Reproductive biotechnology such as in vitro fertilization, the creation of transgenic animals or cloning by nuclear transfer depends on the use of fully grown, meiotically competent oocytes capable of completing meiotic maturation by reaching the stage of metaphase II. However, there exists only a limited quantity of these oocytes in the ovaries of females. In view of their limited number, growing oocytes without meiotic competence represent a possible source. The mechanisms controlling the acquisition of meiotic competence, however, are still not completely clear. A gas with a short half-life, nitric oxide (NO), produced by NO-synthase (NOS) enzyme can fulfill a regulatory role in this period. The objective of this study was to ascertain the role of NO in the growth phase of pig oocytes and its influence on the acquisition of meiotic competence with the help of NOS inhibitors, NO donors and their combinations. We demonstrated that the selective competitive iNOS inhibitor aminoguanidine and also the non-selective NOS inhibitor l-NAME block meiotic maturation of oocytes with partial or even full meiotic competence at the very beginning. NOS inhibitors influence even competent oocytes in the first stage of meiotic metaphase. However, blockage is less effective than at the beginning of meiotic maturation. The number of parthenogenetically activated competent oocytes greatly increased in a pure medium after inhibitor reversion. A large quantity of NO externally added to the in vitro cultivation environment disrupts the viability of oocytes. The effectiveness of the inhibitor can be reversed in oocytes by an NO donor in a very low concentration. However, the donor is not capable of pushing the oocytes farther than beyond the first stage of meiotic metaphase. The experiments confirmed the connection of NO with the growth period and the acquisition of meiotic competence. However, it is evident from the experiments that NO is not the only stimulus controlling the growth period.

In fully grown pig oocytes, meiotic maturation in vitro is retarded by inhibition of histone deacetylases by trichostatin A (TSA). In growing oocytes with partial meiotic competence, culture with TSA has no significant effect on the meiotic maturation. Growing oocytes treated with TSA mature mainly to metaphase I. The ratio of oocytes that mature to metaphase II is very limited. After transient exposure to TSA, the maturation of growing oocytes with partial meiotic competence takes a different course. When these oocytes are first cultured in a TSA-free medium, then cultured for another 24 h with 100 nM TSA and finally again in a TSA-free medium for 24 h, the ratio of oocytes that mature to metaphase II significantly increases reaching 59%. When oocytes were cultured for the same length of time without transient exposure to TSA, only 19% matured to metaphase II. Those oocytes that matured to metaphase II after transient exposure to TSA were successfully activated using calcium ionophore. However, the subsequent cleavage was very limited. We can conclude that transient exposure of growing pig oocytes with partial meiotic competence to TSA increases oocyte meiotic competence, but it does not enhance developmental competence after parthenogenetic activation.

We have used the whole-cell recording technique to compare three stages of primary and secondary oocytes from F1 hybrid mice (C57BL/6J x SJL/J):neonatal germinal vesicle (NGV) stage primary oocytes from 10- to 20-day-old, prepubescent mice; mature germinal vesicle (MGV) stage primary oocytes from 12-week-old, post-pubescent, superovulated mice; first polar body (FPB) stage secondary oocytes from 12-week-old, post-pubescent mice during the normal oestrus cycle or following superovulation. NGV, MGV and FPB oocytes all exhibit two voltage-dependent currents: an inward, rapidly activating/inactivating current, and an outward, slowly activating/non-inactivating current. In 1.5 mmol/1 external Ca the average peak inward current is − 2.9, − 12.4 and − 13.8 μA/cm2 in NGV, MGV and FPB oocytes, respectively. In 20 mmol/1 Ca these currents increase and the reversal potential shifts to the right. The outward current decreases slightly with growth and development: at 40 mV test potentials, NGV oocytes have average outward currents of 8.9 μA/cm2, and MGV and FPB oocytes have currents of 5.0 and 5.5 μA/cm2, respectively. Thus, MGV oocytes express FPB current patterns. The reversal potentials, kinetics and pharmacology of the currents indicate that Ca channels carry the inward current and K channels carry the outward current. During growth in vivo a gradual depolarisation accompanies maturation. Resting potentialsranged from − 45 to − 30 mV in NGV oocytes to − 35 to − 17 mV in MGV oocytes to − 20 mV to − 3 mV in FPB oocytes. These data suggest that a selective increase occurs in the number of Ca channels during oocyte growth. This increase precedes nuclear maturation and coincides with the acquisition of meiotic competence.

Meiotic maturation of mammalian oocytes is under the control of cell cycle molecules Cdc2 kinase and MAP kinase (mitogen-activated protein kinase). In the present study, we investigated the relationship between the ability to activate Cdc2 kinase and MAP kinase and the acquisition of meiotic competence during pig oocyte growth. Growing and fully grown pig oocytes were collected from four groups of antral follicles of various diameters (A, 0.5-0.7 mm; B, 1.0-1.5 mm; C, 2.0-2.5 mm; D, 4.0-6.0 mm) and cultured in vitro. Fully grown oocytes from class D follicles, which have full competence to mature to metaphase II, had the ability to activate both Cdc2 kinase and MAP kinase. In contrast, growing oocytes from class A follicles, which have limited competence to resume meiosis, had no such ability. Cyclin B1 molecules did accumulate, however, with phosphorylated 35 and 36 kDa bands of p34cdc2 appearing in the cultured oocytes. Of the growing oocytes from class B follicles, 60% resumed meiosis but arrested at metaphase I. Some of the oocytes in this class were capable of activating Cdc2 kinase, although they did not appear to have established a MAP kinase-activating pathway or the ability to activate MEK. These results suggest that limited meiotic competence in growing oocytes from class A follicles is due to their inability to activate Cdc2 kinase and their incomplete MEK-MAP-kinase pathway, although the oocytes are capable of accumulating cyclin B1 molecules. During the final growth phase, pig oocytes acquire the ability to activate Cdc2 kinase and then establish the MEK-MAP-kinase pathway for full meiotic competence.