Maturation and fertilization of the sea urchin oocyte: An electrophysiological study

Some electrical properties of the sea urchin oocyte during germinal vesicle breakdown (GVBD) and fertilization have been studied using two intracellular electrodes. Oocytes with distinct germinal vesicles have resting potentials of −70 to −90 mV and the specific membrane resistance may range from 3 to 10 kΩ·cm 2 . Around rest the I–V relationship is concave toward the axis origin and the membrane is K + selective. A second electrical state, of lower potential and higher resistance, preexists in the membrane. Following GVBD, the K + -selective system is lost and the oocyte attains the characteristics of the second state with a resting potential of −10 to −50 mV and specific membrane resistance of 10–50 kΩ·cm 2 . At rest the I–V relationship tends to be convex toward the axis origin. The majority of sea urchin eggs (which have undergone GVBD and completed meiosis) have a resting state of −10 to −30 mV; 10–50 kΩ·cm 2 . The I–V relationship around rest is convex toward the axis origin and the resting potential is sensitive to changes of Na + , Cl − , and K + in the external medium. There is probably no major change in the electrical properties of the oocyte during the completion of meiosis. A small percentage of eggs from suboptimal animals have high resting potentials of −70 to −90 mV and specific membrane resistance of 5–50 kΩ·cm 2 . Such eggs have predominantly K + -selective membranes and we suggest that they are either underripe or aged. The first electrical event across the egg plasma membrane during fertilization is a step-like depolarization which occurs about 2 sec after the attachment of the fertilizing spermatozoon to the vitelline layer. There is no change—at the level of the light microscope—either in the egg surface or in the behavior of the spermatozoon until the second event, the fertilization potential (FP), is initiated 11 sec later. The cortical reaction occurs simultaneously with the FP and during the rising phase of the FP the spermatozoon stops gyrating around its point of attachment. Oocytes, which do not have cortical granules, upon insemination exhibit step events but no FP; in contrast artificially activated eggs, either spontaneous or induced by the ionophore A23187, give rise to only the FP. We suggest that the FP is the electrical result of the modification of the egg plasma membrane during cortical exocytosis.