The membrane potential changes polarity during capacitation of murine epididymal sperm

The membrane potential in murine epididymal sperm was determined with a voltage-sensitive, fluorescent probe. In freshly collected sperm, the potential was inside-negative, viz., -13 mV, and was associated with an intracellular K+ concentration of about 122 mM. Following incubation of sperm in a medium capable of sustaining capacitation and fertilization efficacy, the potential became gradually positive. An inside-positive potential, +24 mV, was obtained after 40 min of incubation, concomitant with an intracellular K+ concentration of approximately 30 mM. At this time, about 70 percent of sperm had capacitated. An inside-positive membrane potential may play a role in facilitating the acrosome reaction.     

Restriction of a sperm surface antigen's mobility during capacitation.

Fluorescent Fab¹ [immunoglobulin G (IgG) fragment with antigen binding capacity from papain digestion of IgG] antibody fragments and globulin from antisera prepared against a single rabbit sperm surface membrane glycoprotein antigen (MGP) were used to study surface antigen mobility. Epididymal and ejaculated spermatozoa exhibited a redistribution of MGP surface antigen over the acrosomal region when labeled at 4°C and warmed to 37°C. Following in vivo capacitation, spermatozoa did not exhibit MGP surface antigen redistribution over the acrosome. The restricted mobility of this surface antigen implies a physiological change in plasma membrane fluidity, which may be a necessary preliminary to the acrosome reaction. Furthermore, it is suggested that the presence or absence of specific peripheral membrane proteins may control the positional relationship between mobile and nonmobile integral membrane components.     

Development of the signalling pathways associated with sperm capacitation during epididymal maturation

As spermatozoa mature within the epididymis they acquire the potential for capacitation and ultimately fertilization. In biochemical terms, the former is reflected in the progressive activation of a signal transduction pathway characterized by cAMP-mediated induction of phosphotyrosine expression on the sperm tail. In this study, we have examined the cellular mechanisms controlling this maturational event. Caput epididymal spermatozoa exhibited tyrosine phosphorylation on the sperm head that was largely unresponsive to cAMP and not significantly impaired by removal of extracellular HCO(3) (-). In contrast, caudal epididymal spermatozoa exhibited low levels of phosphorylation on the sperm head, yet responded dramatically to cAMP by phosphorylating a new set of proteins on the sperm tail via mechanisms that were highly dependent on extracellular HCO(3) (-). The impact of extracellular HCO(3) (-) depletion on caudal cells was not associated with a significant change in the redox regulation of cAMP but could be fully reversed by buffering the intracellular pH with N-Tris[Hydroxymethyl]methyl-3-amino-propanesulfonic acid (TAPS). The pattern of tyrosine phosphorylation was also profoundly influenced by the presence or absence of added extracellular calcium. In the presence of this cation, only caudal spermatozoa could respond to increased extracellular cAMP with tyrosine phosphorylation of the sperm tail. However, in calcium-depleted medium, this difference completely disappeared. Under these conditions, caput and caudal spermatozoa were equally competent to exhibit phosphotyrosine expression on the sperm tail in response to cAMP. These results emphasize the pivotal role played by calcium and HCO(3) (-) in modulating the changes in tyrosine phosphorylation observed during epididymal maturation.     

Intraperitoneal insemination, sperm transport and capacitation in the pig

Intraperitoneal insemination was studied in a total of 58 pigs, both to ascertain the success of this route of sperm deposition with the eventual use of frozen-thawed boar semen in mind and to estimate the timing of capacitation in the absence of uterine exposure of spermatozoa. Ovulation was controlled in mature gilts, and 5–20 ml freshly collected semen containing approximately 10⁸ spermatozoa per ml introduced through the peritoneum either by means of mid-ventral laparotomy or using a 3.5-in (ca. 9 cm) × 18-gauge hypodermic needle.Embryo development to the morula and blastocyst stage appeared chronologically and cytologically normal after intraperitoneal insemination, but the timing of semen deposition was critical: optimal levels of fertilization (60%) arose from insemination in the 12 h preceding ovulation. Fertility was never comparable to that found after natural mating due to the inefficiency of sperm transport into the oviducts and the absence of significant sperm reservoirs. The timing of sperm capacitation after intraperitoneal insemination was not reduced when compared with that found after insemination directly into the oviducts, indicating a negligible contribution of peritoneal exposure to this process. Spermatozoa were not phagocytosed in the oviducts, but rather descended to the uterus at the same time as the developing embryos or degenerating eggs, the sperm flagellum usually being separated from the head by this stage.     

Gossypol-induced inhibition of guinea pig sperm capacitation in vitro

The effect of gossypol acetate at various concentrations (10(-6) to 10(-4) M) on guinea pig sperm forward progressive movement, capacitation, and the acrosome reaction was explored in vitro. We found that 10(-4) M gossypol completely abolished the forward progressive motility of the sperm, and that this inhibition of motility was proportional to the concentration of gossypol used. Also, a dose-dependent decrease in acrosome reactions occurred with concentrations of the agent as low as 5.0 X 10(-6) M. However, we observed that such prevention of the acrosome reaction apparently happens at the capacitation stage rather than during the acrosome reaction itself. Inhibition of capacitation by gossypol was reversible--once the spermatozoa were capacitated in gossypol-free medium, the compound did not block the reaction.     

Alteration of sperm thiol-disulfide status and capacitation in the guinea pig

Epididymal spermatozoa of the guinea pig were incubated under conditions known to promote a rapid synchronous capacitation in a large proportion of the spermatozoa (Ca²⁺-free medium with lysophosphatidylcholine, LC) or in Ca ²⁺-free medium without LC. To study the effects of altered thiol-disulfide status and content, incubations were conducted with reagents that maintain and increase thiol groups (DTT, GSH), maintain and increase disulfide groups (diamide, GSSG), or which irreversibly block thiol groups by alkylation (NEM). The permeable DTT inhibited LC-induced capacitation and at high concentrations diminished the percentage of acrosome reactions in capacitated spermatozoa. The permeable diamide exhibited a stimulatory effect upon capacitation. The largely impermeable GSH and GSSG exhibited effects similar to their respective permeable counterparts but their effects were moderate and required extremely high concentrations. The DTT inhibition of LC-induced capacitation was reversible by washing and a further 1 hr incubation. In this final incubation after removal of DTT by washing, LC was absent too so its stimulatory effect must have been accomplished prior to washing and in the presence of DTT. NEM-alkylation of the existing thiol population did not affect LC-induced capacitation but alkylation of the increased thiol population after prior DTT treatment was inhibitory of capacitation. These results suggest that the maintenance and/or formation of disulfide groups on enzymes or structural proteins may be a component of the capacitation process. In contrast, the formation and maintenance by alkylation of increased thiol groups but not the maintenance of existing thiol groups, is inhibitory of capacitation. The relevance of these findings to a role for a thiol-sensitive proteinase in capacitation is discussed.     

获能期间精子蛋白的酪氨酸磷酸化

哺乳动物精了获能是精子与卵子成功受精的前提。蛋白酪氨酸磷酸化对精子获能十分重要。精了获能期蛋白酪氨酸磷酸化程度增高与sAC/cAMP/PKA途径、受体酪氨酸激酶途径和非受体蛋白酪氨酸激酶途径调节有关。获能过程中酪氨酸磷酸化蛋白分布于精子细胞的不同区域,蛋白的酪氨酸磷酸化与精子功能密切相关。     

Redistribution of a rat sperm epididymal glycoprotein after in vitro and in vivo capacitation.

Rat epididymal glycoprotein DE (37 kDa) associates with the sperm surface during maturation and is localized over the dorsal region of the acrosome. In the present study we examine, by indirect immunofluorescence, the localization of DE after in vitro and in vivo capacitation. While 49% of sperm capacitated in vitro for 5 hr still presented fluorescence over the dorsal region, 51% showed labeling distributed over a domain that corresponds to the equatorial segment of the sperm head. This change in the localization of fluorescence was not associated with sperm deterioration or death and increased gradually as a function of capacitation time, reaching the maximum at 5 hr. The presence of labeling over the equatorial segment results from protein migration and cannot be induced by permeabilization, proteinase, or high ionic strength treatments. The omission of Ca2+ from the standard capacitation medium inhibited the relocalization of DE, and incubation with Ca2+ ionophore A23187 for induction of the acrosome reaction (AR) significantly raised the percentage of cells with DE localized over the equatorial region. Finally, while free and cumulus-associated spermatozoa recovered from the oviducts of in vivo inseminated females presented 15% and 21% of cells with redistribution respectively, all perivitelline (acrosome reacted) spermatozoa showed DE over the equatorial segment. These results indicate that epididymal protein DE migrates to the equatorial segment under in vitro and in vivo capacitating conditions and suggest a possible association between the redistribution of DE and the occurrence of the AR.     

Surface modification of guinea pig sperm during in vitro capacitation: an assessment using lectin-induced agglutination of living sperm

Plant lectins have been used to advantage to study carbohydrate-containing cell surface receptors in numerous systems. In this study, a simple, reliable assay was developed to quantitate lectin-induced agglutinability of sperm. This assay was used successfully to compare some of the surface properties of uncapacitated and capacitated guinea pig sperm. Capacitation was induced by incubating sperm in minimum capacitation medium (MCM) or modified Tyrodes solution (T-PL). Control incubations were done in Ham's F-10 or Hank's balanced salt solution which do not support capacitation. At timed intervals during incubation, sperm samples were assessed for pattern and degree of lectin-induced agglutination. Results establish that: (1) soybean agglutinin (SBA) and to a lesser extent concanavalin A (Con A) induced agglutinability of guinea pig sperm increase during in vitro capacitation in MCM; (2) a similar increase in SBA induced agglutinability occurs during capacitation in T-PL, but not in the non-capacitating media; and (3) for sperm incubated in MCM or T-PL, there is a significant increase in tail to tail agglutination after capacitation. The results with SBA demonstrate that D-galactose and/or N-acetyl-D-galactosamine containing receptor sites or the guinea pig sperm surface are affected by capacitation, and this effect occurs, at least in part, in the sperm tail. Possible explanations for the observed increase in agglutinability are discussed. The agglutination assay may prove useful as a direct test for the occurrence of capacitation and may be especially valuable for species having a small acrosome or limited number of eggs.     

Changes in guinea pig sperm intracellular sodium and potassium content during capacitation and treatment with monovalent ionophores

Guinea pig spermatozoa were collected from the caudae epididymides in various isotonic solutions and the intracellular sodium and potassium content was determined by atomic absorption spectroscopy. The sperm intracellular Na and K content was found to be influenced by large variations in the extracellular concentrations of these ions. Treatment of spermatozoa suspended in a saline-based solution with the monovalent ionophores monensin or nigericin caused an approximate 2-fold increase in the intracellular Na content and a 3–6 fold decrease in the intracellular K content. Incubation of the spermatozoa in a K⁺-free minimal culture medium (MCM-PL) at a pH of 7.6 or 8.3 for 2 hr caused an approximate 2-fold increase in the sperm intracellular Na content and a 5-fold decrease in the intracellular K content. The motile spermatozoa incubated for 2 hr at pH 7.6 showed less than 5% acrosome reactions, compared with 30–40% acrosome reactions after incubation at pH 8.3, in response to the addition of 5 mM Ca²⁺. Changes in the sperm intracellular elemental composition during culture in vitro, which may lead to an acrosome reaction, are discussed.     

Phospholipid composition of isolated guinea pig sperm outer acrosomal membrane and plasma membrane during capacitation in vitro

After capacitation of guinea pig spermatozoa in vitro, the plasma membrane was mechanically separated from the spermatozoa in the presence or absence of HgCl₂ and subsequently isolated by density gradient centrifugation. Examination of the spermatozoa by electron microscopy after homogenization in the presence of HgCl₂ revealed that plasma membrane was removed only from the acrosomal region and remained predominately intact posterior to the equatorial segment of the sperm head, as well as the midpiece and tail. In comparison, spermatozoa homogenized under similar buffer conditions but in the absence of HgCl₂ lose the large apical segment of the acrosome and the plasma membrane is removed essentially from the entire cell. If spermatozoa were homogenized in the absence of Hg²⁺, analysis of plasma membrane phospholipid composition revealed a complete loss of lysophosphatidylcholine (LPC) from the plasma membrane after incubation of spermatozoa in minimal capacitating medium (MCM-PL) for 2 hours. Under these culture conditions the addition of Ca²⁺ (5 mM) to the capacitated spermatozoa induced approximately 78 ± 5% (n = 3) of the motile spermatozoa to undergo acrosome reactions while still maintaining sperm motility (80 ± 5%) (n = 3). If the spermatozoa were homogenized in the presence of Hg²⁺, a time course study revealed that plasma membrane LPC loss occurred between 60 and 90 minutes of incubation. This complete loss of LPC was evident when approximately half of the capacitated spermatozoa had undergone acrosome reactions. Incubation of the spermatozoa with the metabolic and acrosome reaction inhibitor, 2-deoxyglucose (10 mM) for 2 hours, maintained the plasma membrane phospholipid composition similar to that in the noncapacitated state. These data provide evidence that changes in the plasma membrane phospholipid composition may be associated with guinea pig sperm capacitation.     

Albumin-mediated changes in sperm sterol content during capacitation

The role of albumin in mouse sperm capacitation was studied in relation to its activities as a lipid-solubilizing protein and a sterol acceptor. Two bovine serum albumins (BSA) which supported capacitation, Fraction V and fatty acid-free, both contained cholesterol and phospholipid but were without detectable levels of serum high-density lipoprotein (HDL). The lipid content of BSA could be reduced by trichloroacetic acid (TCA) precipitation; however, removal of all detectable lipids required precipitation with ethanolic acetone and diethyl ether extraction. In medium supplemented with Fraction V, fatty acid-free, or TCA-precipitated BSA, mouse sperm were capacitated as evidenced by their ability to fertilize eggs, concomitant with decreases in total cellular sterol and increases in phospholipid content. Delipidated BSA, fractionated on Sephadex G-100 in guanidine HCl also supported capacitation and mediated a 20% decrease in sperm sterol content, while cellular phospholipid levels remained unchanged. When BSA was modified by cholesterol augmentation, fertilization was inhibited in a cholesterol dose-dependent manner. These findings suggest that modulation of sperm lipid levels comprises an event of capacitation and that albumin mediates this process through its activity as a sterol acceptor.     

Kinases, phosphatases and proteases during sperm capacitation

Fertilization is the process by which male and female haploid gametes (sperm and egg) unite to produce a genetically distinct individual. In mammals, fertilization involves a number of sequential steps, including sperm migration through the female genital tract, sperm penetration through the cumulus mass, sperm adhesion and binding to the zona pellucida, acrosome exocytosis, sperm penetration through the zona and fusion of the sperm and egg plasma membranes. However, freshly ejaculated sperm are not capable of fertilizing an oocyte. They must first undergo a series of biochemical and physiological changes, collectively known as capacitation, before acquiring fertilizing capabilities. Several molecules are required for successful capacitation and in vitro fertilization; these include bicarbonate, serum albumin (normally bovine serum albumin, BSA) and Ca(2+). Bicarbonate activates the sperm protein soluble adenylyl cyclase (SACY), which results in increased levels of cAMP and cAMP-dependent protein kinase (PKA) activation. The response to bicarbonate is fast and cAMP levels increase within 60?s followed by an increase in PKA activity. Several studies with an anti-phospho-PKA substrate antibody have demonstrated a rapid increase in protein phosphorylation in human, mouse and boar sperm. The target proteins of PKA are not known and the precise role of BSA during capacitation is unclear. Most of the studies provide support for the idea that BSA acts by removing cholesterol from the sperm. The loss of cholesterol has been suggested to affect the bilayer of the sperm plasma membrane making it more fusogenic. The relationship between cholesterol loss and the activation of the cAMP/PKA pathway is also unclear. During early stages of capacitation, Ca(2+) might be involved in the stimulation of SACY, although definitive proof is lacking. Protein tyrosine phosphorylation is another landmark of capacitation but occurs during the late stages of capacitation on a different time-scale from cAMP/PKA activation. Additionally, the tyrosine kinases present in sperm are not well characterized. Although protein phosphorylation depends upon the balanced action of protein kinases and protein phosphatase, we have even less information regarding the role of protein phosphatases during sperm capacitation. Over the last few years, several reports have pointed out that the ubiquitin-proteasome system might play a role during sperm capacitation, acrosome reaction and/or sperm-egg fusion. In the present review, we summarize the information regarding the role of protein kinases, phosphatases and the proteasome during sperm capacitation. Where appropriate, we give examples of the way that these molecules interact and regulate each other's activities.     

Cyclic nucleotide metabolism in mouse epididymal spermatozoa during capacitation in vitro

The role of cyclic nucleotides in sperm capacitation is equivocal. Using conditions known to support mouse sperm capacitation after 120 min incubation in vitro, the cAMP and cGMP contents of epididymal spermatozoa were measured and the cGMP/cAMP ratio determined. The initial high cAMP content detected upon release of spermatozoa decreased within 30 min to a lower plateau, which was then maintained throughout incubation. With the cGMP content remaining approximately constant, the cGMP/cAMP ratio increased over 120 min. In the presence of 2 mM caffeine, an increased cAMP content was noted at 0 and 30 min before a fall to the plateau level. To investigate cyclic nucleotide metabolism, adenylate cyclase and phosphodiesterase activities were compared in two sperm populations, one essentially uncapacitated and the other incubated for 120 min. Adenylate cyclase activity, higher in the presence of 2 mM Mn²⁺ compared to Mg²⁺, showed increased activity at 120 min compared to 30 min incubation, while phosphodiesterase activity decreased during this period. The ability of spermatozoa to form adenosine and inosine from cAMP indicated endogenous 5′-nucleotidase and deaminase, as well as phosphodiesterase, activities. Although the endogenous cAMP content appeared to remain constant during the time that acrosome loss, hyperactivated motility and fertilizing ability can be demonstrated, activities of the enzymes responsible for cAMP metabolism indicate an increased potential for cAMP availability and turnover. The increased cGMP/cAMP ratio may also play a role during capacitation.     

Changes in human sperm motion during capacitation in vitro

Spermatozoa from 10 fertile donors and from 10 patients with infertile marriages were washed and centrifuged (time zero, T0), and incubated in vitro in capacitation media for 6 h (T6), or 24 h (T24). At each time individual spermatozoa were classified as being morphologically normal or abnormal, and their movement characteristics were determined using high-speed videomicrography. Zona-free hamster oocytes were added to the T24 sperm suspensions. At all times, morphologically normal spermatozoa from donors and patients swam faster and had greater rolling frequency, flagellar beat frequency and amplitude than did abnormally shaped cells. Morphologically normal spermatozoa from donors exhibited a significant change in their movement pattern at T6. This change, which resembles hyperactivation in other species, was characterized by higher values of amplitude of lateral head displacement, and lower values of linearity, beat frequency and flagellar curvature ratio. In contrast, normal spermatozoa from patients showed only a decrease in straight line velocity at T6, with no other significant changes in movement characteristics. No changes in sperm movement could be demonstrated for the abnormal cells in either group of subjects. In sperm suspensions from donors and patients examined at T24, sperm vigour declined regardless of the morphological type. Spermatozoa from all 10 donors were able to penetrate the zona-free hamster oocytes, but spermatozoa from 5 of the 10 patients failed to penetrate oocytes. Correlations between hamster oocyte penetration and indicators of sperm vigour were demonstrated only for spermatozoa of patients.     

Decrease in order of human sperm lipids during capacitation

Ejaculated mammalian sperm must undergo a final maturation (capacitation) before they can acrosome-react and fertilize eggs. Loss of the sperm sterols, cholesterol and desmosterol, is an obligatory step in the capacitation of human sperm. Because sterols can increase the order of membrane phospholipids, it has been suggested that the importance of sterol loss is that it decreases membrane lipid order. The present study tested the hypotheses that sterol loss decreases sperm membrane lipid order during capacitation and that lipid disorder is a sufficient stimulus for capacitation. Steady-state fluorescence anisotropy of the membrane probe, 1,6-diphenyl-1,3,5-hexatriene, decreased during capacitation, indicating a decrease in lipid order. The decrease was dependent on the loss of sperm sterols, suggesting that it reflected diminished sterol-mediated phospholipid ordering. However, the lipid-fluidizing agents, benzyl alcohol and 2-(2-methoxyethoxy)ethyl 8-(cis-2-n-octylcyclopropyl) octanoate, did not cause sperm capacitation or overcome inhibition by cholesterol. In summary, loss of sperm sterols caused a significant decline in lipid order during capacitation; however, decreased bulk lipid order was not sufficient to trigger the subsequent events that complete capacitation.     

Surface changes in chimpanzee sperm during epididymal transit

Intact chimpanzee caput and cauda epididymal sperm, sperm cell lysates, and caput and cauda epididymal fluid were radiolabeled by enzymatic iodination with lactoperoxidase and Na125 I and were compared by sodium dodecyl sulfate (SDS)-polyacrylamide gel electrophoresis. Caput epididymal sperm showed nine labeled macromolecular components of 90, 64, 56, 48, 38, 31, 20, 18 and 16 Kd and cauda epididymal sperm showed eleven macromolecular components of 90, 64, 55, 47, 42, 33, 27, 18, 17, 15 and 11 Kd. Six of the components labeled on caput sperm (90, 64, 56, 48, 18 and 16 Kd) were detected in equal amounts of cauda sperm and two (38 and 20 Kd) were detected at greatly reduced labeling intensities. In the cauda epididymidis, four new components (33, 27, 17 and 11 Kd) became prominent features of the sperm surface. Analysis of labeled caput and cauda sperm cell lysates resolved components distinct from those detected on sperm surfaces. Electrophoresis of caput epididymal fluid showed five labeled components of 66, 56, 47, 41 and 37 Kd, while electrophoresis of cauda epididymal fluid showed eight labeled components of 92, 66, 56, 48, 31, 27, 24 and 11 Kd. Three components (66, 56 and 47 Kd) were present in both caput and cauda fluid, two (41 and 37 Kd) in caput fluid only, and five (92, 31, 27, 24 and 11 Kd) in cauda fluid only. Components of 37 Kd were labeled in caput fluid and on caput sperm but not on cauda sperm, whereas components of 27 Kd and 11 Kd were labeled in cauda fluid and on cauda sperm but not on caput sperm. These data show that chimpanzee sperm undergo extensive surface modifications during epididymal maturation and that some of these modifications may be related to exogenous proteins/glycoproteins in epididymal fluids.     

On the role of glucose in capacitation and acrosomal reaction of guinea pig sperm

In order to determine whether metabolizable sugars delayed capacitation of guinea pig spermatozoa, these cells were pre-incubated in Tyrode's pyruvate lactate glucose medium (T-PLG) or Tyrode's glucose solution (T-G). They were then transferred to minimal culture medium containing pyruvate and lactate (MCM-PL) and the occurrence of acrosomal reactions (AR) was determined by light microscopic observations of wet mount aliquots. The percentage of acrosomal reactions was quantitated in fixed samples and occurrence of a true AR was confirmed by electron microscopy. Activated acrosome-reacted spermatozoa were observed within 5 min when cells were transferred to MCM-PL solution, after preincubating them for 60–120 min either in T-PLG or T-G media. By 15 min in MCM-PL the percentage of acrosome-reacted spermatozoa reached values similar to those obtained in cells pre-incubated from the beginning in MCM-PL medium (P > 0.05 in both) but significantly different from T-PLG and T-G controls (P < 0.0005 in both). The acrosomal reaction was external calcium dependent and independent of the Tyrode's media pH ranging from 7.2 to 8.0. The results obtained suggested that capacitation occurred in T-PLG and that it was not delayed by glucose; the results also suggested that capacitation could occur within a short time with glucose as the only exogenous substrate, but that the acrosome reaction could have been arrested by a glucose metabolite. Data are presented which suggest that intracellular levels of glucose-6-phosphate (as 2-deoxyglucose-6-phosphate)could play a key role in the expression of the acrosome reaction in sperm already able to perform it. A new hypothesis is suggested for the development of the fertilizing potential of guinea pig sperm when in the female genital tract.