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1.
小麦雪霉叶枯病菌的侵染过程 总被引:7,自引:0,他引:7
本文报道了小麦雪霉叶枯病菌Gerlachia nivalis的叶面侵染过程。该菌分生孢子发芽后相互结合,形成网状复合体,产生粗壮的叶面菌丝,经由气孔保卫细胞间隙侵入,不产生特化的侵染机构。侵染菌丝在叶肉细胞间和细胞内扩展,也可由气孔逸出在叶面蔓延。分生孢子梗由分生孢子座上产生,由气孔抽出。产孢细胞顶端有环痕。叶面菌丝亦能产孢。寄主组织病变特点表明该菌产生活性很强的胞外酶。 相似文献
2.
辽宁省玉米纹枯病病原学研究 总被引:29,自引:2,他引:27
从辽宁省各地分离到93个玉米纹枯病菌株,经菌丝融合测定,结合培养性状及酯酶同工酶谱带比较,首次明确了辽宁省玉米纹枯病菌的主要菌丝融合群为Rhizoctonia solani AG1-IA。致病性测定表明:R. solani AG1-IA是辽宁省玉米纹枯病的主要致病菌,其中以丹东RS-9501菌株的致病力最强;品种间存在抗性差异,沈试28最抗病,沈试29最感病。研究发现不同生育期的玉米下位叶鞘对纹枯病菌的抗性存在差异,按拔节期-抽雄期-吐丝期顺序递减,这种趋势在第7叶位上表现较第3叶位明显。此外,还从碳源、氮源,VB1,温度,pH值,病菌存活力和腐生定殖能力6方面研究了玉米纹枯病菌的生物学特性。 相似文献
3.
多堆柄锈菌侵染玉米的细胞学及超微结构特征 总被引:2,自引:1,他引:1
为明确玉米对多堆柄锈菌Puccinia polysora侵染后病理反应的细胞学特征,利用扫描和透射电镜技术分析了玉米自交系与多堆柄锈菌互作中二者的细胞变化过程。多堆柄锈菌对玉米的侵染主要以直接穿透叶片表皮侵入为主,少量可从气孔和细胞间隙侵入。接种后,病菌夏孢子在感病自交系叶片上快速并大量萌发,在叶表生长蔓延并侵入表皮组织细胞,7 d后形成夏孢子堆;在抗病自交系上,病菌萌发、菌丝生长均受到明显抑制,少量入侵的病菌也由于寄主细胞死亡而导致菌丝和夏孢子干瘪死亡。侵染早期在感病寄主细胞间隙出现菌丝并穿透细胞壁,在胞内产生分枝菌丝,此时寄主细胞结构正常;随着菌丝进一步扩展,叶绿体等结构发生紊乱,被侵染细胞逐渐死亡。在抗病自交系上,接菌24 h后寄主即出现过敏性坏死反应,侵入位点与周围细胞快速坏死,抑制菌丝生长蔓延;叶绿体中清晰可见深色颗粒状物质;72 h后细胞壁外侧产生大量致密的深色结晶体,应为与抗病反应相关的酚类物质。表明抗多堆柄锈菌的玉米材料可能存在2种抗病途径,即寄主与病菌互作中由分子识别引起的免疫反应和病菌侵入后的系统防卫反应。 相似文献
4.
本文报道了通过微分干涉衬显微镜、荧光显微镜及扫描电镜和透射电镜所观察到的菜豆锈菌的侵入和扩展过程。菜豆锈菌夏孢子萌发多产生1个芽管,偶尔也产生双芽管。芽管以气孔侵入为主,也可从表皮直接侵入。侵入前形成或不形成明显的附着胞。气孔侵入的芽管首先在气孔腔内形成气孔下囊,再进一步分化出圆形的膨大体,由膨大体产生1~2支初生菌丝。初生菌丝与叶肉细胞壁接触后分化出吸器母细胞,吸器母细胞进入叶肉细胞内部形成吸器。初生侵染菌丝在产生吸器母细胞的部位的后部产生分枝,形成次生侵染菌丝在叶肉细胞间蔓延。 相似文献
5.
球毛壳ND35菌株在宿主植物上的侵染定殖 总被引:3,自引:2,他引:1
为了解球毛壳Chaetomium globosum ND35菌株在宿主植物上的侵染定殖方式和途径,以毛白杨组培苗为宿主植物,借助光学显微镜、扫描电镜、透射电镜,结合免疫荧光标记技术,研究了球毛壳ND35菌株子囊孢子萌发后在毛白杨上的侵染行为及其菌丝在组培苗根部的定殖。结果显示,子囊孢子萌发后形成的菌丝,能从杨树苗根、茎部表面细胞间的缝隙侵入或在根表面形成附着胞,进而形成侵染钉直接从表皮细胞侵入,在叶部主要从气孔侵入叶片内部。侵入根部的菌丝主要定殖于表皮细胞、外皮层细胞和细胞间隙,未进入内皮层和维管束组织。 相似文献
6.
玉米丝黑穗病原菌侵染的一些细胞学研究 总被引:7,自引:1,他引:7
在玉米生育早期,以幼芽鞘为材料,对11个抗病性不同的自交系进行了研究。玉米丝黑穗病原菌[Sphacelotheca reiliana (Kühn) Clint var.zeae Pass]可在玉米幼芽鞘内表皮上生长和繁殖;其侵染菌丝可直接侵入表皮细胞或通过气孔进入寄主体内。菌丝的侵入诱导了芽鞘内表皮细胞的细胞壁、细胞质和细胞膜特性的异常变化;抗性不同的自交系对病原菌侵入的反应不同,揭示了在生育早期玉米芽鞘细胞就表现了其固有的抗病性。 相似文献
7.
青杨叶锈病菌(Melampsora larici-populina Kleb.)侵染过程的超微结构研究 总被引:3,自引:0,他引:3
采用电子显微镜技术对青杨叶锈病菌(Melampsora larici-populina Kleb.)的侵染过程进行了研究。发现该菌夏孢子萌发产生1~3个芽管,且具较多的树杈状分枝。芽管由气孔侵入,侵入前不形成明显的附着胞或仅个别芽管形成附着胞。芽管侵入气孔后在气孔腔内形成气孔下囊,再分化出圆形的膨大体而产生1~2支初生菌丝。初生菌丝在寄主细胞间扩展,与叶肉细胞壁接触后分化出吸器母细胞,吸器母细胞中的细胞器与胞间菌丝相同,双核。吸器母细胞产生侵入钉侵入叶肉细胞内部形成吸器,成熟吸器由细长具颈环的管状颈部和膨大的吸器体组成,此时胞间菌丝在吸器母细胞处分化出次生菌丝,在叶肉细胞间扩展形成次生菌落,产生孢子堆。病菌在寄主细胞间隙或沿寄主细胞壁延伸时,寄主细胞仍保持正常状态。 相似文献
8.
多堆柄锈菌侵染不同抗性玉米的组织病理学研究 总被引:2,自引:0,他引:2
[目的] 了解不同抗感玉米自交系对南方锈病的组织病理学反应,为今后筛选不同类型抗病自交系提供参考。[方法] 采用曲利苯蓝透明染色法,以4个玉米自交系为材料,研究了玉米南方锈病致病菌—多堆柄锈菌在不同抗性材料上侵染过程的组织学特征。[结果] 多堆柄锈菌侵入和定殖可以分为5个阶段:孢子萌发与芽管形成、附着胞形成、侵入细胞、胞内吸器产生、菌丝在细胞间扩展。在不同抗性的玉米材料上,病菌孢子萌发和芽管形成差别不明显,但侵入后病菌在不同抗性材料内的发育进程和发育程度具有显著差异。在抗病玉米材料上,病菌初生菌丝、吸器母细胞、次生菌丝的形成时间推迟,胞内吸器少,菌丝分枝少,菌丝生长缓慢。[结论] 这些抗性特征与田间表现出的细胞过敏性坏死、叶片上夏孢子堆少的特征具有一致性。 相似文献
9.
玉米叶片受新月弯孢菌侵染后的细胞病理学变化 总被引:6,自引:0,他引:6
本文利用透射电子显微镜技术与细胞化学技术研究了玉米叶片受弯孢菌侵染后的超微结构和细胞壁的组成成份变化。透射电镜观察发现,病菌侵入后,菌丝先在寄主细胞间扩展,随着寄主细胞病变、坏死,菌丝可进入寄主细胞形成胞内菌丝。随病菌侵入和在寄主体内扩展,寄主细胞先后发生了一系列的超微结构变化,叶绿体、液泡等细胞器解体,出现质壁分离现象,并最终解体、坏死、变形。细胞化学标记定位发现,受侵寄主细胞壁中纤维素、木聚糖和果胶质的标记密度明显低于未接种的健康组织,表明细胞壁降解酶(如纤维素酶、木聚糖酶和果胶酶)的产生与病菌侵染和致病过程密切相关。 相似文献
10.
核盘菌侵入油菜超微结构及侵染机制的研究 总被引:8,自引:0,他引:8
通过电子显微镜观察核盘菌在油菜叶片上侵染过程,发现该菌首先在叶片上形成复合附着器。每个分枝末端一般生出一个侵染钉。侵染钉侵入叶表面腊质、角质层和表皮细胞壁时.不仅靠附着器产生的压力,而且供助于酶对寄主表面的软化、消解作用。该菌通过角质层和表皮细胞壁侵入油菜叶片,尚未发现通过气孔侵入的现象。侵入叶片后,该菌的继续生长,导致了油菜组织的溃烂。然后菌丝在腐烂的叶片上集结形成菌核。 相似文献
11.
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. 相似文献
12.
Infection cushions were formed by isolates of Rhizoctonia solani , anastomosis group 1 IA (AG-1 IA, aerial blight) and AG-1 IB (web blight) on leaves of all 10 soybean cultivars tested. Isolates of AG-1 IA and IB did not form infection cushions on soybean leaf surface replicas of either resistant or susceptible cultivars. More infection cushions were formed by isolates of AG-1 IA and IB on collodion membranes placed over leaves of susceptible cultivars compared with resistant cultivars. Isolates of AG-1 IC. AG-4 and AG-5, also formed infection cushions on soybean leaves. However, the isolates of other anastomosis groups did not form infection cushions on soybean leaves. Differential induction of infection cushion formation by the leaves of various plant species was observed, AG-1 IA formed infection cushions on more graminaceous hosts than AG-1 IB, Our results suggest that a chemical stimulus is needed for infection cushion formation. Glucose and 3- O -methylglucose repressed disease severity caused by AG-1 IA and IB isolates to the same extent. Disease severity and the number of infection cushions formed on leaves of ten soybean cultivars were correlated. Fewer infection cushions were formed on resistant cultivars than on susceptible cultivars. 相似文献
13.
Isolates representing 11 anastomosis groups (AGs) of Rhizoctonia solani from various geographic locations and host plants were tested for virulence on soybean leaves at 15, 20, 25, 30, and 35°C, and on soybean seedlings at 20, 25, and 30°C. Numbers of infection cushions formed on soybean leaves were determined using light microscopy. Isolates of AG-1 IA, AG-1 IB and AG-5 were more virulent on soybean leaves at 20, 25, and 30°C than isolates of AG-1 IC and AG-4. Maximum numbers of infection cushions were formed on soybean leaves by AG-1 (IA, IB, and IC), AG-4, and AG-5 at 25 and 30°C. The other AGs tested did not form infection cushions on soybean leaves although some caused minimal disease severity. Isolates of AG-1 IA formed significantly more infection cushions and caused greater disease severity than AG-1 IB and other isolates at 35°C. Maximum seedling infection, based on per cent area of hypocotyl region covered by lesions occurred at 25 C for AG-1 (IA, IB, and IC) and AG-4. Isolates of AG-5 caused greater seedling infection at 20°C than at 25 and 30°C. The other AGs tested caused only minimal damage to the seedlings. Isolates of AG-4 and AG-5 are not known to cause Rhizoctonia foliar blights of soybean in Louisiana, but their potential to be destructive foliar pathogens is confirmed. 相似文献
14.
Northern leaf blight is a lethal foliar disease of maize caused by the fungus Exserohilum turcicum. The aim of this study was to elucidate the infection strategy of the fungus in maize leaves using modern microscopy techniques and to understand better the hemibiotrophic lifestyle of E. turcicum. Leaf samples were collected from inoculated B73 maize plants at 1, 4, 9, 11, 14 and 18 days post-inoculation (dpi). Samples were prepared according to standard microscopy procedures and analysed using light microscopy as well as scanning (SEM) and transmission electron microscopy (TEM). Microscopic observations were preceded by macroscopic observations for each time point. The fungus penetrated the leaf epidermal cells at 1 dpi and the disease was characterized by chlorotic leaf flecks. At 4 dpi the chlorotic flecks enlarged to form spots, and at 9 dpi hyphae were seen in the epidermal cells surrounding the infection site. At 11 dpi lesions started to form on the leaves and SEM revealed the presence of hyphae in the vascular bundles. At 14 dpi the xylem was almost completely blocked by hyphal growth. Hyphae spread into the adjacent bundle sheath cells causing cellular damage, characterized by plasmolysis, at 18 dpi and conidiophores formed through the stomata. Morphologically, lesions started to enlarge and coalesce leading to wilting of leaves. This study provides an updated, detailed view of the infection strategy of E. turcicum in maize and supports previous findings that E. turcicum follows a hemibiotrophic lifestyle. 相似文献
15.
Aetiology of Rhizoctonia in sheath blight of maize in Sichuan 总被引:1,自引:0,他引:1
Rhizoctonia isolates obtained from maize grown in commercial fields in 33 representative counties (or cities) in Sichuan province in China were characterized according to colony morphology, hyphal anastomosis and pathogenicity. Of 141 isolates, 116 were identified as R. solani , 23 as R. zeae and two as binucleate Rhizoctonia . The isolates of R. solani were assigned to four anastomosis groups (AG): AG-1-IA (101 isolates, accounting for 71.6% of the total), AG-1-IB (2, 1.4%), AG-4 (9, 6.4%) and AG-5 (4, 2.8%). The two isolates of binucleate Rhizoctonia belonged to AG-K. On maize, isolates of AG-1-IA caused typical sheath blight symptoms. Lesions produced by isolates of AG-4, AG-5, AG-1-IB and AG-K were darker than those of AG-1-IA. Rhizoctonia zeae usually caused discontinuous lesions with a dark brown margin and a brown centre on the leaf sheaths, as well as ear rot. Isolates of AG-1-IA were the most virulent to maize, with an average lesion length of approximately 15 cm. Isolates of R. zeae produced lesions approximately 12 cm long, while those of AG-4, AG-5, AG-1-IB and AG-K were progressively shorter. On potato dextrose agar (PDA; pH 6.4), the minimum temperature for mycelial growth of R. zeae isolates was 14–18°C, the maximum 38–40°C and optimum 30°C. Isolates of R. zeae did not grow on PDA (28°C) at pH 2.0, the optimum for growth being pH 6.4. 相似文献
16.
Serratia marcescens strain B2 is an antagonistic bacterium that produces the red-pigmented antibiotic prodigiosin and suppresses rice sheath blight caused by Rhizoctonia solani AG-1 IA. Rice sheath blight disease was suppressed when plants were inoculated with this bacterium an hour before pathogen inoculation but not when plants were treated 4 weeks before pathogen inoculation. In both cases the bacteria were detected in the rice rhizosphere 4 weeks after inoculation. Bacteria isolated from the rice plant and rhizosphere inhibited biosynthesis of prodigiosin in S. marcescens strain B2. We suggest that bacteria isolated from rice plants and rhizospheres mediate the suppression of antibiotic production of biological control agents and that such suppression is common under field conditions. 相似文献
17.
The mode of action of acibenzolar-S-methyl (BTH) was investigated against sheath blight of rice and its pathogen, Rhizoctonia solani. BTH exhibited limited fungitoxicity against R solani, in the form of reduced mycelial growth, hyphal browning and sclerotia formation. Parasite fitness of mycelia and sclerotia formed on BTH-amended media was also reduced. When applied as soil drench or foliar spray, BTH inhibited both disease development on inoculated sheaths and its spread to the younger sheaths. The degree of protection against sheath blight increased with increase in duration between BTH application and inoculation. The curative effect of BTH was poor. When applied through roots a protective effect of BTH was visible even with only a 1-h interval between application and inoculation. However, in the case of foliar application, protective effect was recorded only when the gap between application and inoculation was 24 h. BTH reduced the frequency of penetration by R solani, colonization of host tissue and spread of the hyphae from primary lesions to form secondary lesions. BTH induced swelling of hyphal tips on the sheath surface, formation of papillae, browning of penetrated epidermal cells and degeneration of intra-cellular hyphae colonizing epidermal and mesophyll cells. Therefore, the protective effect of BTH against sheath blight was due to combination of its host defence-inducing activity and its adverse effect on growth and vigor (parasite fitness) of the pathogen. 相似文献
18.
Ya-Li Fang Yao-Yao Zhou Xin Li Yue Gao De-Long Wang Min-Jie Liu Zhi-Jia Zhang 《Plant pathology》2022,71(2):251-261
Northern corn leaf blight (NCLB) caused by Setosphaeria turcica is a major foliar disease of maize. The early-stage infection events of this pathogen on maize leaves are unclear. We investigated the optimum temperature for conidial germination and appressorium formation, and characterized penetration and growth of S. turcica in maize leaf sheath and onion epidermis cells, including use of histological staining to assess plant cell viability. The results showed that the optimum temperature for conidial germination and appressorium formation was 20°C. On the maize leaf sheath, the appressoria were formed by germinated conidia, and penetration on the epidermal cells occurred at 8 h postinoculation (hpi). Round vesicles developed beneath the appressoria. Between 16 and 24 hpi, the branched invasive hyphae invaded three to five adjacent cells at most infection sites. The invasive hyphae tended to move along the cell wall and crossed from one cell to another. In the onion epidermis cells, the appressoria formed at 8 hpi, and in most cases the epidermal cells were penetrated through the juncture of the cell walls. At 16–24 hpi, the primary hyphal terminus swelled to a vesicle. The maize leaf sheath cells died at 8 hpi, whereas the onion cells did not. Our findings documented in detail the penetration and invasive hyphal growth in maize leaf sheath and onion epidermis, as well as viability of plant cells, at the early stages of infection, and provide a foundation for elucidating the underlying mechanism of S. turcica–maize interactions. 相似文献
19.
Variation in the early development of Bremia lactucae on lettuce cultivars with different levels of field resistance 总被引:1,自引:1,他引:0
The early stages of development of Bremia lactucae (lettuce downy mildew) were examined on lettuce cultivars possessing high (Iceberg and Regina di Maggio) and low (Great Lakes and Plenos) levels of field resistance. Germ tubes, appressoria, penetration, primary and secondary vesicles, intercellular hyphae and haustoria were observed 3. 6 and 24 h after inoculation of cotyledons and of leaf discs from adult plants. Differences were observed between cv. Iceberg and susceptible genotypes in the percentage of spores germinating and the incidence and speed of development of infection structures. Secondary vesicles were first observed 24 h and 6 h after inoculation in Iceberg and susceptible genotypes, respectively. The lowest incidence of secondary vesicle formation 24 h after inoculation (48 and/or 43%) was recorded in Iceberg and Regina di Maggio, and the highest incidence (68%) occurred in Plenos. The formation of intercellular hyphae and haustoria was not observed in cv. Iceberg some 24 h after inoculation. There were significant differences in the lengths of germ tubes formed on different cultivars. Those on cv. Iceberg were longer than those formed on susceptible cultivars. The results indicate that the field resistance of B. lactucae may result from mechanisms which are effective in the early stages of infection. 相似文献
20.
拮抗内生细菌B20-006菌株对玉米主要防御酶系的影响 总被引:14,自引:0,他引:14
笔者通过对玉米纹枯病拮抗内生细菌筛选研究发现,利用拮抗内生细菌B20-006进行种子包衣处理,对玉米纹枯病的防效最高达67.9%。同时通过抗利福平B20-006突变菌株回接再分离及利用免疫胶体金银染色技术证明,B20-006菌株可通过根系侵人,具有沿维管束进行转运的能力。为进一步明确其生防机理,本文系统研究了B20—006菌株与宿主玉米相互作用过程中主要防御酶系苯丙氨酸解氨酶、过氧化物酶、超氧化物歧化酶及酯酶等的比活性变化。 相似文献