The role of osmotic resistance on equine spermatozoal function

Cryopreservation requires exposure of sperm to extreme variations in temperature and osmolality. The goal of this experiment was to determine the osmotic tolerance levels of equine sperm by analyzing motility, viability, mitochondrial membrane potential (MMP), and mean cell volume (MCV). Spermatozoa were incubated at 22 degrees C for 10 min in isosmolal TALP (300 mOsm/kg), or a range of anisosmolal TALP solutions (75-900 mOsm/kg), for initial analysis, and then returned to isosmolal conditions for 10 min for further analysis. Total sperm motility was lower (P < 0.05) in anisosmolal conditions compared to sperm motility in control medium. When cells were returned to isosmolal conditions, only sperm previously incubated in 450 mOsm/kg TALP were able to recover to control levels of motility. Sperm viability and MMP were lower (P < 0.05) when exposed to hypotonic solutions in comparison to control solutions. Sperm suspensions that were returned to isosmolal conditions from 75, 150, and 900 mOsm/kg had lower (P < 0.05) percentages of viable sperm than control suspensions (300 mOsm/kg). MMP was lower (P < 0.05) in cells previously incubated in 75 and 900 mOsm/kg when returned to isosmolal, as compared to control cells. MCV differed (P < 0.05) from control cell volume in all anisosmolal solutions. Cells in all treatments were able to recover initial volume when returned to isosmolal medium. Although most spermatozoa are able to recover initial volume after osmotic stress, irreversible damage to cell membranes may render some sperm incapable of fertilizing an oocyte following cryopreservation.     

Osmotic tolerance limits and effects of cryoprotectants on the motility, plasma membrane integrity and acrosomal integrity of rat sperm

Osmotic stress is an important factor that can result in cell damage during cryopreservation. The objectives of this study were to determine: (1) isosmotic sperm cell volume; (2) osmotically inactive volume; (3) osmotic tolerance limits of rat sperm; and (4) the effects of addition and removal of glycerol (Gly), ethylene glycol (EG), propylene glycol (PG) or dimethyl sulfoxide (Me(2)SO) on rat sperm function. Sperm from Fischer 344 and Sprague-Dawley rats were used in this study. An electronic particle counter was used to measure the cell volume of rat sperm. Computer-assisted sperm motility analysis and flow-cytometric analysis were used to assess sperm motility, plasma membrane and acrosomal integrity. The isosmotic sperm cell volumes of the two strains were 37.0+/-0.1 and 36.2+/-0.2 microm(3), respectively. Rat sperm behaved as linear osmometers from 260 to 450 mOsm, and the osmotically inactive sperm volumes of the two strains were 79.8+/-1.5% and 81.4+/-2.2%, respectively. Rat sperm have very limited osmotic tolerances. The sperm motility and the sperm plasma membranes of both strains were sensitive to anisosmotic treatments, but the acrosomes of both strains were more sensitive to hyposmotic than hyperosmotic conditions. The one-step addition and removal of Me(2)SO showed the most deleterious effect on rat sperm motility, plasma membrane integrity, and acrosomal integrity among the four cryoprotectants. These data characterizing rat sperm osmotic behavior, osmotic and cryoprotectant tolerance will be used to design cryopreservation protocols for rat sperm.     

Optimal concentrations of cryoprotective agents for semen from stallions that are classified 'good' or 'poor' for freezing

Cryopreserved stallion sperm displays a high degree of male-to-male variability with respect to cell viability after thawing. Animals that have semen with low viability after cryopreservation are classified as 'poor' freezers, and when post-thaw viability is high they are designated as 'good' freezers. Cryoprotective agents that are used for cryopreserving stallion sperm include glycerol, ethylene glycol, methyl formamide, and dimethylformamide, and are typically used in concentrations ranging from 1% to 4%. The aim of this study was to evaluate the osmotic stresses that stallion sperm is exposed to during cryopreservation, and to determine if sperm from 'good' and 'poor' freezers show differences in osmotic tolerance limits and in the suitability of cryoprotective agents. Concentrations of 2-3% of the above mentioned cryoprotectants with freezing extender osmolalities ranging from 580 to 895 mOsm kg(-1) showed the highest motility rates after freeze-thaw, both for 'good' and 'poor' freezers, for all cryoprotectants tested with slightly higher values for glycerol. Freeze-thawed semen from 'poor' freezers was found to have a lower percentage of progressively motile sperm compared to that of 'good' freezers. Assessment of plasma and acrosomal membrane integrity after return to isosmotic conditions revealed that cryopreserved sperm from 'poor' freezers showed lower osmotic tolerance limits as compared to sperm from 'good' freezers. Semen from 'poor' freezers that was frozen using freezing extenders supplemented with more then 2% cryoprotectant showed decreased viability and increased acrosome reaction upon return to isoosmotic conditions, whereas 'good' freezers could withstand cryoprotectant concentrations up to 3% before a decline in viability was observed.     

Ionic regulation of the plasma membrane potential of rainbow trout (Salmo gairdneri) spermatozoa: role in the initiation of sperm motility

The ionic dependence of the trout sperm plasma membrane potential was analysed by measuring the accumulation of the lipophilic ions 3H-tetraphenylphosphonium (TPP) and 14C-thiocyanate (SCN) following dilution in artificial media isotonic to the seminal fluid. Our data showed that the trout sperm plasma membrane has a mixed conductance: the plasma membrane potential is sensitive upon the transmembrane gradients of K+, Na+, and H+. This potential is negative (less than -40 mV) in a 125 mM choline chloride media (ChM) at pH 8.5. Replacement of choline by sodium has a small depolarizing effect. The membrane potential is about -15 mV in a 125 mM potassium chloride and falls near zero mV only if valinomycin is added. In ChM changing the external pH (pHe) greatly affects the membrane potential: its value rises from less than -40 mV at pHe 9.0 to -17 mV at pHe 5.0. This pH effect is observed also in presence of sodium or potassium. A decrease in the transmembrane proton gradient produced by increasing internal pH without changing pHe induces also a depolarisation of the plasma membrane. In the different media in which trout sperm remain immotile after dilution (media with [K+] greater than 20-40 mM or a pH less than 7.5) the plasma membrane is more depolarized than in media allowing motility, suggesting a relationship between the state of membrane polarization and the intracellular effectors of the axonemal movement.     

Activation of K+ and Cl− channels in MDCK cells during volume regulation in hypotonic media

Single-channel patch-clamp experiments were performed on MDCK cells in order to characterize the ionic channels participating in regulatory volume decrease (RVD). Subconfluent layers of cultured cells were exposed to a hypotonic medium (150 mOsm), and the membrane currents at the single-channel level were measured in cell-attached experiments. The results indicate that MDCK cells respond to a hypotonic swelling by activating several different ionic conductances. In particular, a potassium and a chloride channel appeared in the recordings more frequently than other channels, and this allowed a more detailed study of their properties in the inside-out configuration of the patch-clamp technique. The potassium channel had a linear I/V curve with a unitary conductance of 24 +/- 4 pS in symmetrical K+ concentrations (145 mM). It was highly selective for K+ ions vs. Na+ ions: PNa/PK less than 0.04. The time course of its open probability (P0) showed that the cells responded to the hypotonic shock with a rapid activation of this channel. This state of high activity was maintained during the first minute of hypotonicity. The chloride channel participating in RVD was an outward-rectifying channel: outward slope conductance of 63.3 +/- 4.7 pS and inward slope conductance of 26.1 +/- 4.9 pS. It was permeable to both Cl- and NO3- and its maximal activation after the hypotonic shock was reached after several seconds (between 30 and 100 sec). The activity of this anionic channel did not depend on cytoplasmic calcium concentration. Quinine acted as a rapid blocker of both channels when applied to the cytoplasmic side of the membrane. In both cases, 1 mM quinine reversibly reduced single-channel current amplitudes by 20 to 30%. These results indicate that MDCK cells responded to a hypotonic swelling by an early activation of highly selective potassium conductances and a delayed activation of anionic conductances. These data are in good agreement with the changes of membrane potential measured during RVD.     

The effect of the osmolality of sugar-containing media,the type of sugar,and the mass and molar concentration of sugar on the survival of frozen-thawed mouse sperm

Several factors have contributed to problems in mouse sperm cryopreservation, and we and others have found ways to ameliorate them. These include high sensitivity to several types of mechanical stresses and to oxygen-derived free radicals, low tolerance to osmotic cell volume changes, and rather rigorous requirements for cooling and warming rates. Another important factor is the cryoprotective agent. Mouse sperm are unusual in that our best results have been obtained in media containing the nonpermeating sugar raffinose (18% w/v) and lacking glycerol. This paper deals with questions about the basis of the protective action of sugars, and whether raffinose is unusual or unique in its ability to confer protection. More specifically, we investigated whether protection was more related to the total osmolality of the freezing solution, to the mass concentration of sugar, or to the molarity of the sugar, and we looked to see whether there are effects attributable to specific sugars. To investigate these questions, mouse sperm were frozen at the optimal rate of 25 degrees C/min in solutions prepared with different proportions of three sugars-raffinose, sucrose, and glucose-dissolved in 1/4x PBS. In the first experimental series, the total osmolality and the total sugar molarity were varied from 400 to 700 mOsm and from 300 to 530 mM, respectively, while holding the mass concentration of sugar constant at 18% (w/v). In the second experimental series, the mass concentration of sugars was varied from 10 to 18% while the sugar molarity and solution osmolality remained constant at 300 mM and 420 mOsm, respectively. The results suggest that protection against freezing and thawing depends more on the mass concentration of the sugar than on its molar concentration, a conclusion that has mechanistic implications.     

Osmotic shock induces structural damage on equine spermatozoa plasmalemma and mitochondria

The present study aimed to elucidate the effects that osmotic shock exerts on equine spermatozoa. To achieve this goal, a retrospective study of the cellular volume of 40 equine ejaculates subjected to osmolarities ranging from 75 to 900 mOsm in Biggers-Whitten-Whittingham (BWW) media was performed using a Multisizer³ Coulter Counter®. The 300 mOsm BWW solution was used as control. The sperm volume ranged between 37.93 ± 0.6 (mean ± Standard Error of the Mean (SEM)) in 75 mOsm BWW to 21.61 ± 0.27 (mean ± SEM) for 900 mOsm BWW. Thus the spermatozoa behaved as linear osmometers when adjusted to the Boyle Van't Hoff equation (R² = 0.9808). After the different osmotic challenges, spermatozoa were returned to 300 mOsm BWW and the cellular volume was measured again. The results showed that the spermatozoa were able to retrieve the isosmolar volume (20.81 ± 0.34; mean ± SEM). Also, an ultrastructural study of spermatozoa membrane and mitochondria was accomplished using Transmission Electron Microscopy (TEM) after the osmotic challenges in 2 ejaculates. As observed by TEM, sperm plasmalemma swelled and detached from the sperm head in hypotonic conditions (75 mOsm), with blebbing on return to isosmolarity. When subjected to 900 mOsm, the sperm plasmalemma shrank, with disarrangement and blebbing when returned to isosmolarity. Mitochondria were also found to change their volume; the main pathologic change was irreversible vacuolization and changes in their arrangement for all the osmotic challenges tested. The present work leads to a better understanding of how osmotic shock adversely affects equine spermatozoa structure.     

Determination of boar spermatozoa water volume and osmotic response

Boar spermatozoa water volume and osmotic response were determined by a shapeindependent method for measuring cellular volume, electron paramagnetic resonance (EPR), employing the spin label, tempone, and the broadening agent, potassium chromium oxalate (CrOx). A water volume of 18.4 +/- 1.6 mum(3) (X +/- SD) was obtained for individual boar spermatozoa at 290 milliosmolar (mOsm) which, after correction for the presence of cytoplasmic droplets, yields a boar sperm water volume of 13.0 to 15.0 mum(3). Assuming 59% of the total cell volume is water, the total cell volume of boar spermatozoa is 22.0 to 25.4 mum(3). In addition, the experiment indicated that the relative water volume versus the reciprocal of the external osmolality (Boyle van't Hoff plot) was linear over the range of 210 to 1500 mOsm of sodium chloride (r(2) = 0.996), supporting the hypothesis that boar spermatozoa act as ideal osmometers. A non-zero y axis intercept of 0.23 from the Boyle van't Hoff plot indicated a 23% spin label accessible, but osmotically inactive water component.     

Ion channels activated by osmotic and mechanical stress in membranes of opossum kidney cells

Summary For patch-clamp measurements cultured kidney (OK) cells were exposed to osmotic and mechanical stress. Superfusion of a cell in whole cell configuration with hypotonic media (190 mOsm) evokes strong depolarization, which is reversible by returning to the isotonic bath medium. In the cell-attached configuration the exposure to hypotonic media evokes up to six ion channels of homogeneous single-channel properties in the membrane patch. Subsequently, the channels became activated after a time lag of a few seconds. At an applied membrane potential of 0 mV, the corresponding membrane current is directed inward and shows a transient behavior in the time range of minutes. In the same membrane patch these ion channels can be activated by application of negative hydrostatic pressure. The channel has a single-channel conductance of about 22 pS and is permeable to Na⁺ and K⁺ as well as to Cl^–. It is suggested that volume regulation involves mechanoreceptor-operated ion channels.     

Osmotic tolerance limits and effects of cryoprotectants on motility of bovine spermatozoa

This study was conducted to determine the osmotic properties of bull spermatozoa, including the effects of osmotic stress and cryoprotectant agent (CPA) addition and removal, on sperm motility. Semen from beef bulls was collected by electroejaculation and extended 1:3 in TL-Hepes containing 100 micro g/ml pyruvate and 6 mg/ml BSA. In solutions of 150-1200 mOsmolal (mOsm), bull spermatozoa behaved as linear osmometers (r(2) = 0.97) with an osmotically inactive cell volume of 61%. The isosmotic cell volume was 23.5 micro m(3). Motility was determined after exposure to anisosmotic solutions ranging from 35 to 2400 mOsm and after return to isosmotic conditions. Retention of at least 90% of isosmotic motility could be maintained only between 270-360 mOsm. Bull spermatozoa were calculated to retain 90% of their isosmotic motility at 92-103% of their isosmotic cell volume. Motility following a one-step addition and removal of 1 M glycerol, dimethyl sulfoxide, and ethylene glycol was reduced by 31%, 90%, and 6%, respectively, compared with CPA addition only. These data indicate that, during bull spermatozoa cryopreservation, osmotically driven cell volume excursions must be limited by exposure to a very narrow range that may be facilitated by the use of ethylene glycol as a CPA.     

Response of spermatozoa from the emu (Dromaius novaehollandiae) to rapid cooling, hyperosmotic conditions and dimethylacetamide (DMA)

Three experiments conducted to improve the survival of emu sperm during cryopreservation aimed to: (1) minimize chilling injury during the cooling phase; (2) determine the osmotic effects of dimethylacetamide (DMA), sucrose and trehalose; and (3) investigate the timing and nature of cryoprotectant toxicity. We measured sperm membrane integrity, motility, morphology and egg membrane penetration. In Experiment 1, semen diluted 1:1 with a pre-cooled diluent (5°C) prevented chilling injury. In Experiment 2, semen was diluted with DMA, trehalose or sucrose (300-2400mOsm/L) in deionized water. Only added DMA decreased the percentage of morphologically normal sperm. The percentage of motile sperm was higher with DMA than with the sugars, but membrane intact sperm were comparable amongst all cryoprotectants. As for the osmotic effects, the percentage of membrane intact sperm decreased with 2400mOsm/L and sperm motility decreased with 1200-2400mOsm/L, but sperm morphology was similar at all osmolarities. In Experiment 3, sperm membrane integrity, motility and morphology were comparable at all DMA osmolarities between sperm equilibrated for 0 and 15min, and remained unchanged after removal of DMA. We conclude that: (a) loss of sperm function during the cooling phase can be avoided by using a diluent maintained at 5°C; (b) emu spermatozoa tolerate upto 1400mOsm/L; (c) DMA results in a permanent change in sperm morphology when it is dissolved in deionized water, but does not alter sperm membrane integrity and motility; and (d) equilibration time of sperm with DMA can be less than 10min.     

Volume and pH regulation in agnathan erythrocytes: comparisons between the hagfish,Myxine glutinosa,and the lampreys,Petromyzon marinus and Lampetra fluviatilis

The responses of hagfish (Myxine glutinosa) and lamprey (Lampetra fluviatilis and Petromyzon marinus) erythrocytes to osmotic swelling in hypoosmotic medium and to acid-base disturbances induced by ammonium chloride prepulse were studied. The erythrocytes of hagfish regulated neither cell volume after osmotic swelling nor intracellular pH after acidification. In contrast, the erythrocytes of lamprey lost potassium and chloride after osmotic swelling, whereby their volume recovered. Furthermore, the red cell pH of lamprey recovered from experimental acidification in a nominally bicarbonate-free medium in the presence of sodium, confirming that the pathway involved is sodium/proton exchange.Abbreviation DMO 5,5-dimethyloxazolidine-2,4-dione     

Aquaporin3 is a sperm water channel essential for postcopulatory sperm osmoadaptation and migration

In the journey from the male to female reproductive tract, mammalian sperm experience a natural osmotic decrease (e.g., in mouse, from ~415 mOsm in the cauda epididymis to ~310 mOsm in the uterine cavity). Sperm have evolved to utilize this hypotonic exposure for motility activation, meanwhile efficiently silence the negative impact of hypotonic cell swelling. Previous physiological and pharmacological studies have shown that ion channel-controlled water influx/efflux is actively involved in the process of sperm volume regulation; however, no specific sperm proteins have been found responsible for this rapid osmoadaptation. Here, we report that aquaporin3 (AQP3) is a sperm water channel in mice and humans. Aqp3-deficient sperm show normal motility activation in response to hypotonicity but display increased vulnerability to hypotonic cell swelling, characterized by increased tail bending after entering uterus. The sperm defect is a result of impaired sperm volume regulation and progressive cell swelling in response to physiological hypotonic stress during male-female reproductive tract transition. Time-lapse imaging revealed that the cell volume expansion begins at cytoplasmic droplet, forcing the tail to angulate and form a hairpin-like structure due to mechanical membrane stretch. The tail deformation hampered sperm migration into oviduct, resulting in impaired fertilization and reduced male fertility. These data suggest AQP3 as an essential membrane pathway for sperm regulatory volume decrease (RVD) that balances the "trade-off" between sperm motility and cell swelling upon physiological hypotonicity, thereby optimizing postcopulatory sperm behavior.     

The macaque sperm actin cytoskeleton reorganizes in response to osmotic stress and contributes to morphological defects and decreased motility

Sperm undergo extreme variations in temperature and osmolality during cryopreservation, resulting in cell damage that includes plasma membrane defects, changes in cell volume, decreased motility, and flagellar defects. However, the fundamental biologic mechanisms underlying these events are poorly understood. We investigated the effects of osmotic stress and cytochalasins b (CB) and d (CD), naturally occurring toxins that disrupt actin organization, on the actin cytoskeleton and motility of Rhesus macaque sperm (Macaca mulatta). Sperm were diluted in media of low, medium, or high osmolality, or medium-osmolality media containing CB or CD, were stained with phalloidin-fluorescein isothiocyanate, and were processed for microscopy. The majority of sperm incubated in medium-osmolality media exhibited postacrosomal stain, whereas the minority displayed banding patterns of F-actin stain in the head. High-osmolality media, as well as CB and CD incubation, resulted in reorganization of F-actin into bands of stain in the majority of sperm heads. Cytochalasin b treatment also resulted in curled and looped tails, a phenomenon of hyposmotic stress, and CB and CD caused significant, dose-dependent decreases in motility determined by computer-assisted sperm assessment. Rho A cell populations were determined using flow cytometry, and immunocytochemistry analysis demonstrated that Rho A localization was altered after osmotic stress. Together, our results support a mechanism in which reorganization of the actin cytoskeleton induced by osmotic stress and potentially mediated by a Rho A signaling pathway contributes to sublethal sperm flagellar and motility defects.     

Ion Channels and Cancer

Membrane ion channels are essential for cell proliferation and appear to have a role in the development of cancer. This has initially been demonstrated for potassium channels and is meanwhile also suggested for other cation channels and Cl⁻ channels. For some of these channels, like voltage-gated ether à go-go and Ca²⁺-dependent potassium channels as well as calcium and chloride channels, a cell cycle-dependent function has been demonstrated. Along with other membrane conductances, these channels control the membrane voltage and Ca²⁺ signaling in proliferating cells. Homeostatic parameters, such as the intracellular ion concentration, cytosolic pH and cell volume, are also governed by the activity of ion channels. Thus it will be an essential task for future studies to unravel cell cycle-specific effects of ion channels and non-specific homeostatic functions. When studying the role of ion channels in cancer cells, it is indispensable to choose experimental conditions that come close to the in vivo situation. Thus, environmental parameters, such as low oxygen pressure, acidosis and exposure to serum proteins, have to be taken into account. In order to achieve clinical application, more studies on the original cancer tissue are required, and improved animal models. Finally, it will be essential to generate more potent and specific inhibitors of ion channels to overcome the shortcomings of some of the current approaches.     

Regulatory and necrotic volume increase in boar spermatozoa

Spermatozoa of many species initially respond to hypotonicity as perfect osmometers. Thereafter they undergo a regulatory process resulting in a decrease in cell volume, similar to that reported for somatic cells. Regulatory volume increase (RVI), a complementary process which is assumed to occur following initial shrinkage of sperm volume after exposure to a hypertonic medium, has not yet been described in detail for spermatozoa. In this study, we investigated whether spermatozoa are able to regulate their volume after hypertonic stress and whether this ability is maintained in preserved sperm. Cell volume changes were recorded using electronic cell sizing. Sperm response to the ion channels blockers quinidine, tamoxifen, and dydeoxyforskolin, and to protein kinase/phosphatase inhibitors lavendustin, staurosporine, and vanadate was studied to investigate possible mechanisms of RVI. Annexin V staining was used in combination with propidium iodide to determine whether hypertonic stress may induce apoptosis. Overall protein tyrosine phosphorylation under hypertonic conditions was measured via flow cytometry using antiphosphotyrosine antibody. Spermatozoa exposed to hypertonic stress initially responded with an abundant subpopulation according to the perfect osmometer model and recovered their volume from this shrinkage after 20 min. RVI was inhibited by quinidine and tamoxifen, which indicates the involvement of the important cellular ions sodium and chloride in this process. Volume regulatory ability was essentially maintained during storage of liquid semen. However, the response of the sperm population was heterogeneous. A second population raised, containing spermatozoa with larger volumes, which demonstrated irregularities in the volume response with respect to osmotic challenge, ion channel blockers, and storage. Under hypertonic conditions, both protein kinase inhibitors (PKI) led to increased isotonic volumes and to elevated initial relative volumes and subsequent volume decrease. RVI was inhibited by the vanadate. Hypertonic stress did not result in an increase in early apoptotic cells, but produced a shift toward late necrotic cells. Substitution of sodium and chloride by choline and sulfate resulted in decreased isotonic volume of sperm treated with lavendustin. Tyrosine phosphorylation levels were reduced after 20 min under hypertonic conditions. It was concluded that RVI is regulated via a protein tyrosine kinase-dependent pathway, and that dephosphorylation occurs when volume regulation is required. The necrotic volume increase (NVI) is associated with the accumulation of sodium and chloride following uncontrolled opening of the channels. The ability to regulate volume after exposure to hypertonic conditions is important for sperm functionality and can have practical applications in spermatological diagnostics and cryopreservation.     

Cytoplasmic ATP inhibition of CLC-1 is enhanced by low pH

The CLC-1 Cl(-) channel is abundantly expressed on the plasma membrane of muscle cells, and the membrane potential of muscle cells is largely controlled by the activity of this Cl(-) channel. Previous studies showed that low intracellular pH increases the overall open probability of recombinant CLC-1 channels in various expression systems. Low intracellular pH, however, is known to inhibit the Cl(-) conductance on the native muscle membrane, contradicting the findings from the recombinant CLC-1 channels in expressed systems. Here we show that in the presence of physiological concentrations of ATP, reduction of the intracellular pH indeed inhibits the expressed CLC-1, mostly by decreasing the open probability of the common gate of the channel.     

Impact of anisosmotic conditions on structural and functional integrity of cumulus-oocyte complexes at the germinal vesicle stage in the domestic cat

During cryopreservation, the immature oocyte is subjected to anisosmotic conditions potentially impairing subsequent nuclear and cytoplasmic maturation in vitro. In preparation for cryopreservation protocols and to characterize osmotic tolerance, cat cumulus-oocyte complexes (COC) at the germinal vesicle (GV) stage were exposed for 15 min to sucrose solutions ranging from 100 to 2,000 mOsm and then examined for structural integrity and developmental competence in vitro. Osmolarities > or =200 and < or =750 mOsm had no effect on incidence of oocyte nuclear maturation, fertilization success, and blastocyst formation compared to control COC (exposed to 290 mOsm). This relatively high osmotic tolerance of the immature cat oocyte appeared to arise from a remarkable stability of the GV chromatin structure as well as plasticity in mitochondrial distribution, membrane integrity, and ability to maintain cumulus-oocyte communications. Osmolarities <200 mOsm only damaged cumulus cell membrane integrity, which contributed to poor nuclear maturation but ultimately had no adverse effect on blastocyst formation in vitro. Osmolarities >750 mOsm compromised nuclear maturation and blastocyst formation in vitro via disruption of cumulus-oocyte communications, an effect that could be mitigated through 1,500 mOsm by adding cytochalasin B to the hyperosmotic solutions. These results (1) demonstrate, for the first time, the expansive osmotic tolerance of the immature cat oocyte, (2) characterize the fundamental role of cumulus-oocyte communications when tolerance limits are exceeded, and (3) reveal an interesting hyperosmotic tolerance of the immature oocyte that can be increased two-fold by supplementation with cytochalasin B.     

Osmotic tolerance and membrane permeability characteristics of rhesus monkey (Macaca mulatta) spermatozoa

Biophysical characteristics of the plasma membrane, such as osmotic sensitivity and water and cryoprotectant permeability are important determinants of the function of spermatozoa after cryopreservation. A series of experiments was conducted with rhesus macaque spermatozoa at 23 degrees C to determine their: (1) cell volume and osmotically inactive fraction of the cell volume; (2) permeability coefficients for water and the cryoprotectants dimethyl sulfoxide, glycerol, propylene glycol, and ethylene glycol; (3) tolerance to anisosmotic conditions; and (4) motility after a one step addition and removal of the four cryoprotectants. An electronic particle counter and computer aided semen analysis were used to determine the cell volume and permeability coefficients, and motility, respectively. Rhesus spermatozoa isosmotic cell volume was 27.7+/-3.0 microm3 (mean+/-SEM) with an osmotically inactive cell fraction of 51%. Hydraulic conductivity in the presence of dimethyl sulfoxide, glycerol, propylene glycol, and ethylene glycol was 1.09+/-0.30, 0.912+/-0.27, 1.53+/-0.53, and 1.94+/-0.47 microm/min/atm, respectively. Cryoprotectant permeability was 1.39+/-0.31, 2.21+/-0.32, 3.38+/-0.63, and 6.07+/-1.1 (x10(-3)cm/min), respectively. Rhesus sperm tolerated all hyposmotic exposures. However, greater than 70% motility loss was observed after exposure to solutions of 600 mOsm and higher. A one step addition and removal of all four cryoprotectants did not cause significant motility loss. These data suggest that rhesus sperm are tolerant to hyposmotic conditions, and ethylene glycol may be the most appropriate cryoprotectant for rhesus sperm cryopreservation, as it has the highest permeability coefficient of the tested cryoprotectants.