desmosterol and cholesteryl-sulfate

A simple, rapid and accurate method to separate and quantify cholesterol, desmosterol and cholesterol sulfate in human spermatozoa and seminal plasma (SP) is described. This high-performance liquid chromatographic procedure is based on reversed-phase chromatography on a Inertsil ODS2 5 microm silica column with a binary gradient of mixtures of chloroform-methanol and chloroform-methanol-water as the mobile phase at a flow-rate of 0.25 ml/min. Sterols are separated with good resolution and high reproducibility. The eluted sterols are quantified using a light-scattering (mass) detector. As little as 64, 64 and 68 pmol of cholesterol, desmosterol and cholesterol sulfate, respectively, can be quantified under these conditions. Cholesterol is the predominant sterol both in spermatozoa (107+/-7 nmol/10(8) spermatozoa) and SP (0.83+/-0.10 micromol/ml) whereas the concentrations of desmosterol were 38+/-6 nmol/10(8) in spermatozoa and 0.18+/-0.02 micromol/ml in SP. Cholesterol sulfate represents about 6% of total cholesterol in the spermatozoa and SP. In conclusion, this method offers interesting perspectives for the quantitative analysis of these sterols not only in semen, but also in other biological samples.

Topics: Cholesterol; Cholesterol Esters; Chromatography, High Pressure Liquid; Desmosterol; Humans; Male; Reference Values; Reproducibility of Results; Semen

We previously demonstrated that mouse sperm capacitation is accompanied by a time-dependent increase in protein tyrosine phosphorylation that is dependent on the presence of BSA, Ca2+, and NaHCO(3), all three of which are also required for this maturational event. We also demonstrated that activation of protein kinase A (PK-A) is upstream of this capacitation-associated increase in protein tyrosine phosphorylation. BSA is hypothesized to modulate capacitation through the removal of cholesterol from the sperm plasma membrane. In this report, we demonstrate that incubation of mouse sperm medium containing BSA results in a release of cholesterol from the sperm plasma membrane to the medium; release of this sterol does not occur in medium devoid of BSA. We next determined whether cholesterol release leads to changes in protein tyrosine phosphorylation. Blocking the action of BSA by adding exogenous cholesterol-SO-(4) to the BSA-containing medium inhibits the increase in protein tyrosine phosphorylation as well as capacitation. This inhibitory effect is overcome by (1) the addition of increasing concentrations of BSA at a given concentration of cholesterol-SO-(4) and (2) the addition of dibutyryl cAMP plus IBMX. High-density lipoprotein (HDL), another cholesterol binding protein, also supports the capacitation-associated increase in protein tyrosine phosphorylation through a cAMP-dependent pathway, whereas proteins that do not interact with cholesterol have no effect. HDL also supports sperm capacitation, as assessed by fertilization in vitro. Finally, we previously demonstrated that HCO-(3) is necessary for the capacitation-associated increase in protein tyrosine phosphorylation and demonstrate here, by examining the effectiveness of HCO-(3) or BSA addition to sperm on protein tyrosine phosphorylation, that the HCO-(3) effect is downstream of the site of BSA action. Taken together, these data demonstrate that cholesterol release is associated with the activation of a transmembrane signal transduction pathway involving PK-A and protein tyrosine phosphorylation, leading to functional maturation of the sperm.

Topics: Acrosome; Animals; Cholesterol; Cholesterol Esters; Cyclic AMP; Cyclic AMP-Dependent Protein Kinases; Desmosterol; Dose-Response Relationship, Drug; Fertilization; Filipin; Freeze Fracturing; Lipoproteins, HDL; Male; Mice; Phosphorylation; Serum Albumin, Bovine; Signal Transduction; Sperm Capacitation; Spermatozoa; Sterols; Time Factors; Tyrosine

Sterol sulfates are present in relatively high concentrations in the male reproductive tract. Cholesteryl sulfate is the major sterol sulfate in the human epididymis while desmosteryl sulfate is the major sterol sulfate in the hamster epididymis. While the testis is the major source of sterol sulfate in the human, the epididymis of the hamster is the source of demosteryl sulfate. This conjugate accumulates along the length of the epididymis and is taken up by the plasma membrane in the acrosomal region of the spermatozoa. Sulfotransferase activity increases along the epididymis and this is due to the actual synthesis of the enzyme. Sterol sulfates are potent and specific inhibitors of the proteolytic enzyme, acrosin. This property could provide protection against the premature release of proteolytic activity within the male reproductive tract. It is proposed that the removal of this inhibition occurs within the female tract via sulfatase activity in order to enable the acrosome reaction and ovum penetration to occur.

Topics: Acrosin; Acrosome; Animals; Cell Membrane; Cholesterol Esters; Cricetinae; Desmosterol; Epididymis; Female; Genitalia, Female; Humans; Male; Rats; Sheep; Sperm-Ovum Interactions; Steryl-Sulfatase; Sulfatases; Sulfotransferases; Sulfurtransferases

Cholesteryl sulfate is a component of human seminal plasma (avg. 445 mug%) and spermatozoa (15 mug/10 (9) cells) and represents more than 85% of the sterol sulfate fraction. This conjugate is avidly bound by spermatozoa when compared to other steroids or steroid sulfates. Autoradiographic localization of CS associated with the spermatozoa revealed a greater accumulation of the radioactivity in the acrosomal region in many, but not all, of those cells examined. Semen is not a site of metabolism of the sterol sulfate but the enzyme, sterol sulfatase, is present in the human female reproductive tract. This cleavage enzyme was detected in Graafian follicles and the activity in the endometrium was ten-fold that found in the Fallopian tube. These findings lead to the proposal that cholesteryl sulfate, an amphipathic molecule ideally suited for interaction with membrane components and implicated in erythrocyte membrane stabilization, may be involved in membrane modifications of the spermatozoa during the process of fertilization.

Topics: Cervix Mucus; Cholesterol; Cholesterol Esters; Desmosterol; Female; Humans; In Vitro Techniques; Male; Myometrium; Proteins; Semen; Spermatozoa; Steroids; Sterols; Sulfatases