1 Biologie de la reproduction, CECOS and 2 Biochimie, CHU Hôtel-Dieu, Clermont-Ferrand, France
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Abstract |
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Key words: cryoresistance/fluidity/fluorescence anisotropy/membrane/spermatozoa
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Introduction |
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Structural and functional loss of plasma membrane integrity resulting from freezing and thawing have been well documented from ultrastructural studies (Barthelemy et al., 1990; De Leeuw et al., 1990
; Holt et al., 1992
). Membranes are destabilized by the passage to and from the storage temperature (thermal stress), the large volume changes associated with water and cryoprotectant movement and the exposure to high salt concentrations (osmotic stress). At a molecular level, changes in membrane organization such as modifications of specific lipidprotein interaction, phospholipid asymmetry and lipid composition are thought to be implicated in the loss of permeability (Mazur, 1984
; Hinkovska-Galcheva et al., 1989
; Parks and Graham, 1992
). The reversibility of these changes could be dependent on membrane dynamics and the physical properties of the membranes has been assumed to be one of the pivotal factors in the resistance of spermatozoa to freezing (Watson and Morris, 1987
; Quinn, 1989
; Hammerstedt et al., 1990
). However, this concept has never been directly tested for human spermatozoa. Determination of lipid fluidity has been shown to be a submacroscopic approach to the physical and dynamic state of the sperm membrane (Shinitzky and Yuli, 1982
). To test the hypothesis that sperm membrane fluidity reflects the physiological status of the membrane and is relevant to sperm ability to be restored after freeze-induced stress, we studied sperm membrane fluidity on normal ejaculates before and after cryopreservation and examined whether the tolerance of human spermatozoa to the freezing/thawing process could be predicted from the fluidity assessment of fresh semen.
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Materials and methods |
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Cryopreservation
As previously described (Grizard et al., 1999), semen was diluted with an equal volume of cryoprotective medium (glycerol 14%,v/v; sodium chloride 30 mmol/l; glycine 133 mmol/l; sodium citrate 40 mmol/l; glucose 69 mmol/l; antibiotics; pH = 7.4; osmolality = 430 mosm). Addition of the medium was carried out gradually (1 ml/min) with care to avoid osmotic shock to spermatozoa. Samples were maintained for 15 min at room temperature for equilibration and sealed in 0.25 ml straws. Straws were frozen in a Minicool LC40 (Air Liquide Santé, France) following a standard freezing protocol (from 20°C to 4°C at a rate of 5°C/min, from 4°C to 30°C at 10°C/min and from 30°C to 140°C at 20°C/min). Straws were then transferred to liquid nitrogen for storage. Straws were thawed at 37°C for 5 min for estimation of sperm concentration, motility and viability.
Assessment of sperm viability and motility
The following analyses were performed on both fresh and frozenthawed spermatozoa from each patient. Motility was assessed at 37°C and scored under light microscopy. Spermatozoa were classified as progressive, non-progressive or immotile spermatozoa. Viability was assessed using eosinnigrosin test. Unstained (intact) and red coloured (with damaged membranes) spermatozoa were counted using nigrosin as a counterstain. Sperm viability was defined as the percentage of intact cells. The cryosurvival rates regarding the proportion of motile or viable spermatozoa that survived freezing were calculated from the respective formulae:
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Fluidity assessment
Aliquots of fresh spermatozoa (200300 µl) or frozen/thawed material (250 µl) were washed in 5 ml Earle's medium supplemented with 0.3% BSA (bovine serum albumin) and centrifuged 10 min at 1800 g. The washed spermatozoa were suspended at a concentration of 1x106 spermatozoa/ml in 3 ml of PBS (phosphate buffered saline) with 1,6-diphenyl-1,3,5-hexatriene (DPH, 106 mol/l prepared from a DPH stock solution of 2x103 mmol/l in tetrahydrofuran) (Giraud et al., 1999). The suspension was incubated for 30 min at room temperature. The molar ratio of DPH to phospholipid was lower than 1:2000 in order to minimize probeprobe interaction and probe-induced perturbation of the lipid bilayer. The molar ratio of DPH to phospholipid was calculated from the known content of phospholipids in human spermatozoa. Sperm suspensions containing no DPH (blanks) were similarly assessed to check light scattering. The sample was excited with vertically polarized light (365 nm) and emission (430 nm) was measured through polarizer both parallel and perpendicular to the excitation polarizer. The parallel (I//) and perpendicular (I
) fluorescence intensities were recorded at 37°C after careful temperature equilibration. The anisotropy rf was calculated:
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The anisotropy refers to the rotational motion of the DPH distributed throughout the hydrophobic core of the lipid bilayers and is inversely proportional to the membrane fluidity; therefore, the lower the rf is, the more fluid is the membrane.
Statistical analysis
Results are presented as individual data or mean ± SEM. Wilcoxon rank test was used to compare the fresh and post-thaw values. Relationships between anisotropy and sperm parameters or cryosurvival rates were analysed using Spearman's rank correlation analysis. Results were considered significant when P < 0.05.
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Results |
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To investigate whether the cryotolerance could be explained by the membrane anisotropy, we determined the correlation coefficient l between fresh anisotropy and the cryosurvival rates. Both the proportion of motile spermatozoa and the proportion of viable spermatozoa recovered after thawing were significantly correlated with the anisotropy of fresh spermatozoa (l = 0.455, P < 0.05 and l = 0.512, P < 0.05 respectively) indicating that improved recovery of viable or motile spermatozoa was related to lower initial fluidity (Figure 2A and B).
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Discussion |
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The literature regarding the fluidity of mammalian sperm membrane is species specific and often indirectly assessed by lipid compositional data (reviewed by Ladha, 1998). Our observations indicate that variability of the average sperm fluidity existed between patients. Neither the sperm characteristics of fresh ejaculate nor those of thawed samples were significantly correlated with the sperm respective anisotropy except for the progressive motility of fresh spermatozoa and post-thaw viability. As far as the progressive motility is considered, our results agree well with others (Haidl and Opper, 1997), suggesting that membrane fluidity is implicated in the acquisition of progressive motility during epididymal maturation of human spermatozoa.
Cryopreservation processes result in a loss of membrane fluidity. The steady-state fluorescence polarization approach that we used provides information on the rotational motion of lipids in sperm membranous structures at the submacroscopic level. James et al. (1999) have also reported at the single molecule level that lipid diffusion in the membrane plane is reduced in thawed spermatozoa even when the cells survive freezing apparently undamaged. A possible explanation of the rigidifying effect could be the presence of glycerol molecules remaining within the lipid bilayer after washing. Glycerol is known to have a direct effect on the plasma membrane and to alter its fluidity by increasing the order of the fatty acid (Boggs and Rangaraj, 1985; Hammerstedt et al., 1990
). Therefore, it is not clear whether the cryoprotectants per se are having a direct effect or whether the changes are caused by low temperature, or both.
The increased anisotropy observed in frozenthawed spermatozoa was related to the loss of post-thaw membrane integrity. The great range of quality in frozenthawed spermatozoa allows a statistically significant correlation to be detected between the anisotropy and the percentage of viable spermatozoa. Alternatively, taking into account the additivity of the measured anisotropy, the lack of correlation in fresh spermatozoa may result from the large percentage of intact cells overwhelming the contributions from impaired cells.
The dye exclusion test that we used to determine the viability is related to the permeability of membrane, and our results suggest that loss of permeability induced by freeze/thaw is characterized by a decrease in the membrane fluidity. Moreover, Ladha et al. (1997) demonstrated that permeabilized ram spermatozoa presented a large immobile phase over the whole plasma membrane. This rigidification was irreversible. It is important to emphasize that membrane functions are dependent on an optimal fluidity. Change in the dynamic of the membrane would probably alter its barrier function.
The current study suggests that the adaptability of the membrane to damaging effects of the freeze/thaw process is markedly superior for spermatozoa with a high membrane fluidity. Attempts have been made to relate the membrane composition and its underlying physical structure to propensity for survival after a freeze/thaw cycle. Membrane lipid composition is commonly used to indicate change in membrane fluidity as the latter feature is modulated by the cholesterol level, degree of unsaturation of the phospholipid acyl chain, phospholipid composition and membrane protein. Greater resistance of mammalian spermatozoa to cold shock has been noted for species in which the cholesterol to phospholipid molar ratio and the degree of saturated fatty acids in the phospholipid fraction were high (Darin-Bennett and White, 1977; Watson and Morris, 1987
). This comparison of species enabled the formation of two groups: the first one included bull, ram and boar spermatozoa and the second one included rabbit, dog, human spermatozoa, the spermatozoa of the former group being much more cryo-sensitive than the latter (White, 1993
). In terms of dynamics, a marked increase in the two chemical indices of fluidity, i.e. cholesterol/phospholipid and saturated/unsaturated molar ratios, indicates a significant decrease in fluidity of plasma membrane measured at physiological temperature. Therefore, it is conceivable that the first group of species mentioned above will have more fluid sperm membranes than the second one. Likewise, the study of Hinkovka et al. (1993) showed a greater rigidity of the rabbit spermatozoa compared to bull spermatozoa. However, this relationship is subject to controversy. It does not extend to rooster spermatozoa which are highly resistant to cold shock but have a lower sterol content and a greater overall fluidity compared to mammalian spermatozoa as demonstrated by Parks and Lynch (1992). Furthermore, in the current analysis we found a clear correlation between membrane fluidity and cryotolerance in human spermatozoa. Our results are in agreement with the general concept that cold tolerance is associated with membrane fluidity. This relationship was first demonstrated by Sinensky (1974) and then established for various organisms (Cossins and Raynard, 1987
). The adaptation of cells to low environmental temperature results from a `fluidification' of their plasma membrane. Steponkus and Lynch (1989) demonstrated that these membrane changes induced by cold acclimatization increased their cryostability. Moreover, as well as thermal stress affecting the lipid structure of spermatozoa, osmotic stress following cell dehydratation is an important factor involved in the freeze/thaw-induced destabilization of sperm membranes (Gao et al., 1993
; Curry and Watson, 1994
). Rigidification of membrane has been shown to increase the fragility in response to osmotic stress, as demonstrated with erythrocytes (McGown et al., 1982
).
In conclusion, our data provide further support for the view that sperm plasma membrane is a key organelle in controlling sperm cryosurvival. The capacity of human spermatozoa to withstand cryopreservation depends in part on their membrane fluidity. In-vitro manipulation of membrane fluidity may open novel approaches to cryopreservation processes. It will be interesting in future studies to investigate the effects of membrane-fluidizing agents on human sperm cryotolerance and fertilizing capacity.
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Acknowledgments |
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Notes |
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References |
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Submitted on February 15, 2000; accepted on June 20, 2000.