ULTRASTRUCTURAL CHANGES IN DIRECTLY GERMINATING SPORANGIA OF PHYTOPHTHORA PARASITICA

Flagella and cleavage vesicles form during the initial stages of direct germination in the same manner as they do in indirect germination. Later, however, the flagella degenerate and cleavage of the cytoplasm is not complete. Instead, a new wall layer is deposited onto the existing sporangial wall, and this germination wall extends with the germ tube and forms the hyphal wall. Material for the germination wall first appears around vesicular aggregates concentrated at the periphery of the sporangial cytoplasm. As the wall forms the vesicular aggregates become encased in it, and the wall eventually consists of irregular deposits of wall material interspersed with the vesicular aggregates. These are clearly cytoplasmic in nature and different from lomasomes, since they are associated with ribosomes and other small elements of the cytoplasm. Likely to contribute to the wall formation are the endoplasmic reticulum, microbodies, dictyosome-derived vesicles, and possibly polyvesicular bodies and larger vacuoles with fibrillar contents. The basal plug of the sporangium forms the same way as the germination wall and also contains numerous vesicular inclusions. Fewer vesicular inclusions are found in the sporangial wall, and none have been observed in the walls of the growing hyphae. This difference in wall structure can be explained on the basis of their different growth patterns. Penetration of the sporangial plug is concomitant with prominent lomasomal activity and the cytoplasm at the hyphal tip is characterized by the presence of numerous vesicles, which are probably derived from dictyosomes.     

The relationship of echinate inclusions and coated vesicles on wound healing inNitella flexilis (Characeae)

Summary Wound healing in internodal cells of the freshwater algaNitella flexilis (Characeae) was studied in the light and electron microscope. Immediately after punctation of the cell wall a wound plug is formed which stops outflow of cytoplasm. The plug consists of echinate inclusions which are normally located in the central vacuole. A wound wall consisting of pectin and cellulose microfibrils is formed beneath the plug within one to several hours. During that time the wound shows intensive fluorescence when treated with chlorotetracycline indicating transmembrane Ca²⁺ fluxes. Numerous coated pits and vesicles are found at the plasmalemma. The glycosomes undergo pronounced structural changes. Neither plug nor wound wall formation depend on actin filaments or microtubules as shown by inhibitor experiments with cytochalasin and amiprophos-methyl. The function of the coated vesicles and their interrelationship with other cell organelles is discussed.     

薏苡胚乳细胞化的超微结构观察

采用透射电镜对薏苡早期的胚乳细胞化进行了研究,在胚乳游离核时期,胚乳游离核及细胞质绕中央细胞分布,游离核间没有发现胚囊壁内突、成膜体等结构。胚乳细胞化过程中初始垂周壁形成过程如下：（１）胚乳细胞质中出现液泡,使细胞质和核向中央液泡推进：（２）一对相邻细胞核间液泡成对存在,且呈垂周分布,而且两液泡间的细胞质很狭窄;（３）在这狭窄的细胞质中出现成行排列的小泡;（４）小泡融合形成细胞板,细胞板悬于两液泡     

Studies of Ultrastructure and ATPase Localization of Mature Embryo Sac in Vicia faba L.

Studies of ultrastructure and ATPase localization of the mature embryo sac in Vicia faba L. show that the egg cell has no cell wall at thechalazal end, it has a chalazally located nucleus and a large micropylar vacuole. There are many nuclear pores in the nuclear membrane. The cytoplasm is restricted around the nucleus. Dictyosome and mitochondria are few. There are some starch grains and lipid grains in the egg cytoplasm. There are no obvious differences between two synergids. No cell wall is seen at the chalazal end either, but there are some vesicles which project to vacuole of the central cell and fuse with its vacuolar membrane. Plasmodesmata connections occur within the synergid wall where it is adjacent to the central cell. The synergid has a micropylarly located nucleus and a chalazal vacuole, the nucleus is irregularly shaped. The synergid cytoplasm is rich in organelles. The filiform aparatus is of relatively heterogeneous structure. The central cell is occupied by a large vacuole and its cytoplasm is confined to a thin layer along the empryo sac wall, but is rich in various organelles, starch grains and lipid bodies. Nucleolar vacuoles are often present two polar nuclei. The nuclear membranes of two polar nuclei have partly fused. ATPase reactive product was located obviously at the endoplasmic reticulum in cytoplasm of the egg cell and central cell. The embryo sac wall consists of different density of osmiophilic layer. There are some wall ingrowths in chalazal region of the embryo sac. The long-shaped and cuneate cells of chalazal region are peculiar. Special tracks of ATPase reactive products are visible at their intercellular space which may be related to transportation of nutrients.     

Ultrastructural localization of phosphohydrolases in gametes, zygotes and zoospores of Ulva mutabilis Foyn.

Gametes, zoospores, and zygotes of the multicellular, green alga Ulva mutabilis showed acid phosphatase reaction product in Golgi vesicles and on the membrane lining the vacuole. In addition gametes and zoospores showed enzyme reaction product on the entire surface membrane including the flagellar membrane. The surface membrane enzyme activity disappears from the zygote shortly after copulation and at the same time lysosome-like bodies start to appear in the cytoplasm. No alkaline phosphatase activity could be detected. The distribution of acid phosphatase is discussed in relation to the events taking place during and shortly after fertilization.     

Ultrastructure and antigenicity of the unique cell wall pimple of the Candida opaque phenotype.

Cells of Candida albicans WO-1 switch frequently and reversibly between two colony-forming phenotypes, white and opaque. In the white form, budding cells appear similar to those of most other strains of C. albicans, but in the opaque form, budding cells are larger, are bean shaped, and possess pimples on the wall. These pimples exhibit a unique and complex morphology. With scanning electron microscopy, a central pit can be discerned, and in many cases, a bleb can be observed emerging from the pimple center. With transmission electron microscopy, channels are evident in some pimples and vesicles are apparent under the pimple in the cytoplasm, in the actual wall of the pimple, or emerging from the tip of the pimple. A large vacuole predominates in the opaque-cell cytoplasm. This vacuole is usually filled with spaghettilike membranous material and in a minority of cases is filled with vesicles, many of which exhibit a relatively uniform size. An antiserum to opaque cells recognizes three opaque-cell-specific antigens with molecular masses of approximately 14.5, 21, and 31 kilodaltons (kDa). Absorption with nonpermeabilized opaque cells demonstrated that only the 14.5-kDa antigen is on the cell surface; indirect immunogold labeling demonstrated that it is localized in or on the pimple. The possibility is suggested that the vacuole of opaque cells is the origin of membrane-bound vesicles which traverse the wall through specialized pimple structures and emerge from the pimple with an intact outer double membrane, a unique phenomenon in yeast cells. The opaque-cell-specific 14.5-kDa antigen either is in the pimple channel or is a component of the emerging vesicle. The functions of the unique opaque-cell pimple and emerging vesicle are not known.     

An ultrastructural study of zoosporogenesis inPythium proliferum de Bary

Summary Zoosporogenesis in the oomycete,Pythium proliferum de Bary initially involves a condensation of cytoplasm at certain hyphal tips and the subsequent enlargement of these hyphal tips to form sporangia. Deposition of a septum at the base of the sporangium and initiation of an apical papilla are followed by cleavage of the sporangial cytoplasm. Packets of presumptive mastigonemes as well as flagella are recognized in the cytoplasm at this time. Subsequently, cleavage vesicles at the periphery of the sporogenic cytoplasm fuse with the plasmalemma thereby emptying their fibrous contents into the space between the sporogenic cytoplasm and the sporangial wall. It is felt that this fibrous material is instrumental in developing the internal pressure necessary within the sporangium to cause discharge of the sporogenic cytoplasm into an evanescent vesicle wherein delimitation of the zoospores is completed. The formation of the spore vesicle from the multilayered apical cap of the papilla is described here for the first time in the Oomycetes and a new term, vesiculogen, is suggested for this structure. Aspects of centriole replication within vegetative hyphae, papilla formation, and morphogenesis of various vesicular inclusions are also described in this study.     

CHLORTETRACYCLINE-INDUCED FORMATION OF WALL APPOSITIONS (CALLOSE PLUGS) IN INTERNODAL CELLS OF NITELLA FLEXILIS (CHARACEAE)1

The formation of chlortetracycline (CTC)-induced wall appositions or plugs in internodal cells of Nitella flexilis (L.) Ag. was studied with light, fluorescence and electron microscopy. These plugs contain callose and pectin. A few minutes after CTC addition plug formation starts by fusion of polysaccharide-containing vesicles (glycosomes) with the plasmalemma. Plug growth is continued by incorporation of glycosome-endoplasmic reticulum (ER) complexes. The cytoplasm near the plug appears dense because of the accumulation of glycosomes and the increased electron density of plasma matrix and organelles. About 1 h after CTC addition plug growth ceases, the cytoplasm recovers to its pretreatment appearance, and a few glycosomes fuse singly with the plug membrane. Crystalline inclusions which consist of hexagonally packed rods are found near the plug. Coated vesicles and coated pits are clearly seen only in very early and late stages of plug formation. Callose is also found in parts of wound plugs produced after mechanical injury. No callose is present in the underlying, highly ordered wound wall. The failure to produce a wound wall beneath CTC-induced plugs appears to be related to the lower number of coated vesicles during plug formation. The possible significance of the partially coated reticulum in plug and wound wall formation is discussed.     

大葱卵器及受精后助细胞的超微结构

章丘大葱（Ａllium fistulosum L.cv.Zhangqiu)的卵器由１个卵细胞及２个助细胞组成,观察到不少卵器没有卵细胞,只有２个助细胞。卵细胞的核及大部分细胞质位于细胞的合点端,１个大液泡占据了细胞其他部位。卵细胞含有很多的核糖体及多聚核糖体、嵴明显的线粒体、粗面内质网、高尔基体具小泡,卵细胞似是一个活跃的细胞。细胞外被细胞壁,其合点端及侧方与助细胞共同壁不连续,助细胞有一较大的核,位于细胞膨大的部位,众多的小液泡遍布细胞中。核糖体及聚合核糖体、线粒体,粗面内质网及风心圆环状粗面内质丰富,高尔基体及小泡常见,反映了其活跃的代谢作用。助细胞合点端及侧方与卵细胞、中央细胞的共同壁不连续,与卵细胞共同壁含胞间连丝,壁不连续处,有不状多层膜结构伸入卵细胞质,显示助细胞可能对卵细胞提供营养,伟粉后,一个助细胞退化,宿存助细胞至随胚胚期尚存在,它经历了一个缓慢的退化过程,出现质壁分离,细胞质变稀,液泡扩大,细胞器逐渐减少,在椭形胚期,宿存助细胞核内的染色质及核仁消失,有细胞质侵入核内,因宿存助细胞壁变厚,细胞质出现现脂滴,宿存助细胞可能仍有合成功能,宿存助细胞壁出现若干无壁部位,细胞内的营养物质可能通过无壁部位向胚乳转运,供游离核胚乳及胚乳细胞化初期的发育。     

DEVELOPMENT OF PERIPHERAL VACUOLES IN PLANT CELLS

The vacuolar apparatus of various plant cells consists of two distinct features: the large central vacuole and peripheral vacuoles which are derived from invaginations of the plasma membrane. Peripheral vacuoles are conspicuous structures in both living and fixed hair or filament cells of Tradescantia virginiana. They occur as spherical structures along the inner boundary of the peripheral cytoplasm and can be recognized as projections into the central vacuole. These structures are variable in size and number within a cell and can represent a significant proportion of the volume of the vacuole. Peripheral vacuoles most frequently are observed in motion with the streaming cytoplasm although their velocity is usually somewhat slower that that of the cytoplasmic organelles. Ultrastructural studies show two closely approximated membranes, one for each vacuole, in areas where a peripheral vacuole projects into the central vacuole. These are separated by an intermembrane zone continuous with the peripheral cytoplasm. The movement of organelles over the perimeter of the peripheral vacuole is presumed to occur along this intermembrane zone. The internal area of the peripheral vacuoles may appear empty although some contain a vesicular content of unknown origin and function.     

On the formation of the pattern of crystal idioblasts — in Canavalia ensiformis DC

Summary Light and electron-microscope observations were made of the crystal idioblasts in the leaves of Canavalia. The crystal-containing cells occur as pairs in which the crystals, nuclei, and the majority of the chloroplasts are symmetrically arranged with regard to the common wall. The chloroplasts are found in the cytoplasm along this wall.The crystals originate in a vacuole. The space in which the young crystal develops is delimited by a membrane. One to several additional membranes surround the crystal inside the vacuole. Numerous vesicles are distributed between these vacuolar membranes. Dense groups of tubules or fibrils are oriented toward a portion of the crystal surface, suggesting that the material forming the crystal might be transported to the surface by these structures.The cytoplasm of the young idioblasts contains many mitochondria and dictyosomes with associated vesicles. Concentrations of what is assumed to be protein are present in the cytoplasm. These protein accumulations are not seen in neighboring cells, suggesting that protein synthesis is especially high in the idioblasts.In older crystal cells, layers of wall material are deposited on the wall between the two crystals of the pair and towards the cell wall adjacent to the mesophyll. Not only does the original wall become thickened but a new wall develops at the border of the crystal vacuole. Eventually this wall material becomes continuous and the crystal becomes, on two sides, directly connected with the wall.     

葡萄果实发育过程中果肉细胞超微结构的观察

用透射电镜观察了“巨峰”葡萄(Vitis vinifera×V.labrusca)果实3个发育时期中果肉细胞超微结构的变化。果实第一次快速生长期的果肉细胞超微结构表现出物质和能量代谢旺盛的特点。缓慢生长期的果实虽外部形态平静少变,但果肉细胞超微结构表现出深刻的变化:细胞核形状特化为裂瓣状是最显著的特点;线粒体数目丰富;粗面内质网槽库膨大形成的囊泡富集,出现向液泡汇融和向质膜靠近的现象;质膜内陷;液泡膜完整。另外,原生质也出现一些降解的现象。但总体结构特点表明果肉细胞在此期处于十分活跃的物质周转代谢和信息交换过程中。果实第二次快速生长期果肉细胞超微结构表现出衰老降解的特点,但线粒体结构依然完整,数量仍然丰富,原生质膜也保持了很好的完整性,这似乎与维持第二次快速生长或成熟有关。     

Development of the discharge apparatus in the fungus Entophlyctis

Correlative light and electron microscopic observations were used to reconstruct the morphological events involved in the development of the discharge apparatus of Entophlyctis zoosporangia. A discharge plug formed as vesicles containing fibrillar material fused with the plasma membrane and deposited their matrices between the plasma membrane and zoosporangial wall. At the apex of the enlarging plug, the zoosporangial wall lost its microfibrillar appearance, became diffuse, and left an inoperculate discharge pore. The discharge plug exuded through this pore and then expanded into a sphere which rested at the tip of the discharge papilla or tube. After the release of the discharge plug, the number of fibrilla containing vesicles decreased and abundant endoplasmic reticulum appeared in the cytoplasm below the plug. Granular material then accumulated at the interface of the discharge plug and the plasma membrane. This was the endo-operculum. A single layer of endoplasmic reticulum subtended the area of plasma membrane which the endo-operculum covered. Later, dictyosomes appeared in the cytoplasm below the endo-operculum. Fusion of Golgi vesicles with the plasma membrane below the endo-operculum coincided with the initiation of cytoplasmic cleavage. This sequence of events indicates that, unlike the discharge plug, the endo-operculum does not originate by vesicular addition of preformed material.     

Morphological study of cysts of Pelomyxa palustris Greeff, 1874

Pelomyxa palustris Greeff, 1874, is the only representative of pelomyxoid amoebae with rest cysts in its life cycle. The morphology of the P. palustris cysts was studied using light and electron microscopy. The encystation of P. palustris under the climatic conditions of northwestern Russia occurs in August through September. The rest of the cysts have complex, trilaminar walls. The most developed are the two inner layers, i.e., the electron-dense structureless endocyst and the laminated mesocyst; the thickness of each layer can reach 0.6–0.7 μm. The thickness of the superficial electron-dense ectocyst lamina usually does not exceed 0.1–0.2 μm. The encysted cell of P. palustris has a unique structure. About 60% of its cell volume is occupied by a giant central vacuole filled with prokaryotic cytobionts. This vacuole has also been found to contain vacuoles and vesicles of different natures, restricted by vacuole membranes, autophagosomes, and lipid droplets. The amoeba cytoplasm occupies the space between the endocyst inner surface and the central vacuole. It contains no inclusions, prokaryotic cytobionts and most of cell organelles. In the cytoplasm there are 4 large nuclei filled with relatively homogeneous karyoplasm. The nuclear envelope forms numerous long tubular outgrowths, piercing the cytoplasm and underlining the central vacuole membrane. In this state the encysted pelomyxoids survive until the beginning of excystation. The excystation of P. palustris in the studied region occurs in spring, during the second half of April through the beginning of May. The cysts undergo complex morphofunctional changes due to reorganization of the wall and formation of young multinucleate amoebae. Out of the three initial lamina of the wall, only one persists until the moment of encystation. The central vacuole is destroyed and its content penetrates into the cytoplasm. Pelomyxoid nuclei divide twice. Prokaryotic cytobionts are localized in the cytoplasm and in the perinuclear area. Young multinuclear P. palustris individuals exiting cysts do not differ from the adult forms by their organization.     

白刺胚乳早期发育的超微结构研究

白刺(Nitraria sibirica)胚乳发育经历游离核阶段、细胞化阶段和被吸收解体阶段。游离核胚乳沿胚囊壁均匀排列为一层,胞质浓厚,其中有丰富的质体、线粒体、高尔基体、内质网和各种小泡等细胞器。珠孔区域的胚囊壁具发达的分枝状壁内突,而周缘区域的胚囊壁具间隔的钉状内突,内突周围的细胞质中具多数线粒体和小泡。胚乳细胞化时,初始垂周壁源于核有丝分裂产生的细胞板。在细胞板两端开始壁的游离生长,一端与胚囊壁相连接,另一端向心自由延伸。壁的游离生长依赖于小泡的融合。早期胚乳细胞具大液泡,具核或无核,细胞质中有大量的线粒体,质体缺乏,其壁仍由多层膜结构组成。     

The morphological study of the cysts Pelomyxa palustris Greeff, 1874

Pelomyxa palustris Greeff, 1874, is the only species of pelomixoid amoebas with the rest cysts in its life cycle. The morphology of the P. palustris has been studied by the light and electronic microscopy. Encystation of P. palustris under climatic conditions of North-West of Russia occurs within August-September. Rest cysts have a complex, trilaminar wall. Two inner lamina are the dense endocyst and the laminated mesocyst, thickness of each layer runs up to 0.6-0.7 microm. Thickness of the electron-dense ectocyst usually does not exceed 0.1-0.2 microm. The encystated cell of P. palustris has the unique structure. About 60 % of the cell volume are occupied by a huge vacuole placed in the center and filled up with the prokaryotic cytobionts. Different vacuoles, small vesicles of various nature, autophagosomes and lipid drops could be found inside that huge vacuole. The amoebae cytoplasm occupies the space in between endocyst's inner surface and the central vacuole. No any inclusions, prokaryotic cytobionts and most of cell organelles are absent in the cytoplasm. There are 4 large nuclei filled with relatively homogeneous karyoplasm lying in the cytoplasm. Nuclear envelope forms a lot of long tubular channels, running through the cytoplasm and lining the membrane of the central vacuole. Encysted pelomixoid stay in this state up until the beginning of excystation. Excystation of P. palustris in the studied region occurs in spring, during the latter half of April and the beginning of May. Cysts undergo complex morphofunctional changes, related to the reorganization of the wall and formation of young multinucleate amoebas. Only one wall lamina of the 3 initial ones is left up to the moment of excystation. The central vacuole endures ruination and its content penetrates into the cytoplasm. Pelomixoid nuclei divide twice. Prokaryotic cytobionts are localized in cytoplasm and in the perinuclear area. Young multinuclear species of P. palustris coming out of the cysts do not differ in their structure from the adult forms.     

An Ultrastructural Study on Triggering of Cell Division in Young Pollen Protoplast Culture of Hemerocallis fulva L.

The ultrastructural changes of young pollen protoplasts under culture condition in Hemerocallis fulva were studied. In comparison with the original pollen grains, the pollen protoplasts had been completely deprived of pollen wall, but kept the internal structure intact, including a large vacuole, a thin layer of cytoplasm and a peripherally located nucleus. After 8 days of culture a few pollen protoplasts were triggered to cell division: some of them were just undergoing mitosis with clearly visible chromosomes and spindle fibers; the others already divided into 2-celled units. The two daughter cells were equal or unequal in size but with similar distribution of organelles inside. Besides cell division, there were also free nuclear division, amitosis and formation of micronuclei indicating a diversity of division modes in pollen protoplast culture, A series of changes occurred during the process of induction of cell division, such as locomotion of the nucleus toward the central position, disappearence of the large vacuole, increase of electron density of cytoplasm, increase and activation of organelles, diminishing of starch granules in plastids, etc. However, the regeneration of surface wall was not sufficient it contained mostly vesicles with only a few microfibrits. The wall separating the two daughter cells were either complete or incomplete. The weak capability of wall formation is supposed to be one of the major obstacles which has so far restricted sustained cell divisions of young pollen protoplasts under current culture condition.     

The specialized chalazal endosperm inArabidopsis thaliana andLepidium virginicum (Brassicaceae)

Summary Endosperm of the nuclear type initially develops into a large multinucleate syncytium that lines the central cell. This seemingly simple wall-less cytoplasm can, however, be highly differentiated. In developing seeds of members of the family Brassicaceae the curved postfertilization embryo sac comprises three chambers or developmental domains. The syncytium fills the micropylar chamber around the embryo, spreads as a thin peripheral layer surrounding a large central vacuole in the central chamber, and is organized into individual nodules and a large multinucleate cyst in the chalazal tip. Later in development, after the endosperm has cellularized in the micropylar and central chambers, the chalazal endosperm cyst remains syncytial and shows considerable internal differentiation. The chalazal endosperm cyst consists of a domelike apical region that is separated from the cellularized endosperm by a remnant of the central vacuole and a basal haustorial portion which penetrates the chalazal proliferative tissue atop the vascular supply. In the shallow chalazal depression ofArabidopsis thaliana, the cyst is mushroom-shaped with short tentacle-like processes penetrating the maternal tissues. The long narrow chalazal channel ofLepidium irginicum is filled by an elongate stalklike portion of the cyst. In both, the dome contains a labyrinth of endoplasmic reticulum, dictyosomes with associated vesicles, nuclei, and plastids. The basal portions, which lack the larger organelles, exhibit extensive wall ingrowths and contain parallel arrays of microtubules. The highly specialized ultrastructure of the chalazal endosperm cyst and its intimate association with degrading chalazal proliferative cells suggest an important role in loading of maternal resources into the developing seed.     

Development and ultrastructure of the marine,parasitic Oomycete,Lagenisma coscinodisci Drebes (Lagenidiales): Formation of the primary zoospores and their release

Summary Zoosporogenesis inLagenisma begins after the final nuclear division by the development of encystment vesicles which presumably are derived from Golgi vesicles. The sporangial wall is secreted simultaneously. Initially, the encystment vesicles have an internal coat of fine ribs which becomes a uniform mass during the complicated invagination of the vesicles. When the sporangial wall is complete the protoplast cleaves centripetally by means of narrow cleavage cisternae apparently coming from the distal face of the dictyosomes and being detached by interposing ER cisternae. The cleavage cisternae fuse with each other and with the plasmalemma to which they are often parallel. Narrow cytoplasmic compartments are then cut off and swell to become separation vesicles which lie between the developing zoospores but later disintegrate. Basal bodies develop from procentrioles after the final nuclear division and elongate into flagella (without participation of a flagellar vesicle) when cleavage is complete. The mastigonemes are formed within the ER, mature within the peripheral elements of the dictyosomes near the flagellar bases and appear to be extruded after the elongation of the flagellum. Structurally, especially in the organization of the flagellar root apparatus, the zoospores resemble primary zoospores of other Oomycetes. They become motile within the zoosporangium but seem to be driven out by means of additional unknown forces.—Formation of the encystment vesicles and the manner of cleavage are compared with those of other Oomycetes and general aspects ofLagenisma zoosporogenesis are discussed.     

A putative DEAD-box RNA-helicase is required for normal zoospore development in the late blight pathogen Phytophthora infestans

The asexual multinucleated sporangia of Phytophthora infestans can germinate directly through a germ tube or indirectly by releasing zoospores. The molecular mechanisms controlling sporangial cytokinesis or sporangial cleavage, and zoospore release are largely unknown. Sporangial cleavage is initiated by a cold shock that eventually compartmentalizes single nuclei within each zoospore. Comparison of EST representation in different cDNA libraries revealed a putative ATP-dependent DEAD-box RNA-helicase gene in P. infestans, Pi-RNH1, which has a 140-fold increased expression level in young zoospores compared to uncleaved sporangia. RNA interference was employed to determine the role of Pi-RNH1 in zoospore development. Silencing efficiencies of up to 99% were achieved in some transiently-silenced lines. These Pi-RNH1-silenced lines produced large aberrant zoospores that had undergone partial cleavage and often had multiple flagella on their surface. Transmission electron microscopy revealed that cytoplasmic vesicles fused in the silenced lines, resulting in the formation of large vesicles. The Pi-RNH1-silenced zoospores were also sensitive to osmotic pressure and often ruptured upon release from the sporangia. These findings indicate that Pi-RNH1 has a major function in zoospore development and its potential role in cytokinesis is discussed.