Bicarbonate/CO2, an effector of capacitation, induces a rapid and reversible change in the lipid architecture of boar sperm plasma membranes.

Bicarbonate/CO2 is believed to be the key in vitro effector of sperm capacitation, a process which induces major changes in the sperm plasma membrane in preparation for fertilization. In a flow cytometric study, we examined the effect of bicarbonate on boar spermatozoa using merocyanine, an impermeant lipophilic probe which binds to plasma membranes with increasing affinity as their lipid components become more disordered. We found that bicarbonate causes a rapid increase in the ability of live boar spermatozoa to bind merocyanine. First detected about 100 sec after exposure to bicarbonate and largely complete by 300 sec, this increase appears to result from individual cells within the sperm population switching from a low merocyanine-binding state to a high binding state. The majority of live spermatozoa are capable of responding in this way, and do so in proportion to bicarbonate concentration, half-maximal response being induced by about 3 mM bicarbonate; however, overall population response varies greatly between ejaculates. Increased merocyanine stainability is observed over the whole surface area of the cell, and is reversible both with respect to temperature (it is only manifested above 30 degrees C) and with respect to presence of bicarbonate. A similar effect can be induced by phosphodiesterase inhibitors such as isobutylmethylxanthine, and enhanced by a permeant cyclic nucleotide analogue. We conclude that bicarbonate causes a major alteration in sperm plasma membrane lipid architecture, apparently by perturbing enzymic control processes. This novel action of bicarbonate may represent an initial permissive event in the capacitation sequence.

Flow cytometric detection of bicarbonate-induced changes in lectin binding in boar and ram sperm populations.

Boar and ram spermatozoa were incubated in Tyrode's medium in the presence or absence of bicarbonate/CO2, a component believed essential for capacitation. At intervals, samples were stained with a range of FITC-lectins to detect changes in surface glycoconjugates, using a rapid staining technique to avoid problems of lectin toxicity. The samples were then analysed directly by flow cytometry, using propidium iodide to distinguish dead cells. In the presence of bicarbonate, a live subpopulation of spermatozoa developed, which in both animal species showed higher binding affinities towards Phaseolus Vulgaris Agglutinin (PHA-E), Sophora Japonica Agglutinin (SJA), and Soybean Agglutinin (SBA), and lower binding affinity towards Erythrina Cristagalli Lectin (ECL). In boar samples, the modified subpopulation reached a maximum after 3 hr incubation, whereas in ram samples it maximized after 1.5 hr. No changes were seen when spermatozoa were incubated in bicarbonate-free medium. The bicarbonate-induced changes in lectin binding were not due to the onset of acrosome reactions, because spermatozoa induced to undergo acrosome reactions with the ionophore A23187 displayed very different lectin-binding patterns. Tested on boar spermatozoa, seminal plasma not only inhibited but reversed the bicarbonate-induced development of the modified subpopulation. EGTA also inhibited development of boar sperm subpopulations; excess Ca2+ was unable to overcome this inhibition, suggesting that multivalent metal ions might be involved in bicarbonate's action. We conclude that bicarbonate causes a loss of surface coating material with affinity for ECL and an unmasking of binding sites for SBA, SJA and PHA-E. A modified subpopulation of live spermatozoa is thereby established, which appears to maximize at a rate in accord with reported capacitation times.

Survival of ram spermatozoa at high dilution: protective effect of simple constituents of culture media as compared with seminal plasma.

During incubation of ram spermatozoa at 1 x 10(7) cells mL-1 or less in a simple HEPES-buffered saline medium, high levels of cell death were detected using propidium iodide as a probe of viability (membrane integrity): some 70% of the cells died during 3 h incubation at 37 degrees C. Because the conditions of incubation were similar to those encountered during manipulations for in vitro fertilization, this phenomenon was investigated further. If ram spermatozoa were diluted in an equivalent sucrose-based medium, or if the saline medium was supplemented with 10% seminal plasma, survival was greatly improved (only 5-15% died during a 3-h incubation at 37 degrees C); the protective effect of seminal plasma resided in a 5-10 kDa fraction. Sperm death in the basal saline medium was strongly dependent on cell concentration below 5 x 10(7) spermatozoa mL-1 whereas little effect of concentration was seen in the sucrose medium or in the presence of seminal plasma. The presence of Ca2+ (2 mM), EGTA (1 mM) or mercaptoethanol (1 mM) enhanced sperm survival in saline medium, but no effect was gained by replacing NaCl with KCl, and neither BSA nor fetal calf serum were beneficial. However, when a combination of pyruvate (1 mM), lactate (21.7 mM), Mg2+ (0.4 mM), phosphate (0.3 mM) and Ca2+ (2 mM) was included in the saline medium (to render it similar to Tyrode's medium), cell survival was greatly improved (12% died during the 3-h incubation).(ABSTRACT TRUNCATED AT 250 WORDS)