Focal orchitis in undescended testes: discussion of pathogenetic mechanisms of tubular atrophy.

OBJECTIVE: To evaluate seminiferous epithelium lesions in adult cryptorchid testes showing lymphoid infiltrates in seminiferous tubules and interstitium (i.e., focal orchitis). Also, to consider the possible role of this lesion in the etiology of tubular atrophy. METHODS: We performed a histopathologic study of the cryptorchid testes and adjacent epididymides removed from 50 adult men who had not been previously treated for cryptorchidism. The study included morphologic and semiquantitative evaluation of seminiferous tubule pathology (according to germ cell numbers), Sertoli cell morphology, tubular lumen dilation, rete testis pattern (normal, hypoplastic, or cystic), and epididymal pattern (normal or epididymal duct hypoplasia). The study also included immunohistochemical evaluation of immune cell markers. The results were compared with clinical and laboratory findings. RESULTS: Focal lymphoid infiltrates (mainly lymphocytes) in seminiferous tubules and interstitium were found in 22 patients (44%), all of whom had unilateral cryptorchidism. The course of orchitis was asymptomatic, and laboratory data were normal. According to the seminiferous tubule pathology, a variety of histopathologic diagnoses, were made: (1) mixed atrophy consisting of Sertoli cell-only tubules intermingled with tubules showing maturation arrest of spermatogonia (11 testes, 4 of which also showed hyalinized tubules); (2) Sertoli cell-only tubules plus hyalinized tubules (4 testes); (3) Sertoli cell-only tubules (3 testes); (4) intratubular germ cell neoplasia (2 testes, 1 of which also showed hyalinized tubules); (5) complete tubular hyalinization (1 testis); and (6) tubular hyalinization plus some groups of tubules with hypospermatogenesis (all germ cell types were present although in lower numbers, 1 testis). Dysgenetic Sertoli cells, that is, Sertoli cells that had undergone anomalous, incomplete maturation, were observed in all nonhyalinized seminiferous tubules with inflammatory infiltrates. Tubular ectasia was observed in 13 cases. The rete testis was hypoplastic and showed cystic transformation in 18 testes, and the epididymis was hypoplastic in 15 testes. CONCLUSIONS: The causes of these focal inflammatory infiltrates are unknown. It is possible that tubular ectasia and Sertoli cell dysgenesis are involved and that these alterations cause a disruption of the blood-testis barrier and allow antigens to enter the testicular interstitium, giving rise to an autoimmune process.     

Herpes simplex virus inoculation in murine rete testis results in irreversible testicular damage

This study aimed to establish the influence of herpes simplex virus (HSV) on testis morphology and germ cell development using a model of ascending urogenital HSV infection in mice. Adult C57BL/6J mice were inoculated with 100 plaque‐forming units of HSV1 in rete testis. Viral proteins and HSV DNA were detected from 3 days postinoculation (DPI), while capsids and virions could be visualized at 6 DPI. Infectious activity of HSV was revealed by rapid culture method in testes from 3 to 14 DPI, and virus DNA by PCR – from 3 to 100 DPI. Germ and Sertoli cells were infected during the early stages of the infection, whereas interstitial cells only occasionally contained the virus at 21 and 45 DPI. Microscopic analysis revealed severe degeneration of the germinal epithelium in the infected testes. By 21 DPI, testes became atrophic and most Sertoli cells were destroyed. No testicular regeneration and no spermatozoa in the epididymis were observed at 45 and 100 DPI. From 3 DPI, inflammatory cells accumulated in the interstitium between damaged tubules; a significant increase in the number of CD4⁺, CD8⁺ T lymphocytes and F4/80⁺ cells was observed in the infected testes. This study shows that in the case of HSV retrograde ascent into seminiferous tubules, the acute viral infection results in irreversible atrophy of the germinal epithelium, orchitis and infertility. These results may be used to further study viral orchitis and the influence of HSV on spermatogenesis and male fertility.     

Early testicular changes after vasectomy and vasovasostomy in Lewis rats

The testes of Lewis rats were studied at intervals from 2 weeks to 3 months after bilateral vasectomy, vasectomy followed 1 month later by vasovasostomy, or sham operations. Aims were to determine the nature of early alterations after vasectomy, and to determine whether vasovasostomy after 1 month would result in reversal of vasectomy-induced changes. Approximately one-fourth of the testes in the vasectomy and vasovasostomy groups displayed histological changes, which consisted mainly of depletion of germ cells. The extent of the depletion varied greatly in different seminiferous tubules. In testes altered in this way, no abnormal infiltrations of lymphocytes, macrophages, or other cells were observed in the seminiferous epithelium or in the interstitium. The rete testis and straight tubules were normal in testes with altered seminiferous epithelium. A few testes in the vasectomy and vasovasostomy groups had necrotic centers. The results suggest that depletion of germ cells occurred as a result of shedding from the seminiferous epithelium into the lumen of the tubules. A cellular immune response, such as occurs in experimental allergic orchitis in other species, did not appear to be responsible for the observed loss of germ cells. This suggests a possible role for humoral antibody in this model, since there is an association between testicular changes and serum antisperm antibodies at longer intervals after vasectomy. Testicular alterations were not reversed by performance of a vasovasostomy 1 month after vasectomy.     

A new mouse model for autoimmune orchitis

Experimental autoimmune orchitis (EAO) was induced in SMA mice (H-2^nondefined) by repeated injection at intervals of 30 days of syngeneic testis homogenate (TH) together with Klebsiella O3 lipopolysaccharide (KO3 LPS) as a potent adjuvant. EAO was not induced by repeated injection of TH alone or KO3 LPS alone. At 10 days after the secondary injection of TH + KO3 LPS, there was marked infiltration with neutrophils in the seminiferous tubules and in the interstitium of the testis accompanied by destruction of the architecture of the seminiferous tubules and hypospermatogenesis. At 20 days after the secondary injection, infiltration with neutrophils in these areas had been replaced mostly by mononuclear cells (lymphocytes, plasma cells, and macrophages). Histopathological changes of the testes became severer by further injections until the 10th injection. The EAO lesions in the terminal stage were characterized by complete destruction of the tubular architecture of the testis, fibrosis, and aspermatogenesis. Lesions in the terminal stage were not restored at all. Spermagglutinating antibody titers in the serum increased and delayed-type hypersensitivity against TH estimated by footpad swelling developed in mice injected repeatedly with TH + KO3 LPS. Using immunofluorescence, antibodies against acrosomal components and tail components of the spermatozoa were detected in serum of these mice.     

Experimental allergic orchitis in mice. I. A new model induced by immunization without adjuvants

Experimental allergic orchitis (EAO) was induced in cyclophosphamide (CY)-pretreated C3H/He mice by immunization with viable testicular cells (TC) without any adjuvants. The pathological changes such as hypospermatogenesis in the seminiferous tubules and mild cellular infiltration in the interstitium were observed in most mice thus treated. Delayed footpad reaction (DFR) against testicular antigen and anti-sperm antibody in sera were detected in those mice. This murine model of orchitis is new and simple in that no adjuvants are used for induction and can be useful in further studies on mechanisms of induction and maintenance of EAO.     

Endothelin and endothelin receptors A and B in the human testis

 Human testicular capillaries interconnect Leydig cells and seminiferous tubules. Microcirculation and blood flow are therefore essential for the maintenance of spermatogenesis. The expression and the localisation of ET (endothelin) and its receptors in testicular tissue, in seminiferous tubules and in human testicular capillaries were studied. ET-1 mRNA was detected in whole testicular tissue and in seminiferous tubules whereas isolated testicular capillaries were negative. Big ET-1 (Big endothelin 1) and ET peptides were localised in Leydig and Sertoli cells whereas interstitial and intramural capillaries (within the lamina propria) remained unstained. ET was also found in mature spermatids. ET-A (endothelin receptor A) mRNA was detected in seminiferous tubules and whole testicular tissue whereas testicular blood vessels were negative. ET-A immunostaining was displayed in Leydig and Sertoli cells and in spermatids. ET-B (endothelin receptor B) mRNA was detected in whole testicular tissue, seminiferous tubules and in testicular capillaries. ET-B peptide was prominent in Leydig cells, peritubular cells, endothelial cells and pericytes of interstitial and intramural capillaries as well as in vascular endothelial and smooth muscle cells. From these results we conclude that ET produced in Leydig and Sertoli cells can act in a paracrine manner via ET-B on the human testicular microvasculature and the peritubular cells. The presence of both ET-A and ET-B in Leydig cells and of ET-A in Sertoli cells leads to the assumption that ET could influence these cells as an autocrine factor. Accepted: 9 October 1998     

Immunohistochemical analysis of connexin43 expression in infertile human testes

Connexin43 (Cx43) is abundantly expressed in mammalian testes and implicated in the regulation of cell-to-cell interaction between germ cells and Sertoli cells, which is essential to the normal process of spermatogenesis. In the present study, we investigated the relation between Cx43 expression and the degree of spermatogenesis in infertile human testes. Immunohistochemical analysis of Cx43 was performed on testicular biopsies from 29 patients with azoospermia (n=23) and severe oligospermia (n=6), who gave informed consent to this experiment. The degree of testicular spermatogenesis was evaluated by Johnsen score. In the interstitium, immunostaining for Cx43 was localized to some focal parts of plasma membrane between neighboring Leydig cells. In seminiferous tubules with normal spermatogenesis, Cx43 expression was found between Sertoli cells and germ cells. However, Cx43 expression in maturation arrest was decreased and located mainly in the basal compartment of seminiferous tubules. Finally, there was a significant positive correlation between histological score of spermatogenesis and intensity of Cx43 (p=0.0294). These data suggest that the alteration of Cx43 expression may be involved in spermatogenic impairment, and that the communication between Sertoli cells and germ cells through Cx43 may be important for maturation of spermatogenesis.     

Androgen insensitivity syndrome: an immunohistochemical, ultrastructural, and morphometric study

OBJECTIVE: To evaluate the morphometric, immunohistochemical, and ultrastructural lesions of the testes in prepubertal and adult patients with androgen insensitivity syndrome. METHODS: We examined the testicular biopsy using immunohistochemistry for vimentin, smooth muscle actin, and collagen IV antigens. Quantification of seminiferous tubules and testicular interstitium was performed in prepubertal and adult patients with androgen insensitivity syndrome and results were compared with normal testes from both infants and adults. RESULTS: The adult testes presented nodular and diffuse lesions that consisted of Sertoli-cell-only seminiferous tubules. Two types of Sertoli cells could be distinguished, namely, immature vimentin-positive Sertoli cells and nearly mature Sertoli cells. In the nodules, the lamina propria was thin and contained a scant number of actin-positive peritubular cells. Leydig cells were hyperplastic. The prepubertal patients showed only diffuse lesions characterized by Sertoli cell hyperplasia, decreased germ cell numbers, and a discontinuous immunoreaction to collagen IV. CONCLUSIONS: The testicular lesions in androgen insensitivity syndrome are probably caused by primary alterations that begin during gestation. These lesions become progressively more pronounced at puberty, when the nodular lesion pattern (adenomas) is completely developed.     

Orchitis and human immunodeficiency virus type 1 infected cells in reproductive tissues from men with the acquired immune deficiency syndrome.

Mechanisms underlying human immunodeficiency virus type 1 (HIV-1) infection of the male reproductive tract and the sexual transmission of HIV-1 through semen are poorly understood. To address these issues, the authors performed morphologic and immunocytochemical analyses of reproductive tissues obtained at autopsy from 43 male acquired immune deficiency syndrome (AIDS) patients. Monoclonal antibodies recognizing different subpopulations of white blood cells were used to detect leukocyte infiltration and map the location of potential lymphocytic/monocytic HIV-1 host cells and immunocytochemistry and in situ hybridization techniques were used to detect HIV-1-infected cells in the testis, excurrent ducts, and prostate. Distinct pathologic changes were observed in a majority of testes of AIDS patients that included azoospermia, hyalinization of the boundary wall of seminiferous tubules, and lymphocytic infiltration of the interstitium. The reproductive excurrent ducts and prostate appeared morphologically normal except for the presence of focal accumulations of white blood cells in the connective tissue stroma. In the testis many white blood cells were shown to be CD4+, indicating the presence of abundant host cells (T-helper/inducer lymphocytes and macrophages) for HIV-1. Furthermore macrophages and cells of lymphocytic morphology were observed migrating across the boundary walls of hyalinized seminiferous in tubules to enter the lumen. In 9 of the 23 cases tested for HIV-1 protein expression by immunocytochemistry. HIV-1 + cells of lymphocytic/monocytic morphology were found in the seminiferous tubules and interstitium of the testis, epididymal epithelium, and connective tissue of the epididymis and prostate. One patient with epididymal blockage had accumulations of HIV-1-antigen-positive cells of macrophages morphology in the distended lumen of the efferent ducts. There was no evidence of active HIV-1 infection in germ cells or Sertoli cells of the seminiferous tubules or other epithelial cells lining the excurrent ducts or prostatic glands.     

Fate of bone marrow stem cells transplanted into the testis: potential implication for men with testicular failure

To assess adult stem cell differentiation in the testis, we injected bone marrow cells from adult green fluorescent protein (GFP) transgenic mice into the seminiferous tubules and the testicular interstitium of busulfan-treated wild-type or c-kit mutant (W/W(v)) mice. Ten to 12 weeks after transplantation, we examined the fate of the transplanted bone marrow cells and found that they survived in recipient testes. In both the busulfan-treated and W/W(v) mice, some of the GFP-positive donor cells had a Sertoli cell appearance and expressed follicle-stimulating hormone receptor within the seminiferous tubules. In addition, GFP-positive donor cells were found in the interstitium of recipient testes, and they expressed the cytochrome P450 side chain cleavage enzyme (P450scc). In the seminiferous tubules of busulfan-treated mice, GFP-positive donor cells had the appearance of spermatogonia or spermatocytes and expressed VASA. However, this was not found in the seminiferous tubules of W/W(v) mice. We conclude that adult bone marrow cells, in a favorable testicular environment, differentiate into somatic and germ cell lineages. The resident neighboring cells in the recipient testis may control site-appropriate stem cell differentiation. This clinically relevant finding raises the possibility for treatment of male infertility and testosterone deficiency through the therapeutic use of stem cells.     

Congenital Leydig cell hyperplasia

The testes and epididymes collected at autopsy from 21 newborns showed apparent Leydig cell hyperplasia which was studied by light and electron microscopy. Twelve newborns were the sons of diabetic mothers, two had undergone rhesus isoimmunization, two were twins of a non-diabetic mother, three had Beckwitz-Widemann's syndrome, and two had leprechaunism. In the first two groups the placentas were also collected and studied. All the testes showed normal seminiferous tubules and diffuse Leydig cell hyperplasia in the testicular interstitium. In addition one son of a diabetic mother and another with Beckwitz-Widemann's syndrome presented multiple Leydig cell nodules in the mediastinum testis and epididymis. The number of Leydig cells per unit area of the testis was calculated on histological sections stained with the peroxidase-anti-peroxidase method for the detection of testosterone. These numbers varied from 1.4 to 3.2 times those found in age-matched controls, except for the two testes with nodular hyperplasia in which the increase in Leydig cells was even greater. The differential diagnosis between Leydig cell hyperplasia, ectopic adrenal cells and leydig cell tumour is discussed. It is proposed that the cause of congenital Leydig cell hyperplasia might be related to placental secretion of human chorionic gonadotrophin.     

A new murine model of autoimmune orchitis induced by immunization with viable syngeneic testicular germ cells alone. II. Immunohistochemical findings of fully-developed inflammatory lesion.

Previous studies demonstrated that experimental autoimmune orchitis (EAO) was produced in C3H/He mice with very high incidence by two or three subcutaneous injections of viable syngeneic testicular germ cells, without the use of any adjuvants or immunopotentiators and that the disease induced was characterized by a complete lack of epididymitis despite a definite orchitis with hypospermatogenesis. In this report, immunohistochemical characterization of immune cells in the fully-developed orchitic lesion was carried out using monoclonal antibodies and immunoperoxidase staining. Thy-1.2+ cells, Mac-1+ cells, B220+ cells and cytoplasmic Ig-bearing cells in the lesion were estimated to be approximately 30, 15, 20 and 30% of all inflammatory cells, respectively. Major phenotype of T cells in the lesion was CD4+ (approximately 85%) with the remainder (approximately 15%) being CD8+. The percentages of cytoplasmic IgG-, IgA- and IgM-bearing cells were estimated as approximately 35, 60 and 5% of all cytoplasmic Ig-bearing cells, respectively. Deposits of immunoglobulins and third component of complement were identified on the basement membrane of the seminiferous tubules, interstitium between the tubules, vessel endothelium and degenerated germ cells in the lesion. Circulating antibodies directed against the acrosomal portion of germ cells were detected in IgG and IgM classes but not in IgA class. Inflammatory cells (including macrophages, B cells and, probably, activated T cells) in the lesion were Ia+, but Leydig cells, Sertoli cells and germ cells did not stain for Ia at all.     

Testis morphology in patients with idiopathic hypogonadotropic hypogonadism

BACKGROUND: Adult patients with idiopathic hypogonadotropic hypogonadism (IHH) typically present with absent puberty and therefore have prepubertal testes. IHH is recognized as one of the few curable causes of male infertility and is often effectively treated with either gonadotropins or pulsatile GnRH therapy. The objective of this study was to determine the structure of the testis prior to initiation of treatment. METHODS AND RESULTS: Eight adult IHH patients with prepubertal testes (<4 ml), with no previous gonadotropin therapy and with no history of cryptorchidism underwent open bilateral testicular biopsy prior to the initiation of hormonal treatment. The testes of all patients showed seminiferous cords separated by interstitium composed of blood vessels, connective tissue cells and collagen fibres but typical adult Leydig cells were absent. The cords contained only Sertoli cells and early type A spermatogonia. The spermatogonia mostly resided in the centre of the cords and were often large, typical of gonocytes. Sertoli cells appeared immature with ovoid nuclei devoid of infoldings and cytoplasm that lacked polarity. Tight junctional complexes commonly found connecting adult Sertoli cells were lacking. CONCLUSIONS: These results demonstrate that the immature testes from patients with the severe form of IHH possess early spermatogonia that could possibly reinitiate spermatogenesis with appropriate hormone stimulation. Therefore, the immature testis of this IHH subset resembles those of prepubertal boys and may provide important biologic and genetic insights into testicular development.     

Postinflammation stage of autoimmune orchitis induced by immunization with syngeneic testicular germ cells alone in mice

We previously established an immunological infertility model, experimental autoimmune orchitis (EAO), which can be induced by two subcutaneous injections of viable syngeneic testicular germ cells on days 0 and 14 in mice without using any adjuvant. In this EAO model, CD4+ T-cell-dependent lymphocytic infiltration and immune deposits were found with spermatogenic disturbance on day 120. However, the late stage of EAO (= postactive inflammation stage on day 365) has not yet been investigated. Therefore, we investigated the histopathological characteristics of the late stage. The results revealed that the lymphocytic infiltration finally resolved; however, the seminiferous epithelium persistently showed maturation arrest and the Sertoli cell-only feature. In the seminiferous tubules showing maturation arrest, both proliferation and apoptosis of germ cells had occurred simultaneously. It was also noted that there were deposits of immunoglobulin G and the third component of complement on the thickened basement membrane of seminiferous tubules in the late stage of EAO. These results indicate that histopathology after active inflammation in EAO comprises persistent damage to the seminiferous epithelium and may resemble the histopathology of “idiopathic disturbance of spermatogenesis” in man.     

Renal receptors evoking a spinal vasometer reflex

1. A permeability barrier in or around the seminiferous tubules of rams has been demonstrated by studying the rate of passage of a variety of substances from blood plasma into fluid collected from the rete testis and into testicular lymph.2. All substances studied passed readily into testicular lymph.3. Tritiated water, urea, ethanol and bicarbonate in rete testis fluid equilibrated with blood plasma within 3 hr; Na(+), K(+), Rb(+), Cl(-), I(-), CNS(-), creatinine and galactose entered slowly and p-aminohippurate (PAH), glutamate, iodinated albumin, inulin and [(51)Cr]EDTA did not appear in rete testis fluid at all.4. Rubidium was excluded relative to iodoantipyrine from the testes of control and hypophysectomized rats and from rat testes heated to 37, 40, 43 and 45 degrees C; no such exclusion was seen in testes of rats which had been given cadmium chloride 5 months earlier so as to destroy the seminiferous tubules.5. It is suggested that this permeability barrier will regulate the access to the seminiferous epithelium of some constituents of blood plasma, isolate the germinal cells immunologically and help to maintain the concentration differences between rete testis fluid and lymph or blood plasma.     

Development and Morphogenesis of Testis in Human Fetuses

Development and maturation of prenatal testis was studied on 104 human male fetuses. At 9 weeks, the testes were seen as elongated yellowish tissue superolateral to the developing urinary bladder and medial to mesonephros. The testis assumed ellipsoidal shape at 13 weeks. At about 16 weeks, the testes developed convexity on its anterior aspect. Epididymis and testis were at the same level until 20 weeks thereafter the upper testicular pole was encroached upon by the epididymis, with complete encroachment till its anterior aspect at 24 week. The sinus was also distinctly present between the two. The testis assumed miniature adult testis at term, but its size was approximately 1/15th of the adult. Cytoarchitecture of the testis at 9 weeks revealed radially disposed sex cords. At 13 weeks, tunica albuginea,tubular organization in the parenchyma and the Leydig cells were identifiable. At 17 weeks, tunica vasculosa and incomplete lobules were apparent. At 24 weeks, testis was marked by more but solid seminiferous tubules lined by 4–5 germ layers. Leydig cells were also identifiable till 24 weeks. Spermatogenic cells, both pale and dark type were distinguishable although pale spermatogonia were more numerous than dark cells. 28 weeks onwards tunica vaginalis and complete septa in the testicular parenchyma were evident. Moreover, the seminiferous tubules developed central vacuolation. By 30 weeks, seminiferous tubules became more complex as evident by their increase in number and coiled and tortuousity. At term, the fetal testis had not yet attained the cytoarchitecture of the adult testis suggesting that testicular maturation continues postnatally.     

Immune privilege and inflammation of the testis – lessons from the infertile male

Immune cells are regular components of the testis and likely to participate in the complex local regulation of testicular function. Studies in experimental animals indicate that the testis is an immunologically privileged site where germ cell antigens are protected from autoimmune attack and foreign tissue grafts may survive for extended periods. However, the testicular environment does not preclude immune activation resulting in inflammatory reactions. Active immunization with testicular tissue or adoptive transfer of specific T lymphocytes causes autoimmune orchitis. Whereas symptomatic orchitis due to viral or bacterial infections is considered to be rare in man, recent studies among infertile males revealed a high prevalence of asymptomatic testicular inflammatory reactions associated with impaired spermatogenesis. Notably, the infiltration of T lymphocytes into the testis reflects disturbance of the delicate local immunoregulation. Both predominant peritubular localization of lymphocytes and characteristic morphological changes of the seminiferous tubules support the concept that activation of autoreactive T cells inducible by various etiological factors including noninfectious agents is involved. With regard to localization and functional polarization of T lymphocytes, adhesion molecules as well as chemokines and their receptors have to be considered as crucial components. In conclusion, immunopathological reactions in the testis should not be neglected as underlying reason or cofactor of male infertility. Further investigation of the mechanisms that regulate testicular immune functions in health and disease may encourage the search for appropriate therapeutic strategies such as specific immunomodulation.     

Ectopic Leydig cells of testis An immunohistochemical study on tissue microarray

The incidence of ectopic Leydig cells (LCs) has been reported to be 40% to 90%. Several theories have been proposed to account for ectopic LCs, including in situ differentiation, migration from testicular interstitium, and trapping of peritubular LCs in the tunica propria of the seminiferous tubule during its thickening. To document the nature of ectopic LCs and to compare them with interstitial LCs, Sertoli cells, epididymal cells, mesothelial cells, and epithelial cells in rete testis, immunostainings with calretinin, CD10, inhibin, CK7, and CK20 were performed in 40 cases of orchiectomy specimens using tissue microarray sections. In addition, the frequency of ectopic LCs was evaluated. Of the 40 orchiectomy specimens, 14 cases demonstrated ectopic LCs with an incidence of 35%. Inhibin was positive in more than half of ectopic LCs (9/14, 64.3%) and in almost all interstitial LCs. Calretinin was positive in most of ectopic LCs (12/14, 85.7%) as well as in most of normally located interstitial LCs and mesothelial cells and some of rete testis epithelial cells. The ectopic and interstitial LCs as well as Sertoli cells were negative for CK7, CK20, and CD10. CK7 was positive in all epididymal cells and in most mesothelial cells and epithelial cells in rete testis. CD10 was positive in some of epididymal cells and epithelial cells in rete testis. CK20 was negative in all cells in the testis and epididymis. Ectopic LCs showed similar staining patterns to interstitial LCs with positive immunoreactivity for calretinin and inhibin. In this study, the frequency of ectopic LCs was 35%. The lower incidence in this study was most likely because of the limited sampling. Immunohistochemically, ectopic LCs showed identical immunohistochemical patterns with those of interstitial LCs. Calretinin appeared to be more sensitive but less specific than inhibin for LCs. Because calretinin is frequently positive in cells other than ectopic or interstitial LCs, a precaution is required to differentiate LCs from mesothelial cells and rete testis epithelial cells. Based on our study, we could not add anything else of what is known in regard to the histogenesis of ectopic LCs. The current theories including in situ differentiation, migration from testicular interstitium, and trapping of peritubular LCs in the tunica propria of the seminiferous tubules during its thickening seem to be valid histogenetic theories.     

F4/80-positive cells rapidly accumulate around tubuli recti and rete testis between 3 and 4 weeks of age in the mouse: an immunohistochemical study

PROBLEM: Previous studies demonstrated that F4/80 antigen (murine macrophage-specific antigen)-positive cells in testes of normal adult mice accumulate particularly in the interstitium adjacent to the tubuli recti and rete testis (i.e., the central region). However, it remains unknown whether this accumulation is a congenital or acquired phenomenon. METHOD OF STUDY: The distribution of F4/80-positive cells on frozen sections of testes obtained from various aged mice was immunohistochemically examined to determine when the positive cells specifically accumulate in the central region. RESULTS: F4/80-positive cells were homogeneously distributed throughout the testicular interstitium with no specific accumulation until 2 weeks of age. However, at 3 weeks of age, the density of positive cells in the central region became slightly, but significantly, higher than that in the interstitium between the seminiferous tubules. Between 3 and 4 weeks of age, the cell density in the central region increased rapidly, the density at 4 weeks of age reaching the level of the mature testes of 8-week-old mice. CONCLUSION: These results demonstrate that the specific accumulation of F4/80-positive cells in the central region is an acquired phenomenon, which starts and ends before puberty.     

Histologic changes in the mouse testis after treatment with gossypol tetra-acetic acid

The effect of oral administrations (20 or 40 mg/kg body weight/day, for 21 days) of gossypol tetraacetic acid on the testis of the Parkes strain mouse was investigated. Gossypol treatment did not affect the body weight or testicular weight, but caused a significant depression in the weight of the seminal vesicle. Histologically, the testes in mice treated with gossypol possessed regressed seminiferous tubules showing the exfoliation of germ cells, the occurrence of giant cells, a disorganization of the germinal epithelium, the degeneration of germinal elements, intraepithelial vacuolation and dislocation of the Sertoli cells into the luminal portion. However, the effect of gossypol was not uniform, and normal features were also observed in the majority of the tubules in the testes of the gossypol-treated mice. When quantitatively analysed, the frequency of regressed seminiferous tubules was significantly higher in the testes in the treated mice than the controls. The results suggest that the gossypol treatment induces non-uniform regressive changes in the seminiferous tubules in the mouse testis.