苜蓿假盘菌侵染苜蓿叶片的细胞学研究

采用微分干涉相差显微镜、扫描和透射电镜技术系统研究了苜蓿假盘菌Pseudopeziza medicaginis在苜蓿叶片的侵染过程及超微结构特征。结果表明,接种4h后,子囊孢子萌发产生芽管;12h后,芽管以直接侵入的方式进入表皮细胞形成侵染菌丝;24h后,表皮细胞中侵染菌丝向相邻表皮细胞扩展,同时侵入到叶肉细胞以胞内生长方式扩展;接种72h后,侵染菌丝在表皮细胞下的叶肉组织中形成初始菌落;第5d后,菌丝扩展至整个叶片组织,大量菌丝聚集形成子座组织,并进一步形成子囊盘与子囊。病菌菌丝在侵入寄主细胞初期,并不穿透寄主质膜与原生质,而是被其所包围。但随着菌丝进一步扩展,叶片组织发生了一系列的病理变化,其中包括叶肉细胞肿胀、细胞质消解、叶绿体等细胞器解体以及寄主细胞坏死塌陷,并最终在叶表面产生典型的褐斑病症状。     

苜蓿假盘菌侵染苜蓿叶片的细胞学研究

采用微分干涉相差显微镜、扫描和透射电镜技术系统研究了苜蓿假盘菌Pseudopeziza medicaginis在苜蓿叶片的侵染过程及超微结构特征。结果表明,接种4h后,子囊孢子萌发产生芽管：12h后,芽管以直接侵入的方式进入表皮细胞形成侵染菌丝：24h后,表皮细胞中侵染菌丝向相邻表皮细胞扩展,同时侵入到叶肉细胞以胞内生长方式扩展：接种72h后,侵染菌丝在表皮细胞下的叶肉组织中形成初始菌落;第5d后,菌丝扩展至整个叶片组织,大量菌丝聚集形成子座组织,并进一步形成子囊盘与子囊。病菌菌丝在侵入寄主细胞初期,并不穿透寄主质膜与原生质,而是被其所包围。但随着菌丝进一步扩展,叶片组织发生了一系列的病理变化,其中包括叶肉细胞肿胀、细胞质消解、叶绿体等细胞器解体以及寄主细胞坏死塌陷,并最终在叶表面产生典型的褐斑病症状。     

落叶松-杨栅锈菌在感病杨树寄主上发育过程的组织学研究

采用荧光染色技术、光学显微镜和电子显微镜技术,系统研究了落叶松-杨栅锈菌在感病杨树叶片上的发育过程。结果表明,在侵染前期（接种12h以内）,锈菌夏孢子在杨树叶片上萌发,利用芽管或附着胞穿透叶表气孔后形成气孔下囊,进而在胞间产生侵染菌丝。进入活体营养生长阶段（接种后24-96h）,锈菌不断产生大量吸器来满足营养需求的同时,侵染菌丝在叶肉细胞间隙蔓延分枝生长至形成菌落结构。最终在产孢阶段（接种120h之后）产孢菌丝分化形成的夏孢子在表皮下聚集成堆,待成熟后突破表皮显露出来。     

小麦叶锈菌侵染过程的显微和超微结构

采用光学显微技术和电子显微技术对小麦叶锈菌的侵染过程进行了研究。发现叶锈菌从气孔侵入后在气孔腔内形成气孔下泡囊,然后分化出圆形的膨大体,由膨大体产生1—2初生菌丝,初生菌丝在寄主细胞间隙延伸扩展,与叶肉细胞壁接触后分化形成吸器母细胞,吸器母细胞进入寄主细胞后形成吸器。初生菌丝在吸器母细胞处产生分枝,形成次生菌丝在叶肉细胞间蔓延。在病原菌侵染早期(接种后8—24h),寄主细胞的超微结构变化并不明显。侵染中、后期(接种48—72h),被侵染叶肉细胞发生严重质壁分离,叶绿体膨胀变形,基粒片层排列疏松。线粒体嵴突退化。     

冠盘二胞Marssonina coronaria侵染不同抗性苹果叶片的组织病理学研究

利用光学和电子显微镜,从组织细胞学水平系统研究了冠盘二胞Marssonina coronaria在苹果抗、感病品种叶片上的侵染过程及侵染后寄主细胞的超微结构特征。结果表明：冠盘二胞的侵入和定殖过程可以分为6个阶段：孢子萌发与芽管形成、附着胞形成、侵入细胞角质层、在叶肉细胞内产生吸器、菌丝在叶肉细胞间和细胞内扩展、分生孢子盘形成。随着菌丝扩展,受侵寄主细胞出现细胞壁加厚,细胞壁降解,质壁分离,叶绿体内淀粉粒、嗜饿颗粒积累,叶绿体基粒片层瓦解,线粒体空泡化等现象。在不同抗性的苹果品种上,分生孢子萌发率差别不明     

柿树炭疽菌侵染不同柿树种、品种和部位的细胞学特征

用柿树炭疽病菌Colletotrichumgloeosporioides的分生孢子制备孢子悬浮液,接种无核柿、野柿、冬柿和浙江柿的新梢、叶柄和叶片,并观察致病性、附着胞形成和侵染特性。柿树炭疽菌可以侵染无核柿枝条和叶柄以及野柿枝条,但不侵染无核柿叶片、野柿叶柄和叶片,也不侵染冬柿和浙江柿枝条、叶柄和叶片。室内接种试验与田间自然发病结果一致。柿树炭疽菌在不同柿树表面均能形成附着胞,附着胞产生在寄主表皮背斜细胞壁间结合处(JACWs)或近结合处的百分率达81%~93%。接种12h后,不同柿树表面都有附着胞形成;36h后,无核柿枝条、叶柄中有侵染菌丝存在;48h后,无核柿枝条、叶柄中观察到膨大初生菌丝和较细次生菌丝,初生菌丝可扩展到相邻细胞中,而野柿枝条中仅观察到侵染菌丝;60h后,野柿枝条中也观察到膨大的初生菌丝和较细的次生菌丝,但初生菌丝仅局限在最初侵染的细胞中,无核柿枝条和叶柄以及野柿枝条中都有分枝的次生菌丝在细胞内、细胞间或相邻的细胞中扩展;直到接种90h后,在冬柿和浙江柿上都未观察到侵染菌丝的形成。结果表明,柿树炭疽菌在不同柿树种和品种上侵染菌丝的形成和扩展方式可能是其寄主专化性(或致病性)差异的重要机制之一。     

短柄草柄锈菌在感病寄主二穗短柄草上发育过程的组织学研究

本研究采用荧光染色和荧光显微镜技术,系统研究了短柄草柄锈菌Puccinia brachypodii (分离系F-Co和K-Ki)在感病二穗短柄草Brachypodium distachyon自交系Bd21-3叶片中的发育过程。荧光显微镜观察结果表明,接种12-18 h时,病原菌通过芽管侵入短柄草叶表皮气孔后形成气孔下囊,产生初生菌丝并形成吸器母细胞,进而侵入植物细胞形成吸器;接种24-48 h后,病原菌初生菌丝分支并形成次生菌丝;接种72 h后,短柄草锈菌开始形成菌落。F-Co的发育过程快于K-Ki,在120-216 h时,F-Co的菌落扩展面积明显高于K-Ki。本研究证实F-Co、K-Ki和二穗短柄草均为亲和互作。     

指状青霉Penicillium digitatum侵染柑橘果实的细胞学研究

采用电子显微镜技术系统研究了指状青霉Penicillium digitatum对柑橘果实的侵染过程及超微结构特征。结果表明室温条件下,接种12h后,伤口附近的分生孢子开始萌发产生芽管;然后从伤口处直接侵入果实表皮细胞内;接种24h后,受侵染果实细胞中的菌丝向相邻细胞扩展蔓延,寄主细胞壁开始消解,质壁分离,细胞内含物及各类细胞器凝集,颜色加深,最后完全消解,伤口部位的果皮开始变软,伤口处的菌丝向外生长;84h后伤口处病斑软化,部分长出白色的霉层;96h后病斑软化面积直径达3cm,白色霉层面积逐渐扩大;120h后白色霉层中间伤口处霉层颜色加深变为灰绿色;144h后整个果实变软腐烂。果胶质标记结果表明,菌丝侵入果实后产生果胶酶并降解柑橘细胞壁中的果胶,使得细胞壁松弛,软化腐烂。     

秦冠苹果品种对苹果黑星病的组织学抗性研究

为揭示苹果抗病品种秦冠在组织细胞学水平上抗苹果黑星病的特征,本研究采用扫描和透射电镜技术,将苹果黑星菌Venturia inaequalis接种侵染寄主后,系统观察抗病品种秦冠和感病品种嘎啦的叶片组织和细胞结构变化。扫描电镜观察结果表明,黑星菌分生孢子悬浮液接种秦冠和嘎啦叶片48 h后,病菌沿叶脉生长扩展,其菌丝可从叶片气孔或直接侵入。透射电镜观察结果表明,秦冠叶片的角质层厚度明显高于嘎啦,其中秦冠角质层平均厚度为1.75 μm,嘎啦为1.06 μm。透射电镜观察结果表明,黑星菌菌丝在寄主叶肉细胞间扩展,导致嘎啦栅栏组织细胞萎缩,排列松散,叶绿体变形受损,细胞内出现较大淀粉粒和胞内物质外渗流失,并在后期发展成大量细胞坏死;而秦冠虽症状类似,但受损程度明显小于嘎啦。以上结果表明,秦冠在组织细胞学上对苹果黑星病具有抗侵染、抗扩展和延缓病程发展的作用,可作为苹果黑星病抗性育种材料加以利用。     

尖角突脐孢菌在稗草和水稻上的萌发和侵染行为比较研究

本试验结合曲利苯兰和荧光素钠两种染色方法的优点,从显微角度研究了尖角突脐孢菌(Exserohilum monoceras)两个菌株X-27和HN-14在稗草和水稻上萌发和侵染行为的差异。结果表明,在寄主稗草上,接种4h后尖角突脐孢菌孢子开始从一端或两端萌发形成初生芽管;10h后芽管顶端膨大形成附着胞,附着在寄主表面,两端萌发的孢子约90%一端败育,仅一端形成成熟附着胞;在接种后24h内成熟附着胞形成率与接种时间成正相关,24h后趋于稳定;16h后在成熟附着胞下方受侵染的细胞内指状吸器开始形成,随后发育为掌状吸器;接种36h后菌丝在组织表面扩展形成网状,同时稗草叶片上显现叶斑病症状,部分菌丝能在细胞间蔓延扩展。在非寄主植物水稻上,同样观察到孢子萌发产生芽管,但是萌发起始时间滞后大约4h,初生菌丝分枝明显减少,且未能观察到附着胞和吸器的产生。     

Penetration of Phytophthora cinnamomi into disease tolerant and susceptible eucalypts

The mechanisms of penetration of Phytophthora cinnamomi Rands into seedling eucalypt roots were studied by light and electron microscopy. Culture grown seedlings of root-rot tolerant Eucalyptus st johnii and root-rot susceptible Eucalyptus obliqua were inoculated with both zoospores and mycelium. Zoospores encysted on roots of both species and the germ tubes penetrated without the formation of appressoria. Swellings, previously described as appressoria, were formed when the germ tube was slow to enter the host by intracellular penetration. Vegetative hyphae penetrated both inter- and intracellularly into the zones of root elongation and differentiation, often through root hairs. Evidence of hydrolysis of the host cell-wall at the point of penetration was observed in electron micrographs. Several hours after the germ tube penetrated the epidermis, a thick plug of amorphous material formed in the germ tube slightly below the level of the outer walls of the epidermal cells, sealing off the hypha within the root. Behaviour of zoospores and germ tubes and the mechanism of penetration were similar on both hosts. Micrographs do not suggest any kind of a hypersensitive reaction by the host cells during the early stages of infection.     

Infection Process of Plectosporium tabacinum on False Cleavers (Galium spurium)

A native fungus, Plectosporium tabacinum (van Beyma) M. E. Palm, W. Gams et Nirenberg, has potential as a bioherbicide for the control of both herbicide-resistant and herbicide-susceptible false cleavers. Limited information is available on the infection process of P. tabacinum. P. tabacinum spore distribution pattern, germination, penetration, and colonization on false cleavers leaves were examined using confocal, light, and scanning electron microscopy. The results demonstrated that conidia were distributed over the entire surface of leaves and cotyledons. More than 90% of the conidia germinated on the leaf surface 6-8 h after inoculation. Penetration of the leaf epidermis by conidia started 8-10 h after inoculation. Histological observation showed that no appressoria were formed by P. tabacinum, but its hyphae produced appressed club-like structures that penetrated the cuticle and epidermal layers. No stomata or other natural openings were observed on the upper leaf surface of false cleavers seedlings. Penetration occurs directly on epidermal cells with more frequent intercellular penetrations. Hyphal penetration was visualized at a depth of 30 and 40 üm after 8 and 16 h of incubation, respectively. Secondary hyphae colonized mesophyll cells 16 h after inoculation. Even spore distribution, short spore germination time, club-like infection structure formation, direct penetration, quick colonization, and mucous secretion on false cleavers leaves may contribute to the kill of false cleavers by P. tabacinum. Slow spore germination and germ tube growth, low spore germination numbers, and no infection structure formation on Brassica napus leaves may be factors affecting the host selectivity of P. tabacinum.     

Studies on turfgrass snow mold caused byTyphula ishikariensis. II. Microscopical observation of infected bentgrass leaves

Light and transmission electron microscopy revealed thatTyphula ishikariensis penetrated into bentgrass leaves either through cuticles or stomata either by single hyphae or infection cushions formed on host surfaces. Time course study on infected leaves showed that penetration through stomatal subsidiary cells and their adjacent cells seemed to occur earlier than that through epidermal cells located farther from stomata. More than 30% of epidermal cells were infected by 10 days after inoculation. When hyphae penetrated through an intact cuticle of epidermal cells, they seemed to dissolve host cell walls enzymatically at penetration sites. Physical pressure also seemed to be involved in penetration.     

柿树炭疽菌侵染寄主的细胞学研究*

超微结构研究表明,柿树炭疽菌(Colletotrichum gloeosporioides)侵染后在寄主细胞中形成初生菌丝和次生菌丝,寄主细胞膜外沉积了一层厚的电子不透明物质,初生菌丝与具有沉积物的寄主原生质膜之间有一层界面基质(interfacial matrix)。当初生菌丝扩张并侵染相邻细胞时, 围绕着初生菌丝层的界面基质消失,具有沉积物的原生质膜被逐步降解。初生菌丝在穿透寄主细胞壁过程中形成一个漏斗状的菌丝锥,然后穿透寄主细胞壁并迅速膨大, 然后形成厚壁的初生菌丝。初生菌丝在寄主细胞壁中收缩狭窄处产生一个隔膜,隔膜两边菌丝中细胞质的电子密度明显不同,菌丝锥中有浓密的电子密度。死体营养的次生菌丝在死的细胞中繁殖和扩展,并产生分枝。次生菌丝可直接穿透较薄的寄主细胞壁,无缢缩或任何变形现象,菌丝顶端部分未见隔膜产生;在穿透较厚的细胞壁时,靠近顶端处产生隔膜,顶端细胞膨大,使寄主细胞壁撕裂。接种90h后分生孢子盘在枝条表面形成。柿树炭疽菌其侵染过程有两个阶段,即初生菌丝的活体营养阶段和次生菌丝的死体营养阶段。     

Compared Anatomy of Young Leaves of Prunus persica (L.) Batsch with Different Degrees of Susceptibility to Taphrina deformans (Berk.) Tul

Anatomical observations of leaves infected by Taphrina deformans were studied in tolerant peach trees (TPT) and in very susceptible (VSPT) ones. Leaves from the first sampling (2nd April) showed hyphae penetrating through the stomata or into the cuticle of the host tissue; anatomical structures of leaf sections were similar for both TPT and VSPT. The ultrastructure of the leaves of TPT showed seemingly normal mesophyll cells. In contrast, mesophyll cells of the VSPT showed important signs of degradation. Cells were organelle‐free and the middle lamella was expanded and invaded by hyphae of T. deformans. In some samples, the leaves of TPT showed deformed epidermal cells, loss of some spongy cells and increase of the intercellular spaces and division of the palisade cells. The pathogen proliferation in the leaves of the VSPT was considerably superior. In this case, stimulation of cell division occurred in the abaxial epidermis. Cells showed periclinal and oblique divisions, with an increased number of plasmodesmata; palisade or spongy cells were not differentiable. Leaves from TPT collected on 26th April showed hyphae with a non‐cylindrical section and with a squashed aspect. The hyphae were very evident in the intercellular spaces, showing abundant endoplasmic reticulum of rough type (RER) in the cytoplasm. On the other hand, epidermis of the leaves of the VSPT had numerous hyphae under the cuticle, which were growing in a thick pectin matrix. Leaves from TPT and VSPT collected on 6th May showed relevant differences. The leaves of TPT had a palisade mesophyll with fewer cells but with active chloroplasts. In contrast, the leaves from VSPT showed empty mesophyll cells, the cytoplasm was collapsed and the adaxial epidermis was covered with the fungus fructification. The observed anatomical and ultrastructural differences of leaves from TPT and VSPT confirm a different behaviour in plant‐host reaction at early stages of infection.     

暗罗属植物叶的比较解剖学研究

利用扫描电镜技术、叶片叶片离析方法和石蜡切片法对暗罗属12种植物叶和形态结构进行了比较研究。结果表明,叶表皮细胞形状、气孔器形态、表皮毛类型、表皮细胞中晶体类型、叶肉中油细胞分布位置、栅栏组织和海绵组织厚度的比值,以及主脉维管组织的结构特征等具有明显的种间差异。可以利用这些叶的解剖特征将暗罗属植物相互区别开来。     

番荔枝科蚁花属和澄广花属叶的比较解剖学研究

利用扫描电镜技术,叶片离析方法和石蜡切片法对蚁花属1种和澄广花属9种植物叶的形态结构进行比较研究。结果表明,两属植物有许多相似之处,但又有以下一些显著不同;蚁花属植物叶表皮细胞均具一晶族,叶肉组织中具1-2层栅栏组织细胞,油细胞均匀分布在栅栏组织和海绵组织中,栅栏组织在主脉处不连续,而澄广花属植物叶的表皮细胞内具一单斜晶,叶肉组织中具1层栅栏组织细胞,油细胞仅分布在海绵组织中,栅栏组织在主脉处连续,结果为蚁花属和澄广花属的分类学处理提供了新证据。     

番荔枝科植物叶的比较解剖学

利用扫描电镜、叶表皮离析法和石蜡切片法研究了番荔枝科93种2变种植物叶片的形态结构.结果表明番荔枝科植物叶片形态结构具有较大相似性,如叶表面均具有表皮毛,表皮细胞具有晶体,气孔器为平列型,具2～6个副卫细胞,仅分布在远轴面,普遍具有败育气孔器,叶肉组织中普遍含有油细胞等,但表皮毛的类型,表皮细胞的形状,表皮细胞内晶体的类型和形态,叶肉组织的结构具有明显的属间和种间差异.