In an effort to investigate the nature of the cellular injury caused when mammalian spermatozoa are cooled prior to cryopreservation, the occurrence of thermal phase transitions amongs the lipid components of the sperm plasma membrane was investigated by the use of freeze-fracture electron microscopy. The mechanisms by which glycerol and egg yolk exert protective effects during semen cooling and freezing were also examined. Ram and blackbuck spermatozoa, maintained at 30 degrees C prior to fixation at this temperature, exhibited randomly distributed intramembranous particles over the acrosomal, postacrosomal, and flagellar regions of the plasma membrane. In contrast, spermatozoa fixed at 5 degrees C after slow cooling to this temperature exhibited particle clustering over the postacrosomal region of the head as well as over the tail. These effects were not influenced by the presence of egg yolk or glycerol during the cooling procedure, although these substances protected the spermatozoa against loss of motility. Particle clustering over the sperm tail, induced by the slow cooling process, was found to be only partially reversible. The extensive areas of particle-free lipid, noted to result from the cooling procedure, were absent if the spermatozoa were rewarmed to 30 degrees C; however, the original distribution of particles was not restored and numerous small particle-free domains persisted. It is proposed that this type of irreversible change within the sperm plasma membrane may contribute to the loss of motility and fertility suffered by spermatozoa after cooling and freezing. Furthermore, it is suggested that protective substances such as egg yolk may exert their effects by countering these deleterious changes, rather than by preventing their occurrence.
The objective of this investigation was to examine the nature of freeze/thaw-induced plasma membrane damage in an effort to validate hypotheses about cryoinjury in ram spermatozoa. Spermatozoa were loaded with fluorescein diacetate (FDA), a marker for plasma membrane integrity, and cooled (15 degrees C/min) to temperatures between -10 degrees C and -30 degrees C on a cryomicroscope stage. Post-thaw fluorescence intensity measurements of individual cells indicated that freezing to temperatures between -10 degrees C and -15 degrees C did not induce significant membrane permeabilization. However, freezing below -15 degrees C was followed by membrane permeabilization immediately after thawing. A majority (> 60%) of flagellar plasma membranes of cells frozen to -10 degrees C remained ultrastructurally intact during thawing; principal-piece membranes were more robust than middle piece membranes (p = 0.001). Significant middle-piece membrane breakage was, however, induced as the post-thaw temperature increased from +10 degrees C to +30 degrees C (10 degrees C, 64 +/- 12.3% intact membranes [mean +/- SEM]; 30 degrees C, 43 +/- 12.5% intact membranes [mean +/- SEM]; p = 0.0085). Cells frozen to -30 degrees C did not exhibit this thawing effect, although the distinction between middle-piece and principal-piece plasma membranes was evident (p = 0.002). All sperm head plasma membranes were damaged by freezing and thawing to any combination of temperatures. Although acrosomes became swollen after freezing and thawing, the incidence of outer acrosomal membrane vesiculation remained at control (unfrozen) levels with all treatments used. Experimental exposure to the hyperosmotic conditions generated during freezing induced little flagellar membrane permeabilization, but significant damage was caused by restoration of osmotic equilibrium. It is suggested that membranes are initially destabilized during the freezing process, both by low temperature effects and by exposure to high salt concentrations. The resultant post-thaw degeneration of the plasma membrane is caused by a combination of temperature and osmotic effects.
A steady-state fluorescence polarization technique, using the membrane probe 1,6-diphenyl-1,3,5-hexatriene (DPH), showed that separately detectable transitions occurred in the regions of 17, 26 and 36 degrees C in isolated preparations of ram sperm plasma membrane. An independent technique based on the temperature-related behaviour of calcium- and magnesium-activated ATPase detected a single phase transition in the region of 24 degrees C. Modulation of ATPase by neighbouring lipid composition was inferred from findings that phospholipase A2 caused significant stimulation of the enzyme. Cholesterol-rich liposomes caused an upward shift of the phase-transition temperature from 24 degrees C to 30 degrees C, but the reasons for this are unclear. It is considered that these phase transitions may have profound effects on sperm survival and physiology, both during normal fertilization processes and in response to cryostorage.
Cryoinjury in ram sperm was investigated by direct observation, using cryomicroscopy, to validate model hypotheses of freezing injury in such a specialized cell. Fluorescein diacetate was used to determine when during the freeze-thaw cycle the sperm membrane became permeable. In noncryoprotected sperm plasma membrane, integrity was maintained throughout the cooling and freezing process, but fluorescein leakage occurred during rewarming. The temperature of post-thaw permeabilization varied in relation to the minimum temperature reached during freezing; cells cooled to -10 degrees C retained fluorescence into the post-thaw temperature range of 9-24 degrees C (mean +/- SEM; 13.25 +/- 0.91 degrees C), whereas cells cooled to -20 degrees C lost fluorescence shortly after thawing (mean +/- SEM; 2.62 +/- 0.91 degrees C). Sperm cooled to 5 degrees C, but not frozen, retained fluorescence during rewarming up to 20-30 degrees C. The inclusion of glycerol and egg yolk in the freezing medium significantly and independently increased the post-thaw permeabilization temperature. Maintenance of fluorescence was also correlated with ability to resume motility after thawing. Sperm reactivation experiments were undertaken to examine deleterious effects of freezing upon the flagellar microtubular assembly. No direct evidence for such effects was obtained. Instead, a highly significant correlation between minimum freezing temperature and post-thaw temperature of initial reactivation was detected.
The effects of controlled stress, i.e. cooling, upon the distribution of actin in ram spermatozoa were examined to investigate the hypothesis that cytoskeletal proteins are involved in the maintenance of sperm plasma membrane integrity. The normal distribution of actin on the spermatozoon was initially determined. A monoclonal antibody (IgM) interacted exclusively with the post-acrosomal region and the principal piece of the flagellum. By the use of a polyclonal antibody, actin was detected on the acrosome (excluding the equatorial segment), the post-acrosomal region and the whole of the flagellum. The actin was present in its non-filamentous form. Spermatozoa fixed at 39 degrees C and then treated for the immunofluorescent detection of actin with the monoclonal antibody were mostly unstained (proportion stained = 4.4% (+/- 1.6; s.e.m.); n = 8 ejaculates). Provided spermatozoa were permeabilized by greater than 0.025% Triton X-100 before immunofluorescence, actin was localized in the postacrosomal region of all sperm heads, and to a minor extent on the principal piece of the flagellum. Use of the polyclonal antibody confirmed that the post-acrosomal antigen was unmasked by detergent treatment. Slow cooling, over 2-h periods to various temperatures between 5 and 15 degrees C, also induced an increase in the proportion of cells showing post-acrosomal actin immunoreactivity. Cooling through the temperature range 15 to 10 degrees C markedly increased the proportion of immunoreactive cells (mean +/- s.e.m.; 12 +/- 4.5% at 15 degrees C; 27 +/- 4.5% at 10 degrees C; n = 4 ejaculates). Further cooling to 5 degrees C failed to elicit increased staining. Ultrastructural examination of cooled spermatozoa confirmed that a subpopulation of spermatozoa exhibited post-acrosomal actin immunoreactivity after cooling. These results are compatible with the suggestion that actin fulfills a stabilizing function in spermatozoa.
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