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。     

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。     

香螺精子发生及精子超微结构

本文采用透射电镜技术对香螺(NpatunedecumingiCrosse)精子发生过程进行了观察。结果表明,精原细胞胞质中含有大量的线粒体;初、次级精母细胞的细胞核和大量的线粒体呈极性分布;精子细胞分化过程中,细胞核形态、核内物质以及线粒体的形态发生显著变化;细胞核的核质由不均匀颗粒状浓缩成纤丝状,再浓缩成细线形,最后呈致密均匀状态,细胞核由近圆形伸长为粗线形,具有核后窝;在细胞核后端有8个膨大的线粒体,由卵圆形变为螺旋形,弯曲盘绕在轴丝外部,形成精子的中段;根据细胞核和线粒体的变化特点,将精子形成分为早、中、后三个时期。香螺典型性精子属于进化型,头部呈线形,中段加长,糖原颗粒包围轴丝构成主段。在精子发生过程中,细胞质内没有发达的高尔基复合体和前顶体池,没有观察到香螺精子的顶体。在成熟个体的精巢内,同时存在不具有受精能力的畸变精子。     

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。     

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。     

菲律宾蛤仔的精子发生和精子超微结构

用透射电镜研究了菲律宾蛤仔(Ruditapes philippinarum)精子结构和精子发生过程中细胞形态结构的变化及细胞器的演变规律。菲律宾蛤仔雄性生殖细胞的形态由椭圆形渐变为辣椒状,细胞核的形态由椭圆形逐渐拉长,渐变为锥形。染色质的凝集经历：小颗粒团块状一较大颗粒均匀状一粗颗粒均匀状的过程。线粒体在演化过程中数量先增多后逐渐减少,嵴数逐渐增多,电子密度和体积逐渐增大。高尔基体在初级精母细胞期已经发育,随后的各期中发育良好,分泌旺盛。精细胞Ⅱ期,高尔基体分泌的潴泡开始融合,形成前顶体囊。精细胞Ⅲ期,高尔基体的分泌物仍不断融合。精细胞分化的后期,前顶体囊逐渐发育形成顶体。菲律宾蛤仔成熟精子呈长辣椒状,为原生型,由头部、中段和尾部构成。头部的顶体为细长柱形,末端渐细,电子密度较小;细胞核为锥形;中段线粒体4个,尾部鞭毛为典型的“9 2”型结构。此外在成熟精子线粒体环横切面有一特殊“风车状”结构。     

拟目乌贼精子发生和精子的超微结构

应用扫描电镜和透射电镜观察了拟目乌贼(Sepia lycidas)精子的发生过程和超微结构。结果表明,精子发生经历了精原细胞、初级精母细胞、次级精母细胞、精细胞和成熟精子5个阶段,其中精细胞可以分为Ⅰ、Ⅱ、Ⅲ、Ⅳ、Ⅴ5个时期,精细胞Ⅱ期又可分为前期和后期。细胞核经历了一个横向收缩、纵向拉长的过程,由圆形或椭圆形,变为不规则的纺锤形、稍弯曲的长柱形;核内染色质由絮状,变为絮块状、致密颗粒状、细纤维状、粗纤维状和片层状,直至高电子密度均质状;顶体由圆形,变为头盔形、圆锥形、倒\"U\"字形,直至子弹头形;线粒体由空泡状经过融合和迁移,变为内嵴丰富的椭球形,形成不完全包围鞭毛的线粒体距。成熟精子全长101.28μm,由头部和尾部组成,头部呈长辣椒状,长7.73μm,宽1.51μm,由顶体和细胞核组成;尾部细长,为93.18μm,为典型的\"9+2\"结构,由中段、主段和末段三部分组成。     

纹藤壶精子发生和成熟精子的超微结构

甲壳动物的精子形态各异.其中3个亚纲的精子具鞭毛,能运动,其它5个亚纲的精子无鞭毛且不运动.     

拟目乌贼精子发生的超微结构

应用扫描电镜和透射电镜观察了拟目乌贼(Sepia lycidas)精子的发生过程和超微结构。结果表明,精子发生经历了精原细胞、初级精母细胞、次级精母细胞、精细胞和成熟精子五个阶段,其中精细胞可以分为Ⅰ、Ⅱ、Ⅲ、Ⅳ、Ⅴ五个时期,精细胞Ⅱ期又可分为前期和后期。细胞核经历了一个横向收缩、纵向拉长的过程,由圆形或椭圆形,变为不规则的纺锤形、稍弯曲的长柱形;核内染色质由絮状,变为絮块状、致密颗粒状、细纤维状、粗纤维状和片层状,直至高电子密度均质状;顶体由圆形,变为头盔形、圆锥形、倒“U”字形,直至子弹头形;线粒体由空泡状经过融合和迁移,变为内嵴丰富的鸡冠状,形成不完全包围鞭毛的线粒体距。成熟精子全长101.28μm,由头部和尾部组成,头部为稍弯曲的长柱形,长7.73μm,宽1.51μm,由顶体和细胞核组成;尾部细长,为93.18μm,为典型的“9 2”结构,由中段、主段和末段三部分组成。     

鸭绿江细鳞鱼的生物学

细鳞鱼是鸭绿江的重要经济鱼类。幽门垂数、鳃耙数及侧线鳞数与国内其他产地相比呈现明显交叉。支流十三道沟河口以上的5公里江段为主要产卵场。产卵期为4—5月,盛期4月末。成熟个体多数4龄,最小成熟雌鱼体长309毫米。体长285—438毫米,体重315—1098克的个体绝对怀卵量1629至3119(平均2194),与体长L的关系式N=9.54924 L-1297.3246,与体重W的关系式N=2.2207W 641.6345。卵径3.5—4.0毫米。水温5.3—9.0℃时,受精后625小时孵出。用鳞片测定年龄及生长。3龄鱼体长可达356毫米,5龄鱼体长一般为389毫米。体长与体重的关系式W_(?)=0.002486L~(2.9146),W_♀=0.004509L~(2.8978)。     

不同温度条件下运动和摄食对细鳞鲑幼鱼代谢模式的影响

为了揭示不同温度条件下运动和摄食对细鳞鲑幼鱼代谢模式的影响,在饱和溶氧(>8.0 mg·L^-1)条件下,分别测定了空腹组和摄食组在5个处理温度(4、8、12、16和20 ℃)下的运动前代谢率(MO_2p)、活跃代谢率(MO_2a)、代谢范围(MS)、临界游泳速度(U_C)以及10个流速水平下的实时游泳代谢率(MR).结果表明: 在各个温度条件下,摄食组的MO_2p和MO_2a均显著高于空腹组(P<0.05),且分别提高了15%和12%(4 ℃)、47%和23%(8 ℃)、30%和21%(12 ℃)、43%和36%(16 ℃)及8%和7%(20 ℃);摄食组与空腹组的U_C和MS均无显著性差异(P>0.05),但随着温度升高,两组的MS均呈现下降趋势;随流速的增加,各组的游泳代谢率呈先升高后降低的变化规律,且摄食组显著大于空腹组(P<0.05),各组的最大代谢率峰值均出现在低于U_C的流速条件下;在细鳞鲑幼鱼的游泳速度接近70%U_C的运动过程中,其代谢率不断增大至峰值,随后在游泳速度达到U_C的过程中,代谢率呈下降趋势.表明在一定温度范围条件下,细鳞鲑幼鱼的最大代谢率是由运动与摄食共同诱导产生的,在达到最大代谢率峰值的过程中代谢表现为添加模式;之后随游泳代谢率的下降,摄食诱导的代谢率被削减,该过程表现为运动优先代谢模式.     

基于线粒体控制区和微卫星标记探讨秦岭细鳞鲑物种有效性

文章基于线粒体控制区基因序列和微卫星标记比较秦岭细鳞鲑(Brachymystax tsinlingensis Li)、黑龙江流域的尖吻细鳞鲑(Brachymystax lenok Pallas)和钝吻细鳞鲑(Brachymystax tumensis Mori)的分子遗传差异,为澄清其分类地位争议提供分子证据。结果表明:(1)扩增217个样本的mtDNA D-loop区序列,共获得45个单倍型,类群间无共享单倍型;基于单倍型构建的系统进化树显示三个细鳞鲑类群呈独立的支系;(2)基于14个呈多态性位点的遗传分化结果表明,秦岭细鳞鲑与尖吻或钝吻细鳞鲑之间的遗传距离均大于尖吻细鳞鲑和钝吻细鳞鲑之间的遗传距离;(3)基于线粒体D-loop和多态性微卫星位点计算出的遗传分化系数(F_ST)都远高于0.25表明三个类群间的遗传分化程度极高。这些结果表明,秦岭细鳞鲑与黑龙江流域细鳞鲑之间遗传分化程度高,结合前期发现秦岭细鳞鲑与黑龙江细鳞鲑类群有明显形态分化的研究结果及它们之间地理隔离已久的现状,研究初步判定秦岭细鳞鲑为独立物种,并建议以Brachymystax tsinlinge...     

Expression of the soluble adenylyl cyclase during rat spermatogenesis: evidence for cytoplasmic sites of cAMP production in germ cells

To gain insight into the mechanisms of cAMP signaling in germ cells, the expression and subcellular localization of the full-length form of the soluble adenylyl cyclase (sAC) was investigated during rat spermatogenesis and in spermatozoa. A full-length sAC-specific antibody was generated by using a glutathione S-transferase (GST)-sAC carboxyl-terminal region (1399aa-1608aa) fusion protein as the antigen. The selectivity of the purified antibody was confirmed by immunoblotting with lysates from HEK293 cells overexpressing full-length sAC or truncated sAC. Western blot analysis demonstrated that full-length sAC protein appeared on day 25 during testis development. The expression levels increased progressively on days 30 and 35 and remained elevated in adult testis. Full-length sAC protein is retained in spermatozoa from the cauda epididymis. Consistent with the timing of the appearance of the Western blot signal, immunohistochemistry with testis sections at different stages of development detected sAC in late pachytene spermatocytes as well as round and elongating spermatids. Further experiments on the subcellular localization of native or recombinant enzymes revealed that full-length sAC is not only recovered in soluble fractions but also in particulate fractions of testis extracts. Immunofluorescence detection showed localization of the protein in the cytoplasm as well as in organelles of pachytene spermatocytes and spermatids. These findings indicate that cAMP production in spermatids and spermatozoa may occur at sites other than the plasma membrane and suggest that full-length sAC may play a role during spermatid differentiation.     

Effect of hypoxia by intermittent altitude exposure on semen characteristics and testicular morphology of male rhesus monkeys

Semen characteristics and testicular morphology of rhesus monkeys were studied on exposure to a simulated high altitude of 4411 m for 21 days. There was a partially reversible decrease in the semen volume, sperm count and sperm motility, as well as an elevation of pH and fructose concentration. These changes were associated with degeneration of the germinal epithelium and spermatogenic arrest at the end of third week of exposure which had not recovered even 3 weeks after the exposure.     

Characterization of the Testis-specific Proteasome Subunit α4s in Mammals

The 26 S proteasome is responsible for regulated proteolysis in eukaryotic cells. It is composed of one 20 S core particle (CP) flanked by one or two 19 S regulatory particles. The CP is composed of seven different α-type subunits (α1-α7) and seven different β-type subunits, three of which are catalytic. Vertebrates encode four additional catalytic β subunits that are expressed predominantly in immune tissues and produce distinct subtypes of CPs particularly well suited for the acquired immune system. In contrast, the diversity of α subunits remains poorly understood. Recently, another α subunit, referred to as α4s, was reported. However, little is known about α4s. Here we provide a detailed characterization of α4s and the α4s-containing CP. α4s is exclusively expressed in germ cells that enter the meiotic prophase and is incorporated into the CP in place of α4. A comparison of structural models revealed that the differences in the primary sequences between α4 and α4s are located on the outer surface of the CP, suggesting that α4s interacts with specific molecules via these unique regions. α4s-containing CPs account for the majority of the CPs in mouse sperm. The catalytic β subunits in the α4s-containing CP are β1, β2, and β5, and immunosubunits are not included in the α4s-containing CP. α4s-containing CPs have a set of peptidase activities almost identical to those of α4-containing CPs. Our results provide a basis for understanding the role of α4s and male germ cell-specific proteasomes in mammals.     

Acrogranin,an acrosomal cysteine-rich glycoprotein,is the precursor of the growth-modulating peptides,granulins, and epithelins,and is expressed in somatic as well as male germ cells

Spermatogenesis is a unique system of differentiation involving cellular remodeling and the biogenesis of sperm-specific organelles. To study the biogenesis of one such organelle, the acrosome, we have been examining the gene expression, biosynthesis, and targeting of specific acrosomal proteins during mammalian spermatogenesis. An acrosomal marker that we recently purified and began characterizing is acrogranin, a 67,000-molecular-weight glycoprotein originally isolated from guinea pig testes. This glycoprotein is detected in pachytene spermatocytes and is found later in the acrosomes of developing spermatids and sperm. Immunoblotting of several tissues and immunofluorescent localization in frozen sections of guinea pig testes suggested that acrogranin was a germ cell-specific glycoprotein that was expressed meiotically and post-meiotically. However, Northern blot analysis demonstrated that the mRNA for acrogranin was ubiquitously expressed in all guinea pig and mouse tissues examined. Furthermore, the primary structures of guinea pig and mouse acrogranins, deduced from the cDNA sequences, reveal that this glycoprotein is a cysteine-rich molecule with a motif that is tandemly repeated seven times, very similar to that of the human epithelin/granulin precursor. We conclude that guinea pig and mouse acrogranins are homologues of the precursor of the human and rat epithelin/granulin peptides previously demonstrated to have growth-modulating properties. © 1993 Wiley-Liss, Inc.     

海月水母精巢发育及排精过程的观察

采用实验生态学及显微观察的方法研究了海月水母(Aurelia sp.)的精巢发育及其排精过程,并对其精子活力进行了测定。结果表明:在水温20~22℃的条件下,海月水母碟状体经过40 d生长,达到伞径(7.50±0.71)cm、体重(28.70±6.60)g时,精巢出现并生长发育;经过60 d生长,达到伞径(11.77±0.51)cm、体重(83.54±10.36)g时,精巢发育成熟并开始排精;生长90 d后,精巢开始出现退化,当生长110 d时,精巢退化完全。在精巢发育过程中,其宽度和长度分别伴随海月水母伞径的增长而增宽和伸长,并出现折叠现象。海月水母的排精路线为:精子先粘附于精子细丝上,从精巢排出,继而经过胃循环沟、胃口腕沟,最后由口腕基沟排出体外。在水温22℃、盐度30、p H 8.0的条件下,海月水母精子活力随时间延长而降低,其快速运动时间和寿命分别为4 h 30 min和10 h。本研究结果显示,在适宜的环境条件下,海月水母精巢发育迅速,排精路线与过程相对简单,其精子活力强、寿命长,这种高效的生殖策略为其暴发奠定了基础,这或许也是海月水母能在地球上存活年代久远的原因之一。     

基于线粒体DNA控制区序列变异探讨黑龙江和图们江细鳞鲑属鱼类的分类地位

基于细鳞鲑属Brachymystas鱼类的线粒体DNA控制区基因序列变异,对分布于黑龙江水系中国境内的尖吻细鳞鲑(sharp-snouted lenok)和钝吻细鳞鲑(blunt-snouted lenok),及分布于图们江的图们江细鳞鲑B.tumensis进行分子系统关系研究,为进一步确定黑龙江水系2种细鳞鲑的分类学地位、有效命名及图们江细鳞鲑物种地位性提供分子生物学依据.分布于黑龙江水系的细鳞鲑种群在系统发育树中明显构成2个独立的进化分支,分别对应可经形态鉴别而差异显著的尖吻细鳞鲑和钝吻细鳞鲑,平均序列分歧为1.9%,在属内已达到种间分化水平;图们江细鳞鲑与尖吻细鳞鲑的呼玛河、乌苏里江、奎勒河等种群共同构为1个进化分支,与尖吻细鳞鲑的序列分歧(平均为1.2%)远低于与钝吻细鳞鲑的序列分歧(平均为2.2%).结合形态学的初步研究结果(图们江细鳞鲑的主要形态特征偏向于尖吻细鳞鲑),不支持图们江细鳞鲑独立种的分类地位,建议为尖吻细鳞鲑B.lenok的同物异名,也不支持普遍认为的钝吻细鳞鲑的有效学名为B.tumensis,其有效命名还待商榷,暂属未定名种.综上所述,基于基因序列分析的遗传学结果进一步验证了形态学的分类结论,即在黑龙江水系细鳞鲑属有2个独立的种,分别为尖吻细鳞鲑B.lenok和钝吻细鳞鲑B.sp.,而图们江细鳞鲑B.tumensis应归为尖吻细鳞鲑B.lenok的同物异名.