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You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Ｙｏｕ（Ｓｅｂａｓｔｉｓｃｕｓ ｍａｒｍｏｒａｔｕｓ）精细胞的成熟变化和精子结构。褐菖Ｙｏｕ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;染色质浓缩和块状,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     

刘氏蝎蛉的精子发生和精子超微结构

【目的】精子超微结构在不同昆虫类群中变异较大,在昆虫种类鉴别和系统发育分析中具有重要意义。但截止目前,长翅目(Mecoptera)昆虫的精子发生和精子超微结构研究还很不充分。【方法】采用光学显微镜和透射电子显微镜技术,观察了刘氏蝎蛉Panorpa liui Hua的精子发生和精子超微结构。【结果】刘氏蝎蛉精原细胞在精囊内共分裂7次,产生128个精子细胞。这些精子细胞同步发育,成熟后结合形成数目略低于128的精子束。精子形成期,精子细胞内高尔基复合体产生的原顶体颗粒物质形成精子顶体;球状细胞核伸长、核内染色质凝集,形成致密的线形细胞核;分散的线粒体聚集、融合产生的副核转化形成2条线粒体衍生物。成熟精子由头部、颈区和长鞭毛组成。精子头部包括双层顶体和具有2条侧沟的细胞核两部分;颈区主要由中心粒和致密的鞘状中心粒侧体组成。鞭毛螺旋状,主要由1条9+2型轴丝、2条大小不等的线粒体衍生物和2条副体组成。【结论】刘氏蝎蛉精子束内精子数目略低于128,可能与精子复杂的形成过程及细胞的吞噬作用有关。线粒体衍生物在不同类群间差异显著,可为长翅目系统发育分析提供有用的特征。     

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。     

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。     

细角螺卵子发生的细胞学和超微结构的研究

利用组织切片和透射电镜观察细角螺卵细胞发育的显微和超微结构,结果表明:细角螺卵原细胞期细胞核体积较大,呈椭圆形,核膜明显且有不规则的凹陷,细胞质内出现大量的线粒体和高尔基体.根据卵黄颗粒物的多少和大小可将卵母细胞分为前、中、后三个时期:前期卵母细胞细胞核内染色质浓缩,核仁可见,并出现核周间隙;中期卵母细胞内细胞核移向细胞的一端,核内染色质仍呈高电子密度状态,核仁不明显或消失;后期卵母细胞内的细胞核受挤压形状变得不规则,细胞质内可见少量的线粒体,大量的卵黄颗粒聚集在细胞质中并融合成很大的卵黄球.成熟期卵母细胞卵黄物质多且有较大的脂滴.     

泥螺精子发生的超微结构研究

利用透岸民镜观察了泥螺精子发生的过程。结果表明;泥螺精子发生经历了一系列重要的形态和结构变化,主要有核逐渐延长,染色质浓缩,顶体形成,线粒体逐步发达与融合,胞质消除及鞭毛的形成等。泥螺精细胞分化可分为3个时期,在精细细胞分化过程中,细胞核形态及染色质的变化与其他软体动物有较大的差异,核内椭圆形到肾形,再变化为长圆柱形;染色质由絮状颗粒变为细纤维丝状,再变为长纤维丝状,最后向高电子密度均质状态转变,初步探讨了泥螺精子发生过程中核及细胞器的超微结构变化在分类上的意义。     

白肛海地瓜精子发生及形态的超微结构

通过透射和扫描电镜观察了白肛海地瓜(Acaudina leucoprocta)的精子发生过程及其形态结构,揭示了白肛海地瓜精子发生时期一系列变化,其精子发生分为精原细胞、初级精母细胞、次级精母细胞、精细胞、成熟精子5个时期。精原细胞体积最大。精母细胞染色质开始凝集。精细胞前顶体颗粒形成。白肛海地瓜成熟精子的超微结构为原生型,由头部、中部、尾部组成,头部圆形,最前端为顶体,核染色质凝集成团块状,中部是线粒体和中心粒复合体融合成1个超大结构,尾部长约60μm,尾部鞭毛横切面为典型的"9+2"型结构。     

中华鳖精子头部的形成

应用透射电镜技术详细研究了中华鳖精子头部形成过程的超微结构变化。结果显示,中华鳖精子头部的形成过程可分成5个连续时期：第1期前顶体泡形成并移向细胞核一侧,同侧核膜凹陷成浅窝。前顶体泡底部中央出现小的顶体颗粒,纤维物质层位于核前端与前顶体泡底壁之间,其核膜一侧的中央形成更小的顶体下颗粒,将与核内小管的形成有关。细胞核开始端移和变形。第Ⅱ期核浅窝逐渐外推,前顶体泡变成扁囊状覆盖于隆突的核顶端,顶体颗粒弥散成中等电子致密物分布于顶体帽中,纤维物质层发育为顶体下锥。环形核套微管在顶体后端的核周围逐渐形成,核内染色质开始浓缩成圆形颗粒,核膜下出现明显问隙,细胞核体积变小。顶体下颗粒消失,但其下端的核质中可见2-4条核内小管开始发生。第Ⅲ期拉长的细胞核前端突出于精子细胞外,表面有顶体复合体覆盖,核后端最宽并出现植入窝。染色质进一步浓缩,颗粒间隙变小,细胞核更细长。第Ⅳ期染色质浓缩成致密均质物,核肩之前的细胞核变细,成为核前突。环形核套微管先后改建为斜行和纵行核套微管,支持细胞突起形成“袖领”包绕顶体。第Ⅴ期核套微管解聚而消失,顶体周围的“袖领”也消失,顶体下间隙出现。结果显示中华鳖精子头部的形成过程,即核质浓缩的形态变化过程、顶体的形成和核内小管的发育与变化方面,存在许多与其他爬行动物不同之处。     

银杏雄配子体发育的细胞学研究

运用光学和电子显微镜对银杏雄配子体发育进行了研究。结果显示,花粉粒进入贮粉室后,通过侧向萌发产生吸器状花粉管。精原细胞在发育过程中依次产生生毛体、液泡状结构和纤维颗粒体。生毛体由一个电子致密的核心和由此向周围发散出的辐射状中心粒组成;液泡状结构为染色较深、质地均匀,看不到膜结构包被的圆球形,其周围细胞器丰富,DAPI染色证实液泡状结构中含有遗传物质。纤维颗粒体染色很深,外形小规则。临近受精前,精原细胞纵向分裂形成2个半球形的精细胞,成熟精核直径约40μm,而受精时与卵核融合的精核直径约20μm,说明精核在受精前体积浓缩。精核以变形虫式运动穿过较小的颈卵器口,进入卵细胞与卵核融合。在受精前的一些精细胞中可观察到其核内出现一个直径约20～30μm染色较深的球形区域,推测精核浓缩前遗传物质先浓缩到一个区域,然后精核浓缩。     

Spermiogenesis in Lumbricus herculeus; an electron microscope study

Small pieces of the sperm sacs of Lumbricus herculeus were fixed for 4 hours in chrome-osmium, embedded in methacrylate, sectioned with a Porter-Blum microtome, and studied with a R.C.A. EMU-2C electron microscope. Each spermatid of a group developing synchronously is attached by a cytoplasmic strand to a common nutrient protoplasmic mass. This mass contains mitochondria and yolk bodies but is anucleate. The proximal centriole, that is, the centriole nearer the nucleus, is at first associated with a small peg which becomes firmly attached to the nuclear membrane. Later these two bodies become separated during the development of the middle-piece which is differentiated in the usual manner from a nebenkern formed by the fusion of 6 or 7 mitochondria. The acrosome develops in relation to the dictyosome (Golgi body), itself composed of 8 or more individual flattened sacs and situated in the cytoplasm opposite the point of attachment of the spermatid to the nutrient mass. Soon after its formation, the acrosome becomes incorporated into a cytoplasmic appendage or acrosome carrier. The carrier moves from its original position, along the lateral border of the elongating nucleus, to the distal margin of the nucleus where the acrosome is deposited. No evidence was found of a centriole located at the point of junction between nucleus and acrosome as suggested by earlier workers.     

Spermiogenesis in Lumbricus herculeus : An Electron Microscope Study

Small pieces of the sperm sacs of Lumbricus herculeus were fixed for 4 hours in chrome-osmium, embedded in methacrylate, sectioned with a Porter-Blum microtome, and studied with a R.C.A. EMU-2C electron microscope. Each spermatid of a group developing synchronously is attached by a cytoplasmic strand to a common nutrient protoplasmic mass. This mass contains mitochondria and yolk bodies but is anucleate. The proximal centriole, that is, the centriole nearer the nucleus, is at first associated with a small peg which becomes firmly attached to the nuclear membrane. Later these two bodies become separated during the development of the middle-piece which is differentiated in the usual manner from a nebenkern formed by the fusion of 6 or 7 mitochondria. The acrosome develops in relation to the dictyosome (Golgi body), itself composed of 8 or more individual flattened sacs and situated in the cytoplasm opposite the point of attachment of the spermatid to the nutrient mass. Soon after its formation, the acrosome becomes incorporated into a cytoplasmic appendage or acrosome carrier. The carrier moves from its original position, along the lateral border of the elongating nucleus, to the distal margin of the nucleus where the acrosome is deposited. No evidence was found of a centriole located at the point of junction between nucleus and acrosome as suggested by earlier workers.     

中国雨蛙精子形成的研究

中国雨蛙的精子形成过程中,细胞核的浓缩经历了５个时期。从第１期进入第２期,染色质纤维增粗并聚集成卷曲的柱状结构。从第２期进入第３期,染色质纤维进一步增粗,细胞核逐渐伸直成柱状。进入第４期,染色质紧密聚集,纤维之间间隙很小。进入第５期,染色质纤维聚集成均匀的致密结构。伴随着染色质的浓缩,核膜数次更新,核内不参与浓缩的物质渐次从核中排出,核中出现一串核泡。顶体在染色质未浓缩之前（第１期）开始分化,由一     

SPERMIOGENESIS IN THE PULMONATE SNAIL,EUHADRA HICKONIS III. FLAGELLUM FORMATION*

The formation of the flagellum in the spermatid of the Japanese land snail, Euhadra hickonis, is introduced by the appearance of a central indentation in the differentiated posterior side of the spherical nucleus early in spermiogenesis. One centriole moves to this part of the cell, changes in several structural respects and acquires a short-lived “centriole adjunct”. At first it lies tangential to the nuclear surface as it begins to induce formation of the flagellar axoneme; then it turns so that its proximal end fits into the deepening nuclear indentation (“implantation fossa”). Cytoplasmic tubules appear to mediate this shift in direction. Internal changes in the centriolar components begin as it initiates formation of the axoneme, and continue throughout spermiogenesis. First, a dense “cap” forms at its proximal end, the microtubular triplets become doublets and a pair of singlets occupies the center of the complex. All these microtubules extend from the dense cap and are continuous with those of the axoneme. As the basal body (modified centriole) becomes set in the implantation fossa, the material of the centriole adjunct forms 9 strands, which are continuous with the peripheral coarse fibers when these develop. The microtubular doublets of the basal body are visible for a short time between the fiber strands; in the mature spermatozoon they are found embedded in the basal body portions of the coarse fibers in a degenerated form. Posterior to the basal body, however, they separate from the inner sides of the striated coarse fibers and become the doublets of the axoneme. The proximal part of the elongating axoneme lies in a posterior extension of the cell, in which glycogen particles and mitochondria are conspicuous. As the mitochondria unite into a sheath tightly surrounding the axoneme, the structure of their cristae changes to form a paracrystal-line “mitochondria derivative”, which consists of many layers close to the nucleus and progressively fewer posteriorly. Outside of this “primary sheath”, more modified mitochondria unite to form a “secondary sheath” of paracrystalline lamellae which encloses a compartment, filled with glycogen particles, that extends in a low-pitched helix nearly to the end of the flagellum. In the late spermatid, microtubules become arranged at regular intervals around the nucleus and secondary sheath of the flagellum for a short period while the remaining cytoplasm and spermatid organelles such as the Golgi complex are being discarded. The flagellum of the mature spermatozoon is 250–300 μm in length, tapering gradually from a diameter of ca 1 μm just behind the nucleus to less than 0.3 μm at its tip, as the result of reduction in the amount of stored glycogen, the number of paracrystalline lamellae and the diameter of the peripheral fibers.     

Fine structure of the spermatozoa of Chiton marginatus (mollusca: Amphineura), with special reference to nucleus maturation

The spermatozoon of Chiton marginatus is a long uniflagellate cell displaying structural features of “modified sperm.” The nucleus presents a conical shape with a long apical cylindrical extension. The chromatin is homogeneously dense. Scattered inside the condensed nucleus, a few nuclear lacunae are visible. The acrosomal complex is lacking. Some mitochondria are located in a laterofrontal structure side by side with the nucleus. The typical midpiece is absent. The cytoplasm forms a thin layer around the nucleus and the mitochondria. The proximal centriole is in a basal nuclear indent. The distal centriole serves to form the axoneme tail with the usual microtubular pattern. During nuclear maturation, the early spermatid nucleus is spherical and contains fine granular chromatin patches. The nuclear envelope shows a deposit of dense material at the base of the nucleus, forming a semicircular invagination occupied by a flocculent mass. In middle spermatid stage, the chromatin gets organized in filaments, coiled as a hank, attached over the inner surface of the basal thickening of the nuclear envelope. The nucleus starts to elongate anteroposteriorly. At the pointed apical portion of the spermatid, a group of microtubules is observed seeming to impose external pressure to the nucleus giving rise to the long apical nuclear point. The mitochondria have a basal position. Late spermatids have an elongated conical nucleus. The chromatin filaments are further condensed, and lacunae appear inside the nucleus. Some mitochondria migrate to a lateral position.     

Ultrastructural analysis of spermiogenesis in Admetus pomilio (Arachnida,amblypygi)

The mature spermatozoon of Admetus pomilio is a spherical cell containing nucleus and tightly coiled flagellum. In early spermatids the Golgi apparatus forms the acrosomal vesicle and at the opposite side the distal centriole gives rise to the axonemal complex of the sperm tail. As the nucleus elongates, chromatin forms twisted filaments and the spermatid nucleus takes on a helical form. Microtubules are juxtaposed with the nucleus envelope, which is separated from a central chromatin mass by an electron lucid region. A long perforatorium, located on the border of the chromatin mass, runs helically in the nucleus from the centriolar region to subacrosomal space. During tail elongation, the anterior part of the axoneme is surrounded by a long, spiral mitochondrial sheath. In the late spermatid, chromatin filaments appear twisted and become aggregated. The nucleus and flagellum undergo further contortions in which the nucleus coils and the flagellum winds up into the body of the cell and coils in a regular fashion. The mitochondrial sheath surrounds about 2/3 of the 9 + 3 axoneme. These features of spermatid ultrastructure resemble those in the primitive Liphistiomorpha.     

日本沼虾精子发生的研究

对日本沼虾精子发生全过程的电镜观察表明：精原细胞核染色质分散,胞质内有线粒休、内质网的分布。初级精母细胞核染色质块状,不均匀地分布于核中,内质同多小泡多。次级精母细胞核染色质大多分布于核膜内侧,内质网聚集成团,精细胞分化形成精子的早期,胞核增大,核侧形成内质同多小泡的聚合体;中期的核内染色质浓缩,同时形成空囊状结构,     

Spermiogenesis in three species of cicadas (Hemiptera: Cicadidae)

Spermiogenesis in three species of cicadas representing one cicadettine (Monomatapa matoposa Boulard) and two cicadines (Diceroprocta biconica [Walker] and Kongota punctigera [Walker]) was investigated by light and electron microscopy. Although spermiogenesis was occurring in the testis of adult males of all species, earlier spermiogenic stages were observed in D. biconica only. While spermiogenesis was similar to that described for other insects, some differences were noted. For example granular material did not assemble around the centriole to form a centriolar adjunct but did accumulate in the cytoplasm of early spermatids adjacent to a region of the nuclear membrane where nuclear pores were aggregated. In late spermatids this material accumulated anterior to the mitochondrial derivatives in a developing postero‐lateral nuclear groove. While this material has been named the ‘centriolar adjunct’ by previous authors, its formation away from the centriole raises questions about its true identity. Second, during acrosome maturation an ante‐acrosomal region of cytoplasm develops. Although present in later spermatids, this region is lost in spermatozoa. Interspecific variations in chromatin condensation patterns and the number of microtubule layers encircling the spermatid nucleus during spermiogenesis were noted.