Tyrosine phosphorylation of the a kinase anchoring protein 3 (AKAP3) and soluble adenylate cyclase are involved in the increase of human sperm motility by bicarbonate.

Mammalian testicular spermatozoa are immotile, thus, to reach the oocyte, they need to acquire swimming ability under the control of different factors acting during the sperm transit through the epididymis and the female genital tract. Although bicarbonate is known to physiologically increase motility by stimulating soluble adenylate cyclase (sAC) activity of mammalian spermatozoa, no extensive studies in human sperm have been performed yet to elucidate the additional molecular mechanisms involved. In this light, we investigated the effect of in vitro addition of bicarbonate to human spermatozoa on the main intracellular signaling pathways involved in regulation of motility, namely, intracellular cAMP production and protein tyrosine phosphorylation. Bicarbonate effects were compared with those of the phosphatidyl-inositol-3 kinase inhibitor, LY294002, previously demonstrated to be a pharmacological stimulus for sperm motility. Bicarbonate addition to spermatozoa results in a significant increase in sperm motility as well as in several hyperactivation parameters. This stimulatory effect of bicarbonate and LY294002 is mediated by an increase in cAMP production and tyrosine phosphorylation of the A kinase anchoring protein, AKAP3. The specificity of bicarbonate effects was confirmed by inhibition with 4,4'-di-isothiocyanostilbene-2,2'-disulfonic acid. We remark that, in human spermatozoa, bicarbonate acts primarily through activation of sAC to stimulate tyrosine phosphorylation of AKAP3 and sperm motility because both effects are blunted by the sAC inhibitor 2OH-estradiol. In conclusion, our data provide the first evidence that bicarbonate stimulates human sperm motility and hyperactivation through activation of sAC and tyrosine phosphorylation of AKAP3, finally leading to an increased recruitment of PKA to AKAP3.

Human spermatozoa as a model for studying membrane receptors mediating rapid nongenomic effects of progesterone and estrogens.

In the past few years, besides the classical genomic effects of steroid hormones, a plethora of so called rapid non genomic effects have been described in different cell types, which are too rapid to be due to activation of gene expression. Although some of these effects might involve the same nuclear steroid receptors acting on different cellular signalling, others have been ascribed to poorly characterized membrane receptors. Several rapid nongenomic effects of progesterone (P) and estrogens (E) have been recently demonstrated in human spermatozoa. They seem to be mediated by the steroid binding to specific receptors on plasma membrane different from the classical ones. In particular, P has been demonstrated to stimulate calcium influx, tyrosine phosphorylation of sperm proteins, including extracellular signaling regulated kinases, chloride efflux and cAMP increase, finally resulting in activation of spermatozoa through induction of capacitation, hyperactivated motility and acrosome reaction. Conversely, E, by acting rapidly on calcium influx and on protein tyrosine phosphorylation, seem to modulate sperm responsiveness to P. Several attempts have been used to characterize the putative membrane receptors for P (mPR) and E (mER) in spermatozoa, however their isolation still remains elusive. However, in the past few years our laboratory has obtained several evidences supporting the existence and functional activity of mPR and mER in human spermatozoa. To characterize these membrane receptors, we used two antibodies directed against the ligand binding domains of the classical receptors, namely c262 and H222 antibodies for PR and ER respectively, hypothesizing that these regions should be conserved between nongenomic and genomic receptors. In western blot analysis of sperm lysates the antibodies detected a band of about 57 kDa for PR and of 29 kDa for ER, excluding the presence of the classical receptors. On live human spermatozoa, both antibodies were able to block the calcium and AR response to P and E respectively, whereas, antibodies directed against different domains of the classical PR and ER were ineffective. Moreover, c262 antibody also blocks in vitro human sperm penetration of hamster oocytes. Taken together all these data strongly support the existence of mPR and mER different from the classical ones, mediating rapid effects of these steroid hormones in human spermatozoa.