Prostasomes, dérivés actifs de l’oxygène et sperme humain

Prostasomes are particular lipid vesicles secreted by the human prostate and found in the semen. No specific action has yet been attributed to prostasomes, but they appear to act at various levels. For example, prostasomes enhance sperm motility in vitro and participate in the immunomodulation properties of seminal plasma. Excessive production of reactive oxygen species (ROS) in human semen has a negative influence on the functional capacities of spermatozoa. The presence of leukocytes in semen is associated with increased production of ROS that can be harmful to sperm cells, under certain conditions. Previous results tend to suggest a possible role of prostasomes on ROS production in human semen. After reviewing the literature concerning the structural and functional characteristics of prostasomes and the role of ROS in human semen, we report our results concerning the influence of prostasomes on ROS production and the consequences on semen. We have demonstrated that prostasomes exert an antioxidant function in human semen. This function is effective both on polymorphonuclear neutrophils and on sperm cells. The mechanism of action of prostasomes is unusual, as they act on ROS production mainly on the plasma membranes of neutrophils. They induce a decrease of NADPH-oxidase activity associated with rigidification of the plasma membrane. Prostasomes protect the functional capacities of spermatozoa during an oxidative stress created by the presence of NADPH in the incubation medium.     

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 105,000 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.     

Interactions between prostasomes and leukocytes

Prostasomes are membranous vesicles (150–200 nm diameter) 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 sperm and are involved in a number of biological functions. In a previous work, we found that prostasome can fuse to spermatozoa at slightly acidic pH values, as demonstrated by the transfer of the lipophilic octadecylrhodamine probe. In this paper, we study the interactions of two leukocyte populations (polymorphonuclear and mononuclear) with prostasomes and find a pH-dependent adhesion (revealed by microscopic observation), but no fusion. These phenomena may be relevant for the functions of leukocytes in human reproduction.     

Role of Cholesterol, DOTAP, and DPPC in Prostasome/Spermatozoa Interaction and Fusion

Prostasomes are membranous vesicles present in ejaculated human semen. They are very rich in cholesterol and can interact with spermatozoa. Their physiological roles are still under study. Prostasomes were mixed with liposomes prepared from various lipids, such as N-[1-(2,3-dioleoyloxy)propyl]-N,N,N-trimethylammonium (DOTAP), DOTAP/1,2-dipalmytoyl-sn-glycero-3-phosphorylcholine (DPPC, 4:1 molar ratio) and DOTAP/cholesterol (4:1, molar ratio) at different pH values (5–8). The mixing of the lipid phases (fusion) was determined by the relief of octadecyl rhodamine B chloride (R₁₈) self-quenching and the radii of the vesicles, by light scattering measurements. The mixing of lipids and the radii of prostasomes were both influenced by the addition of liposome, although in a different manner. The ability of prostasomes (modified by previous treatment with liposomes) to transfer lipid to spermatozoa was also measured. Pretreatment with DOTAP decreased the phenomenon and addition of DPPC abolished it. On the other hand, pretreatment of prostasomes with DOTAP/cholesterol liposomes did not affect the transfer of lipid between prostasome and spermatozoa. Therefore, the ability of vesicles to fuse (or, at least, to exchange the lipid component) was affected by the enrichment in either natural or artificial lipid. This may open new possibilities for the modulation of spermatozoa capacitation and acrosome reaction.     

Fusion of Human Sperm to Prostasomes at Acidic pH

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. Received: 19 June 1996/Revised: 4 September 1996     

Progesterone-induced increase of sperm cytosolic calcium is enhanced by previous fusion of spermatozoa to prostasomes

Ejaculated spermatozoa must undergo a number of modifications before becoming able to fertilize the oocyte. The interaction of sperm with other semen components may influence these phenomena; human semen contains vesicles of prostatic origin, called prostasomes that may fuse to sperm at slightly acidic to neutral pH values.Prostasomes contain calcium and it has been demonstrated that their fusion with spermatozoa produces a transient increase (wave) of [Ca(2+)](i) in these cells. The fusion process also transfers protein and lipid to spermatozoa. These phenomena may induce long-lasting changes of sperm properties. We test the hypothesis that spermatozoa, as modified by fusion, change their ability to undergo the progesterone-induced increase of [Ca(2+)](i) and we find that the increase of [Ca(2+)](i) produced by the fusion with prostasomes and by the stimulation with progesterone are independent and additive phenomena. We also find that spermatozoa present a stronger response to the progesterone-induced increase of [Ca(2+)](i) if they are previously made to fuse with prostasomes. This effect does not depend directly on the [Ca(2+)](i) increase due to fusion, since it is still present after the [Ca(2+)](i) has returned to resting values.     

The prostasome: its secretion and function in man

An intact organelle, the prostasome, is secreted by the acinar epithelial cell of the human prostate gland. The ultrastructural location of the prostasome is within membrane-bound storage vesicles in the epithelial cells. Prostasomes are delivered into the glandular lumen by an exocytotic event, which is preceded by fusion of adjacent membranes belonging to the storage vesicle and the epithelial cell. Alternatively, the storage vesicle can be translocated in toto from the cell interior into the acinar lumen through the plasma membrane. This latter event has been designated diacytosis. Both phenomena seem to occur with approximately equal frequency in the human prostate gland. An ATPase system that is Mg2+ and Ca2+-dependent is firmly linked to the membranes encasing the prostasomes. The ATPase system may be the molecular basis for vectorial transport of calcium into these organelles. Also a protein kinase activity is located in the membranes. An increase in membrane thickness was observed on phosphorylation. The physiologic function of the prostasomes is not known. They may be important for promoting forward motility of spermatozoa.     

Cholesterol regulates prostasome release from secretory lysosomes in PC-3 human prostate cancer cells

Prostasomes are vesicles secreted by epithelial cells of the prostate gland. However, little is known about the mechanism and the regulation of prostasome secretion. Since endocytic organelles may be involved in prostasome release, PC-3-derived prostasomes were investigated by Western blot analysis for the presence of marker proteins normally associated with these organelles. Prostasomes secreted by PC-3 cells contain clathrin, Tsg101, Hrs, Rab11, Rab5, LAMP-1, LAMP-2, LAMP-3/CD63, and annexin II. Moreover, electron microscopy of PC-3 cells revealed the presence of characteristic multivesicular body-like secretory lysosomes containing vesicles with the same size-distribution as released prostasomes. Ultrastructural immunogold labelling showed that LAMP-1, LAMP-2 and LAMP-3/CD63 were associated with these vesicles. In addition, we have investigated whether cholesterol plays a role in prostasome release by the human prostate cancer cell line PC-3. Interestingly, prostasome release was significantly increased when the cholesterol levels of PC-3 cells were reduced by the cholesterol-sequestering agent methyl-beta-cyclodextrin (MBCD), or by treatment with lovastatin and mevalonate. In conclusion, these studies indicate that cholesterol plays an important role in the release of prostasomes by the human prostate cancer PC-3 cells, and suggest that prostasomes may be released after fusion of secretory lysosomes with the plasma membrane.     

Spermatozoa recruit prostasomes in response to capacitation induction

Seminal plasma contains various types of extracellular vesicles, including ‘prostasomes’. Prostasomes are small vesicles secreted by prostatic epithelial cells that can be recruited by and fuse with sperm cells in response of progesterone that is released by oocyte surrounding cumulus cells. This delivers Ca^2 + signaling tools that allow the sperm cell to gain hypermotility and undergo the acrosome reaction. Conditions for binding of prostasomes to sperm cells are however unclear. We found that classically used prostasome markers are in fact heterogeneously expressed on distinct populations of small and large vesicles in seminal plasma. To study interactions between prostasomes and spermatozoa we used the stallion as a model organism. A homogeneous population of ~ 60 nm prostasomes was first separated from larger vesicles and labeled with biotin. Binding of biotinylated prostasomes to individual live spermatozoa was then monitored by flow cytometry. Contrary to assumptions in the literature, we found that such highly purified prostasomes bound to live sperm only after capacitation had been initiated, and specifically at pH ≥ 7.5. Using fluorescence microscopy, we observed that prostasomes bound primarily to the head of live sperm. We propose that in vivo, prostasomes may bind to sperm cells in the uterus, to be carried in association with sperm cells into oviduct and to fuse with the sperm cell only during the final approach of the oocyte. This article is part of a Special Issue entitled: An Updated Secretome.     

Increase of human spermatozoa intracellular Ca2+ concentration after fusion with prostasomes.

Prostasomes are membranous vesicles (150-200 nm diameter) present in human semen. They are secreted by the prostate gland and contain large amounts of cholesterol, sphingomyelin and calcium, and some of their proteins are enzymes. Prostasomes are involved in a number of biological functions. In previous work, we discovered that prostasomes may fuse to sperm at neutral or at slightly acidic pH values. This mechanism may deliver calcium to sperm, thereby influencing sperm functions. We measured sperm [Ca2+]i with the fura-2 AM method and found that it increased after mixing prostasomes and sperm at pH values allowing fusion (pH 5-7). The increase of [Ca2+]i was proportional to the extent of fusion as measured through the relief of R18 self-quenching. We also examined the increase of sperm [Ca2+]i and the extent of fusion as a function of sperm to prostasome ratio and, also in this case, there was proportionality between the extent of fusion and the increase of [Ca2+]i that reached its maximal values in about 10-20 min. However, a detectable increase of [Ca2+]i was attained after 2 min of fusion. This would represent a new mechanism to influence sperm [Ca2+]i besides ion-exchange systems and ATP-dependent pumps. The value of [Ca2+]i remained elevated, unless Na+ was also present in the external medium. Therefore, the mechanism of fusion might influence deeply the physiology of sperm by producing a transient increase of [Ca2+]i.     

Identification of distinct populations of prostasomes that differentially express prostate stem cell antigen, annexin A1, and GLIPR2 in humans

In addition to sperm cells, seminal fluid contains various small membranous vesicles. These include prostasomes, membrane vesicles secreted by prostate epithelial cells. Prostasomes have been proposed to perform a variety of functions, including modulation of (immune) cell activity within the female reproductive tract and stimulation of sperm motility and capacitation. How prostasomes mediate such diverse functions, however, remains unclear. In many studies, vesicles from the seminal plasma have been categorized collectively as a single population of prostasomes; in fact, they more likely represent a heterogeneous mixture of vesicles produced by different reproductive glands and secretory mechanisms. We here characterized membranous vesicles from seminal fluid obtained from vasectomized men, thereby excluding material from the testes or epididymides. Two distinct populations of vesicles with characteristic sizes (56 ± 13 nm vs. 105 ± 25 nm) but similar equilibrium buoyant density (～1.15 g/ml) could be separated by using the distinct rates with which they floated into sucrose gradients. Both types of vesicle resembled exosomes in terms of their buoyant density, size, and the presence of the ubiquitous exosome marker CD9. The protein GLIPR2 was found to be specifically enriched in the lumen of the smaller vesicles, while annexin A1 was uniquely associated with the surface of the larger vesicles. Prostate stem-cell antigen (PSCA), a prostate-specific protein, was present on both populations, thereby confirming their origin. PSCA was, however, absent from membrane vesicles in the seminal fluid of some donors, indicating heterogeneity of prostasome characteristics between individuals.     

Prostasome-like vesicles stimulate acrosome reaction of pig spermatozoa

Background  

The presence of small membranous particles characterizes the male genital fluids of different mammalian species. The influence of semen vesicles, denominated prostasomes, on sperm functional properties has been well documented in humans, but their biological activity is scarcely known in other species. The present work investigated prostasome-like vesicles in pig semen for their ability to interact with spermatozoa and to affect acrosome reaction.     

Lipid fatty acid and protein pattern of equine prostasome-like vesicles

The semen of several mammals contains vesicles of different composition and origin. We have recently reported on the presence of lipoprotein vesicles in stallion semen. To a certain extent, these resemble human prostasomes, but differ from them in amount and composition. These horse-semen prostasome-like vesicles may be important, not only in horse reproductive physiology, but also in view of stallion semen cryopreservation. In this paper, we have studied horse-semen prostasome-like vesicles and found that they possess less saturated fatty acid than human prostasomes. Moreover, their protein pattern (SDS-PAGE electrophoresis) shows that the 30–50-kDa fraction is less abundant in stallion vesicles. In addition, fluidity (measured as fluorescence anisotropy of diphenylhexatriene) is higher in horse prostasome-like vesicles than in human prostasomes, albeit being much lower than that of most membranes. These findings may be connected to some species-related differences in reproductive physiology: the vaginal milieu of the mare is not acidic and the deposition of semen is intrauterine in the horse but vaginal in humans.     

Prostasomes from four different species are able to produce extracellular adenosine triphosphate (ATP)

Background

Prostasomes are extracellular vesicles. Intracellularly they are enclosed by another larger vesicle, a so called “storage vesicle” equivalent to a multivesicular body of late endosomal origin. Prostasomes in their extracellular context are thought to play a crucial role in fertilization.

Methods

Prostasomes were purified according to a well worked-out schedule from seminal plasmas obtained from human, canine, equine and bovine species. The various prostasomes were subjected to SDS-PAGE separation and protein banding patterns were compared. To gain knowledge of the prostasomal protein systems pertaining to prostasomes of four different species proteins were analyzed using a proteomic approach. An in vitro assay was employed to demonstrate ATP formation by prostasomes of different species.

Results

The SDS-PAGE banding pattern of prostasomes from the four species revealed a richly faceted picture with most protein bands within the molecular weight range of 10–150 kDa. Some protein bands seemed to be concordant among species although differently expressed and the number of protein bands of dog prostasomes seemed to be distinctly fewer. Special emphasis was put on proteins involved in energy metabolic turnover. Prostasomes from all four species were able to form extracellular adenosine triphosphate (ATP). ATP formation was balanced by ATPase activity linked to the four types of prostasomes.

Conclusion

These potencies of a possession of functional ATP-forming enzymes by different prostasome types should be regarded against the knowledge of ATP having a profound effect on cell responses and now explicitly on the success of the sperm cell to fertilize the ovum.

General significance

This study unravels energy metabolic relationships of prostasomes from four different species.     

Galectin-3 is associated with prostasomes in human semen

Galectin-3 is a β-galactoside-binding protein involved in immunomodulation, cell interactions, cancer progression, and pathogenesis of infectious organisms. We report the identification and characterization of galectin-3 in human semen. In the male reproductive tract, the ~30 kDa galectin-3 protein was identified in testis, epididymis, vas deferens, prostate, seminal vesicle, and sperm protein extracts. In seminal plasma, galectin-3 was identified in the soluble fraction and in prostasomes, cholesterol-rich, membranous vesicles that are secreted by the prostate and incorporated into seminal plasma during ejaculation. Two-dimensional immunoblot analysis of purified prostasomes identified five galectin-3 isoelectric variants with a pI range of 7.0 to 9.2. Affinity purification and tandem mass spectrometry of β-galactoside-binding proteins from prostasomes confirmed the presence of galectin-3 in prostasomes and identified a truncated galectin-3 variant. The intact galectin-3 molecule contains a carbohydrate recognition domain and a non-lectin domain that interacts with protein and lipid moieties. The identification of a monovalent galectin-3 fragment with conserved carbohydrate-binding activity indicates the functional relevance of this truncation and suggests a regulatory mechanism for galectin-3 in prostasomes. Surface biotinylation studies suggested that galectin-3 and the truncated galectin-3 variant are localized to the prostasome surface. Prostasomes are proposed to function in immunosuppression and regulation of sperm function in the female reproductive tract, are implicated in facilitating sexually-transmitted infections, and are indicated in prostate cancer progression. Given the overlap in functional significance, the identification of galectin-3 in prostasomes lays the groundwork for future studies of galectin-3 and prostasomes in reproduction, disease transmission, and cancer progression.     

Biochemical characterization and membrane fluidity of membranous vesicles isolated from boar seminal plasma

Mammalian seminal plasma contains membranous vesicles (MV), which differ in composition and origin. Among these particles, human prostasomes and equine prostasome-like MV have been the most studied. The aim of the present work is to characterize the biochemical composition and membrane fluidity of MV isolated from boar seminal plasma. The MV from boar seminal plasma were isolated by ultracentrifugation and further purification by gel filtration on Sephadex G-200. The MV were examined by electron microscopy (EM), amount of cholesterol, total phospholipid, protein content, and phospholipid composition were analyzed. Membrane fluidity of MV and spermatozoa were estimated from the electron spin resonance (ESR) spectra of the 5-doxilstearic acid incorporated into the vesicle membranes by the order parameter (S). The S parameter gives a measure of degree of structural order in the membrane and is defined as the ratio of the spectral anisotropy in the membranes to the maximum anisotropy obtained in a rigidly oriented system. The S parameter takes into consideration that S = 1 for a rapid spin-label motion of about only one axis and S = 0 for a rapid isotropic motion. Intermediate S values between S = 0 and S = 1 represents the consequence of decreased membrane fluidity. The EM revealed the presence of bilaminar and multilaminar electron-dense vesicles. Cholesterol to phospholipid molar ratio from the isolated MV was 1.8. Phospholipid composition showed a predominance of sphingomyelin. The S parameter for porcine MV and for boar spermatozoa was 0.73 +/- 0.02 and 0.644 +/- 0.008, respectively, with the S for MV being greater (p < 0.001) than the S for spermatozoa. The high order for S found for boar MV was in agreement with the greater cholesterol/phospholipids ratio and the lesser ratio for phosphatidylcholine/sphingomyelin. Results obtained in the present work indicate that MV isolated from boar semen share many biochemical and morphological characteristics with equine prostasome-like MV and human prostasomes. The characteristics of the porcine MV of the seminal plasma, however, differed from those of boar sperm plasma membranes.     

Occurrence of prostasome-like membrane vesicles in equine seminal plasma

Equine seminal plasma was shown to contain membrane vesicles that are similar to the well characterized prostasomes in human seminal plasma. Determination of nucleoside and nucleotide concentrations of these particles have shown that ATP, ADP and adenosine are the main components of the nucleotidic pool. 5' nucleotidase, endopeptidase and dipeptidyl peptidase i.v. activities have been found on the surface of the particles. The interaction between these prostasome-like vesicles and spermatozoa was demonstrated by electron micrograph scans which revealed the steps of a fusion-like process leading to mixing of the membranes. In addition, endopeptidase activity, a marker enzyme of these seminal vesicles that is normally absent from equine spermatozoa, was shown to be acquired by these cells after interaction with the vesicles. The addition of these vesicles to equine spermatozoa resulted in the modification of adenylate catabolism. Therefore, a role in stabilizing the energy charge of the spermatozoa thus allowing longer viability is proposed for these organelles.     

哺乳动物精浆胞外囊泡及各组分的功能

精浆胞外囊泡是一种存在于精浆的膜性囊泡,按分泌器官分为附睾小体和前列腺小体。囊泡可与精子细胞膜发生融合,通过传递内容物或介导信号通路进而调节精子功能。它含有多种活性物质,其中蛋白质组分可影响精子活力以及顶体反应,并有清除损伤精子和促进细胞粘附的作用;脂质组分具有调节靶细胞质膜稳定性的作用;核酸组分主要参与免疫反应、跨代遗传及男性不育;离子则是多种酶的辅助因子,在调节酶活性和精浆微环境中发挥重要作用。不同组分对精子功能的影响不尽相同,本文将对此方面的研究进展进行详尽的综述,以期为该领域相关研究人员提供一定的参考。     

Changes in sperm quality and lipid composition during cryopreservation of boar semen

Egg yolks are commonly used in diluents in order to improve the freezability of semen. Two aspects of the role of lipids in boar semen freezability are reported in this article. The first one concerns the eventual exchanges of lipid components between the spermatozoa and the yolk-based diluent during cryopreservation. Two types of yolk have been considered as ingredients in diluents for cryopreservation: yolks with a standard fatty acid composition and yolks enriched in docosahexaenoic acid (DHA). The relation between lipid exchanges and the quality of fresh semen is considered. The other aspect concerns the possibility to enhance the freezability of boar spermatozoa by altering the plasma membranes under the influence of dietary fatty acids. Spermatozoa were damaged significantly by the cryopreservation cycle in all experiments. Spermatozoa with the best fresh quality had accumulated the largest quantity of lipids upon thawing. A general decrease in the proportion of polyunsaturated fatty acids was observed after thawing. The yolks enriched in n-3 fatty acids failed to improve the quality of sperm following cryopreservation. The proportion of DHA was significantly higher in spermatozoan phospholipids from thawed cells that had been in contact with n-3 yolks. A significant reduction in cholesterol was observed in spermatozoa after the cryopreservation cycle, which correlated with an increased number of acrosome-reacted cells and changes in the parameters of motility. The addition of 3% fish oil to the daily boar ration significantly increased the content of DHA (from 33 to 45% of the total fatty acids) in the spermatozoa. Ejaculate concentrations were significantly increased in the experimental group. DHA-enriched semen did not show improved freezability, at least not as assessed by in vitro parameters.     

Changes in turkey semen lipids during liquid in vitro storage

The changes in lipid composition of spermatozoa and seminal plasma and changes in motility, viability, and morphological integrity of spermatozoa were measured in turkey semen diluted in Beltsville poultry semen extender and stored for 48 h (4 degrees C). The total phospholipid content of spermatozoa decreased during storage, while no quantitative decrease was observed in seminal plasma. More precisely, significant decreases in phosphatidylcholine, and to a lesser extent in sphingomyeline, phosphatidylserine, and phosphatidylinositol were observed in spermatozoa. The fatty acid profile of turkey spermatozoa partly reflected diet composition and had a high level of n-9 polyunsaturated fatty acids. Neither fatty acid profile nor free cholesterol were affected by storage. The lipid composition of seminal plasma was quite different from that observed in spermatozoa and was similar to the high density lipoprotein composition of chicken seminal plasma. In vitro storage did not significantly affect lipid classes and only small changes were observed in phospholipid classes of seminal plasma. The motility, viability, and morphological integrity of spermatozoa decreased during storage. These changes in phospholipid content may be explained by membrane phospholipid lysis followed by endogenous metabolism or by a complex combination of lysis, metabolism, and peroxidation. They are likely to affect semen quality and the success of in vitro storage severely.