中国鲎精子发生的研究:Ⅱ.精子形成

应用电技术研究中国鲎精子形成过程和特点,早期精子细胞核圆,染色质呈网状分布,胞质中有许多线粒体和高尔基液泡,精子形成期间,出现合胞体现象,核分裂而胞质不分裂,细胞通过胞质桥相联系,随后出现隔板,逐渐将细胞核分开。细胞随访核向后移动而呈现极化现象。核的顶部出现一个高尔基－线粒体区,顶体由高在液泡演变而。精子形成期间,核中央位置形成贯穿整个的中央通道,并在核中形成植入窝,中心粒位于其中,成熟精子胞质极     

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。     

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     

拟异蚖和古蚖精子的超微形态和精子形成的研究(原尾目:古蚖科)

余山拟异蚖和3种古蚖的精子均为扁圆形,未见顶体,线粒体集中在一侧;核呈环形、边位、中部由膜状体分布其间.领结古蚖的早期精细胞为球形,染色质凝集成团,继而核中裂并沿细胞赤道逐渐围绕成环,染色质呈细沙状,胞间有“桥”相通.核膜一端开始内陷,出现黑点.待发育到中期精细胞,这些黑点逐渐形成奇特的管状核膜陷体;染色质变成短线形,随后排成4—5行.线粒体颗粒状,细胞间仍有“桥”连通.晚期精细胞的染色质凝集成粗带,最后形成光滑质密的核,而多余的核物质,一段一段从精子一端脱离,形成一串孢囊状体夹在精子之间,待精子成熟游离时,这些孢状体分散开来.从观察结果表明拟异蚖精子与古蚖的非常相近.     

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,     

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。     

半滑舌鳎精子发生和精子形成的超微结构

用电子显微镜对半滑舌鳎(Cynoglossus semilaevis)精子发生的过程及精子的超微结构进行了观察。半滑舌鳎精巢属于小叶型,精小叶由各期生精细胞和支持细胞构成。半滑舌鳎的精子发生经历了初级精原细胞、次级精原细胞、初级精母细胞、次级精母细胞和精子细胞,再经过精子形成过程发育成为精子。初级精母细胞成熟分裂的前期Ⅰ,同源染色体经历了联会复合体形成和解聚的变化。在精子形成的过程中,精细胞大致经历了核质浓缩、线粒体迁移及鞭毛的发生等过程。核质浓缩时,精细胞核内位于植入窝周围的染色质首先由细颗粒状浓缩成粗大颗粒状,然后细胞核其他部位的染色质也逐渐浓缩成粗大颗粒状。这些已浓缩成粗大颗粒状的染色质再进一步浓缩为电子密度高的均匀状物质。随着核质的浓缩,核外膜与核内膜之间的间隙增大形成核膜间隙,核内一些没有参与染色质浓缩的物质通过出芽形成囊泡,先排入核膜间隙,然后再外排到细胞质中。核浓缩过程中细胞核的体积和表面积都大大缩小;鞭毛的形成与细胞核的浓缩是同步进行的,当一对中心粒移近细胞核时,核膜凹陷形成植入窝,其周围染色质浓缩的同时,远端中心粒(基体)逐渐向后产生轴丝。成熟精子无顶体,头细长,主要为核占据,核凹窝发达,线粒体4-5个环绕在鞭毛基部形成袖套,尾细长,具侧鳍,尾部轴丝为"9 2"结构。     

褶纹冠蚌精子发生的研究

光镜和透射电镜研究结果表明：褶纹冠蚌精子发生是非同步的,精子发生经历了一系列重要的形态和结构变化,主要包括：核逐步延长、染色质浓缩、线粒体逐渐发达与融合、胞质消除以及鞭毛的形成。精原细胞胞质中含有许多致密的轴纤丝,它们后来形成鞭毛轴丝。精母细胞质中含有线粒体、中心粒、内质网和电子透明的囊泡。精细胞分化为４个时期。成熟精子属原始类型,由头部、中段和尾部三部分组成。多核结构和细胞间桥自始至终存在于精子     

长江华溪蟹精子形成的研究

1994年9-11月,对采自安徽省宁国县的长江华溪蟹(Sinopotamon yangtsekiense),利用透射电镜技术,并结合细胞化学方法,研究了其精子形成过程。结果显示:早期精细胞圆形,胞质丰富,内含大量内质同小泡及线粒体。核也为圆形,较小。精细胞开始分化,细胞膨胀为长椭圆形,核质重新分布,分别移向细胞的两端。精子的顶体由高尔基体产生,其过程为:高尔基体分泌产生囊泡,继而形成原顶体囊,进一步发育成顶体囊,最后形成顶体。在顶体囊与核之间有膜复合体。中心粒位于核内面凹陷处。细胞化学反应显示,核杯为Feulgen阳性,顶体为PAS阳性。       

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。     

锯缘青蟹精子发生的超微结构

采用透射电镜观察锯缘青蟹精子发生过程中超微结构的变化,结果表明：精原细胞椭圆形,染色质分布于核膜周围,胞质中具嵴少的线粒体,内质网小泡等。初级精母细胞染色质呈非浓缩状,胞质中具众 内质网小泡,特殊的膜系及晶格状结构。次级精母细胞核质间出现由内质小泡聚集成的腔。     

三疣梭子蟹精子的发生及超微结构研究

用透射电镜观察三疣梭子蟹的精子发生过程及精子的超微结构。发现精原细胞较大，卵圆形。核大而圆，染色质分散，附着于核膜之内侧。胞质少，内含线粒体和粗面内质网等结构。初级精母细胞比精原细胞略小，卵圆形，核内染色质凝聚成团块，散布于核质中，除线粒体外，胞质中尚含有很多内质网小泡和游离核糖体。次级精母细胞多边形，核卵圆形，染色质致密，线粒体等含量均下降。早期精细胞质中由内质网产生许多颗粒，这些颗粒合并成为大     

Sperm ultrastructure of the spider crab Maja brachydactyla (Decapoda: Brachyura)

This study describes the morphology of the sperm cell of Maja brachydactyla, with emphasis on localizing actin and tubulin. The spermatozoon of M. brachydactyla is similar in appearance and organization to other brachyuran spermatozoa. The spermatozoon is a globular cell composed of a central acrosome, which is surrounded by a thin layer of cytoplasm and a cup‐shaped nucleus with four radiating lateral arms. The acrosome is a subspheroidal vesicle composed of three concentric zones surrounded by a capsule. The acrosome is apically covered by an operculum. The perforatorium penetrates the center of the acrosome and has granular material partially composed of actin. The cytoplasm contains one centriole in the subacrosomal region. A cytoplasmic ring encircles the acrosome in the subapical region of the cell and contains the structures‐organelles complex (SO‐complex), which is composed of a membrane system, mitochondria with few cristae, and microtubules. In the nucleus, slightly condensed chromatin extends along the lateral arms, in which no microtubules have been observed. Chromatin fibers aggregate in certain areas and are often associated with the SO‐complex. During the acrosomal reaction, the acrosome could provide support for the penetration of the sperm nucleus, the SO‐complex could serve as an anchor point for chromatin, and the lateral arms could play an important role triggering the acrosomal reaction, while slightly decondensed chromatin may be necessary for the deformation of the nucleus. J. Morphol., 2010. © 2009 Wiley‐Liss, Inc.     

Spermiogenesis and sperm structure in the crabUca tangeri (Crustacea,Brachyura), with special reference to the acrosome differentiation

Summary Early spermatids of the crabUca tangeri consists of the nucleus of granular chromatin and the cytoplasm, which contains a proacrosomal vesicle in close association with membrane lamellae. In the mid spermatids an invagination of the acrosomal vesicle membrane gives rise to the formation of the perforatorium, a spindle-shaped tubule which encloses tubular membranous structures. The pair of centrioles located at the base of the acrosome is not directly involved in perforatorial differentiation. The acrosomal vesicle shows a heterogeneous content composed of the operculum, the thickened ring, and three layers of different materials concentrically arranged around the perforatorium. During the late spermatid stage the nuclear profile differentiates numerous slender arms and the chromatin arranges into fibers. Membranous tubules from the cytoplasm become incorporated into the tubular structures of the perforatorium. The mature spermatozoon has the typical structure of the branchyuran sperm, with a complex acrosome, cupped by the nucleus, and a thin cytoplasmic band intervening between the former main elements. The centrioles are degenerate. The nuclear arms are unusually numerous (more than 20) and lack microtubules or microtubular derivatives.     

斑节对虾精子发生的超微结构

斑节对虾精子发生划分为精原细胞、初级精母细胞、次级精母细胞、精子细胞和精子五个阶段。精子发生中，从精原细胞到精子，染色质经历了从以异染色质为主变为高度凝聚态，再经解聚为弥散絮状的变化过程。同时，核从具有完整核膜变为核膜不完整。成熟的的精子含有核仁。顶体由高尔基囊泡逐渐演化而成，并向外伸长成为棘突。这是斑节对虾精子发生的主要特征。     

Spermatogenesis and distinctive mature sperm in the giant freshwater prawn, Macrobrachium rosenbergii (De Man, 1879)

The structures of differentiating male germ cells in the testis of the giant freshwater prawn, Macrobrachium rosenbergii, were studied by light and electron microscopy. Based on ultrastructural characteristics, the developing male germ cells are classified into 12 stages, including spermatogonia, six phases of primary spermatocytes (leptotene, zygotene, pachytene, diplotene, diakinesis and metaphase), secondary spermatocyte, three stages of spermatids and mature sperm. During spermatogenesis, the differentiating germ cells have characteristics similar to those of other invertebrates, but they exhibit some unique characteristics during spermiogenesis. In particular, an early spermatid has a round nucleus with highly condensed heterochromatin, appearing as thick interconnecting cords throughout the nucleus. In contrast to most invertebrates and vertebrates, the chromatin begins to decondense in one-half of the nucleus at the mid spermatid stage. In the late spermatid, the chromatin becomes almost entirely decondensed with only a small crescent-shaped heterochromatin patch remaining at the anterior pole of the nucleus. Mature sperm possess an everted umbrella-shaped plate with a spike covering the anterior pole of the nucleus, whose chromatin is totally decondensed as only small traces of histones H3 and H2B remain. The acrosome appears at the ruffled border of the spike plate as small sac-like structures. Few mitochondria remain in the cytoplasm at the posterior pole.     

Spermiogenesis in the Marine Shrimp, Sicyonia ingentis

Spermiogenesis in the marine prawn Sicyonia ingentis was examined using transmission electron microscopy. The acrosomal vesicle, derived from the fusion of pro-acrosomal vesicles blebbed from the nuclear envelope, contains the membrane pouches, anterior granule and a spike. The anterior granule is formed from the coalescence of granular aggregates within the proacrosomal vesicles. Primordia underlying the apical acrosomal vesicle membrane polymerize to form a spike approximately 6 μm long. The convoluted pouch membranes arise from the posterior acrosomal vesicle membrane. Lateral and apical portions of the acrosomal vesicle are surrounded by a pentalaminar membrane comprised of the spermatid plasma membrane and the acrosomal vesicle membrane. Subacrosomal structures include the dense saucer plate, granular core and crystalline lattice. These components condense just posterior to the acrosomal vesicle and are separated from the chromatin by a nuclear plate.
The spermatid nucleus becomes surrounded by rough endoplasmic reticulum (RER) and membranous lamellar bodies. RER gives rise to smooth endoplasmic reticulum. These membrane systems degenerate, forming a band of reticular elements around the lateral and posterior portions of the nucleus. The nucleus undergoes condensation followed by decondensation with concomitant breakdown of the nuclear envelope. The resultant chromatin is fibrillar in appearance.     

Transition of basic protein during spermatogenesis of <Emphasis Type="Italic">Fenneropenaeus chinensis</Emphasis> (Osbeck, 1765)

According to the ultrastructural characteristic observation of the developing male germ cells, spermatogenesis of the crustacean shrimp, Fenneropenaeus chinensis, is classified into spermatogonia, primary spermatocytes, secondary spermatocyte, four stages of spermatids, and mature sperm. The basic protein transition during its spermatogenesis is studied by transmission electron microscopy of ammoniacal silver reaction and immunoelectron microscopical distribution of acetylated histone H4. The results show that basic protein synthesized in cytoplasm of spermatogonia is transferred into the nucleus with deposition on new duplicated DNA. In the spermatocyte stage, some nuclear basic protein combined with RNP is transferred into the cytoplasm and is involved in forming the cytoplasmic vesicle clumps. In the early spermatid, most of the basic protein synthesized in the new spermatid cytoplasm is transferred into the nucleus, and the chromatin condensed gradually, and the rest is shifted into the pre-acrosomal vacuole. In the middle spermatid, the nuclear basic protein linked with DNA is acetylated and transferred into the proacrosomal vacuole and assembled into the acrosomal blastema. At the late spermatid, almost all of the basic protein in the nucleus has been removed into the acrosome. During the stage from late spermatid to mature sperm, some de novo basic proteins synthesized in the cytoplasm belt transfer into the nucleus without a membrane and almost all deposit in the periphery to form a supercoating. The remnant histone H4 accompanied by chromatin fibers is acetylated in the center of the nucleus, leading to relaxed DNA and activated genes making the nucleus non-condensed.