Fertilization and early embryology: Intracytoplasmic sperm injection for Rhesus monkey fertilization results in unusual chromatin, cytoskeletal, and membrane events, but eventually leads to pronuclear development and sperm aster assembly

The disassembly and reorganization of sperm-derived structures are landmarks for the onset of embryonic development. Since complete information on these events is not yet available, we examined the disassembly of the sperm axoneme, the formation of the sperm aster, and the decondensation and development of the male and female pronuclei in inseminated Rhesus monkey oocytes conceived by in-vitro fertilization (IVF) or by intracytoplasmic sperm injection. During IVF, the spermatozoa lose their acrosomes after contacting the zona pellucida, and the plasma membrane and nuclear envelope disappear after fusion with the oolemma. Subsequently, a sperm aster of microtubules forms around the proximal centriole, which is bound to the sperm connecting piece. This process is then followed by the formation of both pronuclei, which single sperm centriole later duplicates and the bipolar mitotic apparatus is observed. Following sperm injection, the spermatozoa have both an intact plasma membrane and acrosome. Although the microtubules form the sperm aster in a fashion identical to that seen during IVF, the presence of an intact acrosome appears to be associated with a heterogeneity in the decondensation of sperm chromatin. While this may indicate an abnormal pattern of chromatin decondensation during the formation of the male pronucleus following sperm injection, the male pronucleus eventually fully decondenses, as during IVF. Sperm mitochondria are displaced as the sperm centriole is exposed. Annulate lamellae and a previously undescribed organelle which seems to contain annulate lamellae precursors, as well as maternal mitochondria, are found in association with the developing pronuclear envelopes. This information increases understanding of fertilization in primates, and may also be of significance for use in assisted human reproduction as well as in the preservation of endangered mammalian species. In addition, these results demonstrates the similarities between fertilization in Rhesus monkeys and humans, providing additional evidence for the use of this non-human primate as a model system in which to investigate the cellular and molecular biological basis of human reproduction.