Identification of structural elements of the testis-specific voltage dependent calcium channel that potentially regulate its biophysical properties.

Abstract

Calcium influx through voltage-dependent calcium channels regulates the physiological acrosome reaction of mammalian spermatozoa. Expression of the mRNA for these voltage-dependent calcium channels and its co-ordinated translation is initiated early in rat male germ line development and continues throughout spermatogenesis. Herein, we report the complete mRNA and deduced amino acid sequence of the alpha1c pore-forming subunit of the rat testis-specific L-type calcium channel. This subunit is transcribed from the alpha1c gene, which is also expressed in brain and cardiac muscle. The cardiac- and testis-specific isoforms of the alpha1c subunit are produced by alternate splicing of the same primary transcript. The testis-specific isoform differs from that of cardiac tissue at its amino terminus and in transmembrane segments IS6, IIIS2 and IVS3, which are also dihydropyridine binding sites. In somatic tissues, segments S2 and S3 regulate channel activation while the amino terminus and segment IS6 contribute to channel inactivation kinetics. The amino terminus and IS6 segment of the testis-specific alpha1c subunit are also expressed respectively, in the brain and in smooth muscle from lung where they alter the electrophysiological characteristics of the subunit to produce relatively slow inactivation kinetics. These findings provide a molecular explanation for the detection by others, by patch clamp analysis, of T-type calcium currents in immature spermatogenic cells and of atypical L-type calcium currents in mature spermatozoa.