Thyroid Hormone Regulates Postnatal Development of the Rete Testis in Mice.

Thyroid hormone regulates the rate of testis maturation in mammals. Manipulations of thyroid hormone levels in neonatal animals affect various aspects of testis biology. However, there have been no studies examining the effects of thyroid hormone on the rete testis (RT). Here, we used animal models of neonatal hyperthyroidism (injections of triiodothyronine, or T3) and hypothyroidism (goitrogen 6-propyl-2-thiouracil [PTU] treatment) and found that higher levels of thyroid hormone accelerate RT development, while lower levels of thyroid hormone delay it. T3 and PTU treatments influence RT size, proliferation of RT cells, and expression of DMRT1 and androgen receptor in the RT. T3 supplementation accelerates RT development in an organ testicular culture, which indicates the local action of thyroid hormone. Additionally, it was found that follicle-stimulating hormone could be involved in the regulation both of RT proliferation and RT size. The fact that RT cells in a cell culture do not respond to T3 suggests indirect action of thyroid hormone on the RT in vivo or the loss of the responsiveness to the hormone in vitro.

A comparative analysis of genes differentially expressed between rete testis cells and Sertoli cells of the mouse testis.

The rete testis (RT) is a region of the mammalian testis that plays an important role in testicular physiology. The RT epithelium consists of cells sharing some well-known gene markers with supporting Sertoli cells (SCs). However, little is known about the differences in gene expression between these two cell populations. Here, we used fluorescence-activated cell sorting (FACS) to obtain pure cultures of neonatal RT cells and SCs and identified differentially expressed genes (DEGs) between these cell types using RNA sequencing (RNA-seq). We then compared our data with the RNA-seq data of other studies that examined RT cells and SCs of mice of different ages and generated a list of DEGs permanently upregulated in RT cells throughout testis development and in culture, which included 86 genes, and a list of 79 DEGs permanently upregulated in SCs. The analysis of studies on DMRT1 function revealed that nearly half of the permanent DEGs could be regulated by this SC upregulated transcription factor. We suggest that useful cell lineage markers and candidate genes for the specification of both RT cells and SCs may be present among these permanent DEGs.

A mechanism of self-lipid endocytosis mediated by the receptor Mincle.

Cellular lipid uptake (through endocytosis) is a basic physiological process. Dysregulation of this process underlies the pathogenesis of diseases such as atherosclerosis, obesity, diabetes, and cancer. However, to date, only some mechanisms of lipid endocytosis have been discovered. Here, we show a previously unknown mechanism of lipid cargo uptake into cells mediated by the receptor Mincle. We found that the receptor Mincle, previously shown to be a pattern recognition receptor of the innate immune system, tightly binds a range of self-lipids. Moreover, we revealed the minimal molecular motif in lipids that is sufficient for Mincle recognition. Superresolution microscopy showed that Mincle forms vesicles in cytoplasm and colocalizes with added fluorescent lipids in endothelial cells but does not colocalize with either clathrin or caveolin-1, and the added lipids were predominantly incorporated in vesicles that expressed Mincle. Using a model of ganglioside GM3 uptake in brain vessel endothelial cells, we show that the knockout of Mincle led to a dramatic decrease in lipid endocytosis. Taken together, our results have revealed a fundamental lipid endocytosis pathway, which we call Mincle-mediated endocytosis (MiME), and indicate a prospective target for the treatment of disorders of lipid metabolism, which are rapidly increasing in prevalence.

Establishment of a pure culture of immature Sertoli cells by PDGFRA staining and cell sorting.

Sertoli cells are key somatic cells in the testis that form seminiferous tubules and support spermatogenesis. The isolation of pure Sertoli cells is important for their study. However, it is a difficult effort because of the close association of Sertoli cells with peritubular myoid cells surrounding seminiferous tubules. Here, we propose a novel approach to the establishment of a pure Sertoli cell culture from immature mouse testes. It is based on the staining of testicular cells for platelet-derived growth factor receptor alpha (PDGFRA), followed by fluorescence-activated cell sorting and culturing of a PDGFRA-negative cell population. Cells positive for a Sertoli cell marker WT1 accounted for more than 96% of cells in cultures from 6 to 12 days postpartum (dpp) mice. The numbers of peritubular myoid cells identified by ACTA2 staining did not exceed 4%. Cells in the cultures were also positive for Sertoli cell proteins SOX9 and DMRT1. Amh and Hsd17b3 expression decreased and Ar and Gata1 expression increased in 12 dpp cultures compared to 6 dpp cultures, which suggests that cultured Sertoli cells at least partially retained their differentiation status. This method can be employed in various applications including the analysis of differential gene expression and functional studies.

Formation of the rete testis during mouse embryonic development.

BACKGROUND: The rete testis connects seminiferous tubules of the testis with efferent ducts having a mesonephric origin. The development of the rete testis is insufficiently studied, but there is evidence suggesting that it originates from gonadal cells. Here, the formation of the rete testis was investigated from E11.5 to E16.5 using immunofluorescent staining and 3D-modeling. RESULTS: The rete testis became visible by SOX9 and PAX8 staining starting from E12.5. It was located in the mesonephros but connected with testis cords formed by Sertoli cells expressing SOX9, AMH, DMRT1. Between E13.5 and E14.5, AMH+ network of testis cords at the mesonephric side began to disintegrate in a gradient-dependent manner along the anterior-posterior axis of the gonad and connections between testis cords gradually lost AMH becoming a part of the rete. Cells combining features of Sertoli and rete cells (PAX8+ AMH+ and DMRT1+ AMH- cells) were detected starting from E14.5, suggesting that some rete cells originated from Sertoli cells. The rete ovarii, a female counterpart of the rete testis, developed in a similar way as the rete testis until E13.5. CONCLUSIONS: A part of the rete testis originates from connections between testis cords. Evidence that Sertoli cells contribute to rete cells is provided.

The rete testis harbors Sertoli-like cells capable of expressing DMRT1.

Sertoli cells (SCs) are supporting cells in the mammalian testis that proliferate throughout fetal and postnatal development but exit the cell cycle and differentiate at puberty. In our previous study, we isolated a population of highly proliferative Sertoli-like cells (SLCs) from the region of the adult mouse testis containing the rete testis and adjacent seminiferous tubules. Here RNA-seq of the adult SLC culture as well as qPCR analysis and immunofluorescence of the adult and immature (6 dpp) SLC cultures were performed that allowed us to identify SLC-specific genes, including Pax8, Cdh1, and Krt8. Using these, we found that SLCs are mostly localized in the rete testis epithelium; however, some contribution of transitional zones of seminiferous tubules could not be excluded. The main feature of SLCs indicating their relationship to SCs is DMRT1 expression. More than 40% of both adult and immature SLCs expressed DMRT1 at different levels in culture. Only rare DMRT1+ cells were detected in the adult rete testis, whereas more than 40% of cells were positively stained for DMRT1 in the immature rete testis. One more SC protein, AMH, was found in some rete cells of the immature testis. It was also demonstrated that SLCs expressed such SC genes as Nr5a1, Dhh, Gdnf, and Kitl and interacted with germ cells in 3D co-culture with immature testicular cells. All these similarities between SLCs and rete cells on one the hand and SCs on the other, suggest that rete cells could share a common origin with SCs.

Receptor Mincle promotes skin allergies and is capable of recognizing cholesterol sulfate.

Sterile (noninfected) inflammation underlies the pathogenesis of many widespread diseases, such as allergies and autoimmune diseases. The evolutionarily conserved innate immune system is considered to play a key role in tissue injury recognition and the subsequent development of sterile inflammation; however, the underlying molecular mechanisms are not yet completely understood. Here, we show that cholesterol sulfate, a molecule present in relatively high concentrations in the epithelial layer of barrier tissues, is selectively recognized by Mincle (Clec4e), a C-type lectin receptor of the innate immune system that is strongly up-regulated in response to skin damage. Mincle activation by cholesterol sulfate causes the secretion of a range of proinflammatory mediators, and s.c. injection of cholesterol sulfate results in a Mincle-mediated induction of a severe local inflammatory response. In addition, our study reveals a role of Mincle as a driving component in the pathogenesis of allergic skin inflammation. In a well-established model of allergic contact dermatitis, the absence of Mincle leads to a significant suppression of the magnitude of the skin inflammatory response as assessed by changes in ear thickness, myeloid cell infiltration, and cytokine and chemokine secretion. Taken together, our results provide a deeper understanding of the fundamental mechanisms underlying sterile inflammation.

Only a small population of adult Sertoli cells actively proliferates in culture.

Adult mammalian Sertoli cells (SCs) have been considered to be quiescent terminal differentiated cells for many years, but recently, proliferation of adult SCs was demonstrated in vitro and in vivo We further examined mouse SC behavior in culture and found that there are two populations of adult SCs. The first population is SCs from seminiferous tubules that hardly proliferate in vitro The second population is small and consists of SCs with atypical nuclear morphology from the terminal segments of seminiferous tubules, a transitional zone (TZ). TZ SCs multiply in culture and form colonies, display mixture of mature and immature SC characteristics, and generate cord-like structures in a collagen matrix. The specific features of TZ SCs are ACTA2 expression in vitro and DMRT1 low levels in vivo and in vitro Although the in vivo function of TZ SCs still remains unclear, this finding has significant implications for our understanding of SC differentiation and functioning in adult mammals.

Neonatal testicular cell transplantation restores murine spermatogenesis damaged in the course of herpes simplex virus-induced orchitis.

Genital tract infection and inflammation may affect male fertility, causing germ and Sertoli cell loss. We determined if testicular cell transplantation is effective at repairing testicular injury induced by herpes simplex virus (HSV) orchitis. ROSA26 mice were used as donors and the recipients were C57BL/6 mice after HSV testicular inoculation; some of the recipients were treated with the antiviral drug acyclovir (ACV). ACV reduced the amount of HSV antigen in testes on Day 3 after transplantation and enhanced the efficacy of transplantation at Day 30. In recipient testes, donor Sertoli cells formed new seminiferous tubules; significantly more new tubules were observed in the testes of ACV-treated mice compared with mice not treated with ACV (17.8% vs 3.6%). Over half (50.4%) of new tubules in ACV-treated testes contained germ cells and round spermatids were detected in 14.2% of new tubules compared with 15.9% and 5.3% in testes not treated with ACV, respectively. At Day 150 the seminiferous epithelium was completely recovered in some donor tubules and elongated spermatids were observed inside it. Thus, our findings reveal the effectiveness of the combination of antiviral therapy with neonatal testis-cell transplantation for the restoration of spermatogenesis damaged by viral infection.

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.