Inhibition of the metabolism of ram spermatozoa by derivatives of α-chlorohydrin

The effects of the male antifertility agent, α-chlorohydrin, six of its derivatives, and glycidol were studied on the metabolism of washed ram spermatozoa in vitro with fructose as substrate. The α-chlorohydrin derivatives were the amino, the phosphorylated, and four glycol-bridge (ketal) compounds. All compounds except glycidol, in a concentration between 0.1 and 100 mM, reduced the aerobic glycolsis and/or oxidation of fructose. However, there was not a high correlation between the ability of these compounds to inhibit the metabolism of ram spermatozoa in vitro and their antifertility activity when administered to male rats. Other factors are clearly involved in their antifertility activity, eg, the concentration of the compounds in the epididymis and their conversion of either more or less spermicidal compounds in the body.     

Disruption of the metabolism, motility and morphology of spermatozoa by injection of alpha-chlorohydrin into rams.

Ejaculated spermatozoa from rams given intramuscular injections of alpha-chlorohydrin (25 mg/kg, daily for 5 days) were studied. Respiratory and glycolytic activity of the spermatozoa was almost entirely suppressed within 1 day and motility had decreased within 4 days of the first injection. Morphologically abnormal spermatozoa appeared in ejaculates after 2 weeks. The most common abnormality was an increase in the number of spermatozoa with looped or bent tails. There was little change in the fructose or amino acid concentration of the seminal plasma. All effects of alpha-chlorohydrin were fully reversible. It is suggested that the initial primary mode of action of alpha-chlorohydrin is to disrupt the metabolism of spermatozoa in the cauda epididymis.     

Inhibition of bull and rabbit sperm enzymes by alpha-chlorohydrin.

High concentrations of alpha-chlorohydrin were found to inhibit hyaluronidase, beta-glucuronidase, and aryl sulphatases in bull and rabbit spermatozoa, but not acrosin and neuraminidase. Preincubation of the enzyme and alpha-chlorohydrin was essential to achieve the maximum inhibition which was irreversible.     

Amino acids in ram testicular fluid and semen and their metabolism by spermatozoa

1. The testis of the ram secretes considerable amounts of amino acids (200μmoles/day) into the fluid collected from the efferent ducts. The principal amino acid in this testicular fluid is glutamate, which is present in concentrations about eight times those in testicular lymph or in blood from the internal spermatic vein. 2. The concentration of glutamate in seminal plasma from the tail of the epididymis is about ten times that in testicular fluid, and, though glutamate is the major amino acid in ejaculated seminal plasma, its concentration is less than in epididymal plasma. 3. After the intravenous infusion of [U-¹⁴C]glucose, labelled glutamate was found in the testicular fluid. Radioactivity was also detected in alanine, glycine, serine plus glutamine and aspartate. Alanine had the highest specific activity, about 50% of the specific activity of blood glucose. 4. When [U-¹⁴C]glutamate was infused, the specific activity of glutamate in testicular fluid was only about 2% that in the blood plasma. 5. Testicular and ejaculated ram spermatozoa oxidized both [U-¹⁴C]glutamate and [U-¹⁴C]leucine to a small extent, but neither substrate altered the respiration from endogenous levels. 6. No radioactivity was detected in testicular spermatozoal protein after incubation with [U-¹⁴C]glutamate or [U-¹⁴C]leucine. Small amounts of radioactivity were detected in protein from ejaculated ram spermatozoa after incubation with [U-¹⁴C]glutamate. 7. The carbon of [U-¹⁴C]glucose was incorporated into amino acids by testicular spermatozoa; most of the radioactivity occurred in glutamate.     

The antifertility actions of alpha-chlorohydrin in the male.

It seems probable that α-chlorohydrin enters sperm cells, competes with glycerol (52) for glycerol kinase (23) and becomes phosphorylated, the product, α-chlorohydrin phosphate, being an inhibitor of glyceraldehyde-3-phosphate dehydrogenase (57). The rate of sperm glycolysis and the concentration of ATP (54) are reduced with sperm motility declining (44, 45, 46) to such an extent that fertilization cannot be successful. In higher doses, α-chlorohydrin affects the efferent ducts and caput epididymis (60) by an unknown mechanism leading to an occlusion preventing the passage of testicular sperm to the epididymis. This action leads to prolonged or even permanent infertility. The inactivity of α-chlorohydrin in some species may be due to the inability of the compound to gain access to the sperm across an epididymal barrier (12, 32) and strain differences in susceptibility could be accounted for by degrees in the rates of metabolism and/or excretion.     

Hydrolysis of phospholipid monolayers by human spermatozoa. Inhibition by male contraceptive gossypol

Monomolecular films of phospholipid were used to study the interaction of intact human spermatozoa with model membranes. Exclusively with negatively charged phosphatidylglycerol monolayers rapid penetration of spermatozoa into the monolayer with subsequent hydrolysis of the lipid was triggered by the addition of 5 mM calcium into the medium. The results suggest the localization of a calcium-dependent phospholipase A2 at the outer acrosomal or plasma membrane of human spermatozoa with its active site exposed to the external environment. Preincubation of the cells with 100 microM gossypol completely abolished the ability of human spermatozoa to hydrolyze or penetrate monolayers of phosphatidylglycerol. The inhibition of the phospholipase activity by gossypol may contribute to the unknown contraceptive mechanisms of this non-steroidal male antifertility agent.     

Mode of action of a lysostaphin-like bacteriolytic agent produced by Streptococcus zooepidemicus 4881.

Electron microscopy of zoocin A-treated sensitive streptococcus cells revealed cytoplasmic disruption and ultimately complete rupture of the cell wall. Culture viability and optical density were shown to decrease rapidly and simultaneously in Streptococcus pyogenes FF22 but less quickly in the relatively more resistant Streptococcus mutans 10449. Zoocin A was shown to cleave hexaglycine in a colorimetric cell-free microtiter assay system, and it is concluded that the killing action of zoocin A, like that of lysostaphin, is most probably the result of direct cleavage of the peptidoglycan cross-links in the cell wall. The relationship between sensitivity to zoocin A and the peptidoglycan cross-linkage structure of Streptococcus zooepidemicus, Lactococcus spp., S. pyogenes, Streptococcus gordonii, Streptococcus oralis, S. mutans, and Streptococcus rattus has been evaluated.     

Comparison of neutral proteinase activities in cock and ram spermatozoa and observations on a proacrosin in cock spermatozoa.

Cock spermatozoa, like trypsin, induced a rapid fall in the viscosity of gelatin solutions but ram spermatozoa and inhibitor-free ram acrosin were ineffective. The gelatin-hydrolysing activity in cock spermatozoa was solubilized at pH 8 in the presence of calcium ions but comparable extracts of ram spermatozoa were inactive. Both extracts showed acrosin activity (assayed with benzoylarginine ethyl ester). The two catalytic activities of cock spermatozoa were each susceptible to the same trypsin inhibitors and during fractionations they were not separable. We deduce that cock acrosin, and probably some other avian acrosins, have the power to degrade dissolved gelatin while ram acrosin does not. The acrosin in cock spermatozoa, unlike that in ram spermatozoa, was inactivated at pH 2-7. Acid extracts of the former contain an inactive precursor of acrosin which undergoes spontaneous re-activation in buffers, pH 8, containing calcium ions. In this respect it resembles the proacrosin of rabbit testis.     

In vitro capacitation and induction of acrosomal exocytosis in ram spermatozoa as assessed by the chlortetracycline assay

We have described the different patterns of chlortetracycline (CTC) binding to ram spermatozoa, immediately after ejaculation and upon in vitro capacitation and calcium ionophore-induced acrosomal exocytosis. Four different forms of CTC distribution were found. Form I showed an even distribution of fluorescence over the entire head, with a brighter band in the equatorial region. In Form II, uniform fluorescence was observed without equatorial band. Form III consisted of fluorescence in the anterior portion of the head. Form IV showed no fluorescence over the head. In all cases, fluorescence in the middle piece of the flagellum was observed as well. Immediately after ejaculation, Form I was the most abundant one (78%) in fresh semen with Forms II and III being relatively scarce (less than 15%). Form IV was virtually absent or appeared only occasionally. Incubation under in vitro capacitating conditions led to a significant decrease in Form I and to a significant increase in Forms II and III. Form II was mainly associated to intact acrosomes, while most spermatozoa in Form III showed intermediate forms of acrosomal status. Incubation of spermatozoa with the calcium ionophore A23187 resulted in 55% of spermatozoa showing Form IV, suggesting that it represents the acrosome-reacted stage. Form I was abruptly decreased at 30 min of incubation and was neglectible after 60 min. In contrast, Forms II and III increased at 30 min but decreased later on, suggesting that both forms represent intermediate stages before the acrosomal exocytosis. Analysis of acrosomal status in spermatozoa from individual CTC forms revealed that all spermatozoa that remained in Form II after incubation had intact acrosomes. Intermediate stages were predominant in Form III-spermatozoa, while most Form IV-spermatozoa underwent full acrosomal exocytosis. These results show that CTC binding can be used to monitor changes in ram spermatozoa during capacitation and acrosome-reaction.