Effects of progesterone on sperm function: mechanisms of action

doi:10.1093/humrep/15.suppl_1.28

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Human Reproduction, Vol. 15, No. suppl_1, pp. 28-45, 2000
© 2000 European Society of Human Reproduction and Embryology

Effects of progesterone on sperm function: mechanisms of action

Aldo E. Calogero¹^,3, Nunziatina Burrello¹, Nunziata Barone¹, Irina Palermo², Umberto Grasso¹ and Rosario D'Agata¹

¹ Division of Endocrinology, University of Catania Medical School Catania, Italy ² Department of Andrological Sciences: New Methodologies in Human Reproductive Medicine, Department of Internal Medicine, University of Catania Medical School Catania, Italy

Correspondence: ³To whom correspondence should be addressed

Progesterone stimulates sperm functions, e.g. hyperactivation,acrosome reaction, binding to oocyte zona pellucida and penetrationrate into the hamster oocyte. The physiological relevance ofthese effects has been shown using female genital tract fluidswhich modulate sperm function according to their progesteronecontent. Progesterone interacts with specific sperm bindingsites that, unlike the classic nuclear receptors, are locatedon the plasma membrane of the spermatozoon. Binding studieshave revealed the presence of two classes of progesterone receptorsin the human spermatozoon, one class has an elevated affinityconstant (nanomolar) and is specific for progesterone, whereasthe other class has an affinity constant in the micromolar rangeand binds equally well other hydroxylated progesterone derivatives.Following exposure to progesterone, the main event is a rapid(within seconds) increase of the intracellular free calciumconcentration, followed by a sustained rise lasting for severalminutes (plateau phase). Both these calcium transients are dependentupon entry of extracellular calcium. The nature of the calciumchannel that mediates the effects of progesterone is, currently,unknown. It has been postulated that it may be: (i) part ofthe progesterone receptor; (ii) voltage-dependent; or (iii)operated by second messengers following activation of the progesteronereceptor. Progesterone also modulates sperm function by stimulatinga trypsin-like proteolytic activity, the biosynthesis of polyamine(putrescine and spermidine), phospholipase A₂ activity and proteintyrosine kinase activity in the sperm cell. Recent studies haveshown that chloride ion efflux is vital for progesterone topromote the acrosome reaction. This effect is achieved by interactionwith a sperm membrane receptor which resembles the neuronalGABA_A receptor. Accordingly, GABA_A receptors have been foundin the spermatozoon plasma membrane and GABA stimulates hyperactivationand promotes the acrosome reaction.

Key words: GABA_A receptor/intracellular calcium/progesterone/sperm function

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