189 CHARACTERIZATION OF THE FIRST SPERM-INDUCED CALCIUM TRANSIENT IN PIG OOCYTES

Abstract

Fertilization in mammals is associated with repetitive elevations in the oocytes’ intracellular free calcium concentration. The elevations are triggered by the fertilizing sperm and are responsible for stimulating embryo development. In mouse oocytes, the sperm-induced calcium signal starts with a calcium rise that is larger and longer in duration than any succeeding transients. It also has unique characteristics: it begins with a rapid increase for 2–3 s followed by a shoulder, which is an inflection point that represents a brief decline in the rise of calcium levels. Once calcium level reaches its maximum, it decreases but remains elevated for several minutes while it is superimposed by several smaller calcium spikes. In bovine oocytes the situation is somewhat different. In this species, the first sperm-induced calcium transient is larger than the additional spikes but it lacks the sustained elevation phase and is not superimposed by small calcium rises. In the present study our purpose was to characterise the first sperm-induced calcium transient in pig oocytes. Oocytes were obtained from ovaries of prepubertal gilts collected at an abattoir and matured in vitro for 44 h. Mature oocytes were loaded with the calcium indicator dye fura-2; subsequently, they were either IVF or used for intracytoplasmic sperm injection (ICSI). Changes in their intracellular free calcium concentration were then immediately monitored using InCyt Im2, a dual-wavelength fluorescence imaging system. Characteristics of the first transients (including amplitude and duration) were compared to those of the additional ones using Student’s t-test. We found that in oocytes that underwent IVF (n = 11), the oscillations started 83.4 ± 23.2 min after adding the sperm to the oocytes. In the ICSI group (n = 10 oocytes) the calcium oscillations started sooner, 27.1 ± 17.7 min after injection. The average peak amplitude and the mean interval between the calcium transients varied among individual oocytes, but no significant differences were found between the IVF and ICSI groups (which on average were fluorescence ratio of 2.6 ± 1.1 and 23.5 ± 11.4 min, respectively; P > 0.1). The oscillation patterns showed slight differences between individual oocytes in terms of spike frequency, which has been described before and may be due to variations in the amount of sperm-derived activating factor present in the ooplasm. Most importantly, in all oocytes measured, the initial calcium spike showed no differences when compared to subsequent calcium transients: its amplitude and duration was similar to the additional transients. This points at potential species-specific differences in the regulation of calcium signalling in oocytes and provides essential information for the better understanding of the fertilization process.

This work was supported by Agriculture and Food Research Initiative Competitive Grant 2011–67015–30006 from the USDA National Institute of Food and Agriculture.