗性由一个显性抗病基因(定名为RppC)控制,该抗病基因被定位于10号染色体短臂端部,位于SSR标记umc1380和umc1291之间,分别与两标记相距3.5 cM和8.8 cM。通过回交,并利用分子标记辅助选择,RppC被转移到了优良自交系昌7-2中。