分株紫萁卵发生的超微结构

用透射电镜对蕨类植物分枝紫萁(Osmunda cinnamamae L. var. asiatica Fernald)卵发牛进行了超微结构的研究。卵发生过程中,许多泡囊不仅移向细胞周围,而且在细胞质膜内排为一列,并通过胞吐作用聚集在细胞质膜外,它们释放或分泌嗜锇物质。观察到少数泡囊内含片层状结构的嗜饿物质紧贴于细胞质膜,似乎将其冲破。与此同时,在卵细胞和颈卵器壁之问形成分离腔,其宽度大于以往报道的真蕨类,在卵细胞质膜外出现额外的卵膜,其宽度大于蕨属和鳞毛蕨属。造粉体被大型常呈三角状半圆形或近椭圆形的淀粉粒所充满,当卵成熟时逐渐减少。核大型平扁状,核内出现2-3对平行的双层膜,紧贴核膜。未发现核外突。线粒体一度似不发育,最后恢复正常。     

分株紫萁卵发生的超微结构

用透射电镜对蕨类植物分枝紫其(Osmunda cinnamamae L. var.asiatica Fernald)卵发生进行了超微结构的研究.卵发生过程中,许多泡囊不仅移向细胞周围,而且在细胞质膜内排为一列,并通过胞吐作用聚集在细胞质膜外,它们释放或分泌嗜锇物质.观察到少数泡囊内含片层状结构的嗜饿物质紧贴于细胞质膜,似乎将其冲破.与此同时,在卵细胞和颈卵器壁之间形成分离腔,其宽度大于以往报道的真蕨类,在卵细胞质膜外出现额外的卵膜,其宽度大于蕨属和鳞毛蕨属.造粉体被大型常呈三角状半圆形或近椭圆形的淀粉粒所充满,当卵成熟时逐渐减少.核大型平扁状,核内出现2~3对平行的双层膜,紧贴核膜.未发现核外突.线粒体一度似不发育,最后恢复正常.     

银杏精子细胞生毛体及其它细胞器的超微结构

生毛体与嗜锇颗粒是银杏 (Ginkgobiloba)精子细胞中最具有标志性的结构。生毛体是细胞质内一直径为 3～ 4μm的圆球形结构 ,它由一个电子致密的核心和由此向周边发散出的辐射状中心粒组成 ,致密核心上具有微管结构的弱电子染色区域 ,并有微管从生毛体延伸到细胞质。嗜锇颗粒直径为 1 0～ 2 0μm,呈圆球状 ,位于生毛体和细胞核之间 ,其相对的另一侧存在纤维颗粒体。在精子细胞质内 ,特别是嗜锇颗粒和生毛体周围线粒体、质体、内质网、高尔基体等细胞器丰富。银杏精子细胞核较大 ,在细胞核内 ,核仁结构呈球形 ,电子染色致密的颗粒区在周围 ,而纤维组分则在圆球的中间。在核膜表面布满了分布不均匀的核孔复合体。     

薄荷盾状腺毛分泌过程的超微结构研究

电镜观察表明,刚形成的薄荷盾状腺毛的头部细胞,细胞核较大,细胞质浓,其中具一些小液泡,质体和线粒体丰富。分泌前期,质体和线粒体数量增加,体积扩大,质体内出现黑色嗜锇物质。以后,嗜锇物质从质体转移到细胞质中,通过小兴泡加工形成的灰色小滴形式进入液泡内,并在液泡内积累直至充满整个液泡。     

木姜子油细胞发育的超微结构研究

利用超薄切片法和透射电镜研究了木姜子（Litsea pungens Hemsl.）油细胞的发育过程。油细胞3层细胞壁的发育可分为4个阶段,阶段1：油细胞仅有初生纤维素壁层,又可分为原始细胞和细胞 泡化两个时期。此阶段质体具透明小泡和黑色嗜锇物质,并与液泡融合。阶段2：木栓质化壁层的形成,片层状木栓质不断叠加在初生纤维素壁内侧,其细胞结构与前期相似,阶段3：内纤维素壁层的形成,较厚而松散的内纤维素壁层叠加在木栓质化壁层的内侧,在内纤维素壁层中可见黑色嗜锇物质,胞间连丝成为被阻塞的特化结构,此时大液泡被嗜锇油脂充满,成为油囊。阶段4：油细胞成熟及细胞质解体,杯形构造由内纤维素壁层向细胞腔内突起形成,油囊由液泡膜包被连接到杯形构造上,油呈浅灰色嗜锇状态,其细胞质和细胞器解体,变得电子不透明或呈杂乱状态。     

鲤鱼精子超微结构的研究

鲤鱼精子由头部,中片和尾部组成,头部的细胞核卵形,染色质致密。核中有些小空隙,空中的电子致密物质存在。中片紧连在核的后端。中片由中心粒复合体和袖套组成。中心粒复合体位于核后植入窝中,袖套一侧肥厚,一侧狭窄,袖套中有线粒体和囊泡。囊泡有二类,一类含有电子致密物质;另一类无电子致密物质。近袖套内膜处的细胞质中还存在着与内膜平行的膜,精子尾部从袖套腔中伸出。尾部的轴丝与基体相接。尾部的近核端多有许多囊泡     

地钱卵发育超微结构和细胞化学的研究

采用电镜和细胞化学技术对地钱(Marchantia polymorpha)卵发生过程进行了研究,根据卵发生过程中细胞化学和超微结构特征可将卵发育过程分为幼卵、中期卵和成熟卵3个阶段.幼卵阶段,卵细胞、腹沟细胞及颈沟细胞间有发达的胞间连丝,但卵与腹沟细胞间的胞间连丝很快退化,幼卵细胞内具大量透明的囊泡,均匀分布于细胞质中;卵发育中期,突出特征是卵细胞质内产生嗜锇性的脂滴,位于囊泡中,与此同时,腹沟细胞退化,其细胞质内产生大型囊泡,囊泡内分泌物与卵细胞外的物质类似,呈PAS反应阳性,表明该物质应为多糖类;卵成熟时,腹沟细胞和颈沟细胞完全退化,卵细胞外包被大量粘性多糖类物质,卵细胞核表面不规则,产生明显的核外突,众多的小泡围绕着细胞核,脂滴聚集成簇,卵细胞内其他细胞器不易区分.卵发育过程中,质体不含淀粉粒,线粒体退化,高尔基体相对发达.地钱卵发育的这些特征显著区分于蕨类植物.     

水蕨卵膜的形成及其超微结构的观察

蕨类植物成熟卵的周围有一层卵膜,但其细微结构和形成过程仍不清楚,本研究应用透射电镜技术对水蕨(Ceratopteris thailictroides)卵细胞发育过程中卵膜的形成及超微结构进行了观察.结果表明水蕨卵细胞在发育中期开始形成卵膜,卵上方的卵膜十分显著,是由多层嗜锇性内质网片层附着于质膜内表面形成的,成熟时卵上方的卵膜中心部分厚,向边缘逐渐变薄,在嗜锇性片层之间填充有嗜锇性物质.比较而言,卵下方及侧面的卵膜薄,由两层紧密连接的嗜锇性膜构成.首次阐明了蕨类植物卵膜形成的超微结构,并对卵膜的一些功能进行了探讨.     

傅氏凤尾蕨精子发生超微结构的研究

超微结构研究显示傅氏凤尾蕨（Pteris fauriei Hieron）精子发生过程包括生毛体、多层结构和鞭毛等运动细胞器重新发生,环状线粒体形成,核塑形等过程,最后形成一个螺旋形的游动精子,这与其他真蕨类精子发生过程相似。本研究观察到的一些新现象包括：精细胞在分化早期呈极性,细胞核位于精细胞的近极端,生毛体、线粒体和质体等细胞器主要分布远极端;在生毛体分化早期,可见大量微管从其发出,其周围线粒体丰富;基体分化经历了前中心粒、中心粒和基体3个阶段,它们的内部结构不同;研究表明生毛体内的不定形物质是微管组织者,多层结构、附属微管带及鞭毛等细胞器均由不定形物质分化形成;精细胞在分化过程中产生了丰富的膜结构,它们可能为精核塑形提供原料。本研究报道了傅氏凤尾蕨精细胞分化的一些细节,这有助于进一步揭示蕨类植物精子发生的细胞学机制。     

蕨类植物分株紫萁精子发生过程中生毛体和多层结构的超微结构

应用电镜技术对蕨类植物分株紫萁(Osmunda cinnamomea L. var.asiatica Fernald)精子发育过程中的生毛体和多层结构的超微结构进行了研究.生毛体在幼精子细胞中出现,正在分化的生毛体略呈球状,球状体的中央由一团染色深的颗粒状物质构成,外围分化出若干柱状体.已分化的生毛体由柱状体分散或辐射状排列构成,呈球状,球体中心不含染色深的物质.多层结构位于精子细胞内的基体和巨大线粒体之间,刚形成时仅由片层构成,片层相互平行排列形成片层带.多层结构在分化中期由微管带、片层带和蚀斑三层构成.多层结构在分化末期又形成附属微管带、嗜锇冠和嗜锇层.微管带从多层结构长出,沿细胞核的表面伸展,并与核膜之间形成复合结构.基体由柱状体转变而成,它向两端生长,在远端产生鞭毛的轴丝,在近轴端形成楔状结构.本文首次详细阐明了原始薄囊蕨分株紫萁生毛体和多层结构发育的超微结构特点,并与其他蕨类进行了比较,发现其片层带出现在微管带形成之前.     

Ultrastructure of Oogenesis in Dryopteris crassirhizoma Nakai

The ultrastructure ofoogenesis in Dryopteris crassirhizoma Nakai has been investigated using transmission electron microscopy. The nucleus in the young egg is rounded with an uneven outline. As it develops, it becomes amoeboid and extends nuclear protrusions that are not only sac-like nuclear evaginations like those often seen in the oogenesis of other ferns, but also mushroom-like and finger-like, with an opening at their end allowing the nucleolus material to flow out from the openings. This has not been observed previously. The nuclear protrusions differ from Dryopterisfilix-mas (L.) Schott. in the absence of sheets of nuclear membrane in the form of a closed ring. As the egg matures, the nucleus transforms into a tuber-like structure with a smooth surface, lying transversely in the egg cell. In the immature egg, vesicles almost encircle the nucleus twice and are most remarkable. In the maturing egg, the vesicles are distributed at the periphery, except for at the top of the egg, and affect the formation of the separation cavity and extra egg membrane. Simultaneously, vesicles from the venter canal cell move to the egg and take part in the formation of separation cavity and extra egg membrane. In the mature egg, a large number of small vesicles containing fragments of lamellae or osmiophilic material emerge from the cytoplasm. The origin of these vesicles is obscure. Irregular plastids containing a cylindrical starch grain dedifferentiated progressively.Mitochondria seem to have been undeveloped during the process, but return to normal at later stages of oogenesis. There is a high frequency of ribosomes in the mature egg. Microtubules, rarely seen in the eggs of D.filix-mas (L.) Schott. and Pteridium aquilinum (L.) Kuhn, have been observed inside the plasmalemma of the maturing egg in D. crassirhizoma.     

Ultrastructure of Oogenesis in Dryopteris crassirhizoma Nakai

The ultrastructure of oogenesis in Dryopteris crassirhizoma Nakai has been investigated using transmission electron microscopy. The nucleus in the young egg is rounded with an uneven outline. As it develops, it becomes amoeboid and extends nuclear protrusions that are not only sac-like nuclear evaginations like those often seen in the oogenesis of other ferns, but also mushroom-like and finger-like, with an opening at their end allowing the nucleolus material to flow out from the openings. This has not been observed previously. The nuclear protrusions differ from Dryopteris filix-mas (L.) Schott. in the absence of sheets of nuclear membrane in the form of a closed ring. As the egg matures, the nucleus transforms into a tuber-like structure with a smooth surface, lying transversely in the egg cell. In the immature egg, vesicles almost encircle the nucleus twice and are most remarkable. In the maturing egg, the vesicles are distributed at the periphery, except for at the top of the egg, and affect the formation of the separation cavity and extra egg membrane. Simultaneously, vesicles from the venter canal cell move to the egg and take part in the formation of separation cavity and extra egg membrane. In the mature egg, a large number of small vesicles containing fragments of lamellae or osmiophilic material emerge from the cytoplasm. The origin of these vesicles is obscure. Irregular plastids containing a cylindrical starch grain dedifferentiated progressively.Mitochondria seem to have been undeveloped during the process, but return to normal at later stages of oogenesis. There is a high frequency of ribosomes in the mature egg. Microtubules, rarely seen in the eggs ofD. filix-mas (L.) Schott. and Pteridium aquilinum (L.) Kuhn, have been observed inside the plasmalemma of the maturing egg in D. crassirhizoma.     

The ultrastructure of Sorubim lima (Teleostei, Siluriformes, Pimelodidae) spermatogenesis: premeiotic and meiotic periods

The ultrastructure of Sorubim lima spermatogenesis during the premeiotic and meiotic periods was studied. Our observations showed that the germ cells in the cysts are connected by cytoplasmic bridges and the mitotic and meiotic divisions are slightly asynchronous. The first and the last spermatogonial generations differ in the cellular and nuclear volume, nucleolus, chromatin condensation, distribution, size, density, and shape of the mitochondria, presence of 'lamellae anulata', amount and dimension of the 'nuages', and movement of the centrioles. In addition to the nuclear prophase structures, the spermatocyte I shows changes in all other cellular organelles and elongated vesicles appear in the cytoplasm. The accentuated cytoplasmic density and thickened walled vesicles are morphological characteristics that differentiate spermatocytes II from the other germ cells in the cysts of Sorubim lima testis.     

绵马贯众多糖超声提取工艺优化及抗氧化活性分析

绵马贯众是中国传统常用中药,本研究以温度、时间、超声功率、液料比为影响因子,多糖得率为评价指标,通过响应面法优化超声辅助提取绵马贯众多糖的工艺条件,同时测定其基本理化性质及抗氧化活性。研究结果表明,绵马贯众多糖的最佳提取工艺条件为:温度64℃、时间60 min、超声功率210 W、液料比27 mL/g。此时多糖得率为9.57%,与预测值接近。理化性质分析表明绵马贯众多糖为含少量蛋白的酸性多糖。体外抗氧化研究表明绵马贯众多糖具有很强的DPPH自由基清除活性,IC50值为0.29 mg/mL;较好的羟基自由基清除活性,其IC50值为1.10 mg/mL;对DNA的氧化损伤有显著的保护作用。绵马贯众多糖可以作为一种潜在的抗氧化剂应用于食品和化妆品等领域。     

A transmission electron microscopy investigation: the membrane complex in spermatogenesis of <Emphasis Type="Italic">Fenneropenaeus chinensis</Emphasis>

The transforming characteristics of the membrane complex in spermatogenesis of Fenneropenaeus chinensis have been studied by using transmission electron microscopy. Two types of membrane complex have been investigated based on their sources: one originating from nucleus and the other from cytoplasm. The first one, consisted of annular structures, monolayer membrane blebs, and double or multi-lamellar membrane vesicles, emerges in the primary spermatocyte, then diffuses with the nuclear membrane and finally enters the cytoplasm. This type of membrane complex seems to play an important role in the materials transfusion from nucleus to cytoplasm, and it mainly exists inside the primary spermatocyte with some inside the secondary spermatocyte. The latter, originated from cytoplasm, is formed during the anaphase of spermiogenesis. It also exists in mature sperm, locating at both sides of the nucleus under the acrosomal cap. This type of membrane complex mainly comprises rings of convoluted membrane pouches, together with mitochondria, annular lamina bodies, fragments of endoplasmic reticulum, nuclear membrane and some nuclear particles. It releases vesicles and particles into the acrosomal area during the formation of the perforatorium, suggesting a combined function of the endoplasmic reticulum, mitochondria and Golgi’s mechanism.     

Phagotrophy and two new structures in the malaria parasite Plasmodium berghei

Blood collected from rats infected with Plasmodium berghei was centrifuged and the pellet was fixed for 1 hour in 1 per cent buffered OsO(4) with 4.9 per cent sucrose. The material was embedded in n-butyl methacrylate and the resulting blocks sectioned for electron microscopy. The parasites were found to contain, in almost all sections, oval bodies of the same density and structure as the host cytoplasm. Continuity between these bodies and the host cytoplasm was found in a number of electron micrographs, showing that the bodies are formed by invagination of the double plasma membrane of the parasite. In this way the host cell is incorporated by phagotrophy into food vacuoles within the parasite. Hematin, the residue of hemoglobin digestion, was never observed inside the food vacuole but in small vesicles lying around it and sometimes connected with it. The vesicles are pinched off from the food vacuole proper and are the site of hemoglobin digestion. The active double limiting membrane is responsible not only for the formation of food vacuoles but also for the presence of two new structures. One is composed of two to six concentric double wavy membranes originating from the plasma membrane. Since no typical mitochondria were found in P. berghei, it is assumed that the concentric structure performs mitochondrial functions. The other structure appears as a sausage-shaped vacuole surrounded by two membranes of the same thickness, density, and spacing as the limiting membrane of the body. The cytoplasm of the parasite is rich in vesicles of endoplasmic reticulum and Palade's small particles. Its nucleus is of low density and encased in a double membrane. The host cells (reticulocytes) have mitochondria with numerous cristae mitochondriales. In many infected and intact reticulocytes ferritin was found in vacuoles, mitochondria, canaliculi, or scattered in the cytoplasm.     

东方扁虾精子发生的超微结构

应用电镜技术研究了东方扁虾（Thenus orientalis)精子发生的全过程,精原细胞呈椭圆形,其染色质分布较均匀,线粒体集中于细胞一端形成“线粒体区”。初级精母细胞较大,染色质凝聚成块,次级精母细胞核质间常出现大的囊泡,胞质内囊泡丰富而线粒体数量却明显减少,早期精细胞核发生极化、解聚,部分胞质被抛弃。中期精细胞外观呈金字塔形,分为三区;正在形成的顶体位于塔顶,核位于塔基部,居间的细胞质基质内富含膜复合物,后期精细胞顶体进一步分化。形成顶体帽和内、外顶体物质等三个结构组份。成熟精子核呈盘状或碗状,具有5-6条内部充满微管的辐射臂。     

Some observations on spermatogenesis in Gelastocoris oculatus (Hemiptera) with the aid of the electron microscope

The nuclear cap in the spermatogonial and early spermatocyte cells of Gelastocoris is an aggregate of closely packed mitochondria with their long axes perpendicular to the nuclear membrane. Eventually in the early growth period, the mitochondria move from the cap and appear to become more or less equally distributed in the cytoplasm where they remain until their fusion in the spermatid to form the nebenkern. The Golgi complex consists of clusters of lamellae and vesicles, the Golgi bodies. Granules form within the vesicles, increase in size, move from their place of origin and become distributed at random in the cytoplasm. They are the pro-acrosomal granules and at the end of the growth period fuse to form the proacrosome, about which Golgi bodies collect. The Golgi bodies, however, never fuse into an acroblast. At one end of the oval-shaped pro-acrosome is a small dark body and a less dense vesicle the future of which is uncertain. The dark body eventually occupies a position at the tip of the acrosome. The pro-acrosome, after moving to the side of the nucleus opposite the nebenkern, differentiates into the acrosome which elongates into a tail-like structure. The nuclear membrane of some spermatocytes may appear wave-like in cross section, with the crest and trough different in appearance. Near the membrane and in the troughs of the waves large clusters of granules are frequently present. Similar clusters may be found elsewhere in the cytoplasm. Presumably they had their origin near the membrane but this is not conclusive. Bodies of indeterminate origin and structure may be present in the cytoplasm. They could be lysosomes but evidence is lacking. In late spermatocytes and in spermatids, a group of ten or twelve granules is present. They are smaller than the pro-acrosomal granules, are always closely associated and pass as a group into the tail. Their significance is unknown. The endoplasmic reticulum is typical of cells in general. There are no granule accumulations within the vesicles as in some secretory cells. Vesicles of various shapes and sizes are present within the centrosphere of the first meiotic division. While their location is similar to that of the centriole, the identity of the vesicles is uncertain.     

Fine structure of spermatogonia and primary spermatocytes in rabbits

Summary The fine structure of rabbit Spermatogonia and primary spermatocytes in meiotic prophase has been studied with different methods of preparation, including a technique for acid phosphatase activity. The spermatogonial cytoplasm is rich in free ribosomes and containes moderate amounts of vesicular, smooth-surfaced endoplasmic reticulum and mitochondria, a simple Golgi-apparatus, some micropinocytotic vesicles, and occasional multivesicular bodies, vacuoles and dense bodies with acid phosphatase activity. The large type A Spermatogonia have a prominent nucleolus and their mitochondria sometimes form clusters with a dense intermitochondrial substance, similar to that in spermatocytes.The nucleus and cytoplasm of primary spermatocytes increase markedly in volume and density during meiotic prophase. The Golgi apparatus enlarges and becomes more differentiated and finally forms small proacrosome granules. The endoplasmic reticulum produces numerous small, mainly smooth vesicles and might also be the source of a new organelle: numerous piles of narrow cisternae with opaque contents. These piles disintegrate late in prophase. The mitochondria become aggregated in clusters with dense intermitochondrial substance and their internal structure is characterized by highly dilated cristae and small particles, interpreted as mitochondrial ribosomes, in the matrix. The role of these structures in the formation of new mitochondria is discussed. The clusters of mitochondria finally disperse and their cores of dense intermitochondrial substance, possibly containing ribonucleoprotein, coalesce into a large chromatoid body similar to that in spermatids. Micropinocytosis and a few lysosomes occur in most spermatocytes. The pachytene nuclei show prominent nucleoli and a distinct sex vesicle without any synaptinemal complex.The importance for spermatid differentiation of some events taking place in the cytoplasm of primary spermatocytes is emphasized.Financial support for this study was received from the Swedish Medical Research Council.     

Structures related to the germ plasm in mouse

This report presents data from ultrastructural and morphometric studies on the germinal-body-like structures, nuage, nuage-mitochondrial clusters and chromatoid bodies in 4.5-day embryo cells and spermatogenic cells of the laboratory mouse Mus musculus. In the 4.5-day embryo cells the germinal-body-like structures that, according to previous data, arise by condensation of mitochondria in Graafian oocytes, were found not to undergo any ultrastructural alterations. In spermatogonia the germinal-body-like structures presumably were transformed into nuage that functioned as 'intermitochondrial cement' binding the mitochondrial clusters. In primary spermatocytes mitochondria aggregated by nuage were found with large vacuoles containing membraneous conglomerates that were obviously excreted by organelles into the cytoplasm. The chromatoid bodies that arose in spermatocytes and finally disintegrated in the posterior part of late spermatids seemed not to be implicated in the pathway of the germinal-body-like structure. The dispersion of chromatoid bodies was noted to be accompanied by excretion of membraneous conglomerates by late spermatid mitochondria. The spermatozoa were not found to contain either the germinal-body-like structures or any other germ-plasm-related structures.