Motility activation, respiratory stimulation, and alteration of Ca2+ transport in bovine sperm treated with amine local anesthetics and calcium transport antagonists

Optimal concentrations of dibucaine and other structurally related tertiary amines, variously classified as local anesthetics, Ca²⁺ transport antagonists or calmodulin-directed agents greatly stimulate respiration and the motility of bovine spermatozoa in a reversible manner. Because dibucaine also increases lactate production by sperm made dependent upon glycolysis, the induced metabolic stimulation is probably a secondary response to the greater energy demands resulting from increased motility. Microscopic and time lapse photomicrographic examinations indicate that dibucaine increases the proportion of motile cells and alters the predominant linear swimming path to a peculiar figure eight pattern of movement. Frame by frame analysis of video recordings indicate that this pattern of movement closely resembles, or is identical to the characteristic “motility activation” that occurs during the capacitation sequence which obligatorily precedes fertilization of many, if not all, mammalian species. Dibucaine and the Ca²⁺ transport antagonists, D600 and TMB-8, inhibit the net uptake of Ca²⁺ by sperm suspensions. The dose-response relationships indicate that inhibition of Ca²⁺ uptake does not bear a causal relationship to the activation of motility and metabolism and further suggest a common action of these agents rather than selective effects of D600 and TMB-8 upon Ca²⁺ channels in the sperm plasma membrane. In addition, dibucaine and D600 each induce release of that Ca²⁺ which was accumulated by intact sperm in a preliminary incubation in the absence of the drugs and also inhibit uptake of Ca²⁺ by digitonin-treated sperm. Apparently, therefore, local anesthetics have a direct deleterious action on sperm mitochondrial function. Treatment with the high concentrations of local anesthetics that are required to inhibit uptake of Ca²⁺ completely results in a rapid and irreversible immobilization of the sperm. This loss of motility is either not mediated, or mediated indirectly, through an action of the drug on mitochondrial function because sperm similarly become immotile when a glycolytic substrate is supplied simultaneously.     

Effects of thyroid states on the Cori cycle,glucose-alanine cycle,and futile cycling of glucose metabolism in rats

The effect of thyroid status on glucose recycling was measured in intact rats by comparing the fates of differently labeled [³H]- and [¹⁴C]glucose. Glucose recycling at the level of three-carbon compounds (i.e., Cori and glucose-alanine cycles) was measured by comparing the rates of turnover of [6-³H]- and [6-¹⁴C]glucose in the same animal. The rate of recycling increased (33–110%) in hyperthyroid rats and decreased (22–30%) in hypothyroid (thyroidectomized) rats. The relative importance of the Cori and glucose-alanine cycles was measured by analyzing the labeled glycolytic intermediates after the injection of labeled glucose; and by measuring the rate of glucose production from the infused labeled lactate and alanine. The results showed that the rate of the Cori cycle is much greater than the glucose-alanine cycle in rats. Substrate cycling at the level of glucokinase-glucose-6-phosphatase was measured by comparing the rates of turnover of [2-³H]- and [6-³H]glucose; and phosphofructokinase-fructose bisphosphatase was measured by comparing the rates of turnover of [3-³H]- and [6-³H]glucose. These cycles were also affected by thyroid states of the animals. The rate of the phosphofructokinase-fructose bisphosphatase cycle increased threefold in hyperthyroid rats and decreased by about half in hypothyroid rats. The glucokinase-glucose-6-phosphatase substrate cycle occurred at the rate of nearly 2 μmol/min/100 g body wt in the hyperthyroid, fasted rats; it was not detectable in hypo- or euthyroid rats. The contribution of the energy released by these cycles to thyroid thermogenesis was discussed. Effects of thyroid states on glucose metabolism in perfused muscles were also studied. There is an apparent shift in the source of energy for oxidation in the hyperthyroid rat. The ratio of lactate production to glucose uptake was significantly elevated in the hyperthyroid rats. This change predisposes for increased glucose recycling in hyperthyroid rats to avoid lactate accumulation and acidosis.     

Regulation of calcium content in bovine spermatozoa

Plasma membrane vesicles isolated from bovine epididymal and ejaculated spermatozoa have widely different capabilities for transporting Ca2+. Spermatozoa were ruptured by nitrogen cavitation, and the plasma membrane fraction was harvested after low speed and sucrose gradient centrifugation; purity was assessed by marker enzyme analyses, electron microscopy, and sedimentation properties. Plasma membrane vesicles isolated from epididymal sperm accumulate Ca2+ passively at a faster rate and to a greater extent than vesicles prepared from ejaculated sperm. Ca2+ transport across bovine sperm plasma membranes is an ATP-independent, Na+-dependent process that obligatorily exchanges intravesicular Na+ for external Ca2+. The rate of Na+/Ca2+ exchange is significantly lower in ejaculated sperm vesicles than in those of epididymal sperm. Bovine plasma membranes contain little or no Ca2+-dependent ATPase activity. It is suggested that, at the time of ejaculation, calcium flux into bovine sperm is prevented by the interaction of the plasma membrane with putative factors in seminal fluid that specifically interfere with Na+/Ca2+ exchange. We have isolated a protein from seminal plasma that prevents calcium accumulation by bovine epididymal sperm (Rufo, G. A., Jr., Singh, J. P., Babcock, D. F., and Lardy, H. A. (1982) J. Biol. Chem. 257, 4627-4632). A protein with properties resembling those of the seminal calcium transport inhibitor is found on the membrane vesicles from ejaculated sperm but not on membranes from epididymal sperm. We conclude that this protein binds strongly to the plasma membrane of bovine sperm and is responsible for preventing calcium uptake by ejaculated sperm.