Zinc-silicon interactions influencing sperm chromatin integrity and testicular cell development in the rat as measured by flow cytometry.

Abstract

Flow-cytometric procedures were used to determine effects of dietary Zn and Si variations on rat testicular cell development, including integrity of caudal epididymal sperm chromatin structure defined as the susceptibility of DNA to denaturation in situ. Concentrations of 4 (deficient), 12 (adequate), and 500 (excessive) mg of Zn/kg of diet were used with Si concentrations of 0 (low), 540 (medium), and 2,700 (high) mg/kg of diet in a 3 x 3 factorial arrangement. Three-week-old Sprague-Dawley male rats were fed the experimental diets for 8 wk. Rats fed the Zn-deficient/Si-low diet demonstrated significant deviations in the ratio of testicular cell types present, including a reduction of S phase and total haploid cells. Furthermore, approximately 50% of epididymal sperm had a significant decrease in resistance to DNA denaturation in situ. In the Zn-deficient/Si-medium treatment, the effects of Si on animal and testicular growth, distribution of testicular cell types, and sperm chromatin structure integrity were quite similar to the effects of the Zn-adequate diets. A toxic effect of Zn on sperm chromatin structure integrity observed in the Zn-excess/Si-medium treatment seemed to be counteracted by Si in the Zn-excess/Si-high treatment. Silicon at medium and high levels seems to affect Zn metabolism through potentiation and antagonistic reactions, respectively. Zinc deficiency likely disrupts the normal sperm chromatin quaternary structure in which Zn plays a role by providing stability and resistance to DNA denaturation in situ.