Carlo Alberto Palmerini

Fusion of human sperm to prostasomes at acidic pH.

Abstract. Prostasomes are membranous vesicles (150–200 nm diameter) present in human semen. They are secreted by the prostate and contain large amounts of cholesterol, sphingomyelin and Ca2+. In addition, some of their proteins are enzymes. Prostasomes enhance the motility of ejaculated spermatozoa and are involved in a number of additional biological functions. The possibility that they may fuse to sperm has never been proved. In this work, we studied the fusion of sperm to prostasomes by using various methods (relief of octadecyl Rhodamine B fluorescence self-quenching, fluorescence microscopy and flow cytometry) and we found that it occurs at acidic pH (4–5), but not at pH 7.5 pH-dependent fusion relies on the integrity of one or more proteins and is different from the Ca2+-stimulated fusion between rat liver liposomes and spermatozoa that does not require any protein and occurs at neutral pH. We think that the H+-dependent fusion of prostasomes to sperm may have physiological importance by modifying the lipid and protein pattern of sperm membranes.

Simultaneous analysis of bases, nucleosides and nucleoside mono- and polyphosphates by high-performance liquid chromatography

A single-column high-performance liquid chromatographic system for the simultaneous separation of bases, nucleosides and nucleoside mono- and polyphosphates has been developed, in which a strong porous anion-exchange resin (Aminex A-14) is used. The chromatographic run, carried out at 55 degrees and at alkaline pH by using a linear gradient both of ionic strength and pH, takes less than 225 min. The quantitative application of the described procedure to the analysis of cell nucleotide pools is reported.

The motility of human spermatozoa as influenced by prostasomes at various pH levels.

Human semen contains several components among which spermatozoa, membranous vesicles called ‘prostasomes’, secreted by the prostate gland and unorganized material. Prostasomes possess an unusual lipid composition, contain a number of proteins and small molecules and have been claimed to take a part in the immune response, in seminal fluid liquefaction and in sperm motility. Since sperm may come in contact with an acidic environment in the vagina, it may be of some interest to know whether prostasomes may affect spermatozoon motility or may protect spermatozoa upon the exposure to an acidic milieu. Human semen was supplied by donors. From whole semen we collected spermatozoa by centrifugation and used the supernatant to prepare prostasomes (centrifugation at 105000 g for 120 min, followed by purification step on Sephadex G 200); spermatozoa were then collected by a swim‐up procedure and exposed to an acidic pH medium (from 5 to 7) in the presence or absence of prostasomes. Spermatozoa motility was subsequently assessed with a superimposed image analysis system (SIAS). Results indicate that the motility of spermatozoa was affected by the pH value of the medium. Acidic media reduced the percentage of motile cells and decreased the straight line velocity of spermatozoa (VLS). Prostasomes had a protective effect and increased the percentage of motile cells. However, they did not change the characteristics of motility (curvilinear and straight). Prostasomes may be considered as a system for counteracting the negative effects of acidic pH values that may be present in the vagina after coitus.

Role of human prostasomes in the activation of spermatozoa.

Prostasomes are small vesicles of prostatic origin contained in human semen. Their composition is peculiar under many aspects. Cholesterol is abundant and many proteins are endowed with enzymatic or other activities. The function of prostasomes has been amply debated and several hypotheses have been put forward. The liquefaction of semen, spermatozoa motility, antibacterial activity and immunological functions have been related to prostasomes. Under certain aspects, prostasomes resemble synaptosomes. The fusion of prostasomes to spermatozoa enriches spermatozoa with cholesterol and causes bursts of cytoplasmic sperm calcium. The interaction of spermatozoa and prostasomes should be limited to vagina since prostasomes are immobile and do not follow spermatozoa in the superior female genital tract. Calcium bursts would increase spermatozoa motility, where cholesterol would decapacitate spermatozoa, so preventing untimely activation. Since spermatozoa receive many different molecules from prostasomes, additional effects are also possible. Prostasomes makes spermatozoa more apt to be activated by progesterone in the proximity of the ovum. Therefore, the fusion between spermatozoa and prostasomes would influence spermatozoa behaviour under many aspects and might be relevant for fecundation. The richness of molecular species in prostasomes is amazing and these small vesicles are expected to lead to many more discoveries in the field of human reproduction.

Fusion of prostasomes to human spermatozoa stimulates the acrosome reaction

OBJECTIVE To determine the effect of the fusion of prostasomes to spermatozoa on the acrosome reaction. DESIGN In vitro study of human spermatozoa. SETTING Healthy volunteers in an academic research environment. PATIENT(S) Healthy volunteer men, 25 to 35 years old. INTERVENTION(S) Human semen was fractionated into spermatozoa and prostasomes. Fusion of prostasome to spermatozoa was performed at pH 5.5. Progesterone (1 microM) was added when required. MAIN OUTCOME MEASURE(S) Evaluation of the acrosome reaction by fluorescence microscopy. RESULTS(S) The percentage of spontaneously acrosome-reacted cells was very low unless the Ca(2+)-ionophore A 23187 was added. The treatment of spermatozoa with 1 microM of progesterone scarcely affected the acrosome reaction; a pretreatment in conditions permitting fusion increased it. The addition of progesterone to prostasome-fused spermatozoa further increased the extent of the acrosome reaction. CONCLUSION(S) The H(+)-dependent fusion with prostasomes makes spermatozoa more sensitive to the effect of progesterone on acrosome-reaction induction.

Prostasome to sperm transfer of CD13/aminopeptidase N (EC 3.4.11.2)

Prostasomes are membranous vesicles (150-200 nm in diameter) that are present in human semen. They are secreted by the prostate gland and contain large amounts of cholesterol, sphingomyelin and Ca2+. In addition, some of their proteins are enzymes. Prostasomes enhance the motility of ejaculated spermatozoa and are involved in a number of additional biological functions. In previous papers, we demonstrated that lipid can be transferred from prostasomes to sperm by a fusion process occurring at slightly acidic pH. CD (cluster antigens) are ubiquitous proteins; in this paper, we demonstrate that CD13/aminopeptidase N is present is semen, where it is bound to prostasomes. Upon mixing prostasomes and sperm at slightly acidic pH (7 or less), aminopeptidase is transferred from prostasomes to sperm. This evidence comes from enzymatic activity determinations and from the use of the monoclonal antibody, anti-human CD13. The transfer was about 8% of total prostasomal activity at pH 5 and with a prostasome to sperm ratio of 2 (on a protein basis). The transfer did not occur at pH 8.0, but was measurable at pH 7. Therefore, this mechanism may represent a means of modifying the composition and the biological properties of ejaculated sperm.

Transfer of CD26/dipeptidyl peptidase IV (E.C. 3.5.4.4) from prostasomes to sperm.

Prostasomes are vesicles present in human semen. They are secreted by the prostate and contain large amounts of cholesterol and sphingomyelin. Some of their proteins are enzymes. Prostasomes are involved in a number of biological functions. In previous papers we demonstrated that lipid can be transferred from prostasomes to sperm by a fusion process occurring at neutral or slightly acidic pH. In this paper we demonstrate that CD26/dipeptidyl peptidase IV, an enzymatic activity absent in sperm, is transferred to sperm from prostasomes. This may be of particular interest since, by this procedure, sperm may acquire new membrane‐bound enzymes and modify the catalytic activity of their surface.

High-performance liquid chromatographic analysis of free hydroxyproline and proline in blood plasma and of free and peptide-bound hydroxyproline in urine.

A rapid, accurate and sensitive method for the determination of free hydroxyproline and proline in plasma and of total hydroxyproline in urine has been developed. Free imino acids and internal standard are extracted from plasma by trichloroacetic acid precipitation of protein and they are selectively derivatized with 4-chloro-7-nitrobenzofurazan, after reaction of the acid extract with o-phthalaldehyde. The highly fluorescent adducts of imino acids are separated on a Spherisorb ODS 2 reversed-phase column using acetonitrile-0.1 M sodium phosphate buffer, pH 7.2 (9:91, v/v) as mobile phase, followed by fluorometric detection. Total hydroxyproline determination in urine hydrolysates is carried out by reaction of the imino acid with 4-chloro-7-nitrobenzofurazan after clean-up on a Sep-Pak C18 cartridge of the o-phthalaldehyde-treated sample, high-performance liquid chromatographic separation and fluorometric quantitation of the derivative.

NO Synthesis in Human Saliva

Human saliva contains nitrate that is converted into nitrite by the activity of facultative, anaerobic bacteria of the oral cavity. Nitrite can be reduced to NO in the acidic gastric milieu; some NO may also form in the mouth at acidic pH values. In this paper, we show that bacteria ( S. salivarius, S. mitis and S. bovis ) isolated from saliva, may contribute to NO production in human saliva. NO formation by bacteria occurs at neutral pH values and may contribute to the antibacterial activity of saliva.

Transfer of aminopeptidase activity from prostasomes to sperm

Prostasomes are membranous vesicles (150-200 nm diameter) present in human semen. They are secreted by the prostate and contain large amounts of cholesterol, sphingomyelin and Ca2+. In addition, some of their proteins are enzymes. Prostasomes enhance the motility of ejaculated spermatozoa and are involved in a number of additional biological functions. It has been demonstrated that lipid can be transferred from prostasomes to sperm by a fusion process occurring at slightly acidic pH. In this paper, we show that an aminopeptidase activity is transferred from prostasome to sperm. This may be of particular interest since it indicates the involvement of protein in the process of fusion and because sperm may acquire new membrane-bound proteins by this procedure.