芝麻枯萎病菌毒素成分分析及其对芝麻幼苗的毒性

芝麻枯萎病(sesame Fusarium wilt,SFW)是由尖孢镰刀菌芝麻专化型[Fusarium oxysporum Schl.f.sp.sesami(Zap.),FOS]引起的一种土传真菌病害,严重影响着我国芝麻生产。为确定FOS是否产生毒素以及毒素成分,利用液相色谱和液质联用等技术分离并分析了FOS菌株培养滤液的主要组成物质。研究发现FOS能够产生4种特异物质,分别为镰刀菌酸(5-丁基吡啶甲酸,FA),及C_(10)H_(13)NO_4(FA+O_2)、C_(10)H_(13)NO_3(FA+O)和C_(10)H_(11)NO_2(FA-H_2)_3种镰刀菌酸类似物。在Richard培养基上强致病力和弱致病力FOS菌株均可获得毒素,不同致病力的菌株所产生4种物质的含量和比例存在差异。芝麻幼苗生长试验结果证明含有上述特异物质的FOS培养滤液能够对幼苗生长产生抑制作用;而随着FOS毒素浓度的增大,芝麻幼苗受毒害程度增大。但在含相同FA浓度的FOS培养滤液处理下,不同芝麻品种幼苗生长受抑制程度无显著差异。该结果为进一步研究FOS致病机理及芝麻-FOS互作奠定了技术和理论基础。     

利用香蕉水培系统测定枯萎病病原菌致病力

 为建立一种评价香蕉枯萎病病原菌(Fusarium oxysporum f.sp. cubense)菌株间致病力差异的体系,在改进的香蕉水培系统基础上,对影响香蕉枯萎病菌致病力的接种菌液浓度、类型及处理方式等因素开展分析,同时与不同菌株盆栽测定结果进行比较以验证该方法的可靠性。结果表明:在香蕉水培系统下,将摇培5 d的菌液稀释10倍以上,使孢子初始浓度为1×10⁶ cfu·mL^-1,直接加入该菌液50 mL即可用于致病力评价,且不同菌株用该测定方法与盆栽测定的致病力结果基本一致。该方法的建立为香蕉枯萎病菌致病力的评价提供了快速简便的方法,也为下一步解析尖孢镰刀菌致病相关基因功能和致病机理及抗病品种的选育奠定了基础。     

莱氏绿僵菌Mr006鉴定及对草地贪夜蛾致病力

收集草地贪夜蛾致病性莱氏绿僵菌,丰富昆虫病原真菌资源,为草地贪夜蛾绿色防控生防制剂开发提供依据。采用形态学和ITS-r DNA序列分析相结合的方法对菌株Mr006进行了鉴定,以浸渍法生物测定了该菌株对草地贪夜蛾幼虫和蛹的致病力,并进行了田间应用效果评价。结果表明,分离的Mr006菌株鉴定为莱氏绿僵菌;该菌株对草地贪夜蛾幼虫、蛹均有致病力,用孢子浓度为1×10⁷孢子/mL接种后,1～5龄幼虫的校正死亡率分别为91.16%、88.38%、70.71%、53.03%和22.73%,蛹的校正死亡率为76.26%;对草地贪夜蛾1～5龄幼虫和蛹的LC₅₀分别为3.55×10⁴、8.23×10⁴、3.63×10⁶、4.16×10⁷、4.23×10⁸和2.57×10⁵孢子/mL;用孢子浓度为1×10⁸孢子/mL接种后,1～5龄幼虫和蛹的LT₅₀值分别缩短至3.47、3.94、4.90、...     

芝麻棒孢叶斑病病原菌鉴定与致病力比较

 为明确芝麻叶斑病病原菌及其致病力,本研究以河南不同地区芝麻上分离所得叶斑病分离物为研究对象,通过形态观察和分子鉴定探讨这些分离物的分类属性,并且进行离体叶片和活体茎杆接菌,进一步探究了不同菌株的致病力差异。结果显示分离所得的6株芝麻叶斑病分离物的菌落形态、生长速率和产孢量存在差异,分生孢子多数呈倒棍棒状,具隔膜,6个菌株的ITS序列与GenBank中Corynespora cassiicola的一致性达99%以上,结合形态特征与ITS序列将其鉴定为山扁豆生棒孢。室内人工接菌芝麻发现,这6个菌株的致病力存在显著的差异;在芝麻叶片上,20180909-03属强致病力菌株,20180821-01、20180909-05和20180824-01属中等致病力菌株,20180904-02-02和SF1-1属弱致病力菌株;在芝麻茎杆上,20180824-01致病力最强,其次是20180821-01、20180909-03和20180909-05,SF1-1和20180904-02-02致病力最弱。研究结果证明山扁豆生棒孢不同菌株在芝麻上的致病力存在明显的分化。     

芝麻棒孢叶斑病病原菌鉴定与致病力比较

 为明确芝麻叶斑病病原菌及其致病力,本研究以河南不同地区芝麻上分离所得叶斑病分离物为研究对象,通过形态观察和分子鉴定探讨这些分离物的分类属性,并且进行离体叶片和活体茎杆接菌,进一步探究了不同菌株的致病力差异。结果显示分离所得的6株芝麻叶斑病分离物的菌落形态、生长速率和产孢量存在差异,分生孢子多数呈倒棍棒状,具隔膜,6个菌株的ITS序列与GenBank中Corynespora cassiicola的一致性达99%以上,结合形态特征与ITS序列将其鉴定为山扁豆生棒孢。室内人工接菌芝麻发现,这6个菌株的致病力存在显著的差异;在芝麻叶片上,20180909-03属强致病力菌株,20180821-01、20180909-05和20180824-01属中等致病力菌株,20180904-02-02和SF1-1属弱致病力菌株;在芝麻茎杆上,20180824-01致病力最强,其次是20180821-01、20180909-03和20180909-05,SF1-1和20180904-02-02致病力最弱。研究结果证明山扁豆生棒孢不同菌株在芝麻上的致病力存在明显的分化。     

一个编码富含丝氨酸蛋白的基因影响大丽轮枝菌的微菌核形成、产孢及致病力

 大丽轮枝菌是一种可在广泛的寄主范围内引发黄萎病的土传植物病原真菌,主要以微菌核的形式在土壤中存活多年,因此鉴定与微菌核形成及致病力相关的基因对防治该病害至关重要。本课题组从前期构建的棉花黄萎病菌T-DNA插入突变体库中筛选到一个微菌核明显减少的突变体,致病力测定结果表明,该突变体致病力明显下降。以棉花黄萎病菌野生型菌株V592的基因组DNA为模板,从棉花黄萎病菌中克隆到被T-DNA插入突变的基因(VdSRP1)编码区全长为415 bp,包含一个外显子,编码一个富含丝氨酸蛋白,与任何已知的注释基因没有显著的序列相似性。为了明确VdSRP1基因在大丽轮枝菌中的功能,利用同源重组的原理及农杆菌介导的遗传转化方法获得了VdSRP1基因的2个敲除体菌株,与棉花黄萎病菌野生型菌株V592相比,VdSRP1基因敲除突变体的微菌核形成明显减少,产孢量及孢子萌发率下降,对棉花的毒力也显著下降。对野生型菌株V592及VdSRP1敲除突变体的转录分析表明,VdSRP1调控一系列与微菌核形成、孢子形成及致病力相关基因的表达。这些结果表明,VdSRP1基因影响大丽轮枝菌的致病力、微菌核形成、产孢及孢子萌发。     

一个编码富含丝氨酸蛋白的基因影响大丽轮枝菌的微菌核形成、产孢及致病力

 大丽轮枝菌是一种可在广泛的寄主范围内引发黄萎病的土传植物病原真菌,主要以微菌核的形式在土壤中存活多年,因此鉴定与微菌核形成及致病力相关的基因对防治该病害至关重要。本课题组从前期构建的棉花黄萎病菌T-DNA插入突变体库中筛选到一个微菌核明显减少的突变体,致病力测定结果表明,该突变体致病力明显下降。以棉花黄萎病菌野生型菌株V592的基因组DNA为模板,从棉花黄萎病菌中克隆到被T-DNA插入突变的基因(VdSRP1)编码区全长为415 bp,包含一个外显子,编码一个富含丝氨酸蛋白,与任何已知的注释基因没有显著的序列相似性。为了明确VdSRP1基因在大丽轮枝菌中的功能,利用同源重组的原理及农杆菌介导的遗传转化方法获得了VdSRP1基因的2个敲除体菌株,与棉花黄萎病菌野生型菌株V592相比,VdSRP1基因敲除突变体的微菌核形成明显减少,产孢量及孢子萌发率下降,对棉花的毒力也显著下降。对野生型菌株V592及VdSRP1敲除突变体的转录分析表明,VdSRP1调控一系列与微菌核形成、孢子形成及致病力相关基因的表达。这些结果表明,VdSRP1基因影响大丽轮枝菌的致病力、微菌核形成、产孢及孢子萌发。     

源于水稻品种空育163的稻瘟病菌菌株致病性分析

 为分析相同遗传背景下稻瘟病菌致病性变化情况,利用24个水稻单基因系品种为评价体系,通过喷雾接种的方式,对36个以空育163为哺育品种的稻瘟病菌株进行了分析,得出以下结论:1、供试菌株致病力强,对24个抗瘟基因的致病率在36.11%~100%之间,平均致病率77.51%,逐年增强趋势明显。2、供试菌株致病性分化严重,相似系数在0.00~1.00之间,在相似系数0.50水平上,共划分为29个类群,优势类群菌株占总菌株的13.89%。3、24个抗瘟基因对供试菌株抗谱在5.56%~56.48%之间,Pi-k^m抗谱最窄, Pi-9(t)抗谱最宽;在基因搭配前提下,Pi-9(t)& Pi-12(t)组合和 Pi-9(t)& Pi-11组合效果略好。总体分析,供试菌株致病力和致病性分化都处于较高水平,目前缺少高效抗源加以控制。     

南方稻区稻瘟病菌株中无毒基因AvrPi9的变异分析

 本研究通过PCR(Polymerase Chain Reaction)和测序技术以及稻瘟病菌致病力检测手段,分析了2020年来自安徽、重庆、福建、广西、湖南、江苏、江西、云南以及浙江等省(直辖市、自治区)的300个稻瘟病分离菌株的无毒基因AvrPi9的分布和变异情况。结果表明,298份稻瘟病菌分离菌株的AvrPi9位点能被有效扩增,扩增产物经测序分析后显示,其中8株供试菌株的AvrPi9基因位点的外显子区域253位发生单碱基变异(C碱基替换成T碱基,AvrPi9^C253T),导致转录提前终止。稻瘟病菌致病力分析表明,AvrPi9^C253T菌株对带有Pi9基因的植株TP309-Pi9产生了致病性,说明该类菌株的AvrPi9位点变异后不能被Pi9识别。上述结果提示培育和种植携带有抗稻瘟病基因Pi9的品种可以较大程度上对南方稻区稻瘟病起到防控作用。这对保障水稻生产安全具有重要意义。     

连作条件下土壤中甘蓝枯萎病菌的致病力变化和种群遗传结构分化

 枯萎病菌致病力的变化可能是连作条件下甘蓝枯萎病严重发生的重要原因之一。本研究在建立适度感染的人工病圃的基础上连续种植甘蓝5茬,每茬收获后随机采集土样。利用驹田氏培养基通过稀释平板法对连作土壤中尖孢镰刀菌种群数量的监测结果表明,连作后尖孢镰刀菌的数量由第二茬后的3.047×10⁴ cfu·g^-1土壤增加到第五茬收获后的1.608×10⁵ cfu·g^-1 土壤。对各茬后所分离30株甘蓝枯萎病菌（Fusarium oxysporum f. sp. conglutinans, Foc）的培养性状的观察结果表明,连作后Foc菌株在菌落形态、菌落扩展速率和产孢量等方面均发生明显的变化。用浸根法进行的致病力测定结果表明,随着连茬次数增加,弱致病力菌株占总供试菌株的比例逐渐变小,到第三茬后由第一茬的6.7%下降为0;而强致病力菌株的比例逐渐上升,由第一茬后的6.7%上升到第四茬后的16.7%。利用11条寡聚核苷酸随机引物对受试菌株进行PCR-ISSR扩增,结果显示从第三茬后Foc群体遗传结构出现分化。UPGMA聚类分析结果表明,第三、四和五茬后的Foc菌株都分为A和B两个类群,每个类群又分为Ⅰ和Ⅱ两个亚类群,但同一类群和亚类群中包含不同致病力的菌株,未发现病菌的致病力变化与遗传结构分化之间的相关。     

西瓜与枯萎病菌非亲和互作相关基因的分离及表达分析

 从整体水平阐明西瓜对西瓜枯萎病菌1号生理小种的抗病分子机制和抗病相关基因的表达特征,以高抗枯萎病菌1号生理小种的西瓜品种“卡红(Calhoun Gray)”为试材,接种西瓜枯萎病菌和蒸馏水的根尖组织作为测验方(Tester)和驱动方(Driver),构建西瓜枯萎病菌胁迫的SSH-cDNA正向文库。利用反向 Northern 斑点杂交技术对文库中克隆进行杂交筛选。随机测序300个阳性克隆,序列比对分析,利用RT-PCR技术分析抗病相关基因的表达特性。259条EST成功测序,167条与已知基因具有较高的同源性,占全部ESTs的65.5%,其中与抗病和防卫相关的有64条23种,占24.7%;卡红对枯萎病菌1号生理小种的抗性相关基因主要涉及抗病信号传导、抗病防卫、转录因子、次生代谢合成和细胞保护等方面;Aquaporin和Peroxidase基因在接种后表达量均增加。Calhoun Gray对枯萎病菌侵染作出的反应是全方位多方面的,抗病相关基因主要集中在系统获得性抗性反应中,获得了一些Calhoun Gray与野生西瓜PI296341在与枯萎病生理小种1互作中差异表达的基因,为深入研究西瓜与枯萎病菌互作的分子机制以及关键基因的功能分析奠定基础。     

大豆枯萎病菌尖孢镰孢遗传多样性及大豆品种抗性

 了解大豆枯萎病菌的群体遗传特征及明确大豆种质对大豆枯萎病的抗性,对抗病育种、抗性品种的合理布局以及制定更有效的病害防治策略具有重要的参考价值。本研究利用随机扩增多态性DNA(random amplified polymorphic DNA,RAPD),对采自我国不同地区的大豆枯萎病菌—尖孢镰孢菌(Fusarium oxysporum)进行遗传多样性分析,筛选到10个多态性随机引物,共扩增出75条RAPD条带,其中55条为多态性条带,占73.3%。利用UPGMA法对DNA扩增图谱进行聚类分析,以相似系数0.68为阈值,55个分离物可分为9个遗传聚类组,表明我国大豆枯萎病菌具有丰富的种内遗传多样性,所划分的群体与分离物来源地不相关。同时,对上述分离物进行致病性分析,发现我国的大豆枯萎病菌具有明显的致病力分化现象。进一步利用3个代表性分离物对来自我国不同大豆产区的180个大豆品种(资源)进行抗大豆枯萎病鉴定,发现皖豆28、中黄13、中黄51、中作X08076和5D034等5个品种对大豆枯萎病具有良好抗性,占供试材料的2.8%,表明不同大豆品种对枯萎病的抗性存在一定的差异。     

铵态氮和硝态氮对香蕉枯萎病发生的比较研究

 为寻找降低香蕉枯萎病发生的防治措施,通过室内盆栽接种试验,研究了铵态氮(NH₄⁺-N)和硝态氮(NO₃^--N)对香蕉枯萎病发生及其植株叶绿素含量、气体交换参数、病原菌在植物体内的数量分布和植物钙(Ca)、镁(Mg)、铁(Fe)、钼(Mo)、可溶性糖和木质素含量的效应。结果表明:不接种病原菌的条件下,不同氮素处理对香蕉幼苗生长影响无差异;接菌情况下,与NH₄⁺-N处理相比,NO₃^--N处理显著降低植株各器官的病原菌数量、发病率和发病严重程度。病原菌侵染后,不同氮素处理下植株光合作用均显著下降:NO₃^--N处理香蕉苗保持比NH₄⁺-N处理更高的光合速率;病原菌侵染后NH₄⁺-N处理的植株Ca、Mg、Fe和Mo含量相对于侵染前没有显著差异,但NO₃^--N处理下此4种元素含量均显著升高。病原菌侵染后的植株叶片可溶性糖含量在不同氮素处理中都没有显著变化,但在根系中,NO₃^--N处理的侵染植株可溶性糖含量显著降低。与此同时,病原菌侵染后,木质素含量在NH₄⁺-N处理植株中变化不显著,但其含量在NO₃^--N处理侵染后显著上升。综上所述,NO₃^--N处理可增加植株抗病相关矿质元素的吸收,诱导香蕉苗木质素形成,使其木质化程度增加,从而维持较高的光合作用,保持较高的抗病水平。     

Occurrence of Fusarium oxysporum f. sp. melonis Race 1 in Japan

In 1994, Fusarium wilt of melon cultivars which are resistant to races 0 and 2 of Fusarium oxysporum f. sp. melonis was observed in southern area of the Lake Biwa region, Shiga prefecture. In commercial fields, mature plants of cv. Amus which were grafted onto cv. Enken Daigi 2, and of cv. FR Amus showed yellowing, wilting and finally death before harvesting of fruits. Diseased plants had vascular and root discolorations, and their stem sections yielded typical colonies of F. oxysporum. When the Shiga strains were tested for their pathogenicity to 12 species of cucurbits, they caused wilts only on melon. Using race differential cultivars of melon, the Shiga strains were classified as race 1 of F. oxysporum f. sp. melonis, which has not been reported in Japan. To further characterize their pathogenicity, the strains were used to inoculate 46 additional cultivars of melon, oriental melon and oriental pickling melon. All the race 1 strains were pathogenic to the cultivars tested, and their host range was apparently different from those of strains belonging to other races (races 0, 2 and 1,2y). DNA fingerprinting with a repetitive DNA sequence, FOLR3, differentiated race 1 strains from strains of races 0 and 2, but not from race 1,2y strains. Received 2 July 1999/ Accepted in revised form 30 September 1999     

大丽轮枝菌侵染抗感棉种的组织学过程观察

 棉花黄萎病是一种极难防治的土传性真菌病害,研究病原菌侵染棉花的组织学过程对致病机理解析和抗病资源利用具有重要意义。本研究利用绿色荧光蛋白标记的大丽轮枝菌系统研究了其对抗病棉种海岛棉7124和三裂棉、感病棉种军棉1号和戴维逊棉的侵染过程。结果表明,大丽轮枝菌对抗/感棉种的初始侵染没有明显差异,接菌5 h后,分生孢子均能吸附在感病和抗病棉种的根表面。但侵染过程存在显著差异,侵染感病棉种中病原菌3~5 d到达皮层,5~7 d达到维管束,随后迅速扩展繁殖,侵染14 d后即完成系统侵染,并开始产生黄萎病症状;而病原菌侵染抗病棉种,5~7 d才侵入皮层,7~10 d到达维管束,14 d后仍无法扩展,病原菌的定殖与发展受到限制,无法形成系统侵染,较少形成黄萎病症状。本研究通过绿色荧光蛋白标记大丽轮枝菌对抗/感棉种的侵染过程研究,为大丽轮枝菌致病机理研究和抗性资源利用提供了强有力的理论依据。     

番茄枯萎病菌和青枯病菌拮抗细菌的评价

为筛选出对番茄枯萎病和青枯病有较好防效的生防菌,采用平板对峙法,以番茄枯萎病菌Fusarium oxysporum和番茄青枯病菌Ralstonia solanacearum为靶标菌,从江苏沭阳、宿迁、溧水及内蒙古海拉尔分离到的2 062株细菌菌株中筛选拮抗菌株,并采用平板对峙法、拮抗菌液灌根法、分子生物学方法进行拮抗物质检测、盆栽试验及种属鉴定。结果表明:从2 062株细菌中共筛选到21株对番茄枯萎病和青枯病具有很强拮抗作用的菌株,均能分泌蛋白酶,具有解磷作用;不能分泌几丁质酶和纤维素酶,仅4株细菌能分泌嗜铁素。拮抗细菌SY290对番茄枯萎病和番茄青枯病防效最高,分别达到74.2%和75.0%,SQ728和LS536次之,但防效均大于60%。结合各菌株形态特征、16S r DNA与gyr-B序列分析结果,菌株SY177、SY290和SQ728鉴定为解淀粉芽胞杆菌Bacillus amyloliquefaciens,菌株LS536为枯草芽胞杆菌B.subtilis。     

Comparative effect of root-knot nematode on severity of verticillium and fusarium wilt in cotton

The effect of root-knot nematode (RKN) (Meloidogyne incognita) onVerticillium dahliae andFusarium oxysporum f.sp.vasinfectum in cotton (Gossypium hirsutum) was investigated. Two different inoculation methods were used, one in which inoculum was added to the soil, so that nematode and fungal inoculum were in close proximity; the other, inoculation into the stem, whereby the two inocula were spatially separated. Invasion of the roots by RKN enhanced disease severity, as measured by the height of vascular browning in the stem, following inoculation with either wilt pathogen. The effect of RKN on Fusarium wilt was more pronounced than that on Verticillium wilt. Nematode-enhanced infection byF. oxysporum is a well known effect but there are few reports of enhanced infection byVerticillium due to RKN. Relative resistance of a number of cotton cultivars to both wilt diseases, as measured by height of vascular browning, was similar to the known field performance of the cultivars. The use of vascular browning as an estimate of disease severity was therefore validated. http://www.phytoparasitica.org posting Feb. 3, 2003.     

Accumulation of phytoalexins in susceptible and resistant near-isogenic lines of tomato infected with Verticillium albo-atrum or Fusarium oxysporum f.sp. lycopersici

The time course of accumulation of two phytoalexins, the terpenoid rishitin and the polyacetylene cis-tetradeca-6-ene-1,3-diyne-5,8-diol, was determined in near-isogenic susceptible and resistant tomato lines inoculated with either Verticillium albo-atrum or Fusarium oxysporum f.sp. lycopersici.Cultivars containing the Ve gene for verticillium wilt resistance accumulated phytoalexins at a rate similar to that in susceptible plants following stem inoculation with V. albo-atrum. Higher amounts of phytoalexins were isolated from susceptible than from resistant plants at 11 days after inoculation. Inoculum concentrations of 10⁵, 10⁶, 10⁷ and 10⁸ conidia ml⁻¹ had no differential effect on phytoalexin accumulation at 3 days after inoculation. Also, no differences were observed between fungal growth in susceptible and resistant cultivars during that period.A cultivar containing the I-1 gene for fusarium wilt resistance contained more rishitin than did susceptible plants at 2 and 3 days after inoculation with 10⁷ conidia of F. oxysporum f.sp. lycopersici ml⁻¹, but at 7 and 11 days after inoculation more rishitin had accumulated in the susceptible plants.No difference was observed between the rate of accumulation of phytoalexin in stem segments from resistant and susceptible plants inoculated by vacuum-infiltration.To estimate the concentration of phytoalexins in the xylem fluid, sap was expressed from vascular tissue and amounts of phytoalexins were determined in the sap and in the expressed tissue. Less than 5% of the phytoalexins present in stem segments was recovered from the sap, indicating that their concentration in the xylem fluid may be relatively low.The role of phytoalexins in resistance to verticillium and fusarium wilt is discussed.     

Seed transmission of<Emphasis Type="Italic">Fusarium oxysporum</Emphasis> f.sp.<Emphasis Type="Italic">lactucae</Emphasis>

Twenty-seven seed samples belonging to the lettuce cultivars most frequently grown in Lombardy (northwestern Italy), in an area severely affected by Fusarium wilt of lettuce, were assayed for the presence ofFusarium oxysporum on a Fusarium-selective medium. Isolations were carried out on subsamples of seeds (500 to 1500) belonging to the same seed lots used for sowing, and either unwashed or disinfected in 1% sodium hypochloride. The pathogenicity of the isolates ofF. oxysporum obtained was tested in four trials carried out on lettuce cultivars of the butterhead type, very susceptible to Fusarium wilt. Nine of the 27 samples of seeds obtained from commercial seed lots used for sowing in fields affected by Fusarium wilt were contaminated byF. oxysporum. Among the 16 isolates ofF. oxysporum obtained, only one was isolated from disinfected seeds. Three of the isolates were pathogenic on the tested cultivars of lettuce, exhibiting a level of pathogenicity similar to that of the isolates ofF. oxysporum f.sp.lactucae obtained from infected wilted plants in Italy, USA and Taiwan, used as comparison. The results obtained indicate that lettuce seeds are a potential source of inoculum for Fusarium wilt of lettuce. The possibility of isolatingF. oxysporum f.sp.lactucae, although from a low percent of seeds, supports the hypothesis that the rapid spread of Fusarium wilt of lettuce observed recently in Italy is due to the use of infected propagation material. Measures for prevention and control of the disease are discussed. http://www.phytoparasitica.org posting Dec. 16, 2003.     

甘草根腐病病原菌鉴定

 甘草(Glycyrrhiza uralensis Fish.)别名甜草、蜜草、甜根子, 为豆科多年生草本植物, 以根与根茎入药, 具有补脾益气、清热解毒、祛痰止咳、缓急止痛、调和诸药之功效, 是我国临床常用的中药材, 也可用作食品添加剂。甘草主要分布在我国的内蒙古、甘肃和宁夏, 在青海、陕西、新疆、黑龙江、辽宁、吉林、河北、山西等地局部地区也有分布。宁夏盐池县是我国乌拉尔甘草的重要产区, 面积大、贮量多、品质好, 1995年被誉为“中国甘草之乡” ^[1]。近年来, 野生甘草遭到了大规模采挖, 甘草蕴藏量急剧减少, 目前主要通过人工种植来满足市场需求。随着甘草种植面积的不断扩大, 甘草病虫害日趋严重, 根腐病危害尤为突出, 直接影响甘草的产量和品质, 造成巨大经济损失。