Evaluation of developmental competence, nuclear and ooplasmic maturation of calf oocytes.

In this study we evaluated nuclear and ooplasmic maturation of prepuberal calf oocytes to determine a possible cause for their low developmental competency. Calf oocytes resumed meiosis and arrested at the MII stage at rates similar to that of adult animals; however, zygotes derived from calf oocytes cleaved and developed at significantly lower rates. Ooplasmic maturation was assessed during oocyte maturation and fertilization. Transmission electron microscopy revealed that a majority of calf oocytes exhibited some delay in organelle migration and redistribution following maturation. Immunofluorescence microscopy showed that following IVF, a higher percentage of calf oocytes had abnormal chromatin and microtubule configurations than those of adult cattle. These anomalies were characterized by delayed formation of sperm aster and asynchronous pronuclear formation. Microfluorometry was used to characterize the Ca2+ responses of calf oocytes to the addition of agonists or after IVF. The addition of thimerosal demonstrated the presence of Ca2+ stores in calf oocytes. Injection of near threshold concentrations of inositol 1,4,5-trisphosphate (InsP3), used to test the sensitivity of the InsP3R, released significantly less Ca2+ in calf than in cow oocytes, whereas higher concentrations of InsP3 (500 microM) released maximal [Ca2+]i in both oocytes. These results suggested that the Ca2+ content of intracellular stores was similar, but the sensitivity of the InsP3R may be different. Following insemination, calf oocytes exhibiting [Ca2+]i oscillations displayed comparable amplitude and intervals to cow oocytes; however, a significantly higher number of fertilized calf oocytes failed to show oscillations. Our findings suggest that the low developmental competence of calf oocytes can be attributed, at least in part, to incomplete or delayed ooplasmic maturation.

Patterns of intracellular Ca2+ concentrations in fertilized bovine eggs.

Sperm-induced calcium (Ca2+) changes were examined in zona pellucida-intact, mature bovine eggs injected with the fluorescent Ca2+ indicator fura-2 dextran (fura-2 D). Fifty four percent (37/68) of the dye-injected, inseminated bovine eggs were fertilized and 43% (16/37) of the fertilized eggs exhibited Ca2+ elevations during the time of measurement. All (16/16) of the eggs with Ca2+ elevations were fertilized but none of the unfertilized eggs (0/31) showed intracellular Ca2+ elevations. Six of 13 eggs that were later examined and found to be fertilized at the time of the Ca2+ recordings did not show sperm-induced Ca2+ elevations. Fifty percent (8/16) of the eggs with Ca2+ elevations exhibited a single Ca2+ rise as a response to sperm penetration during the 60-min period in which these eggs were monitored. Twelve percent (2/16) of the eggs responded with two Ca2+ elevations spaced by 50- and 51-min intervals and 38% (6/16) of the eggs exhibited multiple elevations with intervals of 15-29 min. In the latter group, one egg was polyspermic. The mean amplitude of the sperm-induced Ca2+ elevations was 564 +/- 58 nM. Eggs with single elevations reached higher peak concentrations than eggs with multiple elevations (p < 0.05). The mean duration of the Ca2+ elevations was 166 +/- 13 sec and was similar among eggs with different Ca2+ patterns. The first elevations detected occurred at a mean of 6.6 +/- 0.5 h after insemination. Fertilization in this study was confirmed by looking at pronuclear formation 16 h post-insemination or by DNA staining immediately after the fluorescence readings. Eggs exhibiting Ca2+ elevations ranged in stage of fertilization from just penetrated to pronuclear. Injection of inositol 1,4,5 trisphosphate (5 microM in the injection pipette) into 6 bovine eggs induced an immediate Ca2+ elevation with a mean peak Ca2+ value of 700 +/- 60 nM and a mean duration of 103 +/- 21 sec. Incubation of bovine eggs with 200 microM thimerosal induced periodic Ca2+ rises. The mean number of Ca2+ elevations observed in 35 min of recordings was 3.0 +/- 0.5 (n = 9, range 1-5). The mean peak Ca2+ value of the first thimerosal-induced Ca2+ elevation was 990 +/- 210 nM. The results of this study indicate that fertilization can evoke intracellular Ca2+ elevations in bovine eggs and that the periodicity of these Ca2+ elevations is different among eggs. Furthermore, both inositol 1,4,5-trisphosphate and thimerosal were able to induce intracellular Ca2+ release in bovine eggs.

Influence of cell cycle stage of the donor nucleus on development of nuclear transplant rabbit embryos.

We evaluated the influence of the stage of the cell cycle of the donor nucleus on development in vitro of nuclear transplant rabbit embryos. The developmental potential of nuclei in early, mid-, and late stages of the cell cycle was determined. Duration of the G1 phase in early embryos was determined, and a procedure for reversibly synchronizing donor embryos in the G1 phase was developed. In addition, the extent of development in vitro of nuclear transplant embryos with donor nuclei synchronized in the G1 phase was evaluated. Development to blastocysts was greatly affected by the stage of the cycle of the donor nucleus. Use of early-stage nuclei led to 59% nuclear transplant blastocysts, whereas 32% and 3% were obtained with mid- and late-stage nuclear donors, respectively (p less than 0.001). The short duration of the G1 phase in 16- and 32-cell-stage embryos (approximately 30 min) necessitated a procedure for synchronizing blastomeres in the G1 phase. This entailed, first, a 10-h incubation in 0.5 micrograms/ml colcemid to arrest embryos in metaphase. After release from colcemid, embryos were allowed to cleave in 0.1 microgram/ml of the DNA synthesis inhibitor, aphidicolin, and remained blocked at the G1/S transition. This treatment was reversible, as assessed by the resumption of DNA synthesis, cleavage rate, and development to blastocysts of treated embryos. The beneficial effect of using early-stage donor blastomeres was confirmed by the enhanced rate of development of manipulated embryos to blastocysts with donor nuclei in the G1 phase (71%), as opposed to the late S phase (15%, p less than 0.001).(ABSTRACT TRUNCATED AT 250 WORDS)

Electrical activation of mouse oocytes.

Activation of the oocyte is the least efficient step in nuclear transplantation in the rabbit. We report the influence of age of oocytes, field strength, pulse duration and number, and shape of field on the rate of activation of mouse oocytes by electrical pulses. Regardless of oocyte age, activation rates were similar over a wide range of field strengths and pulse durations. Aged oocytes activated at a higher rate than recently ovulated oocytes (32 vs 3%), which lysed more frequently (13 vs 2%). Fragmentation rate was also higher among aged oocytes (42 vs 6%). The rate of activation increased with the number of pulses, from 9% with a single pulse, to 61% with six pulses. It also increased with the interval between pulses. Comparison of activation chamber geometries showed that the rate of activation was higher in a nonuniform field than in a uniform field and, for a particular field strength, varied from one electrode gap to another. These observations indicate that the rate of activation can be greatly increased by multiple electrical pulses. The activation rate also varied with consistent field strength in chambers with different electrode configurations.