褪黑激素对休情期银黑狐腔前卵泡卵母细胞超微结构的影响

为了研究褪黑激素(Melatonin,MLT)对休情期银黑狐腔前卵泡卵母细胞超微结构的影响。本研究选取健康7月龄埋植和未埋植MLT的银黑狐各5只,取其左侧卵巢共计10枚,制备超薄切片后利用透射电镜分别观察每枚卵巢的各级腔前卵泡各1-5个,并进行拍照。结果埋植和未埋植MLT的银黑狐原始卵泡卵母细胞内均有少量线粒体和高尔基体,而未埋植MLT的银黑狐卵母细胞中还可见少量滑面内质网;初级卵泡卵母细胞内,均开始形成不完整透明带,线粒体及内质网数量均有所增加,沿透明带出现少量皮质颗粒;次级卵泡阶段,未埋植MLT银黑狐卵母细胞微绒毛数量较埋植MLT的多,其余细胞器未见差异。结果表明,MLT对休情期银黑狐卵巢腔前卵泡卵母细胞的线粒体、脂滴、高尔基体、皮质颗粒等细胞器的发育没有影响,仅对初级卵泡阶段内质网的发育有抑制作用。     

"两步法"体外培养山羊卵母细胞的超微结构观察

有假说认为,卵母细胞在体外培养过程中,如果延长GV期,可促进卵母细胞进一步成熟,因而提高发育潜能。采用山羊半卵泡和卵母细胞共培养,抑制卵母细胞GVBD发生,从而延长GV期。比较了共培养前后和恢复成熟培养后卵母细胞的超微结构变化,其目的从亚细胞水平寻找卵母细胞进一步成熟的证据。研究发现,常规成熟培养:有卵周隙存在,但不贯通,局部区域卵膜与透明带结合紧密;部分皮质区尚有细胞器存在;微绒毛大部分从透明带中撤出,倒伏于质膜表面,数量较多,形态较为粗大;皮层颗粒质膜下部分单层分布,部分散布于皮质区;线粒体均匀散布于卵质中央区。共培养前:卵母细胞的卵周隙尚未形成,微绒毛没有从透明带中撤出;线粒体等细胞器分布于皮质区,皮层颗粒成簇状分布,皮质区富含细胞器。共培养后:局部形成卵周隙,微绒毛已自透明带中撤出,数量较多,垂直或倒伏于卵膜表面;线粒体以簇状分批开始内移,皮层颗粒已部分单层分布于质膜下,部分皮质区缺乏细胞器。恢复成熟培养后:卵周隙进一步扩大并且贯通,微绒毛数量减少并且绝大多数垂直于卵膜;线粒体在卵质中央区均匀分布,皮层颗粒卵膜下单层分布,大部分皮质区无细胞器存在。利用“两步法”培养得到的卵母细胞与体外常规成熟培养的卵母细胞相比,更有利于皮层颗粒的质膜下单层分布,卵母细胞卵周隙的形成与贯通,微绒毛数量减少和垂直于卵膜表面,无细胞器皮层区的进一步形成。因此,更有利于卵母细胞胞质的进一步成熟。     

“两步法”体外培养山羊卵母细胞的超微结构观察

有假说认为,卵母细胞在体外培养过程中,如果延长GV期,可促进卵母细胞进一步成熟,因而提高发育潜能。采用山羊半卵泡和卵母细胞共培养,抑制卵母细胞GVBD发生,从而延长GV期。比较了共培养前后和恢复成熟培养后卵母细胞的超微结构变化,其目的从亚细胞水平寻找卵母细胞进一步成熟的证据。研究发现,常规成熟培养：有卵周隙存在,但不贯通,局部区域卵膜与透明带结合紧密;部分皮质区尚有细胞器存在;微绒毛大部分从透明带中撤出,倒伏于质膜表面,数量较多,形态较为粗大;皮层颗粒质膜下部分单层分布,部分散布于皮质区;线粒体均匀散布于卵质中央区。共培养前：卵母细胞的卵周隙尚未形成,微绒毛没有从透明带中撤出;线粒体等细胞器分布于皮质区,皮层颗粒成簇状分布,皮质区富含细胞器。共培养后：局部形成卵周隙,微绒毛已自透明带中撤出,数量较多,垂直或倒伏于卵膜表面;线粒体以簇状分批开始内移,皮层颗粒已部分单层分布于质膜下,部分皮质区缺乏细胞器。恢复成熟培养后：卵周隙进一步扩大并且贯通,微绒毛数量减少并且绝大多数垂直于卵膜;线粒体在卵质中央区均匀分布,皮层颗粒卵膜下单层分布,大部分皮质区无细胞器存在。利用“两步法”培养得到的卵母细胞与体外常规成熟培养的卵母细胞相比,更有利于皮层颗粒的质膜下单层分布,卵母细胞卵周隙的形成与贯通,微绒毛数量减少和垂直于卵膜表面,无细胞器皮层区的进一步形成。因此,更有利于卵母细胞胞质的进一步成熟。     

东北梅花鹿初级卵母细胞的超微结构

研究东北梅花鹿初级卵母细胞发育的超微结构变化,目的是为探索东北梅花鹿初级卵母细胞的发育规律提供组织学和形态学依据。本研究于2003年和2004年的6月初到8月末取3只、9月中旬到10月初取4只,共计7只健康经产2~3胎的成年东北梅花鹿卵巢;卵巢经2·5%戊二醛固定液固定后,切取约1mm3的卵巢皮质和直径0·5~1·5mm及1·5~3mm的卵泡作为电镜观察用材料;该材料经0·1MpH7·2的PBS漂洗、1%锇酸固定、不同浓度乙醇脱水后,再经Epon812和丙酮等量混合液浸透,最后用Epon812包埋制块,并用半薄切片机切成0·5~2μm半薄切片;再经亚甲基兰-天青Ⅱ染色后,在光镜下进行卵泡分类和卵母细胞定位;将经定位的材料用超薄切片机切成厚度为700~800的切片,经醋酸铀和柠檬酸铅双重染色后,用透射电镜观察、记录并照相。观察时将卵泡依其直径大小、透明带的形成、卵泡腔的出现等分为原始卵泡、初级卵泡、次级卵泡和三级卵泡4类。研究结果表明,在原始卵泡阶段,卵母细胞为较规则的圆形,质膜与卵泡细胞膜紧密相贴,有时形成桥粒,细胞器多分布于近核区,高尔基体不典型,线粒体多为圆形,嵴较少;在次级卵泡阶段,2~4层的卵泡细胞局部开始形成透明带,4层以上时形成薄的透明带,微绒毛斜伸入透明带内,方向不规律;在直径为0·5~1·5mm的三级卵泡阶段,卵母细胞的透明带增厚,各种细胞器在皮质区内数量较多,皮质区内高尔基体的数目增多,粗面内质网明显减少;在直径为1·5~3mm的三级卵泡阶段,卵母细胞的透明带继续加厚,微绒毛缩短变弯,开始从透明带退出,许多皮质颗粒开始排列在卵母细胞膜下。     

东方扁虾卵子发生的超微结构

根据卵细胞的形态、内部结构特征及卵母细胞与滤泡细胞之间的关系,东方扁虾的卵子发生可划分为卵原细胞、卵黄发生前卵母细胞、卵黄发生卵母细胞和成熟卵母细胞等四个时期。卵原细胞胞质稀少,胞器以滑面内质网为主。卵黄发生前卵母细胞核明显膨大,特称为生发泡;在靠近核外膜的胞质中可观察到核仁外排物。卵黄发生卵母细胞逐渐为滤泡细胞所包围;卵黄合成旺盛,胞质中因而形成并积累了越来越多的卵黄粒。东方扁虾卵母细胞的卵黄发生是二源的。游离型核糖体率先参与内源性卵黄合成形成无膜卵黄粒。粗面内质网是内源性卵黄形成的主要胞器。滑面内质网、线粒体和溶酶体以多种方式活跃地参与卵黄粒形成。卵周隙内的外源性物质有两个来源:滤泡细胞的合成产物和血淋巴携带、转运的卵黄蛋白前体物。这些外源性物质主要通过质膜的微吞饮作用和微绒毛的吸收作用这两种方式进入卵母细胞,进而形成外源性卵黄。内源性和外源性的卵黄物质共同参与成熟卵母细胞中富含髓样小体的卵黄粒的形成。卵壳的形成和微绒毛的回缩被认为是东方扁虾卵母细胞成熟的形态学标志。       

水貂卵母细胞发育过程中卵泡细胞的微细结构研究

本文应用光镜,电镜及组织化学方法对水貂卵丘形成过程进行了研究。结果表明,在发育过程中,卵泡细胞内含有一些圆形线粒体,许多单个粗面内质网囊池和丰富的核糖体,高尔基复合体罕见,当卵泡细胞变成单层柱状时,细胞内开始出现成团的微丝及一些直径１－２μｍ的厚壁泡。在卵泡细胞膜上可见到胞吐小泡以及细胞间夹有透明带物质,表明卵泡细胞可能参与透明带的形成,随着卵泡腔的形成,卵泡细胞开始出现含中性脂肪及磷脂的颗粒,卵     

马鹿卵母细胞体外培养与体外受精的超微结构

用FSH 对马鹿进行超数排卵,通过抽吸法和切割法采集卵泡卵母细胞,用M199 为基础的培养液在38.5℃、5%CO₂ 和饱和湿度条件下对马鹿卵母细胞进行体外培养与体外受精培养,利用透射电镜观察不同时期马鹿卵母细胞的超微结构,旨在揭示马鹿卵母细胞体外培养前、培养后及受精后超微结构的变化规律。结果表明,培养前卵丘细胞紧紧包围卵母细胞,卵母细胞表面的微绒毛细长,伸入透明带内,皮质区及细胞中心分布大量的细胞器。培养后卵丘细胞与卵母细胞结合松散,卵母细胞表面微绒毛短粗,倒伏于卵表面,第一极体无核,皮质颗粒在皮质区成层排列,细胞质中细胞器分布均匀。受精后卵母细胞表面的微绒毛由倒伏而竖起,第二极体有核,细胞质中细胞器丰富,主要分布于细胞中心。     

不同生殖期鳜肝脏超微结构变化的观察

应用透射电镜对生殖季节与非生殖季节鳜肝脏超微结构的变化进行了观察。鳜肝细胞含有单个卵圆形的核,核仁清楚;细胞质内含有粗面内质网、线粒体、糖原颗粒和脂滴等细胞器和内含物。胆小管由相邻的数个肝细胞质膜凹陷围成,而肝血窦则由内皮细胞的胞质构成。还发现了贮脂细胞、枯否氏细胞和成纤维细胞。胆小管腔和窦周隙内浸润许多由肝细胞发出的微绒毛结构。鳜肝细胞的超微结构在产卵前后呈现明显变化：产卵前的肝细胞内富含线粒体、糖原颗粒和脂滴,粗面内质网发达;而产卵后的肝细胞内核仁发生迁移,部分细胞核囊泡化,糖原颗粒和脂滴排空,少数肝细胞具双核结构。非生殖期多数肝细胞核含有双核仁结构,胞质内溶酶体数量增多。     

剑尾鱼卵子发生的组织学观察

应用光学显微镜对卵胎生硬骨鱼类剑尾鱼(Xiphophorus helleri)卵巢的组织结构进行了观察。结果显示,剑尾鱼卵子的发育过程可划分为6个时相。Ⅰ时相的卵母细胞呈原始分化状态,细胞外具一层细胞质膜。Ⅱ时相卵母细胞外不仅具有质膜,而且还包绕一层滤泡细胞。Ⅲ时相和Ⅳ时相的卵母细胞分化明显,胞质内开始积累脂滴和卵黄颗粒。Ⅴ时相为成熟卵子,卵子的卵膜极薄,胞质内含有丰富的脂滴和卵黄。Ⅵ时相卵母细胞进入退化期,滤泡细胞从卵周向中央突入,卵黄被完全吸收,滤泡细胞自身也变得肥大。结果表明,剑尾鱼卵巢中卵母细胞的发育是不同步的。     

剑尾鱼卵子发生的的组织学观察

应用光学显微镜对卵胎生硬骨鱼类剑尾鱼(Xiphophorus helleri)卵巢的组织结构进行了观察。结果显示,剑尾鱼卵子的发育过程可划分为6个时相。Ⅰ时相的卵母细胞呈原始分化状态,细胞外具一层细胞质膜。Ⅱ时相卵母细胞外不仅具有质膜,而且还包绕一层滤泡细胞。Ⅲ时相和Ⅳ时相的卵母细胞分化明显,胞质内开始积累脂滴和卵黄颗粒。Ⅴ时相为成熟卵子,卵子的卵膜极薄,胞质内含有丰富的脂滴和卵黄。Ⅵ时相卵母细胞进入退化期,滤泡细胞从卵周向中央突入,卵黄被完全吸收,滤泡细胞自身也变得肥大。结果表明,剑尾鱼卵巢中的卵母细胞的发育是不同步的。     

Cytochemical localization of GalNAc and GalNAcβ1,4Galβ1,4 disaccharide in mouse zona pellucida

Carbohydrate residues contained in the zona pellucida play a key role in the process of sperm-egg interaction. In vitro fertilization experiments have shown that a specific monoclonal antibody against GalNAcş,4Galş,4 disaccharide inhibits fertilization in mice. In the present study, the ultrastructural cytochemical localization of GalNAc residues and the GalNAcş,4Galş,4 disaccharide was carried out in ovarian and postovulatory oocytes by using lectin-gold cytochemistry and immunocytochemistry. Plant lectins SBA and DBA showed an affinity for the entire zona pellucida matrix of ovarian oocytes throughout the follicular maturation; however, immunoreactivity for GalNAcş,4Galş,4 disaccharide was not detected in ovarian oocytes at the earliest stages of follicular development but was found to be associated with the inner region of the zona matrix at the trilaminar primary follicle stage. The Golgi apparatus, vesicular aggregates, and cortical granules of the oocyte were intensely labeled by SBA and DBA throughout follicular development. Immunoreactivity to GalNAcş,4Galş,4 disaccharide was first observed in the Golgi apparatus and vesicular aggregates in trilaminar primary follicles. No immunoreactivity was observed in the cortical granules. In postovulatory oocytes, results were similar to those observed in ovarian oocytes. Our results thus suggest that (1) GalNAcş,4Galş,4 disaccharide residues are present only in the inner region of the zona pellucida and, therefore, might be involved in sperm penetration through the zona pellucida, (2) the inner and outer regions of the zona pellucida contain different oligosaccharide chains, (3) the vesicular aggregates detected in the oocyte could represent an intermediate step in the secretory pathway of zona pellucida glycoproteins and might be involved in the formation of cortical granules.     

Morphometric and ultrastructural characterization of Bos indicus preantral follicles

The aim of the present study was to characterize the ultrastructure of zebu cow preantral follicles (PAFs). Ovarian cortex samples were processed for light and transmission electron microscopy. Primordial follicles consisted of an oocyte surrounded by one layer of flattened or flattened-cuboidal granulosa cells. The oocyte contained a large and usually eccentric nucleus. Most organelles were located at the perinuclear ooplasm. Round shaped mitochondria, which contained electron-dense granules, smooth and rough endoplasma reticulum and a Golgi apparatus were also observed. Vesicles and coated pits were often observed in the cortical ooplasm. In primary follicles, the oocyte was surrounded by one layer of cuboidal granulosa cells. Short microvilli were observed on the oolema. Secondary follicles consisted of an oocyte surrounded by a variable number of layers of cuboidal granulosa cells. Small secondary follicles had an ultrastructure very similar to that observed in primary follicles. At this follicular stage, the zona pellucida was beginning to form around the oocyte. In large secondary follicles, the zona pellucida was totally developed around the oocyte. Several granulosa cell projections could be detected that were encroaching into the zona pellucida and protruding towards the oocyte, where gap junctions were observed between oocyte and granulosa cell membranes. Organelles within the oocyte were located at the periphery of the ooplasm, and clusters of cortical granules were observed. Round mitochondria were abundant in all developmental stages. In conclusion, this study described the ultrastructure of zebu cow PAFs, and some unique characteristics could be observed as compared with what has been reported for follicles of Bos taurus cattle.     

Ultrastructural characterization of porcine oocytes and adjacent follicular cells during follicle development: Lipid component evolution

The objective of this study was to characterize the morphometry and ultrastructure of porcine preantral and antral follicles, especially the lipid component evolution. Ovarian tissue was processed for light microscopy. Ovarian tissue and dissected antral follicles (< 2, 2–4, and 4–6 mm) were also processed for transmission electron microscopy using routine methods and using an osmium-imidazole method for lipid detection. Primordial follicles (34 ± 5 μm in diameter, mean ± SD) had one layer of flattened-cuboidal granulosa cells around the oocyte, primary follicles (40 ± 7 μm) had a single layer of cuboidal granulosa cells around the oocyte, and secondary follicles (102 ± 58 μm) had two or more layers of cuboidal granulosa cells around the oocyte. Preantral follicle oocytes had many round mitochondria and both rough and smooth endoplasmic reticulum. In oocytes of primordial and primary follicles, lipid droplets were abundant and were mostly located at the cell poles. In secondary and antral follicles, the zona pellucida completely surrounded the oocyte, whereas some microvilli and granulosa cells projected through it. Numerous electron-lucent vesicles and vacuoles were present in the oolemma of secondary and antral follicles. Based on osmium-imidazole staining, most of these structures were shown to be lipid droplets. As the follicle developed, the appearance of the lipid droplets changed from small and black to large and gray, dark or dark with light streaks, suggesting that their nature may change over time. In summary, although porcine follicles and oocytes had many similarities to those of other mammalian species, they were rich in lipids, with lipid droplets with varying morphological patterns as the follicle developed.     

Ultrastructural characterization of porcine oocytes and adjacent follicular cells during follicle development: lipid component evolution

The objective of this study was to characterize the morphometry and ultrastructure of porcine preantral and antral follicles, especially the lipid component evolution. Ovarian tissue was processed for light microscopy. Ovarian tissue and dissected antral follicles (< 2, 2-4, and 4-6 mm) were also processed for transmission electron microscopy using routine methods and using an osmium-imidazole method for lipid detection. Primordial follicles (34 ± 5 μm in diameter, mean ± SD) had one layer of flattened-cuboidal granulosa cells around the oocyte, primary follicles (40 ± 7 μm) had a single layer of cuboidal granulosa cells around the oocyte, and secondary follicles (102 ± 58 μm) had two or more layers of cuboidal granulosa cells around the oocyte. Preantral follicle oocytes had many round mitochondria and both rough and smooth endoplasmic reticulum. In oocytes of primordial and primary follicles, lipid droplets were abundant and were mostly located at the cell poles. In secondary and antral follicles, the zona pellucida completely surrounded the oocyte, whereas some microvilli and granulosa cells projected through it. Numerous electron-lucent vesicles and vacuoles were present in the oolemma of secondary and antral follicles. Based on osmium-imidazole staining, most of these structures were shown to be lipid droplets. As the follicle developed, the appearance of the lipid droplets changed from small and black to large and gray, dark or dark with light streaks, suggesting that their nature may change over time. In summary, although porcine follicles and oocytes had many similarities to those of other mammalian species, they were rich in lipids, with lipid droplets with varying morphological patterns as the follicle developed.     

Perivitelline space of marsupial oocytes: Extracellular matrix of the unfertilized oocyte and formation of a cortical granule envelope following the cortical reaction

The purpose of this study was to characterize the structure of the vestments surrounding unfertilized and cortical granule-reacted oocytes from a marsupial, the grey short-tailed opossum Monodelphis domestica and to determine if a cortical granule envelope (CGE) forms in the perivitelline space (PVS) following the cortical reaction. Unfertilized oocytes collected from mature ovarian follicles and oviducal oocytes that had undergone a cortical reaction were fixed for electron microscopy in the presence of ruthenium red which stabilizes extracellular matrices (ECM) and facilitates demonstration of a CGE. Unfertilized oocytes were surrounded by a zona pellucida and had a PVS which contained a thick ECM comprised of granules and filaments. This matrix appeared to attach to the oolemma and was structurally similar to matrices reported previously in the PVS of unfertilized oocytes from eutherian mammals and two other marsupials, the Virginia opossum and the fat-tailed dunnart. The cortex of unfertilized oocytes contained cortical granules which were absent in oocytes recovered from the oviducts of mated females. Oviducal oocytes which lacked cortical granules exhibited a new coat within the PVS between the zona pellucida and the tips of the oocyte microvilli. This coat, the CGE, appeared structurally similar to CGEs described previously around fertilized eutherian oocytes. The CGE of the grey short-tailed opossum is approximately 1 μm thick and is made up of numerous small dense granules. The coats of the opossum oocyte are compared to those present around other marsupial and eutherian oocytes. © 1995 Wiley-Liss, Inc.     

Ultrastructural studies of developing goat oocytes in vitro

The structure and distribution of organelles within developing goat oocytes at various stages of incubation were studied. In oocytes with 5 or more layers of cumulus cells, at 0 h of incubation, the zona pellucida had developed although zonation was not evident. Lipid bodies were present but no mitochondria were observed. At 20 h, the zona pellucida had differentiated into thicker and thinner regions. Clusters of membrane-bound electron-transparent bodies were present in the perivitelline space. The mitochondria were fully developed, distributed evenly and usually in close proximity with dilated endoplasmic reticula. Cortical granules were distributed at the periphery. At 40 h of incubation, a number of mitochondria was hooded. In oocytes of 2 to 4 layers of cumulus cells at 0 h, the zona pellucida was penetrated by cumulus cell processes, and the mitochondria were not well developed. However, in 20-h incubated oocytes, fully developed mitochondria, many of which were hooded, could be observed. Clusters of membrane-bound electron-transparent bodies were also observed, while cortical granules were at the periphery. In cumulus-free oocytes, zonation within the zona pellucida was indistinct. Very few vesicles and lipid bodies were observed. At 20 h, mitochondria were sparsely distributed and were not well developed and lacked cristae. At 40 h, the zona pellucida was less compact, and the membrane-bound electron-transparent bodies were less numerous compared with those of the other groups. Endoplasmic reticula were not dilated, and cortical granules were few and had no definite pattern of distribution.     

Oogenesis in the leech Glossiphonia heteroclita (Annelida, Hirudinea, Glossiphoniidae) II. Vitellogenesis, follicle cell structure and egg shell formation

By the end of previtellogenesis, the oocytes of Glossiphonia heteroclita gradually protrude into the ovary cavity. As a result they lose contact with the ovary cord (which begins to degenerate) and float freely within the hemocoelomic fluid. The oocyte's ooplasm is rich in numerous well-developed Golgi complexes showing high secretory activity, normal and transforming mitochondria, cisternae of rER and vast amounts of ribosomes. The transforming mitochondria become small lipid droplets as vitellogenesis progresses. The oolemma forms microvilli, numerous coated pits and vesicles occur at the base of the microvilli, and the first yolk spheres appear in the peripheral ooplasm. A mixed mechanism of vitellogenesis is suggested. The eggs are covered by a thin vitelline envelope with microvilli projecting through it. The envelope is formed by the oocyte. The vitelline envelope is produced by exocytosis of vesicles containing two kinds of material, one of which is electron-dense and seems not to participate in envelope formation. The cortical ooplasm of fully grown oocytes contains many cytoskeletal elements (F-actin) and numerous membrane-bound vesicles filled with stratified content. Those vesicles probably are cortical granules. The follicle cells surrounding growing oocytes have the following features: (1) they do not lie on a basal lamina; (2) their plasma membrane folds deeply, forming invaginations which eventually seem to form channels throughout their cytoplasm; (3) the plasma membrane facing the ovary lumen is lined with a layer of dense material; and (4) the plasma membrane facing the oocyte forms thin projections which intermingle with the oocyte microvilli. In late oogenesis, the follicle cells detach from the oocytes and degenerate in the ovary lumen.