茉莉酸甲酯对水稻白叶枯病的诱导抗性及相关防御酶活性的影响

为探索茉莉酸甲酯(methyl jasmonate,MeJA)诱导水稻抗白叶枯病的效应,采用MeJA喷雾处理剪叶接种法,测定MeJA对水稻幼苗的白叶枯病病情指数、白叶枯病病菌Xanthomonas oryzae pv.oryzae的抑菌效果及对叶片过氧化物酶(peroridase,POD)、过氧化氢酶(catalase,CAT)、超氧化物歧化酶(superoxide dismutase,SOD)、多酚氧化酶(polyphenol oxidase,PPO)和苯丙氨酸解氨酶(phenylalnaine ammonialyase,PAL)等相关防御酶活性的影响.0.05 ～ 2.0 mmol/L的MeJA能降低水稻幼苗白叶枯病的病情指数,但对水稻白叶枯病菌无直接抑菌活性;0.1 mmol/L MeJA的诱导效果最好,处理48h后,感病品种温229和抗病品种嘉早312的诱导效果分别为73.18％和70.43％;0.05 ～2.0mmol/L的MeJA处理水稻叶片中POD、CAT、SOD、PPO和PAL活性呈上升趋势.研究表明MeJA能诱导水稻幼苗对白叶枯病的抗性,且诱导抗性的产生与MeJA提高水稻相关防御酶的活性有关.     

水稻与弱毒丝核菌互作中免疫相关基因表达研究

水稻纹枯病的病原菌为立枯丝核菌(Rhizoctonia solani Kǜhn)。用10株弱毒丝核菌提前接种水稻后,再接种纹枯病病原菌,观察其发病症状,并用实时荧光定量RT-PCR方法研究了接种不同处理后的水稻9个抗性基因表达情况,筛选出参与水稻纹枯病抗病过程的基因和能使水稻提前获得系统抗性的弱毒丝核菌菌株。结果显示,参与水稻诱导抗性的抗性基因主要为PR10a、ORK10、NAC4、WRKY53、WRKY71。大部分弱毒双核丝核菌能诱导水稻抗性基因表达,诱导效果最好的弱毒丝核菌菌株是②BS-J-06-8-1、④chd-YT-3-5和⑨DL-YT-06-4-9。     

杂交稻对白叶枯病的诱导抗性与细胞内防御酶系统关系的初步研究

 在杂交稻幼苗二叶期用水稻白叶枯病弱毒菌株75-1进行诱导处理,至三叶期接种水稻白叶枯病强毒菌株76-25。结果表明:杂交稻感染白叶枯病后,苯丙氨酸解氨酶(PAL)和过氧化物酶(POX)活性升高;超氧物歧化酶(SOD)活性下降,膜脂过氧化产物丙二醛(MDA)含量增加;并且经诱导处理的变化幅度大于未经诱导处理的,抗病组合威优6号的变幅又大于感病组合汕优63。说明杂交稻抗白叶枯病及其诱导抗性与活性氧伤害及细胞内防御酶系有关。     

拮抗细菌诱导番茄植株抗灰霉病机理研究

 拮抗细菌多粘类芽孢杆菌(Paenibacillus polymyxa) W3菌株悬浮液及其滤液可以诱导番茄叶片对灰霉病(Botrytis cinerea)的系统抗性。W3及其滤液诱导处理后,植株叶内苯丙氨酸解氨酶(PAL)、过氧化物酶(POD)、多酚氧化酶(PPO)和超氧化物歧化酶(SOD)活性明显增强。诱导后1 d,PAL活性最大,是对照的3.8~3.9倍,6 d后仍为对照的2.5倍;POD和PPO诱导后3 d活性最高,分别比对照增加34.7%~54.1%和78.5%~78.7%,6 d后仍比对照高;SOD活性诱导后2d达高峰,6 d后稍高于对照。活性氧(O₂^-)产生速率诱导后1 d最大,比对照增加85.6%~88.6%,以后急剧下降,6 d后接近对照。此外,W3诱导后1 d或2 d,处理叶和上一叶位叶片水杨酸含量明显上升,分别是对照的2.6倍和1.6倍,这表明该拮抗细菌诱导的系统抗性可能与水杨酸介导有关。     

蜡质芽孢杆菌AR156防治水稻纹枯病机理初探

蜡质芽孢杆菌AR156是一种防治多种土传病害的生物制剂,对水稻纹枯病具有较好的防治效果。本研究通过温室试验方面验证菌株 AR156的防病效果和促生作用,从细胞水平和基因水平初步揭示了菌株AR156防治水稻纹枯病的机理。结果表明,菌株AR156对水稻纹枯病的温室防效达73.06%,同时促进水稻生物量增加14.45%。菌株AR156处理提高了水稻植株SOD、PAL、POD和CAT等防御酶活性,增强了OsPR1b、OsPR10、OsNPR1和ZB8等防卫相关基因的表达。接种立枯丝核菌Rhizoctonia solani HNW-21之前用菌株AR156预处理的水稻植株,SOD和PAL分别提前4、2 d出现活性峰;防卫相关基因均提前表达,且表达时间延长,从而提高水稻对纹枯病的抗性。     

防御酶系对山茶灰斑病诱导抗性的响应

为揭示水杨酸(SA)诱导山茶产生抗病性反应机制,采用琼脂平板法测定了SA对山茶灰斑病菌Pestalotiopsis guepinii ( Desm.) Stey的影响.结果表明,浓度为0～5 mmol/L的SA对该菌的生长没有抑制作用.用SA喷雾涂布叶片诱导山茶抗性,其植株内过氧化物酶(POD)、多酚氧化酶(PPO )、过氧化氮酶(CAT)、苯丙氛酸解氨酶(PAL)等防御酶时山茶灰斑病菌诱导信号有不同响应.诱导并挑战接种处理的植株体内上述酶活性比只诱导不接种处理上升速度快,不同浓度的SA诱导及诱导后挑战接种植株体内的POD,PPO,CAT,PAL活性与SA浓度呈正相关.各防御酶活性与感病指数的相关性分析表明,CAT活性与感病指数显著负相关(r = - 0.9730),除PPO与感病指数的相关系数很低外,其它酶均较高,尽管未达到显著水平,但仍说明POD,PAL在诱导山茶抗病性中具有重要作用.     

β-氨基丁酸-大黄酸耦合物的合成、生物活性及韧皮部传导性

氨基酸-农药耦合物能够改善母体农药的内吸传导性，提高农药的使用效率，减少因没有到达靶标造成的浪费及对环境的污染。本研究以天然产物大黄酸为先导化合物、以β-氨基丁酸为导向基团，设计、合成了4个目标化合物，并检测了其对6种植物病原菌的抑菌活性，以及对小麦植株苯丙氨酸解氨酶(PAL)和过氧化物酶(POD)活性的影响及在蓖麻幼苗中的韧皮部传导性。结果表明，化合物4b (浓度0.5 mmol/L)不仅对水稻纹枯病菌Rhizoctonia solani Kühn具有一定的抑制活性(菌丝生长抑制率为53.5%)，而且具有诱导抗性(持效期近7 d)和韧皮部传导性(渗出液浓度为15.1μmol/L)。该研究为兼具内吸传导性和诱导抗性杀菌剂的开发提供了新思路。     

水稻转录因子OsBTF3对不同病原菌和信号分子的基因表达反应

 转录因子基因OsBTF3在水稻品种日本晴悬浮细胞中受白叶枯病菌(Xanthomonas oryzae pv.oryzae,Xoo)诱导表达。为了阐明OsBTF3在水稻叶组织中的表达特征,本研究利用RT-Q-PCR技术,对经3种亲和性病原菌[水稻白叶枯病菌(Xoo)、水稻条斑病菌(Xooc)和稻瘟病菌(Mg)]接种和4种信号分子[脱落酸(ABA)、水杨酸(SA)、茉莉酸甲酯(MeJA)、乙烯(ETH)]诱导处理的水稻叶片中OsBTF3的转录本进行了定量分析。结果表明,OsBTF3对Xoo、Xooc和Mg侵染的基因表达反应均显著地受到诱导,但反应速度和强度略有差异。而4种信号分子对OsBTF3表达的诱导作用差异较大,ABA诱导活性最强,MeJA和ETH次之,SA诱导作用不显著。因此,OsBTF3基因表达不仅具有病原菌Xoo、Xooc和Mg的诱导性,而且也具有信号分子MeJA、ETH和ABA的应答性。     

苯并噻二唑诱发水稻对纹枯病的抗性

研究了苯并噻二唑(B1H)诱发水稻产生对纹枯病的抗性。离体条件下，1．0mmol／L BTH对纹枯病菌菌丝生长无明显抑制作用。BTH叶面或灌根处理四叶一心期水稻幼苗，并将植株第2、3和4叶离体接种纹枯病菌，水稻叶片纹枯病病斑长度明显下降，BTH诱发苗期水稻产生抗性的最佳诱导期在处理后的3—5天，最佳浓度为0．1mmol／L，BTH灌根处理诱发抗性的效果较好。用BTH溶液叶面喷雾处理成株期水稻倒二叶后离体接种纹枯病菌，倒二叶、倒一叶和剑叶上病斑长度显著低于对照，最佳诱导期在处理后3—5天。用BTH处理苗期水稻第2叶或成株期倒二叶，可使未经处理的苗期水稻第3和4叶以及成株期水稻倒一叶和剑叶上纹枯病病斑长度显著下降。     

黄绿木霉发酵液对水稻纹枯病菌作用的研究

利用黄绿木霉菌发酵液处理水稻纹枯病丝核菌,初步探讨了黄绿木霉菌发酵液对水稻纹枯病丝核菌的抑菌能力及抑菌机理。试验结果表明：黄绿木霉菌发酵液抑菌作用稳定,经121 ℃处理25 min后,抑菌率为100%; pH3～8的范围内抑菌率均为100%。经黄绿木霉菌发酵液处理的水稻纹枯病丝核菌菌丝电导率与呼吸强度几乎下降为0,光学显微镜观察到菌体形态发生变化,透射电镜下观察到细胞壁出现孔洞。用处理后的水稻纹枯病丝核菌菌丝接种水稻植株,发病率明显降低。     

我国水稻白叶枯病和条斑病发生与防控研究进展

培育和种植抗病品种和研发新型绿色杀菌剂是防治水稻白叶枯病和条斑病的有效措施。最近几年有关稻黄单胞菌Xanthomonas oryzae致病效应蛋白调控水稻抗(感)病性研究取得了突破性进展, 为水稻抗性品种培育提供了新思路、新策略。本文对稻黄单胞菌-水稻互作系统中已知的TALE效应蛋白与水稻抗(感)病基因(R 或 S)的对应关系进行了归纳, 就tal基因与水稻R或S基因的协同进化进行了分析, 结合生物农药和高效低毒杀菌剂的应用现状, 提出了我国水稻白叶枯病和水稻条斑病绿色防控关键策略。     

安徽省水稻品种对水稻白叶枯病的抗性及白叶枯病小种鉴定

为明确安徽省白叶枯病菌小种组成及常用、备用品种对该病的抗性,用白叶枯病强毒性小种FuJ和YN24、中等致病力的安徽省优势小种AH以及弱致病小种YN7对安徽省常用及备用水稻品种进行人工接种鉴定;用鉴别品种IRBB5、IRBB13、IRBB3、IRBB14、IRBB2、R24对安徽的白叶枯病菌株进行鉴定.结果表明,有3.5％的品种抗FuJ,15.4％的品种抗YN24,29.8％的品种抗AH;安徽省白叶枯病菌小种有R2、R5和R8,其中R5为优势小种.抗AH的品种可以用于安徽的水稻生产;生产中应防止FuJ和YN24等毒性强的菌株传入.     

Association of Binucleate Rhizoctonia with Soybean and Mechanism of Biocontrol of Rhizoctonia solani

ABSTRACT The association of binucleate Rhizoctonia (BNR) AG-K with soybean and the interaction of BNR, R. solani AG-4, and soybean seedlings were investigated to elucidate the mechanism of biocontrol of R. solani by BNR. Sixty-hour-old seedlings were inoculated and incubated in a growth chamber at 24 degrees C; plants were examined with light microscopy and with scanning and transmission electron microscopy at various times following inoculation. BNR grew over hypocotyls, roots, and root hairs, but only colonized epidermal cells. Hyphae of BNR appeared to attach to the epidermis and, 5.5 h following inoculation, began penetrating cells by means of penetration pegs without forming distinct appressoria or infection cushions. There was evidence of cuticle degradation at the point of penetration. Infection hyphae moved to adjacent epidermal cells by direct penetration of epidermal radial walls. There were epidermal and cortical cell necrosis, beginning with the fragmentation of the tonoplast and followed by the disintegration of cytoplasm, organelles, and plasma membranes. Cell necrosis was also observed in adjacent cells where there was no evidence of BNR hyphae. Cell walls were not destroyed. After 144 h, there was noevidence of BNR hyphae in cortical cells. Attempted penetrations were observed, but papillae formed on the inside of cortical cell walls. Pre-inoculation of soybean seedlings with BNR 24 or 48 h before inoculation with R. solani (1 cm between inocula) affected the growth of R. solani on soybean tissue. There were fewer hyphae of R. solani, the hyphae branched sparingly, and infection cushions were rare when compared with hyphal growth on soybean inoculated only with R. solani. These effects were observed before the BNR hyphae began to intermingle with the hyphae of R. solani on the surface of the inoculated host. Preinoculation of soybean seedlings 24 h before inoculation with R. solani significantly (P = 0.05) reduced disease incidence and severity caused by R. solani AG-4. The lesions caused by R. solani always appeared distally, not proximally, to the BNR inoculum. The interactions of intermingling hyphae of BNR and R. solani were examined in vitro and on the surface of the host. There was no evidence of lysis, mycoparasitism, inhibition of growth, or any other form of antagonism between hyphae. The results of these studies strongly suggest that induced resistance is the mechanism of biocontrol of R. solani on soybean by BNR. The inhibition of hyphal growth of R. solani on the surface of soybean tissue preinoculated with BNR appears to be a novel characteristic of induced resistance.     

New gene for bacterial blight resistance in rice located on chromosome 12 identified from minghui 63, an elite restorer line

ABSTRACT Bacterial blight, caused by Xanthomonas oryzae pv. oryzae, is a serious disease of rice worldwide. A new dominant gene for bacterial blight resistance in rice, Xa25(t), was identified from Minghui 63, a restorer line for a number of rice hybrids that are widely cultivated in China. This gene conferred resistance to Philippine race 9 (PXO339) of X. oryzae pv. oryzae in both seedling and adult stages. It was mapped to the centromeric region of chromosome 12, 2.5 cM from a disease resistance gene-homologous sequence, NBS109, and 7.3 cM from a restriction fragment length polymorphism marker, G1314. The genomic location of this gene is similar to the previously identified blast resistance genes, Pi-ta and Pi-ta2.     

Induction of systemic resistance byPseudomonas fluorescens Pf1 againstXanthomonas oryzae pv.Oryzae in rice leaves

When lower leaves of rice plants were inoculated with powder formulation of a saprophytic strain ofPseudomonas fluorescens, Pfl, upper leaves, in addition to the inoculated lower leaves, showed resistance to the rice bacterial blight pathogenXanthomonas oryzae pv.oryzae. When the leaves were challenge-inoculated withX. oryzae pv.oryzae 4 days afterP. fluorescens application on lower leaves, the disease intensity in upper leaves decreased from 6.7 to 1.1. When rice seeds were treated with the formulation ofP. fluorescens Pfl and sown, 30-day-old seedlings showed resistance toX. oryzae pv.oryzae and the disease intensity decreased from 6.8 to 1.2. The induced resistance was transient; leaves sprayed withP. fluorescens Pfl at 30 days after treatment and leaves of 60-day-old seedlings fromP. fluorescens-treated seeds did not show resistance to the pathogen. In field trials, seed treatment followed by foliar application of the powder formulation ofP. fluorescens Pfl effectively controlled rice bacterial blight and increased the yield. In the induced resistant leaves a sharp increase in lignification and activities of peroxidase, phenylalanine ammonia-lyase and 4-coumarate: CoA ligase was observed when the leaves were challenge-inoculated withX. oryzae pv.oryzae. An approximately threefold increase in lignin content, peroxidase activity and phenylalanine ammonia-lyase activity and a fivefold increase in 4-coumarate: CoA ligase activity were observed 5 days after challenge inoculation withX. oryzae pv.oryzae in rice leaves pretreated withP. fluorescens for 5 days. A similar increase in defense-related activities was not observed in susceptible interactions or inP. fluorescens-treated plants at later stages of interactions when no resistance to the pathogen was observed.     

水稻近等基因系与白叶枯病菌互作的生理指标研究

用抗水稻白叶枯病的近等基因在ＣＢＢ３（Ｘａ－３）、ＣＢＢ４（Ｘａ－４）、ＣＢＢ１２（Ｘａ－１２）和感病轮回亲本沈农１０３３一两个致病力不同的白叶枯病菌株７５－１、７６－２５组成非亲和性和亲和性反应的组合。以无菌水模拟接种为对照,成株期剪叶接种后分别在不同时间取样测定叶片的苯丙氨酸解氨酶（ＰＡＬ）、过氧化物酶（ＰＯ）和超氧化物歧化酶（ＳＯＤ）活性。ＰＡＬ活性在处理后４８ｈ达到高峰,且接种病菌后的酶活     

The dynamics of homologous and heterologous interactions between rice and strains of Xanthomonas campestris

Lesion development, bacterial multiplication and spread were measured in leaves of cultivars of rice containing different Xa (resistance) genes, following inoculation with different races of the bacterial leaf blight pathogen. Xanthomonas campestris pv. oryzae. Both compatible and incompatible races possessed the ability to colonize rice plants. The difference between compatible and incompatible host pathogen combinations appeared to be mainly in symptom production since multiplication rates and spread were very similar until after the onset of symptoms. No form of HR (hypersensitive response) was observed. The ability of incompatible races to modify host reaction in dual-inoculation was dependent on the genotype of the host plant. The heterologous non-pathogen of rice X. campestris pv. campestris produced few symptoms, failed either to multiply or spread within rice leaves and was unable to induce any marked cross-protection against homologous pv. oryzae strains in dual-inoculation experiments.     

Antagonistic Interactions Between Strains of Xanthomonas oryzae pv. oryzae

ABSTRACT The ability of some phytopathogenic bacterial strains to inhibit the growth of others in mixed infections has been well documented. Here we report that such antagonistic interactions occur between several wild-type strains of the rice bacterial blight pathogen Xanthomonas oryzae pv. oryzae. In mixed inoculations, a wild-type Philippine strain was found to inhibit the growth of a wild-type Korean strain. Furthermore, a nonpathogenic mutant of the Philippine strain maintained these antagonistic properties. Growth curve analysis indicated that both the wild-type Philippine strain and its nonpathogenic mutant inhibited the growth of the Korean strain 2 days after infection and prior to the onset of disease symptoms. When mixed with the nonpathogenic mutant, 10 out of 18 diverse wild-type X. oryzae pv. oryzae strains did not cause disease. Conversely, three of the strains that were not affected by the nonpathogenic mutant were found to inhibit the growth of both the wild-type and mutant Philippine strains, indicating that antagonism is widespread and strain specific. The observed growth inhibition occurred only in planta and did not correlate with bacteriocin activity in vitro. Antagonistic interactions also were found to affect resistance (R) gene-mediated resistance. The R gene Xa21 was capable of protecting rice plants coinoculated with nonantagonistic virulent and avirulent strains; however, when avirulent strains were coinoculated with virulent antagonistic strains, disease ensued. Taken together, these results indicate that X. oryzae pv. oryzae has evolved strategies to compete with rival strains in a fashion that allows virulent strains to evade R gene-mediated protection even when avirulent strains are present in the inoculum.