小鼠生精周期判定方法的改进

目的探讨一种可以在普通HE染色或苏木精复染标本上对精子发生周期进行简单划分的方法。方法应用PAS染色法与普通HE染色法相对照,对比观察小鼠睾丸各级生精上皮在精子发生不同时期的形态学变化特点。结果参照Clermont及Russel等制定的生精上皮时相的判定标准,把小鼠生精上皮分为XⅡ个期。结论通过对比总结,可以在普通HE染色或苏木精复染标本上对精子发生周期进行简单划分,并进一步辨别各型生精细胞。     

树鼩(TUPAIA BELANGERI CHINENSIS)精子发生的季节性变化

对野外成体树鼩进行了不同季节精小管发育的测定和生精上皮细胞学特征的观察。精小管平均直径的高峰值出现在4月,为205.7μm:最低值出现在10月,为88.4μm。1、4月份的生精上皮,表现了高度活跃的精子发生,具有明确周期的12个连续阶段和典型的细胞组合。生精上皮退行性变化最早出现于7月,8月进一步发展,10月最明显。附睾精子数量亦表现了类似的季节性波动。表明树鼩精子发生的活性期始于仲冬,最盛在春季,退行期始于仲夏,秋季最显著,有一个明显的精子发生的季节性周期。季节性生殖受局部环境因子的调节,光照可能是重要因素。     

树qu精子发生的季节性变化

对野外成体树qu进行了不同季节精小管发育的测定和生精上皮细胞学特征的观察。精小管平均直径的高峰值出现在4月，为205.7μm；最低值出现在10月，为88.4μm。1、4月份的生精上皮，表现了高度活跃的精子发生，具有明确周期的12个连续阶段和典型的细胞组合。生精上皮退行性变化最早出现于7月，8月进一步发展，10月最明显。附睾精子数量变表现了类似的季节性波动。表明树qu精子发生的活性期始于仲冬，最盛在春季，退行期始于仲夏，秋季最显著，有一个明显的精子发生的季节性周期。季节性生殖受局部环境因子的调节，光照可能是重要因素。     

Rab13 GTPase在大鼠睾丸中的表达及其与生精上皮周期的关系

目的初步明确Rab13 GTPase在大鼠精子发生及成熟过程中的表达情况和可能发挥的作用。方法首先通过RT-PCR技术检测了Rab13 GTPase在不同日龄大鼠睾丸组织中的表达,又利用RT-PCR和Western-blot检测了Rab13在大鼠不同组织中的表达情况,最后采用免疫组化技术检测Rab13 GTPase在大鼠不同期别生精上皮中的分布。结果 RT-PCR显示Rab13 GTPase mRNA水平在40日龄大鼠睾丸组织中表达达到最高峰;在40日龄大鼠,Rab13 GTPase在心、脑、肺、脾、睾丸等5种组织中均有表达,在肺组织中表达量最多;在精子细胞成熟过程中,Rab13在生精上皮基底部及生精细胞周围都有分布,在精子释放前则主要集中分布于生精上皮基底部。结论 Rab13 GTPase的分布,可能随生精上皮周期的变化而对精子发生过程具有一定的调节作用。     

支持细胞在生精细胞凋亡过程中的重要作用

精子的生成过程是一个连续的周期性的过程,这包括二倍体的精原细胞进行一系列的有丝分裂,减数分裂最后分化成为成熟的单倍体精子的过程。支持细胞(Sertoli cell)是生精上皮的一种大细胞,它从管周肌样细胞所处的基底膜延伸出去,直到生精小管的管腔内。它的底部与精原细胞相连,胞质的侧面则形成许多突起将互相联系的生精细胞包围起来,成熟的精子就从这儿释放出去。在复杂的动态生精过程中,支持细胞作为精曲小管的重要组成部分指挥着生精细胞的一系列动态过程,包括有丝分裂、减数分裂以及以后的分化。支持细胞通过给生精细胞提供激素、营养以及生理支持来完成它的功能。     

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.     

粗糙沼虾精巢发育的组织学

利用光镜技术,对粗糙沼虾精巢发育进行了研究,根据精子发生过程中每种生殖细胞所占的比例和发生的次序,并结合精巢的形态特征,把精巢发育过程分为五个时期,即精原细胞期,精母细胞期,精细胞期,成熟精子期及退化期,精原细胞期,精巢小,透明乳白色,生精小管内的生殖细胞以精原细胞为主;精母细胞期;精巢体积增大,半透明乳白色,主要由处于初级精母细胞的次级精母细胞阶段的生殖细胞组成;精细胞期,精巢体积继续增大,颜色加深,生精小管内的生殖细胞以精细胞为主;成熟精子期,精巢体积可达最大,紫红色,生精小管内充满着成熟的精子,退化期;精巢体积减小,半透明乳白色,生精小管内的成熟精子几乎排空。     

生精细胞凋亡相关基因

细胞凋亡(apoptosis)是一种基因控制的细胞生理性自杀行为,用以维持细胞数量的相对恒定,可由某种刺激或抑制剂的移除而激活。在哺乳动物精子发生过程中,各级生精细胞都会发生相应的凋亡,通过严格调控以确保成熟精子生成的数量和质量。生精细胞的凋亡是一个许多基因参与的复杂的不可逆过程,其中Bcl-2/Bax基因族、p53基因、Fas-Fasl基因、C-myc基因、CREM基因、HSP基因族、c-Kit/SCF基因、Insl3基因、iNOS基因、BMP8B基因、TR基因和存活蛋白(survivin)基因等发挥了重要作用。研究哺乳动物睾丸生精细胞凋亡相关基因,有利于了解生精细胞凋亡机制,为进一步阐明精子发生的调控机制,预防和治疗精子发生相关疾病提供重要的理论依据。     

葫芦藓精子发生过程中胞间连丝与胞质桥的超微结构

从超微结构水平上对葫芦藓(Funaria hygrometrica Hedw.)精子发生过程中胞间连接系统的结构及其变化动态进行了研究。结果表明,同一区中的相邻生精细胞由大量胞质桥相连,而不同区的细胞之间则不存在胞质桥。胞间连丝存在于套细胞之间以及套细胞与生精细胞之间, 但它在生精细胞间不存在。在精子器发生的后期,当精子细胞壁开始降解时,同一个精子器中所有的精子细胞似乎都由扩大的胞质桥相互连接。胞质桥一直保持到精子分化的后期,最终精子细胞同步分化成精子。胞间连丝与胞质桥具有不同的内部结、分布以及生物发生机制,这表明它们在精子器的发育过程中可能扮演着不同的角色。     

葫芦藓精子发生过程中胞间连丝与胞质桥的超微结构

从超微结构水平上对葫芦藓(Funaria hygrometrica Hedw.)精子发生过程中胞间连接系统的结构及其变化动态进行了研究.结果表明,同一区中的相邻生精细胞由大量胞质桥相连,而不同区的细胞之间则不存在胞质桥.胞间连丝存在于套细胞之间以及套细胞与生精细胞之间,但它在生精细胞间不存在.在精子器发生的后期,当精子细胞壁开始降解时,同一个精子器中所有的精子细胞似乎都由扩大的胞质桥相互连接.胞质桥一直保持到精子分化的后期,最终精子细胞同步分化成精子.胞间连丝与胞质桥具有不同的内部结、分布以及生物发生机制,这表明它们在精子器的发育过程中可能扮演着不同的角色.     

A method for quantifying synchrony in testes of rats treated with vitamin A deprivation and readministration

Using a variation of a previously published method for manipulating vitamin A levels, we obtained synchronized rat testes and determined the frequency of stages of the seminiferous epithelium in each rat. In this study, we have demonstrated a method for quantitative analysis of the synchrony. The degree of synchronization was expressed as a fraction of the cycle of the seminiferous epithelium, and thus in terms not influenced by the different durations of the stages of this cycle. The median stage about which the tubules were synchronized was calculated. This method may be used to compare the effects of different synchronizing treatments, which may be subtle, and to study various aspects of spermatogenesis in the synchronized testes. For example, the duration of the cycle of the seminiferous epithelium in synchronized testes is estimated to be 12.5 days.     

Observations on living rat spermatogenic cells in different developmental stages.

In the seminiferous tubules of the rat, as in most mammalian species, the developing germ cells form associations with constant cell composition. These cellular associations or stages follow each other in a regular manner along the seminiferous tubules giving rise to seminiferous epithelial wave. When a freshly isolated unstained seminiferous tubulus of the rat is subjected to transillumination under a stereomicroscope, the different segments of the seminiferous epithelial wave absorb light in a characteristic manner permitting their recognition. Using this technique, small segments with accurately known cell composition can be isolated and studied in living state with phase-contrast microscopy. In several cases, the phase-contrast microscopy gives more information about the cell morphology than conventional histological methods. In this study all major developmental steps from early spermatogonia to mature spermatids have been described. The findings of the present study can be used as reference material in the evaluation and identification of the various cell types of the seminiferous tubules obtained, e.g. by the Staput fractionation method. In addition, the findings may be helpful in the evaluation of spermatogenic and Sertoli cells in culture conditions.     

Stability of spermatogenic synchronization achieved by depletion and restoration of vitamin A in rats

Studies of synchronization of spermatogenesis following vitamin A deficiency have suggested that this may provide an in vivo model for the study of stage-dependent changes in hormonal action and protein secretion within the seminiferous epithelium. However, until now, no information on the stability or durability of this condition has been available. In this study, 200 seminiferous tubules from each of 40 rats (including controls) were classified according to their spermatogenic stage after withdrawal and replenishment of vitamin A. Following 15 wk withdrawal and subsequent replenishment of vitamin A, spermatogenesis was initiated in a synchronous fashion. This synchrony remained stable for more than 10 cycles of the seminiferous epithelium (2.5 spermatogenic cycles). In association with the extended period of vitamin A deficiency, a proportion of tubules (30%) showed morphological characteristics of either Sertoli cells only or Sertoli cells plus spermatogonia with occasional pachytene spermatocytes. During the 11-wk period of observation in this study, no significant change in proportions of damaged tubules were observed. Testicular testosterone concentrations, although elevated with respect to controls, showed no correlation with the stage of the cycle of the seminiferous epithelium observed, whereas pituitary and serum follicle-stimulating hormone levels were elevated, probably due to the number of damaged tubules observed. The persistence of synchrony in spermatogenesis following vitamin A treatment suggests that this model is applicable for studies of paracrine actions within the testis. However, the decreased ratio of synchrony observed with time may provide evidence that duration of the individual stages of the cycle of the seminiferous epithelium might be subject to temporal variation, leading to a progressive desynchronization of spermatogenesis in this model system.     

The murine seminiferous epithelial cycle is pre-figured in the Sertoli cells of the embryonic testis

The seminiferous epithelial cycle and spermatogenic wave are conserved features of vertebrate spermatogenic organisation that reflect the need for the rigorous maintenance of sperm production. Although the cycle and the wave of the adult seminiferous epithelium have been well characterised, particularly in rodent species, their developmental origins are unknown. We show that the Sertoli cells of the pre-pubertal mouse, including those of the germ cell-deficient XXSxra mutant, exhibit coordinated, cyclical patterns of gene expression, presaging the situation in the adult testis, where Sertoli cell function is coupled to the spermatogenic cycle. In the case of the galectin 1 gene (Lgals1), localised differential expression in the Sertoli cells can be traced back to neonatal and embryonic stages, making this the earliest known molecular marker of functional heterogeneity in mammalian testis cords. In addition, the timing of germ cell apoptosis in normal pre-pubertal testes is linked to the temporal cycle of the Sertoli cells. These data show that the cycle and wave of the murine seminiferous epithelium originate at a much earlier stage in development than was previously known, and that their maintenance in the early postnatal cords depends exclusively on the somatic cell lineages.     

Cytokines and junction restructuring events during spermatogenesis in the testis: An emerging concept of regulation

During spermatogenesis in mammalian testes, junction restructuring takes place at the Sertoli–Sertoli and Sertoli–germ cell interface, which is coupled with germ cell development, such as cell cycle progression, and translocation of the germ cell within the seminiferous epithelium. In the rat testis, restructuring of the blood–testis barrier (BTB) formed between Sertoli cells near the basement membrane and disruption of the apical ectoplasmic specialization (apical ES) between Sertoli cells and fully developed spermatids (spermatozoa) at the luminal edge of the seminiferous epithelium occur concurrently at stage VIII of the seminiferous epithelial cycle of spermatogenesis. These two processes are essential for the translocation of primary spermatocytes from the basal to the apical compartment to prepare for meiosis, and the release of spermatozoa into the lumen of the seminiferous epithelium at spermiation, respectively. Cytokines, such as TNFα and TGFβ3, are present at high levels in the microenvironment of the epithelium at this stage of the epithelial cycle. Since these cytokines were shown to disrupt the BTB integrity and germ cell adhesion, it was proposed that some cytokines released from germ cells, particularly primary spermatocytes, and Sertoli cells, would induce restructuring of the BTB and apical ES at stage VIII of the seminiferous epithelial cycle. In this review, the intricate role of cytokines and testosterone to regulate the transit of primary spermatocytes at the BTB and spermiation will be discussed. Possible regulators that mediate cytokine-induced junction restructuring, including gap junction and extracellular matrix, and the role of testosterone on junction dynamics in the testis will also be discussed.     

Flow cytometric quantification of rat spermatogenic cells after hypophysectomy and gonadotropin treatment

DNA flow cytometry was evaluated as a tool to analyze stage-specific changes that occur in absolute cell numbers in the testes. Hypophysectomy was selected as a model system for perturbing testicular cell types, since the cytological sequelae of this treatment post-hypophysectomy in the rat are well documented in the literature. Rat spermatogenic cells in stages II-V, VII, and IX-XIII of the seminiferous epithelial cycle (as defined by Leblond and Clermont, 1952) were quantified in numbers per standard length of seminiferous tubule by DNA flow cytometry after hypophysectomy and subsequent gonadotropin treatment. In agreement with previous histological studies, we found that acrosome- and maturation-phase spermatids disappeared from the seminiferous epithelium after 17 days post-hypophysectomy, whereas meiosis and early spermiogenesis continued at least 164 days. The number of meiotic cells and round spermatids gradually decreased after hypophysectomy. Changes were observed as early as Day 6 post-hypophysectomy. Treatment with human chorionic gonadotropin (hCG) alone maintained most cell numbers within normal limits, and follicle-stimulating hormone (FSH) was needed in addition to hCG to maintain the normal number of cells with the amount of DNA contained in primary spermatocytes and spermatogonia in G2/M-phase (4C) in stages IX-XIII and elongated spermatids (1C') in stages II-V of the epithelial cycle. The absolute numbers of spermatogenic cells at different phases of maturation provide a useful reference for quantitative studies of spermatogenesis. Pathological changes in the seminiferous epithelium can be detected and quantified by DNA flow cytometry.