The terms blood-testis barrier (BTB) or blood-epididymis barrier (BEB), are often described as Sertoli cell-Sertoli cell tight junctions (TJs) or TJs between the epithelial cells in the epididymis, respectively. However, in reality, the BTB and BEB are much more complex than just the TJ. The focus of this minireview is to remind readers that the complete BTB and BEB are comprised of three components: anatomical, physiological, and immunological. The TJs form the anatomical (physical) barrier that restricts passage of molecules and cells from entering or exiting the lumen. The physiological barrier is comprised of transporters that regulate movement of substances in or out of the lumen, thus creating a microenvironment, which is critical for the proper development and maturation of germ cells. The immunological barrier limits access by the immune system and sequesters the majority of the autoantigenic germ cells. Combined with the overall immune-privilege of the testis, this suppresses detrimental immune responses against the autoantigenic germ cells. These three components on their own do not create a complete functional barrier; instead, it is the interaction between all three components that create a barrier of maximal competence.
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To understand the process of sperm maturation, an understanding of interactions between the spermatozoa with the luminal fluid microenvironment and with the epididymal epithelium is necessary. The composition of epididymal luminal fluid of several species is well documented but the manner by which the epididymis contributes to the formation of this specialized milieu is not so well understood. A major role played by the epididymis is to finely regulate the movement of molecules into and out of the lumen. This ensures that as spermatozoa progress along the duct they are exposed to a continually changing, but optimal environment necessary for their maturation and survival. This review focusses on our current understanding of the contributions of the epididymal epithelium to the formation of a specialized luminal fluid microenvironment. The role of the blood-epididymis barrier, the composition of the epididymal luminal fluid, the permeability properties of the epididymal epithelium, and recent studies on a number of luminal fluid proteins and expression of the genes which encode these proteins are discussed.
The major function of the reproductive system is to ensure the survival of the species by passing on hereditary traits from one generation to the next. This is accomplished through the production of gametes and the generation of hormones that function in the maturation and regulation of the reproductive system. It is well established that normal development and function of the male reproductive system is mediated by endocrine and paracrine signaling pathways. Fibroblast growth factors (FGFs), their receptors (FGFRs), and signaling cascades have been implicated in a diverse range of cellular processes including: proliferation, apoptosis, cell survival, chemotaxis, cell adhesion, motility, and differentiation. The maintenance and regulation of correct FGF signaling is evident from human and mouse genetic studies which demonstrate that mutations leading to disruption of FGF signaling cause a variety of developmental disorders including dominant skeletal diseases, infertility, and cancer. Over the course of this review, we will provide evidence for differential expression of FGFs/FGFRs in the testis, male germ cells, the epididymis, the seminal vesicle, and the prostate. We will show that this signaling cascade has an important role in sperm development and maturation. Furthermore, we will demonstrate that FGF/FGFR signaling is essential for normal epididymal function and prostate development. To this end, we will provide evidence for the involvement of the FGF signaling system in the regulation and maintenance of the male reproductive system.
The epididymis serves a critical function of preparing the male germ cells for fertilization. In order for the epididymis to carry out this role it must undergo a highly coordinated succession of molecular and morphogenic events during development. These events begin with the formation of the Wolffian or nephric duct, the embryonic precursor of the male reproductive system, and end with the three-dimensional coiled postnatal epididymis that is comprised of several distinctly functional segments. How the duct changes from a simple straight tube to a highly convoluted structure will be the focus of this article. In reviewing the literature's current understanding of epididymal morphogenesis, we will highlight some of the classic morphological studies and discuss some of the more recent genetic models that have all served to contribute to our understanding of this system. Where published information is scarce we will provide potential hypotheses that warrant further investigation and may open up new directions of exploration using the epididymis as a model for tubular morphogenesis.
The objective of this study was to test the hypothesis that gamma-glutamyl transpeptidase (GGT) catalytic activity and protein level in the initial segment are regulated by testicular factors. In the rat epididymis, levels of GGT catalytic activity were initial segment > caput > corpus = cauda. GGT catalytic activity and protein level in the initial segment decreased after efferent duct ligation (EDL) for 3 days, but were recovered when initial segment pieces were incubated with ovine or rat rete testis fluid (oRTF or rRTF, respectively). Factors responsible for the recovery were shown to be greater than 10 kDa and protein-like, but these factors were not androgen-binding protein or testosterone in oRTF. Further experiments were designed to test the hypothesis that growth factors within oRTF and rRTF regulate GGT catalytic activity and GGT protein level. Basic fibroblast growth factor (bFGF) but not epidermal growth factor recovered GGT catalytic activity and protein level in the initial segment following 3-day EDL. Western blot analyses also revealed that bFGF-like proteins were present in rRTF, epididymal luminal fluid, and rat initial segment homogenate, and that the level of bFGF-like proteins declined in the initial segment following 3-day EDL. Using a bFGF monoclonal antibody, a small amount of bFGF-like proteins was found to be also present in oRTF. Our studies suggest that bFGF is one of the testicular factors involved in the regulation of epididymal GGT catalytic activity and protein level. Since decreased GGT catalytic activity caused by 3-day EDL in the rat initial segment was also recovered by a tumor promoter, phorbol 12-O-tetradecanoylphorbol 13-acetate, it is possible that a signal transduction pathway is involved in the regulation of GGT catalytic activity and GGT protein level by testicular factors. Western blot analyses also indicated that the 43-kDa bFGF-like protein in the lumen of the rat epididymis originates from the testis, is concentrated in the initial segment, and is reabsorbed by the epididymal epithelia from proximal to distal epididymal regions.
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