~~We describe two methods for detecting acrosome reactions of human sperm at the light microscopic level. The techniques include the use of a supravital stain to detect dead sperm in order to differentiate between "physiological" and "degenerative" acrosome reactions. Sperm are incubated with the supravital stain Hoechst 33258 (a fluorescent DNA-binding dye with limited membrane permeability), washed, suspended in 95% ethanol for fixation and permeabilization, and dried onto slides. The sperm are then labeled either by indirect immunofluorescence using rabbit anti-human sperm antiserum or with fluoresceinated Pisum sutivum agglutinin (PSA). Both probes intensely label the acrosomal region of acrosome-intact sperm. Electron microscopy revealed the major site of PSA binding to be the acrosomal contents. Acrosome-reacted sperm have diminished acrosomal labeling by both probes; sperm with nuclei labeled by Hoechst stain are considered nonviable, and are excluded from the assay. Both assays are rapid, give similar results, and detect an increase in acrosome reactions following exposure to the ionophore A23 187.
A full understanding of the acrosome reaction is central to understanding sperm function. Acrosomal status can be determined on living, motile sperm in only a few mammalian species. For other species, many light microscopic methods have been developed, including colored stains for bright-field microscopy, and probes for fluorescence microscopy. We review the existing methods and the criteria that should be considered in the choice of an assay.
Ejaculated mammalian sperm must complete a final maturation, termed capacitation, before they can undergo acrosomal exocytosis and fertilize an egg. In human sperm, loss of sperm sterol is an obligatory, early event in capacitation. How sterol loss leads to acrosomal responsiveness is unknown. These experiments tested the hypothesis that loss of sperm sterol affects the organization of cold detergent-resistant membrane microdomains (lipid "rafts"). The GPI-linked protein CD59, the ganglioside GM1, and the protein flotillin-2 were used as markers for lipid rafts. In uncapacitated sperm, 51% of the CD59, 41% of the GM1, and 90% of the flotillin-2 were found in the raft fraction. During capacitation, sperm lost 67% of their 3beta-hydroxysterols, and the percentages of CD59 and GM1 in the raft fraction decreased to 34% and 31%, respectively. The distribution of flotillin-2 did not change. Preventing a net loss of sperm sterol prevented the loss of CD59 and GM1 from the raft fraction. Fluorescence microscopy showed CD59 and GM1 to be distributed over the entire sperm surface. Flotillin-2 was located mainly in the posterior head and midpiece. Patching using bivalent antibodies indicated that little of the GM1 and CD59 was stably associated in the same membrane rafts. Likewise, GM1 and flotillin-2 were not associated in the same membrane rafts. In summary, lipid rafts of heterogeneous composition were identified in human sperm and the two raft components, GM1 and CD59, showed a partial sterol loss-dependent shift to the nonraft domain during capacitation.
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