Different mechanisms are responsible for 3H-androgen movement across the rat seminiferous and epididymal epithelia in vivo.

Mechanisms involved in the maintenance of the microenvironment of the seminiferous and epididymal tubules were examined in a series of experiments utilizing in vivo microperifusion, microperfusion, and micropuncture. Intraluminal 3H-androgen concentrations in seminiferous tubules increased linearly as interstitial 3H-androgen concentrations increased from 10 nM to 2,000 nM, but in caput epididymidal tubules, intraluminal 3H-androgen concentrations increased hyperbolically across the same range of peritubular 3H-androgen concentrations. Intraluminal 3H-androgen concentrations in the caput epididymidis did not rise above approximately 340 nM even if peritibular 3H-androgen concentrations exceeded 2,000 nM. Perifusion of caput tubules with 0.1 mM dinitrophenol or potassium cyanide or 100 micrograms/ml cyclohexamide significantly reduced proluminal 3H-androgen movement, but tubules perifused with control medium would not support antigrade 3H-androgen movement in the absence of native lumen fluids which contain androgen-binding protein. Antigrade proluminal 3H-androgen movement was not inhibited by competition with estradiol at ten-times 3H-androgen concentrations. Thus, energy-requiring protein synthesis is necessary for antigrade 3H-androgen movement in the caput epididymidis, but the mechanism for the interaction of intracellular protein(s) and 3H-androgen movement remains undetermined.