On the Postnatal Development of the Terminal Segment of the Seminiferous Tubules in Normal and Germ Cell Depleted Rat Testes

The development of the terminal segment of the seminiferous tubules was studied in 5 to 50 days old normal rats. At the age of 5, 10, and 15 days the terminal segment contained fewer gonocytes or spermatogonia than did the corresponding seminiferous tubule. The differentiation of the terminal segment was obvious at 20 days of age due to the high number of germ cells in the seminiferous tubules, where the epithelium became stratified at this stage. The blood-testis barrier in the terminal segment was chiefly established between 15 and 20 days of age as revealed by the lanthanum tracer technique.
To study the effect of the germ cells on the differentiation, the germ cell depleted testes of prenatally irradiated rats were also studied. The modified Sertoli cells of the terminal segment were more vacoulated and had fewer lipid droplets and inter-Sertoli cell junctions than did the Sertoli cells of the seminiferous tubules. The ultrastructure of the modified Sertoli cells of the terminal segment was similar in adult normal and adult SCO (Sertoli cell only) rats. The amount of lipid droplets in the Sertoli cells of SCO rats showed considerable variation among different tubular cross-sections within one testis.     

Expression of beta-catenin in human testes with spermatogenic defects

beta-catenin is a multifunctional molecule that functions in intercellular adhesion and signal transduction during assembly of AJs between Sertoli cells as well as between Sertoli cells and germ cells. To assess changes in the testicular beta-catenin in male infertility conditions, testicular tissues from obstructive azoospermia with normal spermatogenesis, spermatogenic arrest (SA) and Sertoli cell-only syndrome (SCO) patients were examined for immunohistochemical localization of beta-catenin. In normal spermatogenic tissue, expression of beta-catenin was largely found in the Sertoli cell-germ cell (primarily spermatocytes) contact areas. Interestingly, perinuclear localization of beta-catenin was found in spermatocytes and spermatids. In spermatogenic arrest, beta-catenin in cell contact areas between Sertoli cells and germ cells was greatly decreased, but perinuclear beta-catenin in spermatocytes was not. In SCO, weak or negligible immunoreactivity of beta-catenin was found in cell contacts between Sertoli cells. Nuclear localization of beta-catenin was found in myotubular cells in all samples. Taken together, altered expression of beta-catenin in cell contacts within the seminiferous epithelia in spermatogenic arrest and SCO suggests that interactions between Sertoli cells and germ cell are crucial for expression of beta-catenin, and thus functional development of AJs in seminiferous epithelia in human testis. It should be also emphasized that perinuclear beta-catenin in germ cells may play a specific role in spermatogenesis.     

Êxpression of inducible nitric oxide synthase (iNOS) in the azoospermic human testis

Azoospermia, which is the absence of spermatozoa in the ejaculate, is not a rare cause of male infertility. Inducible nitric oxide synthase (iNOS) is a calcium-independent NOS, which is present in the testis and involved in spermatogenesis, and apoptosis of Sertoli and germ cells. Twenty idiopathic infertile men presenting nonobstructive azoospermia were enrolled in this study, and testicular sperm extraction procedures were performed. Tissue extracts were dissected, and the fluid samples were investigated to determine the presence of spermatozoa. Histologic evaluation of the spermatozoa-present samples revealed that seminiferous tubules were normal and were lined by Sertoli cells and spermatogenic cells. However, in the spermatozoa-absent samples, the diameter of the seminiferous tubules was small, and Sertoli-cell-only syndrome was determined in most of the tubules. iNOS expression was very weak in Sertoli cells, germ cells, and in Leydig cells in the spermatozoa-present group. In the spermatozoa-absent group, the immunostaining was very intense in Sertoli and Leydig cells. Electron microscopy findings were supported the histologic results. In conclusion, complete germ cell loss and intense expression of iNOS in the Sertoli and Leydig cells in the spermatozoa-absent groups of azoospermic human testis suggest an essential role of iNOS in spermatogenesis.     

Testicular Biopsy and Hormonal Study in a Male with Noonan''s Syndrome

The testicular biopsy study of a 17-year-old male with Noonan's syndrome revealed seminiferous tubules of reduced diameter with hypospermatogenesis. Many spermatocytes underwent degeneration and many spermatids developed abnormal. The Sertoli cells were similar to immature Sertoli cells. Fully differentiated Leydig cells were rare while precursor Leydig cells were numerous. Both gonadotropin and testosterone levels were low, and a lack of response to LH-RH as well as to clomiphene was found. The testicular biopsy performed at 20 years of age revealed a certain maturation of the seminiferous tubules which increased the germ cell number. The abnormalities in the spermatogenesis as well as the immature appearance of Sertoli cells continued. Leydig cells were more numerous and showed a certain development without reaching the normal pattern. Gonadotropin levels were normal while testosterone levels low. The response to LH-RH was increased and the absence of response to clomiphene persisted. These features suggest a delayed puberty.     

Expression of endothelial nitric oxide synthase in the Sertoli cells of men with infertility of various causes

OBJECTIVE: To investigate how endothelial nitric oxide (eNOS) expression in the seminiferous tubules might be related to spermatogenesis, by examining eNOS expression in testicular tissue of patients infertile from various causes. PATIENTS AND METHODS: The study included five fertile men with a normal sperm concentration, nine patients with obstructive azoospermia, 20 with varicocele testes and eight with idiopathic azoospermia (Sertoli cell-only syndrome). Testicular biopsy specimens were examined by immunohistochemistry for eNOS protein expression, in addition to a routine pathological assessment. eNOS protein was detected using an eNOS monoclonal antibody. A Sertoli cell staining index (SSI) was defined as the ratio of stained Sertoli cells per total number of Sertoli cells, and was compared among the groups. RESULTS: eNOS was localized to Sertoli cells in the seminiferous tubules and Leydig cells in the interstium; although some degenerating germ cells stained, normal germ cells did not. The SSI was significantly lower in patients with Sertoli cell-only syndrome than in either fertile men or patients with obstructive azoospermia or varicocele. However, the SSI did not correlate significantly with the Johnsen score. CONCLUSION: The expression of eNOS in Sertoli cells may depend on the existence of germ cells and be associated with germ cell development.     

Azoospermia and Sertoli‐cell‐only syndrome: hypoxia in the sperm production site due to impairment in venous drainage of male reproductive system

Sertoli‐cell‐only (SCO) syndrome, or germ cell aplasia, is diagnosed on testicular biopsy when germ cells are seen to be absent without histological impairment of Sertoli or Leydig cells. It is considered a situation of irreversible infertility. Recent studies have shown that varicocele, a bilateral disease, causes hypoxia in the testicular microcirculation. Destruction of one‐way valves in the internal spermatic veins (ISV) elevates hydrostatic pressure in the testicular venules, exceeding the pressure in the arteriolar system. The positive pressure gradient between arterial and venous system is reversed, causing hypoxia in the sperm production site. Sperm production deteriorates gradually, progressing to azoospermia. Our prediction was that, if genetic problems are excluded, SCO may be the final stage of longstanding hypoxia which deteriorates sperm production in a progressive process over time. This would indicate that SCO is not always an independent disease entity, but may represent deterioration of the testicular parenchyma beyond azoospermia. Our prediction is confirmed by histology of the seminiferous tubules demonstrating that SCO is associated with extensive degenerative ischaemic changes and destruction of the normal architecture of the sperm production site. Adequate treatment of bilateral varicocele by microsurgery or by selective sclerotherapy of the ISV resumes, at least partially, the flow of oxygenated blood to the sperm production site and restored sperm production in 4 out of 10 patients. Based on our findings the following statements can be made: (i) SCO may be related in part of the cases to persistent, longstanding testicular parenchymal hypoxia; (ii) germ cells may still exist in other areas of the testicular parenchyma; and (iii) if genetic problems are excluded, adequate correction of the hypoxia may restore very limited sperm production in some patients.     

Seminiferous tubule degeneration in human cryptorchid testes

Two types of degenerating seminiferous tubules were found in cryptorchid testes with Sertoli cell hyperplasia of children and adults: 1) tubules with central degeneration, and 2) tubules with total degeneration. Central degeneration begins with degenerative changes in germ cells that accumulate in the lumen of the seminiferous tubule. Some Sertoli cells may also be affected. Degenerated cells finally disappear, and the remaining tubule is composed of only a cuboidal epithelium, which consists mainly of Sertoli cells and occasional germ cells surrounding a wide lumen. Total degeneration is principally seen in tubules with severe germinal hypoplasia. All the seminiferous epithelium cells degenerate and lose their characteristic distribution, forming a disorganized Sertoli cell nodule surrounded by a thickened basement membrane. Lastly, Sertoli cells disintegrate, and the seminiferous epithelium disappears. Tubular degeneration might be related to the thickening of the basement membrane, which hinders metabolic interchange between the seminiferous epithelium and the interstitium.     

Spermatogenese

Spermatogenesis takes place within the testicular seminiferous tubules which consist of the peritubular lamina propria and the seminiferous epithelium. The latter is composed of germ cells and somatic Sertoli cells. Sertoli cells trigger germ cell development by mediating follicle-stimulating hormone and androgen hormonal stimuli. Spermatogenesis comprises proliferation of spermatogonia, meiosis of spermatocytes, and differentiation of spermatids into spermatozoa (spermiogenesis). There are six distinct and specific germ cell associations (I–VI). These “stages of spermatogenesis” occur sequentially along the length of a tubule. Different defects in spermatogenesis occur in adjacent seminiferous tubules (mixed atrophy) and are associated with deficits in differentiation of Sertoli cells. Biopsy specimens should be fixed in Bouin’s solution. Diagnosis of preinvasive carcinoma in situ is based on the immunohistochemical demonstration of placental-like alkaline phosphatase (PLAP), which is expressed exclusively in carcinoma in situ cells. Histological evaluation should be performed using a score count system, and the use of histological techniques for protein and mRNA expression. Testicular biopsy should only be performed in accordance with strict indication criteria, and histological evaluation should be carried out in specialist centres, i.e. as recommended by the European Academy of Andrology (EAA).     

Spermatogenesis--physiology and pathophysiology

Spermatogenesis takes place within the testicular seminiferous tubules which consist of the peritubular lamina propria and the seminiferous epithelium. The latter is composed of germ cells and somatic Sertoli cells. Sertoli cells trigger germ cell development by mediating follicle-stimulating hormone and androgen hormonal stimuli.Spermatogenesis comprises proliferation of spermatogonia, meiosis of spermatocytes, and differentiation of spermatids into spermatozoa (spermiogenesis). There are six distinct and specific germ cell associations (I-VI). These "stages of spermatogenesis" occur sequentially along the length of a tubule. Different defects in spermatogenesis occur in adjacent seminiferous tubules (mixed atrophy) and are associated with deficits in differentiation of Sertoli cells. Biopsy specimens should be fixed in Bouin's solution. Diagnosis of preinvasive carcinoma in situ is based on the immunohistochemical demonstration of placental-like alkaline phosphatase (PLAP), which is expressed exclusively in carcinoma in situ cells. Histological evaluation should be performed using a score count system, and the use of histological techniques for protein and mRNA expression. Testicular biopsy should only be performed in accordance with strict indication criteria, and histological evaluation should be carried out in specialist centres, i.e. as recommended by the European Academy of Andrology (EAA).     

Specific localization of the basigin protein in human testes from normal adults, normal juveniles, and patients with azoospermia

Basigin is a transmembrane protein belonging to the immunoglobulin superfamily. Specific localization of the protein in normal human testes, from those of a 2-year-old boy to those of a 50-year-old man, and in testes with Sertoli cell only syndrome and germ cell arrest, is reported. Basigin localization was determined using an immunohistochemical technique with an antibody against human basigin. In the normal adult testes, basigin was detected at the periphery of both spermatocytes older than zygotene and round spermatids. In the juvenile testes, it was expressed in accordance with the appearance of pachytene spermatocytes. In this study, pachytene spermatocytes were detected in an 11-year-old boy. Basigin was not expressed in immature testes with germ cells younger than pachytene spermatocytes, namely in testes from boys aged 2-9 years. In testes from adult patients with Sertoli cell only syndrome, basigin was expressed at the periphery of Sertoli cells, but localization was confined to the adluminal compartment of the seminiferous tubule. In testes with germ cell arrest, the protein was expressed on germ cells from pachytene spermatocytes to step 2 spermatids, where present. The results show that in the normal human testes basigin is expressed with the onset of spermatocyte differentiation. Because human basigin is expressed in adult testes with Sertoli cell only syndrome, the protein seems to be synthesized in Sertoli cells and expression continues after these cells dedifferentiate in the seminiferous epithelium.     

大鼠曲细精管生殖细胞体外共培养和精子发生过程的观察

目的建立体外长期共培养体系和观察方法,为精子发生过程的研究提供细胞模型。方法采用大鼠曲细精管生殖细胞及支持细胞共培养的方法,对睾丸生精细胞作显微镜观察。结果共培养的支持细胞和生精细胞在体外存活超过6个月。在共培养期间,观察到精母细胞、圆形精子细胞和长形精子细胞。结论在不添加任何细胞因子和生长因子的情况下,大鼠曲细精管生殖细胞长期增生分化,不断产生精子细胞。这一结果暗示组织块和共生的支持细胞可为生殖细胞的增生和分化提供必需的细胞因子。该方法为体外研究精子发生过程提供了实验依据。     

睾丸细胞生物学研究进展

睾丸是男性生殖腺,由生精小管和间质构成。生精小管主要由生精细胞和支持细胞组成,是精子发生场所;间质中主要是间质细胞,间质细胞合成与分泌雄激素。本文介绍睾丸3种细胞的发育分化,以及成年期睾丸细胞的结构和生物学研究进展。     

The effects of aging on the seminiferous epithelium and the blood-testis barrier of the Brown Norway rat.

Steroidogenesis and spermatogenesis decrease in aging Brown Norway rats. We therefore hypothesized that there must be accompanying morphological changes taking place in the seminiferous tubules of the aging testis. The testes of Brown Norway rats ranging in age from 3 to 24 months were prepared for light and electron microscopy. To assess the integrity of the blood-testis barrier with age, a lanthanum nitrate study was done. The normal seminiferous tubules present in rats at 3 and 12 months of age were largely replaced at 24 months by fully regressed tubules that were virtually devoid of germ cells and contained large intercellular spaces. An electron-microscopic study of these regressed tubules showed a complete loss of cyclical variations of the organelles of the Sertoli cells. The nucleus was more irregularly shaped and was present at various levels in the epithelium. The endoplasmic reticulum was a loose, vesiculated network that was unlike the elaborate, tubular, anastomotic network noted in young animals. The lysosomes were large, oddly-shaped, and contained lipidic inclusions, in contrast to the distinct membrane-bound lysosomes and dense core bodies found in the young animals. Adjacent Sertoli cell processes encompassed large, empty intercellular spaces, possibly occupied previously by germ cells. The typical Sertoli-Sertoli junctions of the blood-testis barrier in the young animal were rarely seen at 24 months and were replaced by focal contact points, usually between three Sertoli cell processes. In the aged animals, lanthanum nitrate permeated the basal and adluminal compartments, extending between Sertoli cell processes and entering the intercellular spaces and lumen. In summary, during aging, there is a breakdown of the blood-testis barrier, and there are striking changes in the appearance of Sertoli cells. These results suggest a possible intrinsic limitation that prevents stem cells from renewing themselves, whether because of a degeneration of immunological origin or because of a lack of Sertoli cell support.     

Differential regulation of inhibin subunits by germ cells in human testes

Inhibin B is comprised of two dissimilar disulfide-linked subunits, termed alpha and betaB, and is physiologically more important than inhibin A in the male. The aim of this study was to investigate testicular expression of inhibin subtypes in infertile men to uncover any interaction between Sertoli cells and germ cells. Ten azoospermic patients with Sertoli cell only syndrome (SCO) and 39 oligozoospermic men were included in this study. Follicle-stimulating hormone (FSH), luteinizing hormone (LH), and testosterone concentrations were determined by chemiluminescence assays. The serum concentrations of inhibin B were measured by enzyme-linked immunosorbent assay. Immunohistochemical staining for the alpha-subunit, betaA-subunit, and betaB-subunit of inhibin were performed on testicular biopsy specimens. The results were that serum inhibin B was undetectable in azoospermic men with SCO, while it was 133.8 +/- 82.0 pg/ml in oligozoospermic men. There was little expression of betaA in the testes of any patient. Expression of inhibin alpha and betaB was observed in Sertoli cells. The percentage of Sertoli cells expressing inhibin alpha was similar in azoospermic patients with SCO (55.3% +/- 20.6%) and in oligozoospermic patients (42.8% +/- 30.4%). In contrast, expression of betaB in Sertoli cells of azoospermic patients (24.9% +/- 16.8%) was lower than in oligozoospermic men (43.4% +/- 25.5%: P = 0.0308). There are no significant correlations between testicular expression of inhibin betaB and the serum inhibin B concentrations. The expression of inhibin betaB by Sertoli cells is dependent on the coexistence of spermatogenic activity within these seminiferous tubules, explaining why the level of inhibin B is low in patients with SCO.     

Pattern of Sertoli cell degeneration in cryptorchid prepubertal tests

Seventy-three testicular biopsies from 54 children (aged 2 months-14 years) with undescended testes were examined by light and electron microscopy. The biopsies included abdominal, inguinally fixed, inguinally moveable, and retractile testes. Alterations in Sertoli cell morphology were found in all biopsies. The alterations included dilated elements of rough endoplasmic reticulum, vacuolization of the cytoplasm, mitochondria with poorly preserved cristae, increase in electron density of the matrix, elongation of the nuclei, and irregularities of the nuclear membrane. According to the numerical appearance of these cells and to the extent of lesions in single Sertoli cells, seven phases in the continuous process of tubular alteration were distinguished. The most severe tubular damaged (phase VII) occurred when the seminiferous epithelium consisted exclusively of necrotic cells. All phases of tubular alterations were seen regularly in each of the biopsies investigated. Germ cells occurred only in phases I-IV and were never observed in tubules in phases V-VII. Significant differences became evident between inguinal and retractile testes by morphometric evaluation. It was demonstrated that the number of germ cells per cross-sectioned tubule (S/T value) correlated negatively with the percentage of tubules in phases V-VII. In contrast to inguinal testes, a complete absence of Sertoli cells and an S/T value less than 0.1 were never found in retractile testes and the percentage of tubules in phases V-VII was reduced significantly compared with inguinal testes. Our findings indicate that (i) maldescended testis in patients between 1 and 15 years-of-age is associated with a special pattern of Sertoli cell degeneration; (ii) Sertoli cell degeneration is a continuous process, which can lead eventually to complete dissolution of the seminiferous epithelium; (iii) total degeneration is not related to age but is dependent on testicular position; (iv) a defined phase of degeneration excludes germ cell development, and therefore enhanced Sertoli cell degeneration in cryptorchid testes must also account for the reduction in germ cell number.     

Defect in germ cells, not in supporting cells, is the cause of male infertility in the jsd mutant mouse: proliferation of spermatogonial stem cells without differentiation

C57BL/6 (B6)-jsd/jsd male mice are sterile because of lack of spermatogenesis. To find the cause of the deficient spermatogenesis, we have examined whether the mutation phenotype is the result of a defect in germ cells or in supporting cells using germ cell transplantation. In the seminiferous tubules of B6-jsd/jsd mutant mice, donor germ cells derived from the wild type GFP transgenic mouse (B6-+/+GFP) were able to undergo complete spermatogenesis, indicating that the juvenile spermatogonial depletion (jsd/jsd) mouse possesses normal supporting cell functions. In contrast, undifferentiated spermatogonia derived from B6-jsd/jsd mice were unable to differentiate in the seminiferous tubules of W/W v mice, even if the mutant germ cells successfully settled in the tubules. These results demonstrate that the deficiency in spermatogenesis of B6-jsd/jsd mice can be ascribed to a defect in spermatogonia but not in their supporting cell environment. Furthermore, the defect in B6-jsd/jsd spermatogonia is not in their ability to proliferate, but in their differentiation and may result from their hypersensitivity to high concentrations of androgen in the testis.     

Morphological evidence for two types of idiopathic ''Sertoli-cell-only'' syndrome

Biopsies of testicular specimens taken from 41 patients that were diagnosed as having idiopathic Sertoli-cell-only syndrome were classified into two types, A and B, on the basis of histological and immunohistochemical findings. Thirty eight specimens that were classified as type A exhibited seminiferous tubules of small diameter and with tubular wall hyalinization, but containing normal adult type Sertoli cells. The other three specimens that were classified as type B showed no seminiferous tubular wall hyalinization, and their Sertoli cells had vimentin distribution localized in the subnuclear cytoplasm and had a pseudostratified lining, features resembling the appearance of fetal Sertoli cells. In one patient with a seminoma, a comparative study of the same testis prior to and post-irradiation was undertaken. Judging from this, postpubertal depletion of the germ cell population was considered to be responsible for the tubular atrophy observed in type A. Type B testes, though small in number, were characterized by a morphology distinct from the type A, but their pathogenesis remains unknown.     

雄性生殖细胞体外分化研究现状

生殖细胞的体外研究已建立了多种组织和器官培养系统、精曲小管培养系统、Sertoli细胞和生殖细胞共同培养系统等。随着对血 睾屏障和睾丸细胞极性在体外培养中重要性的逐步重视 ,已初步建立了模拟睾丸分隔结构的双室培养系统和藻酸钙三维培养系统。现有培养系统已经成为深入了解和认识精子发生过程的一种强有力工具。目前在体外已经获得某些动物精子发生的整个减数分裂过程 ,但对雄性生殖细胞体外减数分裂的详细调控机制还知之甚少。本文主要介绍了在雄性生殖细胞体外分化尤其是减数分裂研究方面的发展现状     

睾丸支持细胞与生精细胞凋亡的关系

生精细胞处于支持细胞构造的环境中 ,激素、生长因子和温度以及它们与支持细胞的联系调控着生精细胞的分化与成熟 ;细胞之间的旁分泌信号转导亦调节着生精细胞凋亡的过程。在睾丸生精细胞发生的自发性凋亡和诱发性凋亡中 ,支持细胞表达和分泌的产物扮演重要角色。     

Bilateral prepubertal testicular biopsies predict significance of cryptorchidism-associated mixed testicular atrophy, and allow assessment of fertility

INTRODUCTION: Mixed atrophy of the testis (MAT), a frequent finding in biopsies of formerly cryptorchid and/or infertile patients, is defined as the synchronous occurrence of both seminiferous tubules containing germ cells and Sertoli cell only-tubules in variable proportions. In tubules containing germ cells, different types of abnormalities in spermatogenesis may be seen. The presence of adult spermatids in the biopsy, even in small numbers, correlates with successful spermatozoa retrieval for "in vitro" fertilization techniques. Currently, it is unknown whether precursor lesions of MAT can be identified in cryptorchid patients during childhood. MATERIAL AND METHODS: Eighteen formerly cryptorchid adults who had undergone testicular biopsies in childhood had a repeat testicular biopsy to evaluate infertility. In prepubertal biopsies, abnormalities of the testicular parenchyma were classified into types I (slight alterations), II (marked germinal hypoplasia), and III (severe germinal hypoplasia). In postpubertal biopsies, the percentage of tubules containing germ cells and Sertoli cell only-tubules were estimated, as well as the presence of complete spermatogenesis. Abnormalities in spermatogenesis were classified into lesions of the adluminal or basal compartments of seminiferous tubules. RESULTS: Comparison between prepubertal and postpubertal biopsies revealed that most specimens developing from type III lesions presented with incomplete spermatogenesis (P<0.0001) and more severe lesions of the germinal epithelium (P=0.049). DISCUSSION: Type III lesions correlated with MAT characteristics that confer a worse prognosis for in vitro fertilization. Thus, MAT characteristics may be predicted in prepubertal cryptorchid patients, allowing a fertility prognosis. The pathogenesis of these lesions, and their possible inclusion into the spectrum of the testicular dysgenesis syndrome, are discussed.