Intracellular Ca2+ during fertilization and artificial activation in mouse oocytes.
Abstract
"AIM:
To study the mechanism of oocyte activation in mammals.
METHODS:
Mouse oocytes arrested at metaphase of the second meiotic division were loaded with Fura 2-AM and then activated with ethanol, calcimycin, electric pulse or fertilization. Intracellular free Ca2+ during activation were measured by Spex AR-CM-MIC cation system. Cortical granule exocytosis after activation was detected under electron microscopy.
RESULTS:
Sperm penetration initiated a long lasting Ca2+ oscillation in Ca2+ containing IVF medium in mouse ova. The Ca2+ oscillation lasted for over 3-4 h until the ova developed to pronuclear stage. The Ca2+ oscillated faster as extracellular Ca2+ concentration was increased from normal 1.7 mmol.L-1 to 5.0 mmol.L-1 and ceased to oscillate when extracellular Ca2+ was removed. The ova resumed Ca2+ oscillation after transferred back to IVF (Ca2+ 1.7 mmol.L-1). The ova which exhibited Ca2+ oscillation all extruded second polar body and formed pronuclei. Suppression the Ca2+ oscillation by intracellular injection of egtazic acid (2-10 pL, 200 mumol.L-1) blocked the activation of oocytes. Heparin (100 mumol.L-1) injection failed to prevent the Ca2+ oscillation. In artificial activation, ethanol, calcimycin, and a single electric pulse usually induced a monotonic Ca2+ rise and resulted in the activation only in older oocytes (> 18 h after CG injection). Activation of freshly ovulated oocytes required multiple intracellular Ca2+ increases induced by repetitive electric pulses. Artificial activation elicited the similar cortical granule exocytosis in oocytes as occurring at fertilization. Suppression of the intracellular Ca2+ elevation by introduction of egtazic acid into the oocytes blocked the activation process.
CONCLUSIONS:
The increase of intracellular free Ca2+ is the primary signal responsible for the initiation of oocyte activation but there are distinct differences between fertilization and artificial activation both in Ca2+ change patterns and Ca2+ sources. Young oocytes require oscillatory Ca2+ signals for activation.
"
Keywords:
To study the mechanism of oocyte activation in mammals.
METHODS:
Mouse oocytes arrested at metaphase of the second meiotic division were loaded with Fura 2-AM and then activated with ethanol, calcimycin, electric pulse or fertilization. Intracellular free Ca2+ during activation were measured by Spex AR-CM-MIC cation system. Cortical granule exocytosis after activation was detected under electron microscopy.
RESULTS:
Sperm penetration initiated a long lasting Ca2+ oscillation in Ca2+ containing IVF medium in mouse ova. The Ca2+ oscillation lasted for over 3-4 h until the ova developed to pronuclear stage. The Ca2+ oscillated faster as extracellular Ca2+ concentration was increased from normal 1.7 mmol.L-1 to 5.0 mmol.L-1 and ceased to oscillate when extracellular Ca2+ was removed. The ova resumed Ca2+ oscillation after transferred back to IVF (Ca2+ 1.7 mmol.L-1). The ova which exhibited Ca2+ oscillation all extruded second polar body and formed pronuclei. Suppression the Ca2+ oscillation by intracellular injection of egtazic acid (2-10 pL, 200 mumol.L-1) blocked the activation of oocytes. Heparin (100 mumol.L-1) injection failed to prevent the Ca2+ oscillation. In artificial activation, ethanol, calcimycin, and a single electric pulse usually induced a monotonic Ca2+ rise and resulted in the activation only in older oocytes (> 18 h after CG injection). Activation of freshly ovulated oocytes required multiple intracellular Ca2+ increases induced by repetitive electric pulses. Artificial activation elicited the similar cortical granule exocytosis in oocytes as occurring at fertilization. Suppression of the intracellular Ca2+ elevation by introduction of egtazic acid into the oocytes blocked the activation process.
CONCLUSIONS:
The increase of intracellular free Ca2+ is the primary signal responsible for the initiation of oocyte activation but there are distinct differences between fertilization and artificial activation both in Ca2+ change patterns and Ca2+ sources. Young oocytes require oscillatory Ca2+ signals for activation.
"