精子细胞高尔基体的冰冻蚀刻电镜观察

本实验用冰冻蚀刻方法观察大鼠精子细胞高尔基体的膜结构。冰冻蚀刻复型膜显示了高尔基体膜囊上的膜内颗粒和圆形凹陷结构,这些结构在高尔基体的各层膜囊以及GERL上的数目和分布是不同的。一般认为膜内颗粒代表镶嵌于生物膜类脂双分子层中的蛋白质和酶,因此,它们的数目和分布说明了精子细胞高尔基体各层膜囊结构的分子排列以及酶的活性是不一样的。圆形凹陷结构的具体性质还不清楚,它们可能与高尔基体膜囊融合运输小泡以及长出分泌小泡的过程有关。本文还把高尔基体各部位的膜内颗粒分布与它们的细胞化学反应联系起来进行了讨论。     

中国金藻门植物的新种类

囊壳花瓶形,长16～19μm,宽5～7μm。中间呈椭圆形,前端收缢呈领状,领口向外开展呈漏斗形,后端渐尖成长尾刺。常附生在浮游的绿球藻类细胞表面,单个或多个,呈丛状。原生质体几乎充满整个囊壳,活跃变形,前端常伸出囊壳。鞭毛单条,伸展向前,约与身长相等;色素体缺如。     

形形色色的藻类植物

图1-2 甲藻门 1.Gymnodinium eucyanochroum扫描电镜照片。示细胞的横沟和纵沟中各有1条鞭毛;2.角甲藻Ceratiumhirundinella背面观,示横沟、1个顶角和3个底角,淡水产。图3金藻门锥囊藻属Dinobryon树状群体,每个细胞外均有1个钟罩状的囊壳。生活于清洁的淡水中。图4-7硅藻门(细胞均经过酸化处理,示壳面花纹) 4.蛇目圆筛藻Coscinodiscus argus壳面圆形,具六角形孔纹,呈放射状和螺旋状排列。海产。     

三角帆蚌精子的形态及超微结构

运用电子显微镜技术对三角帆蚌精子的形态和超微结构进行研究。结果发现,三角帆蚌精子为原生型,分为头部、中段和尾部,头部呈子弹头形,电子致密且均匀,主要是核所在的区域。核前端由3－4个小的电子致密颗粒组成一个浅弧形的囊泡,为顶体结构,中段具有5个球形线粒体,环绕着两个相互垂直的中心粒。中段末端具有的鞭毛质领结构（flagellar collar)为一电子致密环,与远端中心粒之间由9个分叉的电子致密小片连接。尾部为典型的9＋2结构。     

无蹼壁虎精子头部形成的研究

本文用透射电镜观察了无蹼壁虎精子头形成的过程。早期精细胞具有显著的高尔基复合体、线粒体集合及细胞质桥、接着高尔基体成熟面分泌出前顶体囊泡,并逐渐向核移动。以后精子形成可分四个时间：时间Ⅰ,当前顶体囊泡移至核膜时,核膜凹陷形成封闭的顶体囊泡,囊泡底部靠近核膜有一电子致密的顶体颗粒;时间Ⅱ,细胞核延长,顶体囊泡变扁平;时期Ⅲ,细胞核进一步延长,核内染色质纤维变粗并沿核纵轴方向排列有序;时间Ⅳ,精子发育     

黄颡鱼(Pseudobagrus fulvidraco)精子的超微结构

黄颡鱼精子由头部、中段和鞭毛(尾部)三部分组成。头部的主要结构是细胞核。核中浓缩了的染色质呈颗粒状。染色质中有核泡存在。核泡中有致密颗粒状物。植入窝里井状,从核后端往前深陷入核的中央。中段的中心粒复合体位于植入窝中,结构独特。近端中心粒和基体首尾相对,排在同一直线上。某些精子的近端中心粒的中央腔中能见到一、二个粗大的颗粒状物。基体的中央腔中有一对中央微管。近端中心粒和基体之间有中心粒间体将两者隔开。中段的袖套连接于细胞核之后,其中分布着线粒体和一些囊泡。近袖套内膜处的细胞质中有一层膜与袖套内膜平行。鞭毛细长,其起始端位于袖套腔中。鞭毛上长有两排侧鳍。侧鳍呈波纹状,分居轴丝两侧,大致与轴丝的两条中央微管同在一个平面上。侧鳍的基部有囊泡。     

中国石龙子精子形成的超微结构研究

采用透射电镜观察中国石龙子精子的形成过程。结果表明:早期精细胞中有高尔基复合体和线粒体集合,由高尔基复合体所分泌的前顶体囊泡,逐渐向核移动,以后的过程可分为四个时期。时期Ⅰ:前顶体囊泡移至核膜时,核膜凹陷形成封闭的顶体囊泡,囊泡底部靠近核膜处有一电子致密的顶体颗粒,近端中心粒及鞭毛开始出现。时期Ⅱ:顶体囊泡变扁平,细胞核延长,染色质浓缩成短丝状的染色质纤维。时期Ⅲ:核进一步延长,染色质纤维变粗变长,按核纵向排列有序。时期Ⅳ:染色质纤维浓缩至最大限度,电子透明的核质消失,核呈高电子致密,顶体复合体发育完全。     

棕鞭藻对蛋白核小球藻的摄食及其营养策略

在研究稻草秸秆对蛋白核小球藻(Chlorella pyrenoidosa)的化感作用时,偶然发现一株对蛋白核小球藻具有强烈的取食作用的鞭毛虫,能有效抑制小球藻的大量繁殖。经形态学观察,该种鞭毛虫具有2片淡黄色色素体,片状、周生;虫体呈球形、椭圆形或卵形,能变形,具2根不等长的鞭毛,从细胞顶部伸出;长鞭毛约为虫体的1.5倍,短鞭毛约为虫体的0.5倍;对蛋白核小球藻的吞噬能力极强,每个虫体可以吞噬3~4个小球藻,虫体大小因吞噬物的多少变化较大。初步确定这种鞭毛虫为棕鞭藻(Ochromonas sp.)。在SE、稻草以及麦粒3种培养基中的种群生长表明,这种棕鞭藻在麦粒培养基最易培养,生长速度最快。结果表明,这种棕鞭藻为混合营养类型,但以吞噬营养为主。     

中国囊裸藻属的新种类

1．旋转囊探藻网纹变种新变种图1：1TrachelomonasvolvocinaEhrenbergvarreticulataShi,var．nov．囊壳圆球形;表面具不规则的网纹。鞭毛孔无加厚环,具一低领。囊壳直径约16μm湖北：武汉,采于鱼池中,197310,31,李尧英采,图1：1（模式图,Iconotypus）本变种与原变种的     

瓶囊碘泡虫成熟孢子的显微及亚显微结构研究

应用光镜、透射电镜和扫描电镜观察,瓶囊碘泡虫Myxobolus ampullicapsulatus Zhao et al.,2008成熟孢子由孢壳、极囊和孢质3部分组成.其孢子壳面观呈梨形,缝面观呈凸透镜形,囊间突明显;2片孢壳厚而均匀且表面凹凸不平.极囊瓶形,位于孢子前端,约占整个孢子长度的2/3;极囊壁由"暗-明"2部分组成;极丝呈双"S"形缠绕并沿极囊纵轴逆时针向上螺旋8～11圈.孢质均匀而稠密,近球形的2个胚核大小不一;孢质中除了可观察到丰富的线粒体、粗面内质网、核糖体、高尔基体、嗜碘泡等细胞器及脂滴等泡状结构外,还可于孢质中观察到有一些数目不等的球状电子致密物质,其中2个分布于极囊周围.     

Ultrastructure of the flagellar apparatus of the green algaTetraselmis subcordiformis

Summary The ultrastructure of the flagellar apparatus of the marine quadriflagellate green algaTetraselmis subcordiformis is described in detail. Special consideration is given to the functional significance of the contractile rhizoplast and also to a complex structure which anchors the flagellar apparatus to the cell membrane and theca. The flagellar apparatus lies at the base of a deep apical depression. Four basal bodies lie in a zigzag row with their long axes nearly parallel. Outer adjacent pairs of basal bodies are structurally linked by a Z-shaped, ribbon-like structure. A striated fiber (transfiber) connects each outer basal body with the inner basal body of the opposite, mirror image pair. A complex system of four laminated oval discs (rhizanchora), microtubule rootlets and fibrous material anchor the flagellar apparatus and rhizoplasts to the plasma membrane and theca. A 4-2-4-2 arrangement of microtubule rootlets is present. Rhizoplasts, which are contractile organelles, branch into five distinct arms and associate with the near outer basal body and each of the four rhizanchora. Rhizoplast contraction is thought to be linked to flagellar activity and may act to alter the direction of motion of the cell.     

DEVELOPMENT OF THE FLAGELLAR APPARATUS OF NAEGLERIA

Flagellates of Naegleria gruberi have an interconnected flagellar apparatus consisting of nucleus, rhizoplast and accessory filaments, basal bodies, and flagella. The structures of these components have been found to be similar to those in other flagellates. The development of methods for obtaining the relatively synchronous transformation of populations of Naegleria amebae into flagellates has permitted a study of the development of the flagellar apparatus. No indications of rhizoplast, basal body, or flagellum structures could be detected in amebae. A basal body appears and assumes a position at the cell surface with its filaments perpendicular to the cell membrane. Axoneme filaments extend from the basal body filaments into a progressive evagination of the cell membrane which becomes the flagellum sheath. Continued elongation of the axoneme filaments leads to differentiation of a fully formed flagellum with a typical "9 + 2" organization, within 10 min after the appearance of basal bodies.     

ULTRASTRUCTURAL MORPHOLOGY OF MICROTHAMNION ZOOSPORES1

The Ultrastructure of Microthamnion zoospores is described (exclusive of the finer details of the flagellar apparatus). The zoospores have a typical chlorophycean morphology but, in addition, many unique features. The chloroplasts contain starch but no pyrenoid. Thylakoids may run from one edge of the chloroplast to the other and usually anastomose into 2- to 8-membered stacks. The internal morphology is highly polarized and characterized by an intimate proximity and constant spacing between many organelle membranes. All the organelles are asymmetrically distributed within the cell in a precise manner. The anterior region of the zoospore is attenuated into a neck which contains a single, massive mitochondrion. A fibrous rhizoplast lies beside the mitochondrion and appears to connect the flagellar apparatus directly with the outer membrane of the nuclear envelope. In addition, this outer membrane is extended over a distance of several microns to eventually lie in close proximity to the basal bodies. Oil vacuoles and lipid bodies are restricted to the posterior end of the zoospore.     

The cytology and ultrastructure of zoospores of Hydrurus foetidus (Chrysophyceae)

The unusual tetrahedral shape of Hydrurus foetidus (Vill.) Trev. zoospores is associated with a complex skeletal system of microtubules extending from a broad flagellar root (up to 19 microtubules) into each of three, pointed anterior processes. The posterior end, also pointed and supported by a separate set of microtubules, contains a single large chloroplast with a prominent posterior furrow containing mitochondrial elements. A large immersed pyrenoid is penetrated by paired thylakoids. There is no eyespot. Numerous large Golgi bodies occur immediately anterior to the nucleus and up to 5–6 contractile vacuoles lie near the cell surface at the anterior end. Two terminally inserted flagella extend from the cell surface, a long one serving for cell locomotion, and the other vestigial with an axonemal pattern of 9+0. The flagellar root system consists of: (1) a thin, striated rhizoplast extending from the basal body of the long flagellum and ramifying over the surface of a conspicuous, anteriorly directed, conical projection of the nucleus; (2) a broad microtubular root which emanates from near the basal body of the long flagellum and appears to function as a MTOC; (3) a compound root, consisting of a striated fiber and two associated microtubules, which runs alongside the basal body of the stubby flagellum before terminating at the cell surface; and (4) a short two-membered microtubular root, also associated with the basal body of the stubby flagellum. Other components of the flagellar apparatus include a large dense body near the proximal end of the basal body of the short flagellum, and a small, dense, core-like structure closely associated with one of its triplet fibers. The flagellar apparatus of H. foetidus is remarkably similar in ultrastructure to that of Chrysonebula holmesii Lund.     

Ultrastructural and immunocytological studies on the rhizoplast in the chrysophycean alga Ochromonas danica

The rhizoplast, a striated band elongating from the flagellar basal body to the nucleus, is conspicuous in cells of Ochromonas danica Prings. In interphase cells, it runs from the basal body of the anterior flagellum to the space between the nucleus and the Golgi body. In O. danica, the rhizoplast duplicates during mitosis and the two rhizoplasts serve as mitotic poles. In the present study, we reinvestigated mitosis of O. danica using transmission electron microscopy and immunofluorescence microscopy, especially focusing on the rhizoplast. The nuclear envelope became dispersed during metaphase, and the rhizoplasts from two sets of the flagellar basal bodies functioned as the mitotic poles. Immunofluorescence microscopy using anti‐α‐tubulin, anti‐centrin and anti‐γ‐tubulin antibodies showed that centrin molecules were localized at the flagellar basal bodies, whereas γ‐tubulin molecules were detected at the rhizoplast during the whole cell cycle.     

Ultrastructure of the quadriflagellate zoospores of the filamentous green algaeChaetophora incrassata andPseudoschizomeris caudata (Chaetophorales,chlorophyceae) with emphasis on the flagellar apparatus

Quadriflagellate zoospores ofChaetophora incrassata andPseudoschizomeris caudata have similar features including an appressed membrane between the pyrenoid matrix and the starch sheath, and identical flagellar apparatuses. Components of the flagellar apparatus include: directly opposed upper basal bodies, lower basal bodies in the clockwise absolute orientation, a grooved distal fiber, peripheral and terminal fibers between adjacent basal bodies, proximal fibers connecting the lower basal bodies to the X-membered rootlets two- and X-membered rootlets associated with electron-dense components, and at least one rhizoplast. The X-membered rootlets, are comprised of five microtubules inC. incrassata and four or five inP. caudata. These features of the flagellar apparatus suggest that the two algae are closely related, and together withStigeoclonium, Uronema, Draparnaldia andFritschiella, form a natural group, the Chaetophoraceae, Chaetophorales (sensu Mattox and Stewart).     

THE FINE STRUCTURE OF MITOSIS AND CELL DIVISION IN THE CHRYSOPHYCEAN ALGA OCHROMONAS DANICA1

At the ultrastructural level, cell division in Ochromonas danica exhibits several unusual features. During interphase, the basal bodies of the 2 flagella replicate and the chloroplast divides by constriction between its 2 lobes. The rhizoplast, which is a fibrous striated root attached to the basal body of the long flagellum, extends under the Golgi body to the surface of the nucleus in interphase cells. During proprophase, the Golgi body replicates, apparently by division, and a daughter rhizoplast, appears. During prophase, the 2 pairs of flagellar basal bodies, each with their accompanying rhizoplast and Golgi body, begin to separate. Three or 4 flagella are already present at this stage. At the same time, there is a proliferation of microtubules outside the nuclear envelope. Gaps then appear in the nuclear envelope, admitting the microtubules into the nucleus, where they form a spindle. A unique feature of mitosis in O. danica is that the 2 rhizoplasts form the poles of the spindle, spindle microtubules inserting directly onto the rhizoplasts. Some of the spindle microtubules extend from pole to pole; others appear to attach to the chromosomes. Kinetochores, however, are not present. The nuclear envelope breaks down, except, in the regions adjacent, to the chloroplasts; chloroplast ER remains intact throughout mitosis. At late anaphase the chromosomes come to lie against part of the chloroplast ER. This segment of the chloroplast ER appears to be incorporated as part of the reforming nuclear envelope, thus reestablishing the characteristic nuclear envelope—chloroplast ER association of the interphase cell.     

THE FINE STRUCTURE OF THE FLAGELLAR APPARATUS OF CARTERIA1,2

The fine structure of the flagellar apparatus of 5 species of the green quadriflagellate alga Carteria is described. The 5 species can be morphologically separated into 2 groups on the bases of cell shape and ultrastructure of the pyrenoid and flagellar apparatus. Group I cells are spherical, possess many pyrenoid thylakoids, and retain a flagellar apparatus similar to that of Chlamydomonas reinhardi. The flagellar bases are oriented at approximately 90° to one another, have distal and proximal fibers, and are associated with 4 cruciately arranged microtubule bands. Cells of group II are ellipsoid, possess few pyrenoid thylakoids, and show a complex system of microtubule bands and sigmoid-shaped, electron dense rods which extend between opposite pairs of basal bodies. The basal bodies of group II cells are directed inward in a circular pattern rather than outward as in group I cells. Unlike Chlamydomonas, the distal fiber of the Carteria species is nonstriated. The proximal fiber is striated, and both distal and proximal fibers are composed of 60–80 Å diameter microfibrils.     

COMPARATIVE ANALYSES OF THE DINOFLAGELLATE FLAGELLAR APPARATUS. III. FREEZE SUBSTITUTION OF AMPHIDINIUM RHYNCHOCEPHALUM1

The flagellar apparatus of the marine dinoflagellate Amphidinium rhynchocephalum Anissimowa was examined using the techniques of rapid freezing/freeze substitution and serial thin section three dimensional reconstruction. The flagellar apparatus is composed of two basal bodies that are offset from one another and lie at an angle of approximately 150° The transverse basal body is associated with two individual microtubules that extend from the proximal end of the basal body toward the flagellar opening. One of these microtubules is closely appressed to a striated fibrous root that also extends from the proximal base of the transverse basal body. The longitudinal basal body is associated with a nine member microtubular root that extends from the proximal end of the basal body toward the posterior of the cell. The longitudinal microtubular root and the transverse striated fiber are connected by a striated connective fiber. In addition to the microtubules associated with the transverse and longitudinal basal bodies, a group of microtubules originates adjacent to one of the transverse flagellar roots and extends into the cytoplasm. Vesicular channels extend from the flagellar openings to the region of the basal bodies where they expand to encompass the various connective structures of the flagellar apparatus. The possible function and evolutionary importance of these structures is discussed.     

COMPARATIVE ANALYSES OF THE DINOFLAGELLATE FLAGELLAR APPARATUS. II. CERATIUM HIRUNDINELLA1

The three-dimensional structure of the flagellar apparatus in the gonyaulacoid dinoflagellate. Ceratium hirundinella var. furcoïdes (Schröder) Hub.-Pest. was determined using serial section electron microscopy. The flagellar apparatus is quite large and consists of several components. The two basal bodies nearly abut at their proximal ends and are separated by an angle of approximately 120° The broad longitudinal microtubular root extends from the cell's left edge of the longitudinal basal body and bends around the sulcal/cingular depression into the cell's left antapical horn. A transverse striated fibrous root is associated with the transverse basal body and a narrow electron dense extension is present along the anterior edge of the transverse basal body. This study revealed severa1 hitherto unreported fibrous components of the flagellar apparatus that link the various microtubular and fibrous components to themselves and to the two striated collars. A large striated fibrous connective links the two striated collars to one another. This fibrous connective is linked to another striated fibrous connective that originates from the longitudinal basal body and lies perpendicular to the longitudinal microtubular root. The readily identifiable and numerous components of the Ceratium flagellar apparatus are comparable to those of other dinoflagellates. The combined presence of well dpveloped striated collars, a striated collar connective, and a basal body angle of approximately 120° indicates that this flagellar apparatus is most like that described for Peridinioid dinoflagellates. Important similarities are also noticeable between this flagellar apparatus and that of Oxyrrhis marina.