七星瓢虫精母细胞内轴丝的形态发生(英文)

应用细胞整装技术研究了七星瓢虫精子轴丝的早期形态发生和超微结构。在精子发生期间,起源于中心粒的两对基体—轴丝复合体出现在精母细胞内,在分裂间期它们彼此完全分离。当基体—轴丝复合体附着于精细胞核的核膜上,中心粒附体开始发生于生长轴丝的近心端,在染色质凝聚前中心粒附体最大。生长着的轴丝伴随着凝聚细胞核伸长。一个早期基体—轴丝复合体的轴丝是由具有内、外动力蛋白臂的9个双微管组成,缺少中央微管。     

褐菖■精细胞晚期的变化及精子结构研究

本文研究卵胎生硬骨鱼褐菖（Ｓｅｂａｓｔｉｓｃｕｓｍａｒｍｏｒａｔｕｓ）精细胞的成熟变化和精子结构。褐菖精细胞发育晚期已具有硬骨鱼类精子的结构雏形：细胞核的背面较平坦,腹面稍外鼓,呈弧面;染色质浓缩成团块状,核的腹侧和后端的染色质较致密;中心粒复合体由近端中心粒和基体组成,近端中心粒和基体排成“Ｌ”形;近端中心粒向细胞核的背侧伸出中心粒附属物,中心粒附属物由９条微管组成,９条微管围成一筒状结构,类似轴丝。在晚期精细胞形成精子的过程中,中心粒附属物和近端中心粒相继退缩以至消失不见,同时细胞核后端的形状也随着发生变化。中心粒附属物和近端中心粒的相继消失可以看作是成熟的最后标志。精子的中心粒复合体由基体及其上方的基体帽组成,袖套接于核的后端,其中约有３０～４０个线粒体;鞭毛从袖套腔中伸出,鞭毛的中心结构是轴丝;轴丝外方为细胞质形成的侧鳍,在鞭毛的近核段,轴丝两侧的侧鳍较宽且不对称。     

七星瓢虫精子鞭毛的超微结构(英文)

应用细胞整装制备和超薄切片技术,在透射电子显微镜下检查了七星瓢虫成熟精子鞭毛的超微结构。精子鞭毛是由一个典型的9＋9＋2轴丝,两个同形结晶的线粒体衍生物,两个附体（每个附体具有两部分,一个嗜锇致密月牙体和一个海绵月牙体）和一个非结晶体组成,在鞭毛终端部,仅存的轴丝失去了两个中央微管保留了9个具有动力蛋白臂的双微管和9个附微管。     

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。     

γ-微管蛋白研究进展

概述了近年来对γ-微管蛋白复合体结构、分子机制以及功能的研究进展.γ-微管蛋白是真核生物体内一种重要的保守性功能蛋白,以γ-微管蛋白小复合体和γ-微管蛋白环式复合体两种形式存在.通过γ-微管蛋白复合体结合蛋白定位于微管组织中心,参与微管的晶核起始以及有丝分裂纺锤体的组装等细胞功能.     

杜氏利什曼原虫无鞭毛体形态及分裂过程的电镜观察

无鞭毛体呈椭圆形,后部有深杯样表膜凹陷,虫体一侧有一小突起。膜下微管数为74—90个。细胞核有1—3个核仁,细胞质内充满核糖体,动基体大小不一,多呈腊肠形,由动基体延伸形成长袋状线粒体。靠近鞭毛袋一侧有一组4个游离微管,鞭毛轴丝为9+2结构,并具有基板_1和基板_2结构,基体为9组三联微管。 无鞭毛体分裂从新鞭毛轴丝形成和动基体DNA纤丝伸长开始,以后DNA纤丝带出现裂隙,继之核仁裂碎、消失,形成核内纺锤体,开始细胞核的分裂,随后虫体一侧表膜出现凹陷,新膜下微管和表膜先后形成,并从此处向细胞内伸入,最后完全包绕两个分裂的虫体,完成细胞分裂。随着虫体的发育繁殖,含虫空泡涨大,电子致密度变低。分裂后的无鞭毛体贴附到含虫空泡膜,并向巨噬细胞细胞质内移动,最后离开原来的含虫空泡,形成新的含虫空泡。     

蕨类植物精细胞运动器和细胞骨架的研究

介绍了近年来蕨类植物游动精子运动器和细胞骨架的研究进展.游动精子由配子体精子器中的非运动细胞发育形成,其分化过程包括了运动器官和细胞骨架的合成和组装.精子发生过程中形成的运动器的各部分结构包括鞭毛、基体、多层结构及附属结构;基体是细胞中新形成的结构,在不同类群的蕨类植物中分别由双中心粒、分支生毛体和生毛体产生.鞭毛、基体和多层结构中的微管带形成了游动精子三个独特的微管列阵,由于微管蛋白的后修饰作用这些微管列阵十分稳定;centrin是运动器中的重要成分,但功能尚不清楚,可能和细胞骨架及运动器的构建有关.     

滇蛙多盘吸虫精子超微结构

利用透射电镜研究多盘吸虫精子的形态和结构。它属于单殖类中Ｐｏｌｙｏｐｉｓｔｈｏｃｏｔｙｌｅａ类型。精子细线形,含两根融入精子内的９＋１型轴丝,细长的细胞核,纤细的线粒体和微管。在第二根轴丝出现前的区段无微管的分布,具两根轴丝的主干段轴丝外无外侧管;细胞核消失后微管呈整圈排列;精子后部含糖原颗粒,背腹面中央向髓布内凹呈哑铃状并两侧向外突出形成波动膜;由精细胞则来的区段具外饰物。     

蟋蟀精子形成部分时期尾部超微结构观察

通过对黄脸油葫芦精子尾部形成过程4～10期超微结构的观察,发现该虫精子细胞发育至第6期轴丝微管束9 9 2完整形成;7、8两期精子细胞内一些高尔基体、内质网膜系统结构包绕着轴丝;第9期精子细胞及成熟精子轴丝内副微管、双微管中的A微管、中央单微管内充满小圆柱状纤维;中心粒侧体纤维状,成熟精子的线粒体衍生体内不具纵嵴;细胞质膜外不具发达的糖蛋白套。通过比较发现该虫精子与蝗总科癞蝗科精子类型比较相似,同属于原始类型精子。     

耳鲍精子的超微结构

本文利用透射电子显微镜对耳鲍(Haliotis asinina Linnaeus)精子的形态及超微结构进行了研究.研究结果表明:耳鲍的精子由头部、中段和尾部三部分组成,全长 41.6 μm.精子头部长 1.8 μm,头部由顶体、顶体下腔和细胞核组成,顶体电子密度比较均匀,呈圆锥形,长 0.6 μm,基部宽度为 0.65 μm,占头部长的 1/3;顶体下腔长 0.03 μm,宽为 0.65 μm,腔中含有中等电子密度物质;细胞核圆棒状,长 1.17 μm,核中部的宽度为 1.0 μm.精子中段较短,长 0.51 μm,宽 1.2 μm,主要由 5 个线粒体包围一对中心粒构成.尾部是一根鞭毛,从前到后逐渐变细,鞭毛是由细胞质膜包被的轴丝组成,轴丝为典型的"9 2"微管结构,即轴丝是由两个中心微管及均匀分布在中心微管周围的 9 对双联体微管组成.因此,耳鲍与其它鲍类精子的基本结构相似,形态结构的主要差异表现在三个方面:一是耳鲍精子的头部似圆锥形,长 1.8 μm,是目前已研究的鲍类中头部最短的种类;二是耳鲍精子顶体长比其基部宽要小,顶体电子密度比较均匀,顶体与核的电子密度差异不明显;三是耳鲍精子中段线粒体的数量为 5 个,没有发现 6 个线粒体现象的存在[动物学报 53(3):552-556,2007].     

TETRAD BASAL BODY-AXONEME COMPLEXES IN THE PRIMARY SPERMATOCYTE OF THE SILKWORM, BOMBYX MORI

Abstract  Using cell whole mount preparation, tetrad basal boby-axoneme complexes in the primary spermatocyte from testicular cysts of fourth instar larvae of Bombyx mori are examined by transmission electron microscopy. There exist two paired basal body-axoneme complexes and the two orthogonally oriented basal bodies are linked together with distal and proximal linking fibers. The growing complex displays voluminous distal swelling. At this stage, the axoneme consists of nine microtubular doublets. A connecting nodule is found at the juncture of basal body's triplet and axoneme's doublet, and the A and B tubules of the former continue through the nodule to become the ones of the latter.     

OBSERVATIONS ON THE CENTRIOLES OF THE SEA URCHIN SPERMATOZOON

The spermatozoon of Lytechinus variegatus has two parallel centrioles. The basal body of the flagellum consists of the proximal centriole (a short cylinder of nine tubule-triplets) and its distal extension of nine tubule-doublets. The distal centriole lies near the distal end of the basal body, between the nucleus and the mitochondrion. The observations suggest that both the proximal and the distal centrioles are polarized structures, their tubule-triplets pitched in the same direction and their distal ends associated with the flagellar axoneme and with the mitochondrion, respectively. The distal centriole in different spermatozoa occupies different positions around the basal body-flagellum complex.     

ULTRASTRUCTURE OF THE FLAGELLAR APPARATUS OF PYROBOTRYS (CHLOROPHYCEAE)1

The flagellar apparatus of Pyrobotrys has a number of features that are typical of the Chlorophyceae, but others that are unusual for this class. The two flagella are inserted at the apex, but they extend to the side of the cell toward the outside of the colony, here designated as the ventral side. Four basal bodies are present, two of which extend into flagella. Four microtubular rootlets alternate between the functional and accessory basal bodies. In each cell, the two ventral rootlets are nearly parallel, but the dorsal rootlets are more widely divergent. The rootlets alternate between two and four microtubules each. A striated distal fiber connects the two functional basal bodies in the plane of the flagella. Two additional, apparently nonstriated, fibers connect the basal bodies proximal to the distal fiber. Another striated fiber is associated with each four-membered rootlet near its insertion into the flagellar apparatus. A fine periodic component is associated with each two-membered rootlet. A rhizoplast-like structure extends into the cell from each of the functional basal bodies. The arrangement of these components does not reflect the 180° rotational symmetry that is usually present in the Chlorophyceae, but appears to be derived from a more symmetrical ancestor. It is suggested that the form of the flagellar apparatus is associated with the unusual colony structure of Pyrobotrys.     

ULTRASTRUCTURAL ORGANIZATION OF CILIA AND BASAL BODIES OF THE EPITHELIUM OF THE CHOROID PLEXUS IN THE CHICK EMBRYO

Ultrastructural studies were performed on normal and abnormal cilia and basal bodies associated with the choroidal epithelium of the chick embryo. Tissues were prepared in each of several fixatives including: 1% osmium tetroxide, in both phosphate and veronal acetate buffers; 2% glutaraldehyde, followed by postfixation in osmium tetroxide; 1% potassium permanganate in veronal acetate buffer. Normal cilia display the typical pattern of 9 peripheral doublets and 2 central fibers, as well as a system of 9 secondary fibers. The latter show distinct interconnections between peripheral and central fibers. Supernumerary fibers were found to occur in certain abnormal cilia. The basal body is complex, bearing 9 transitional fibers at the distal end and numerous cross-striated rootlets at the proximal end. The distal end of the basal body is delimited by a basal plate of moderate density. The tubular cylinder consists of 9 triple fibers. The C subfibers end at the basal plate, whereas subfibers A and B continue into the shaft of the cilium. The 9 transitional fibers radiate out from the distal end of the basal body, ending in bulblike terminal enlargements which are closely associated with the cell membrane in the area of the basal cup. One or 2 prominent basal feet project laterally from the basal body. These structures characteristically show several dense cross-bands and, on occasion, are found associated with microtubules.     

DEVELOPMENT OF THE FLAGELLAR APPARATUS AND FLAGELLAR ORIENTATION IN THE COLONIAL GREEN ALGA GONIUM PECTORALE (VOLVOCALES)1

Vegetative cells of Gonium pectorale have a fine structure similar to that of Chlamydomonas. In addition, three zones comprise an extracellular matrix; a fibrillar sheath and tripartite boundary surround individual cells, and a fragile capsule zone surrounds the entire colony. Cytokinesis is accomplished by a phycoplast and cleavage furrow. The flagellar apparatus of the immature vegetative cell of this colonial alga is similar to that of Chlamydomonas, but the basal bodies are slightly separated at their proximal ends. The four microtubular rootlets alternate between two and four members. During development, the basal bodies become further separated and nearly parallel. The distal fiber is stretched, but it remains attached to both basal bodies. At maturity, the basal bodies of peripheral cells of the colony have rotated in opposite directions on their longitudinal axes resulting in a displacement of the distal fiber to one side, an asymmetrical orientation of the rootlets and loss of 180° rotational symmetry. Central cells remain similar to Chlamydomonas in that basal bodies do not rotate, rootlets are cruciate, the distal fiber remains medially inserted and 180° rotational symmetry is conserved. A “pin-wheel” configuration of flagellar pairs and the orientation of parallel rootlets toward the colony perimeter probably accounts for the rotation of the colonies during forward swimming. In addition, these ultrastructural features support the traditional placement of G. pectorale as an intermediate between the unicellular Chlamydomonas and the more complex colonial volvocalean genera.     

Location of the basal disk and a ringlike cytoplasmic structure, two additional structures of the flagellar apparatus of Wolinella succinogenes.

The basal body of Wolinella succinogenes consists of a central rod, a set of two rings (L and P rings), a basal disk from 70 to 200 nm in diameter, and a terminal knob. In negatively stained preparations of flagellar hook-basal body complexes, some disks remain fixed perpendicularly to the grid and show that such a disk is located on the distal side of the P ring. The basal disks have been isolated with and without the P ring; in both cases there is a hole in the center of the disk. The diameter of the disk is smaller in the presence of the P ring. The L-P ring complex is therefore assumed to be a bushing for the rod. Thin sections of whole bacteria and spheroplasts reveal that the disk is attached to the inner surface of the outer membrane. At the insertions of the flagellar hook-basal body-basal disk complexes, depressions are visible in negatively stained preparations of whole bacteria and spheroplasts. A new ringlike structure is connected to an elongation of the basal body into the cytoplasm in both preparations. Its diameter (60 nm) is larger than that of the M ring. A heavily stained compartment can be seen in between the new ringlike structure and the basal disk, which may be formed by the energy transducing units.     

Tubulobulbar complexes are intercellular podosome-like structures that internalize intact intercellular junctions during epithelial remodeling events in the rat testis

Tubulobulbar complexes are actin-related double-membrane projections that resemble podosomes in other systems and form at intercellular junctions in the seminiferous epithelium of the mammalian testis. They are proposed to internalize intact junctions during sperm release and during the translocation of spermatocytes through basal junction complexes between neighboring Sertoli cells. In this study we probe apical tubulobulbar complexes in fixed epithelial fragments and fixed frozen sections of rat and mouse testes for junction molecules reported to be present at apical sites of attachment (ectoplasmic specializations) between Sertoli cells and spermatids. The adhesion molecules nectin 2 (PVRL2), nectin 3 (PVRL3) and alpha 6 integrin (ITGA6) are present in the elongate parts of tubulobulbar complexes and concentrated at their distal ends. Tubulobulbar complexes contain cortactin (CTTN), a key component of podosomes, and vesicles at the distal ends of tubulobulbar complexes that contain junction molecules are related to early endosome antigen (EEA1). N-cadherin (CDH2), a protein reported to be present at ectoplasmic specializations, is not localized to these unique junctions or to tubulobulbar complexes but, rather, is primarily concentrated at desmosomes in basal regions of the epithelium. Our results are consistent with the conclusion that tubulobulbar complexes are podosome-like structures that are responsible for internalizing intact intercellular junctions during spermatogenesis.     

MORPHOGENESIS OF THE AXONEME IN THE SPERMATOCYTE OF COCCINELLA SEPTEMPUNCTATA LINNAEUS

Abstract  Using cell whole mount preparation, early morphogenesis and ultrastructure of the axoneme of Coccinella septempunctata L. spermatocyte were investigated by transmission electron microscope. During spermatogenesis two pairs of basal body-axoneme complexes originated from centrioles are found in the spermatocyte and they are separated completely from each other at interkinesis. The centriolar adjunct begins to generate while a basal body-axoneme complex is attached to the nuclear envelope of a spermatid nucleus, and it, on the proximal end of a growing axoneme, reaches a maximum before chromatin condensation. The growing axoneme is accompanied by the condensable nucleus elongation. The early axoneme of a basal body-axoneme complex consists nine doublets with only inner and outer dynein arms, no central microtubules.     

A MITOCHONDRIAL PUMP IN THE CELLS OF THE ANAL PAPILLAE OF MOSQUITO LARVAE

Mosquito larvae were raised to fourth instar in distilled water in order to maximally stimulate the salt-absorbing function of the anal papillae. Two exceptional features are observed, at the fine structure level, in the epithelial lining of the papillae. At the basal (cuticular) surface of the cells, the cell membrane is thrown into deep, narrow, parallel folds. The folds not only follow a rigid pattern at the cellular level but are also arranged at right angles to the long axis of the entire organ. A complicated pattern of canaliculi connects to the distal (plasma) surface of the cells. At this surface, paired mitochondria (sometimes triplets) are clamped about the membranes of the canaliculi to form structures referred to as "mitochondrial pumps." Mitochondria are also oriented in rather precise relation to the basal folds. Glycogen granules are found throughout the cytoplasm. The endoplasmic reticulum is sparse. The Golgi zones are flew and not well developed. Unidentifiable, irregular vesicles with lipid-like membranes are found associated with the basal folds. The distal (plasma) surfaces of the cells are covered by a homogeneous granular layer the composition of which is unknown.