棕色田鼠睾丸及附睾胚后发育的形态学变化

通过组织学方法,对产后1 d、10 d、25 d、45 d、60 d及70 d的棕色田鼠Lasiopodomys mandarinus睾丸和附睾发育进行了观察,以探讨其精子发生特点.结果 发现,1 d棕色田鼠的生殖细胞主要是生殖母细胞和前精原细胞;10 d出现大量精原细胞,睾丸间质细胞明显;25 d出现精子细胞;45 d有少量精子出现;60 d和70 d具有各级生精细胞,睾丸生精小管和附睾内出现大量成熟精子.睾丸生精小管管径和生精上皮厚度随日龄增加,于60 d达到最大;附睾管腔直径和附睾上皮厚度也于60 d达到最大.这些结果表明,棕色田鼠在生后45 d左右进入青春期,60 d左右达到性成熟,精子的产生及成熟与附睾的发育同步.     

雄性裸鼹鼠可育个体与不可育个体生殖系统结构与功能差异初探

目的观察和分析雄性裸鼹鼠中可育个体和不可育个体生殖系统结构和功能的差异,初步探索雄性不可育个体不能繁育后代的原因。方法雄性裸鼹鼠可育个体和不可育个体各5只,先采集一侧睾丸和附睾组织,称重后换算脏器系数;再采集另一侧睾丸组织,用中性甲醛溶液进行固定后制备组织切片;取另一侧附睾用作精子计数、精子活动度的测定;采集血清测定血清中黄体生成素(LH)和睾酮(T)浓度。结果与可育个体组相比较,不可育个体组的睾丸重量下降(P0.05),附睾重量显著下降(P0.01),且睾丸系数和附睾系数均显著下降(P0.01);精子数量显著减少(P0.01),精子活动度也显著减弱(P0.01);血清黄体生成素和睾酮水平均显著降低(P0.01);睾丸组织切片观察显示,不可育个体各级生精细胞严重脱落,排列混乱无序,支持细胞和间质细胞均有减少。结论雄性裸鼹鼠不可育个体生殖系统存在睾丸和附睾萎缩、生精功能下降和性激素分泌减少等现象。     

合欢皮总皂苷对雄性小鼠的抗生育作用研究

目的探讨合欢皮总皂苷对雄性小鼠的抗生育作用。方法将60只健康的雄性性成熟昆明小鼠随机分成3个试验组和1个对照组,各试验组小鼠灌胃540 mg·(kg·d)-1,270 mg·(kg·d)-1和135 mg·(kg·d)-1的合欢皮总皂苷水溶液,对照组自由饮水,灌胃1周后按雌雄比2∶1合笼,继续对雄鼠灌胃至19 d,采集雄性小鼠的血液并测定血液生化指标,剖检灌胃雌性小鼠,统计雌性小鼠的怀孕率,测定雄性小鼠睾丸与附睾的脏器系数及附睾精子活力,并固定睾丸和附睾,研究其组织学变化。结果与对照组相比较,雄性小鼠灌胃合欢皮总皂苷后,导致雌性小鼠的怀孕率降低,睾丸脏器系数和附睾精子活率极显著降低(P<0.01),精子畸形率极显著升高(P<0.01)。光学显微镜下,试验组小鼠睾丸和附睾均有一定程度的损失,睾丸生精细胞排列疏松,间质减少,可见曲细精管内有多核巨噬细胞浸润,各级生精细胞脱落。附睾具正常的管腔结构,但能明显观察到管腔内精子几乎消失。结论合欢皮总皂苷对雄性小鼠具有抗生育作用,主要通过影响精子的生成及破坏生精组织而达到。     

薄荷油对雄性小鼠的抗生育作用研究

目的探讨薄荷油对雄性小鼠的抗生育作用。方法将60只健康的雄性性成熟昆明小鼠随机分成3个试验组和1个对照组,各试验组小鼠灌胃0.135 g/(kg·d),0.27 g/(kg·d)和0.54 g/(kg·d)的薄荷油0.5%羧甲基纤维素钠(sodium carboxymethylcellulose,CMC)混悬液,对照组灌胃0.5%羧甲基纤维素钠溶液,灌胃1周后按雌雄比2∶1合笼,继续对雄鼠灌胃至19 d,采集雄性小鼠的血液并测定血液生化指标,剖检灌胃雌雄小鼠,统计雌性小鼠的怀孕率,测定雄性小鼠睾丸与附睾的脏器系数及附睾精子活力,并固定睾丸和附睾,研究其组织学变化。结果与对照组相比较,雄性小鼠灌胃薄荷油后,导致雌性小鼠的怀孕率降低,睾丸脏器系数和附睾精子活率极显著降低(P<0.01),精子畸形率极显著升高(P<0.01)。光学显微镜下,试验组小鼠睾丸和附睾均有一定程度的损伤,睾丸间质减少,睾丸各级生精细胞排列疏松,曲细精管内有多核巨噬细胞浸润。附睾具正常的管腔结构,但能明显观察到管腔内精子减少。结论薄荷油对雄性小鼠具有抗生育作用,且主要通过影响精子的生成及破坏生精组织而达到,具有实际应用价值,可进一步开发成环境友好型鼠类抗生育药剂。     

链脲佐菌素糖尿病小鼠睾丸内生精细胞减少与PCNA和Ki67表达降低

目的通过检测增殖细胞核抗原(proliferating cell nuclear antigen,PCNA)及Ki67在正常及糖尿病小鼠睾丸组织中表达的差异,探讨糖尿病对生精细胞增殖的影响。方法 30只正常雄性C57BL/6小鼠,随机分为对照组(10只)和糖尿病组(20只)。采用腹腔注射链脲佐菌素的方法建立糖尿病小鼠模型,对照组注射相同体积的柠檬酸—柠檬酸钠缓冲液。造模成功3周后处死动物,取睾丸组织,常规固定、石蜡包埋、切片HE染色观察睾丸组织的形态学变化;免疫组织化学SP法检测PCNA及Ki67在睾丸组织中的表达;图像分析技术分析组织中PCNA及Ki67免疫组织化学表达水平。结果 HE染色显示,糖尿病小鼠睾丸内处于精子发生前半期的生精小管内生精细胞排列疏松,细胞层数偏少,附睾管内精子密度相对较低;免疫组织化学染色显示,PCNA和Ki67在糖尿病小鼠睾丸生精小管中的表达均明显降低。结论高糖可能通过降低生精细胞的增殖进而影响睾丸精子的发生。     

中国石龙子雄性生殖腺的年周期变化

20 0 1年 3月至 2 0 0 2年 2月期间 ,通过每月捕捉浙江丽水中国石龙子 (Eumeceschinensis)雄性成体 ,解剖动物、观测性腺的形态和组织学特征 ,研究雄性生殖周期。睾丸重量和体积、附睾重、输精管重和曲细精管直径有显著的季节变化。睾丸 3月份最重 ,5-9月最轻。睾丸体积和重量的年周期变化规律一致。附睾 3月份最重 ,8-9月份最轻。输精管 4月最重 ,8-10月最轻。生精活动始于 9月下旬 ,翌年 4月最为活跃。 3月下旬曲细精管直径达全年最大值 ,管腔中开始出现呈穗状排列的精子。从基膜到管腔 ,各级生精细胞依次排列。 4月份生精上皮的生精活动最为活跃 ,5月下旬生精活动已近停止 ,7-8月份曲细精管管壁仅由精原细胞 (其间夹有支持细胞 )构成。根据曲细精管生精上皮的年周期变化规律 ,中国石龙子 8月份睾丸生精活动处于第Ⅰ期 ,9月至次年 2月份第Ⅱ期 ,3月上、中旬为Ⅲ期 ,3月底至 4月为Ⅳ期 ,5-6月份为Ⅴ期 ,7月份为Ⅵ期。 4月下旬附睾管腔中有大量的成熟精子 ,7月附睾管腔中已无精子。中国石龙子属于关联型繁殖周期     

藏绵羊和小尾寒羊雄性生殖器官组织结构比较

通过比较绵羊(Ovis aries)的两个品种,生活于高海拔(4500 m)地区的藏绵羊与相对低海拔(2080m)地区小尾寒羊雄性生殖器官的组织结构特征,以探讨哺乳动物生殖器官适应高原环境的组织结构基础。采集成年藏绵羊与小尾寒羊的睾丸、附睾、输精管,运用大体解剖、石蜡切片及常规H.E,染色方法,比较二者生殖器官的组织结构差异。结果显示,藏绵羊附睾头和附睾体管腔内的纤毛较长,而附睾尾管腔内的纤毛较短,呈清晰的刷状缘结构,输精管平滑肌细胞较多,固有膜和黏膜层粘连紧密,且形成较明显的不规则皱襞。与小尾寒羊相比,藏绵羊曲细精管的横切面直径、面积和生精上皮的厚度均显著降低(P<0.05);精原细胞和初级精母细胞的直径及面积显著降低(P<0.05),且支持细胞数也显著减少(P<0.05);附睾头、附睾体、附睾尾的管腔内径和外径及纤毛长度均显著减小(P<0.05);附睾体的柱状上皮厚度显著增高(P<0.05),而输精管管腔直径、平滑肌厚度均显著降低(P<0.05)。研究认为,藏绵羊在高海拔低氧环境的长期适应过程中,其生殖器官的组织结构发生了--定的适应性改变,可能与其在高原环境下正常繁殖性能的维持有关。     

长江江豚精巢发育和组织学特征的研究

性成熟的江豚精巢明显增大,其重量约为成熟前的14倍,结合有关江豚捕捞和野外生态学资料,初步认为长江江豚属多雌性群体,而成熟的雄性个体具有较大的精巢,可能对保证群体的成功繁殖非常重要。根据精巢的组织学特征,可将江豚精巢发育分为胚胎早期、胚胎晚期、成熟前期和成熟期(包括活动期和不活动期),通过对精巢生精小管管径大小和白膜厚度进行分析,认为成熟江豚精巢活动呈季节性变化。       

麻黄素对仔鼠睾丸组织结构和Bax、EGF蛋白的影响

为探讨麻黄素对各发育期昆明小鼠(Mus musculus)仔鼠睾丸组织结构及Bax蛋白和表皮生长因子(epidermal growth factor,EGF)阳性表达的影响,选取雄性仔鼠采用递增剂量腹腔连续注射麻黄素,应用生物显微技术观察睾丸组织结构的变化,用免疫组织化学和体视学半定量方法检测Bax和EGF蛋白在睾丸组织中的表达.结果表明,麻黄素组仔鼠各发育阶段生精小管直径及上皮厚度明显小于对照组(P＜0.01或P＜0.05),初级精母细胞直径小于对照组(P＜0.01或P＜0.05),生精小管上皮各级生精细胞的发生较晚,且排列疏松而凌乱,细胞间空隙多,发育成熟期管腔内成熟精子较少;麻黄素组各发育期仔鼠睾丸中Bax和EGF蛋白的阳性表达与对照组相比显著增强(P＜0.01或P＜0.05).上述结果表明,麻黄素影响仔鼠睾丸组织的发育,麻黄素对各发育期仔鼠睾丸组织的损伤可能与Bax和EGF蛋白表达的增强有关.     

褐翅鸦鹃繁殖期雄性生殖系统的组织解剖观察

于2008年4月对4只成体褐翅鸦鹃雄性生殖系统进行组织解剖观察.其左侧睾丸重0.77 g±0.05 g,是右侧的3倍,达体重的0.36%,曲精细管充盈整个睾丸,没有睾丸纵隔和睾丸小叶,生精上皮厚56.88 μm±11.52 μm,睾丸间质较少.附睾1对,小而不明显.输精管长49.16 mm±1.56 mm,黏膜层形成许多纵形的皱壁,单层高柱状上皮细胞含大量糖原颗粒,固有膜无腺体,肌层发达.     

Histology and morphometrics of testes of the white-sided dolphin (Lagenorhynchus acutus) in bycatch samples from the northeastern Atlantic

The testes of 31 Atlantic white-sided dolphins, Lagenorhynchus acutus bycaught in the northeastern Atlantic were studied by histological and morphometric techniques. Twenty specimens were classified as mature, nine as immature and two as pubescent. Between immature and mature specimens there were overlappings in body length and body weight, but clear differences in the diameter of seminiferous tubules (<80 and >80 μm) and the proportion of seminiferous tubules to interstitial tissue (ST:INT-ratio). Also relative testes weight differed clearly. The pubescent specimens showed intermediate characteristics. Spermatogenetic activity of mature dolphins ranged from quiescent to different degrees of activity and varied even in animals from the same site and capture date. The fact that we found mature males with quiescent testes suggests a seasonal rather than a continuous spermatogenesis. We assume that sexual activity in L. acutus begins at an age of 7–8 GLGs and that the reproductive season of this species in the northeastern Atlantic starts in February. Further, the ultrastructure of the spermatozoon is similar to that of the related Lagenorhynchus obliquidens.     

Spermatogenesis in white-lipped peccaries (Tayassu pecari)

We describe here morphological and functional analyses of the spermatogenic process in sexually mature white-lipped peccaries. Ten sexually mature male animals, weighing approximately 39 kg were studied. Characteristics investigated included the gonadosomatic index (GSI), relative frequency of stages of the cycle of seminiferous epithelium (CSE), cell populations present in the seminiferous epithelium in stage 1 of CSE, intrinsic rate of spermatogenesis, Sertoli cell index, height of seminiferous epithelium and diameter of seminiferous tubules, volumetric proportion of components of the testicular parenchyma and length of seminiferous tubules per testis and per gram of testis. The GSI was 0.19%, relative frequencies of pre-meiotic, meiotic and post-meiotic phases were, respectively 43.6%, 13.8% and 42.6%, general rate of spermatogenesis was 25.8, each Sertoli cell supported an average 18.4 germinative cells, height of seminiferous epithelium and diameter of seminiferous tubules were, respectively, 78.4 microm and 225.6 microm, testicular parenchyma was composed by 75.8% seminiferous tubules and 24.2% intertubular tissue, and length of seminiferous tubules per gram of testis was 15.8m. These results show that, except for overall rate of spermatogenesis, the spermatogenic process in white-lipped peccaries is very similar to that of collared peccaries, and that Sertoli cells have a greater capacity to support germinative cells than most domestic mammals.     

Stages and duration of the cycle of the seminiferous epithelium in oncilla (Leopardus tigrinus, Schreber, 1775)

Six adult Leopardus tigrinus (oncilla) were studied to characterize stages of the seminiferous epithelium cycle and its relative frequency and duration, as well as morphometric parameters of the testes. Testicular fragments were obtained (incisional biopsy), embedded (glycol methacrylate), and histologic sections examined with light microscopy. The cycle of the seminiferous epithelium was categorized into eight stages (based on the tubular morphology method). The duration of one seminiferous epithelium cycle was 9.19 d, and approximately 41.37 d were required for development of sperm from spermatogonia. On average, diameter of the seminiferous tubules was 228.29 μm, epithelium height was 78.86 μm, and there were 16.99 m of testicular tubules per gram of testis. Body weight averaged 2.589 kg, of which 0.06 and 0.04% were attributed to the testis and seminiferous tubules, respectively. In conclusion, there were eight distinct stages in the seminiferous epithelium, the length of the seminiferous epithelium cycle was close to that in domestic cats and cougars, and testicular and somatic indexes were similar to those of other carnivores of similar size.     

Seminiferous epithelium cycle of a hantavirus reservoir, the long-tailed mouse Oligoryzomys flavescens (Rodentia-Cricetidae)

Oligoryzomys flavescens, a common rodent of the temperate regions of South America, has been identified as a Hantavirus reservoir. There is still little information concerning its reproductive biology, which is essential to devise effective control measurement of natural populations. This rodent is a seasonal breeder and adult males exhibit a short period of testicular regression during winter months (June-August). In the present study we provided a histological and ultrastructural analysis of the composition of the testis of sexually mature O. flavescens during the breeding season. Over 95% of the testicular parenchyma was occupied by the seminiferous tubules and less than 5% by the interstitial tissue. The mean tubular diameter and epithelium height were 147.2 and 57.8 microm, respectively. The spermatogenic wave was characterized and eight spermatogenesis stages were identified according to the tubular morphology method. Their length, estimated as their relative frequencies, were (I-VIII) 8.8, 14.9, 4.0, 5.0, 10.4, 5.8, 27.0, and 23.9. Ultrastructural features of spermiogenesis are shown for the first time in a sigmodontine rodent.     

Oxidation-reduction potentials and spectral properties of some cytochromes from Thiobacillus versutus (A2)

Antibodies raised against rat hepatic epoxide hydrolase (EC 3.3.2.3) and glutathione S-transferases (EC 2.5.1.18) B, C and E were used to determine the presence and localizations of these epoxide-metabolizing enzymes in testes of sexually immature and mature Wistar and Holtzman rats. Unlabeled antibody peroxidase-antiperoxidase staining for each enzyme was readily detected in rat testes at the light microscopic level. Although significant strain-related differences were not apparent, staining intensity for certain enzymes differed markedly between Leydig cells and seminiferous tubules. Leydig cells of immature and mature rats were stained much more intensely for epoxide hydrolase and glutathione S-transferases B and E than were seminiferous tubules, whereas Sertoli cells, spermatogonia, spermatocytes and spermatids, as well as Leydig cells, were stained intensely by the anti-glutathione S-transferase C. Age-related differences in staining for glutathione S-transferase B were not obvious, while the anti-glutathione S-transferase C stained seminiferous tubules more intensely in immature rats, and antibodies to epoxide hydrolase and glutathione S-transferases C and E stained Leydig cells much more intensely in mature rats. These observations thus demonstrate that testes of both sexually immature and mature rats contain epoxide hydrolase and glutathione S-transferases. Except for glutathione S-transferase C in immature rats, Leydig cells appear to contain much higher levels of enzymes than do seminiferous tubules. During sexual maturation, the testicular level of glutathione S-transferase B appears to remain constant, while levels of epoxide hydrolase and glutathione S-transferases C and E increase within Leydig cells and the level of glutathione S-transferase C decreases within seminiferous tubules.     

Assessment of pubertal development of boars derived from ultrasonographic determination of testicular diameter

At the onset of puberty, seminiferous tubules rapidly increase in diameter, thereby occupying a greater proportion of the testis, resulting in a rapid increase in testicular size. The objective of the current studies was to evaluate ultrasonography for assessing testicular diameter, as a basis for ranking boars relative to their extent of pubertal development. In the initial study, prior to castration at 4, 5, 6, or 7 mo of age, testicular length and diameter were assessed by ultrasonography in 160 anesthetized boars. After castration, testes were weighed. Mean diameter of seminiferous tubules and percentage of the testis occupied by tubules were determined by histological evaluations of all testes. Testicular volume was calculated from length and diameter and was correlated with testicular weight (P < 0.001; r ≧ 0.78) within each of the four age groups. At 4 and 5 mo of age, testicular diameter correlated positively (P < 0.001) with diameter of seminiferous tubules; this relationship was not significant at older ages. In two subsequent studies, testicular diameter determined ultrasonographically in conscious boars was highly correlated (r > 0.8) when assessed twice on the same day, or when diameter of the right was compared with diameter of the left testis. Similarly, testicular diameter obtained initially at 92 d of age correlated positively (P < 0.001) with the diameter observed at older ages, but the magnitude of the relationship decreased as time between evaluations increased. These findings supported ultrasonographic determination of testicular diameter during early pubertal development, as a means to rank boars of similar chronological age for extent of pubertal development.     

Cases of spermiogenesis in young European bison

Development of spermiogenesis and sizes of seminiferous tubules of the testes and epididymal duct were studied in 45 young European bisonBison bonasus (Linnaeus, 1758) males from an enclosed breeding centre and a free-ranging population in the Białowieża Forest. Of 13 males in age class II (up to two years), four showed the presence of elongated late spermatids: one male aged 15 months from the enclosed breeding centre and three from the free-ranging population (2 males aged 18 months and one about 24 months old). Of 7 males from age class III (up to 3 years), four showed spermiogenesis, of which the youngest, 26 and 32 months old, were from enclosed breeding. Spermiogenesis was observed in males with high body weight in a given age class. In males of age class I (up to one year old), the mean diameter of the seminiferous tubules was 49.8 μm, in class II — 110.7 μm, and in class III — 162 μm, the mean diameter of the epididymal duct being 110.8 μm, 187.2 μm and 273.4 μm, respectively. Measurements of seminiferous tubules and epididymal duct were significantly correlated with age and body weight of males and differed significantly between the three age classes.     

Localization of epoxide-metablozing enzymes in rat testis

Antibodies raised against rat hepatic epoxide hydrolase (EC 3.3.2.3) and glutathione S-transferases (EC 2.5.1.18) B, C and E were used to determine the presence and localizations of these epoxide-metabolizing enzymes in testes of sexually immature and mature Wistar and Holtzman rats. Unlabeled antibody peroxidase-antiperoxidase staining for each enzyme was readily detected in rat testes at the light microscopic level. Although significant strain-related differences were not apparent, staining intensity for certain enzymes differed markedly between Leydig cells and seminiferous tubules. Leydig cells of immature and mature rats were stained much intensely for epoxide hydrolase and glutathione S-transferase B and E than were seminiferous tubules, whereas Sertoli cells, spermatogonia, spermatocytes and spermatids, as well as Leydig cells, were stained intensely by the anti-glutathione S-transferase C. Age-related differences in staining for glutathione S-transferase B were not obvious, while the anti-glutathione S-transferase C stained seminiferous tubules more intensely in immature rats, and antibodies to expoxide hydrolase and glutathione S-transferases C and E stained Leydig cells much more intensely in mature rats. These observations thus demonstrate that testes of both sexually immature and mature rats contain epoxide hydrolase and glutathione S-transferases. Except for glutathione S-transferase C in immature rats, Leydig cells appear to contain much higher levels of enzymes than do seminiferous tubules. During sexual maturation, the testicular level of glutathione S-transferase B appears to remain constant, while levels of epoxide hydrolase and glutathione S-transferases C and E increase within Leydig cells and the level of glutathione S-transferase C decreases within seminiferous tubules.     

Seasonal changes in the spermatogenic epithelium of adult Japanese macaques (Macaca fuscata fuscata)

A histological study was undertaken to clarify seasonal changes in the spermatogenic epithelium of Japanese macaques. Testicular tissue samples were excised by biopsies from five adult laboratory-maintained males in mating and non-mating seasons. The samples were fixed with Bouin's solution, embedded in paraffin, and stained with PAS and hematoxylin. Microscopic observations on cross-sections of seminiferous tubules revealed that the seminiferous epithelium in the mating season was thicker than in the non-mating season. PAS-stained granules were found in some of the dark A-type spermatogonia, which significantly increased in the non-mating season. Spermatids of the steps preceding the appearance of the acrosomic cap in stages I to III were observed significantly more often than those in the step coinciding with the formation of the acrosomic cap in stage IV. In stage I, the ratio of mature spermatids or spermatozoa to immature spermatids in the mating season was higher than that in the non-mating season. These findings suggest that spermiogenesis, as well as spermatocytogenesis, is inhibited in the non-mating season.     

Seasonal changes in the testes of the silver fox

In 14 mature male silver foxes in spring and autumn by means of counting dots and transsections, relative and absolute summational volumes and areas of the seminiferous tubule surfaces, interstitial glandulocytes (Leydig's cells) and stroma have been calculated. Average diameter and total length of the tubules have been determined. Increased mass of the testes in spring is the result of a proportional enlargement of the total volume of the seminiferous tubules and stroma, while the total volume of the endocrinic part in the organ changes insignificantly. The increase of the total volume of the seminiferous tubules occurs at the expense of the increasing diameter, though their total length remains the same.