In vitro cell-mediated and complement-mediated cytotoxicity to murine testicular cells

Immunology of the Testis and Male Reproductive Tract

A large body of evidence points to the existence of a close, dynamic relationship between the immune system and the male reproductive tract, which has important implications for our understanding of both systems. The testis and the male reproductive tract provide an environment that protects the otherwise highly immunogenic spermatogenic cells and sperm from immunological attack. At the same time, secretions of the testis, including androgens, influence the development and mature functions of the immune system. Activation of the immune system has negative effects on both androgen and sperm production, so that systemic or local infection and inflammation compromise male fertility. The mechanisms underlying these interactions have begun to receive the attention from reproductive biologists and immunologists that they deserve, but many crucial details remain to be uncovered. A complete picture of male reproductive tract function and its response to toxic agents is contingent upon continued exploration of these interactions and the mechanisms involved.

Tissue microcircumstances for leukocytic infiltration into the testis and epididymis in mice

Spermatozoa do not appear in the seminiferous epithelium until puberty, when immune tolerance has already been established. Therefore, they contain various autoimmunogenic materials which are recognized as foreign by the self immune system. However, the testis and epididymis are known as immunologically privileged organs. In particular, the blood-testis barrier (BTB) formed by Sertoli cells and the blood-epididymal barrier formed by epididymal epithelial cells protect autoimmunogeneic spermatozoa from attack by the self immune system. The immune privileged circumstances in the testis and epididymis have been demonstrated by many studies to involve a local transplantation system. We review here the immune privileged status of these organs from the viewpoint of induction of inflammatory cell responses in mice. The testicular interstitium in mice is resistant to vasculitis, lymphangitis, spermatic granuloma and polymorphonuclear cell infiltration: however, the epididymal interstitium is vulnerable to them. Therefore, the testicular tissue outside BTB is also protected from inflammatory cell infiltration, although many resident macrophages are normally present in the testis. In sharp contrast, subcutaneous injection of viable syngeneic testicular germ cells (TGC) alone induces autoimmune orchitis with no involvement of the epididymitis in mice. In the testes of TGC-immunized animals, severe lymphocytic infiltration with aspermatogenesis was seen in spite of no use of adjuvants. Unexpectedly, injections of viable epididymal spermatozoa (ES) did not evoke any autoimmune inflammation in the epididymides. Therefore, the testis rather than the epididymis may easily become an unprivileged organ as to autoimmunity under some special conditions.

Histopathology of the seminiferous tubules in mice injected with syngeneic testicular germ cells alone

Previously, a model of murine experimental autoimmune orchitis was produced by active immunization with viable syngeneic testicular germ cells without resorting to any adjuvants. The histological mode of the spermatogenic disturbance of this autoimmunity was investigated in A/J mice. A significant spermatogenic disturbance was consistently induced after the appearance of inflammatory cell responses around the tubuli recti. It first appeared seminiferous epithelium adjacent to the tubuli recti, then spread to the peripheral epithelium. The histopathology of the seminiferous tubules in the early phase ranged from partial degeneration and depletion of all kinds of germ cells to complete loss of germ cells other than some remaining spermatogonia, while both Sertoli cells and the basal lamina of the tubules appeared intact. In the late phase, depletion of Sertoli cells, disorganization of the seminiferous tubular wall or filling with many round-shaped degenerating germ cells, appearance of malformed spermatids with signet ring nuclei, depletion of immature germ cells with remaining elongated spermatids, or complete loss of the seminiferous epithelium were observed in addition to the early histopathological features.

Experimental allergic orchitis in mice. VII. Preliminary characterization of the aspermatogenic autoantigens responsible for eliciting actively and passively induced disease

Experimental allergic orchitis (EAO) can be induced actively and passively in mice by either immunization with mouse testicular homogenate (MTH) in conjunction with the appropriate adjuvants or by transferring CD4+ T cells isolated from sensitized donors into non-immunized, naive recipients. The distribution of inflammatory lesions seen in active and passive EAO are markedly different. In active EAO maximal disease is observed in the seminiferous tubules, whereas in passive EAO lesions occur primarily in the straight tubules, rete testis, and ductus efferentes. These observations suggest that different immunopathogenic mechanisms and/or aspermatogenic autoantigens may be responsible for the distinct histopathologic profiles. Two murine testis-specific aspermatogenic autoantigens (mAP1 and mAP2) were partially purified from MT acetone powder by extraction in 7-M urea under reducing conditions, gel filtration, ion-exchange chromatography, and preparative isoelectric focusing from pH 3 to 10. In gel filtration on Sephacryl S-400 in 7-M urea, mAP1 is confined to the V0 peak, while mAP2 is in the major included peak. mAP1 has an isoelectric point of 4.4-4.9, is sensitive to both pronase and DNase but not RNase, and is active at a minimal dose of 250-500 micrograms (dry wt). Dose-response bioassays for active and passive EAO revealed that mAP1 preferentially elicits active disease, whereas mAP2 is most effective at eliciting passive disease. These results support the concept that the different histopathologic profiles seen in active and passive EAO are, in part, the result of different immunopathologic responses elicited by separate aspermatogenic autoantigens.

Phenotypic characterization of lymphocytic cell infiltrates into the testes of rats undergoing autoimmune orchitis

Experimental autoimmune orchitis (EAO) was induced in adult Wistar rats by active immunization with a testicular homogenate (TH) and adjuvants. Fifty per cent of the immunized rats developed EAO. Testicular damage became evident at 50 days after the primary immunization and increased in severity at 80 days. Phenotypic characterization of T-cell subsets (CD4+ and CD8+) and Ia+ cells was performed on cryostat sections of testis obtained from normal rats, rats immunized with adjuvant (control group) and rats immunized with TH and adjuvants (experimental group) at 50 and 80 days. Labelled cells were only detected in the interstitial area; no labelled cells were observed inside the seminiferous tubules with any of the monoclonal antibodies used (W3/25, OX-8, OX-6). A significant increase in the numbers of CD4+ and CD8+, as well as of Ia+ cells, were observed in the testis of rats with severe EAO at 80 days after the first immunization. Rats of the same experimental group without testicular damage showed no major differences compared to rats from the control group, with the exception of a lower number of CD8+ cells. Variations in the lymphocyte subsets in lymph nodes draining the site of immunization showed the opposite pattern to that observed in the testis. In conclusion, these data suggest the traffic of specifically sensitized lymphocytes from lymph nodes to the testis and an active role of CD4+, CD8+ and Ia+ cells in the pathogenesis of EAO in the rat.

Antigen non-specific tissue damage in T cell-mediated experimental autoimmune orchitis: preliminary characterization of a testis-specific T-cell line by using dermal tissue and cells

A previous study demonstrated the establishment of a murine testicular antigen (mTA)-specific CD4+ T-cell line (designated BT.1) which was capable of transferring experimental autoimmune epididymo-orchitis to naive recipient mice. The disease transfer was antigen-specific, because no inflammatory lesion was observed in any other organs and tissues of the recipients. In this study, to investigate the local environment of BT.1 cells, the effect of the cells and their culture supernatant on a local tissue integrity was studied. When BT.1 cells were seeded on cultured fibroblastoid cell monolayers, the cells completely disrupted these monolayers in spite of the absence of the specific antigens. Moreover, the culture supernatant of BT.1 cells induced non-specific dermal inflammation when injected into skin tissue of normal syngeneic mice. Therefore, BT.1 cells were shown to devastate a tissue integrity and cause attraction and activation of inflammatory cells of the recipient origin in a local environment. These results suggest that the transferred BT.1 cells will specifically home to the testis and epididymis of recipients but the following devastation of seminiferous tubules and epididymal ducts might be non-specifically produced by the inflammatory cells of both donor and recipient origin in the lesion.

Lymphocyte subsets in the lymph nodes of rats with autoimmune orchitis

We determined temporal variations of cell subpopulations in the immunization draining lymph nodes during the development of an experimental autoimmune orchitis (EAO) induced in Wistar rats. A phenotypic characterization of T cells and their subsets (CD4+ and CD8+), B, and Ia+ cells was performed by immunofluorescent technique. At the end of the immunization period (30 days), rats injected with testicular homogenate plus adjuvants presented a considerable increase in absolute cell number but normal lymphocyte subset percentages. Testicular damage became evident at 50 days after the first immunization and increased its severity at 80 days: animals that developed EAO presented a lower number of CD8+ cells as compared with undamaged rats. This latter group showed a low CD4/CD8 ratio due to the high proportion of CD8+ cells, which could probably have a suppressor function. At 80 days massive testicular infiltration and decreased absolute cell number in lymph nodes suggest the possible migration of specific lymphocytes to the target organ.

Cell-mediated immunity in infertility

A role of cell-mediated immunity in immunologic infertility is indicated by a number of animal immunization studies and by reported clinical associations between cellular immune responses and infertility. Furthermore, recent technical advances in the field of cellular immunology have enabled advanced studies on the cellular and soluble mediators of cell-mediated immune responses and their interactions with reproductive processes. In this article we review some of the recent technical and conceptual advances in cellular immunology, the classic literature on cellular immune responses in infertility, and recent evidence that certain products of activated lymphocytes and macrophages significantly affect reproductive functions.