Prediction of porcine blastocyst formation using morphological, kinetic, and amino acid depletion and appearance criteria determined during the early cleavage of in vitro-produced embryos.

The determination for early cleavage-stage embryos of noninvasive morphologic and metabolic criteria that are predictive of blastocyst development and/or full-term viability remains an important research target. We describe the derivation of a logistic regression model that predicts the probability of porcine blastocyst formation in vitro. Pig zygotes, derived by in vitro maturation and fertilization of slaughterhouse oocytes, were cultured in NCSU-23 medium that was supplemented with a mixture of 20 amino acids (NCSU-23(aa)). On Day 1, at 21, 23, 25, 27, 29 and 31 h postinsemination, cleaving embryos were evaluated morphologically in terms of the: i) number of blastomeres, ii) evenness of division, and iii) degree of fragmentation. These embryos were then placed in 1.5-microl drops of NCSU-23(aa) for 24 h, after which time the three morphologic criteria were re-evaluated and 1.2 microl of spent medium were removed for analysis by HPLC, in order to determine the net rates of amino acid depletion and appearance. Embryos were then cultured singly in NCSU-23(aa) by placing them between the filaments of a woven polyester mesh until Day 6, in order to permit the identification of individual embryos. Of 256 cleaved embryos, 28.7 +/- 6.2% (n = 5 replicates) developed into blastocysts. Discriminant analysis was used to select a subset of amino acids (threonine, valine, lysine, and phenylalanine) that discriminated optimally between embryos that became blastocysts or degenerated. These discriminant scores were entered into the logistic regression. Significant univariate relationships were established between the probability of blastocyst development and amino acid score (odds ratio [OR] 0.53, 95% confidence interval [CI] 0.40-0.69, P < 0.001), cleavage time (OR 0.79, 95% CI 0.71-0.87, P < 0.001), degree of fragmentation on Day 1 (OR 0.55, 95% CI 0.35-0.84, P = 0.009) and Day 2 (OR 0.53, 95% CI 0.35-0.78, P = 0.002), evenness of division on Day 2 (OR 0.66, 95% CI 0.46-0.96, P = 0.028), and categorical values of blastomere number on Day 2 (all P < 0.02), although no single variate could accurately predict blastocyst formation. However, multivariate analysis of the cell numbers on Day 1 and Day 2 correctly classified 51.9% of the predicted blastocysts. The inclusion of cleavage time in the regression analysis raised this rate to 63.5%, which was increased to 66.2% by the addition of evenness of division and degree of fragmentation. Finally, the full logistic regression model, which incorporated amino acid score together with all the other morphologic and kinetic variables, correctly classified 80.8% of the predicted blastocysts. This represented 51.2% of the observed blastocysts. Our data are novel in that they not only define in a quantitative manner the influence of previously undescribed predictors of porcine blastocyst formation, but they also provide a simple model of preimplantation development with reasonable predictive accuracy. The present study also provides a basic model for the examination and incorporation of additional early morphologic and metabolic correlates of developmental competence and could potentially be applied to the selection of human embryos for transfer in clinical IVF.

Amino acid depletion and appearance during porcine preimplantation embryo development in vitro.

Preimplantation embryos can consume and produce amino acids in a manner dependent upon the stage of development that may be predictive of subsequent viability. In order to examine these relationships in the pig, patterns of net depletion and appearance of amino acids by in vitro produced porcine preimplantation embryos were examined. Cumulus oocyte complexes derived from slaughterhouse pre-pubertal pig ovaries were matured for 40 h in defined TCM-199 medium (containing PVA) before being fertilised (Day 0) with frozen-thawed semen in Tris-based medium. After 6 h, presumptive zygotes were denuded and cultured in groups of 20, in NCSU-23 medium modified to contain 0.1 mM glutamine plus a mixture of 19 amino acids (aa) at low concentrations (0.02-0.11 mM) (NCSU-23(aa)). Groups of 2-20 embryos were removed (dependent on stage) on Day 0 (1 cell), Day 1 (two- and four-cells), Day 4 (compact morulae) and Day 6 (blastocysts) and placed in 4 mul NCSU-23aa for 24 h. After incubation, the embryos were removed and the spent media was analysed by HPLC. The net rate of amino acid depletion or appearance varied according to amino acid (P < 0.001) and, apart from serine and histidine, stage of development (P < 0.014). Glycine, isoleucine, valine, phenylalanine, tryptophan, methionine, asparagine, lysine, glutamate and aspartate consistently appeared, whereas threonine, glutamine and arginine were consistently depleted. Five types of stage-dependent trends could be observed: Type I: amino acids having high rates of net appearance on Day 0 that reached a nadir on Day 1 or 4 but subsequently increased by Day 6 (glycine, glutamate); Type II: those that exhibited lower rates of net appearance on Days 0 and 6 compared with the intermediate Days 1 and 4 (isoleucine, valine, phenylalanine, methionine, arginine); Type III: amino acids which showed a continuous fall in net appearance (asparagine, aspartate); Type IV: those that exhibited a steady fall in net depletion from Day 0 to Day 6 (glutamine, threonine); Type V: those following no discernable trend. Analysis of further embryo types indicated that presumptive polyspermic embryos on Day 0 had increased (P < 0.05) net rates of leucine, isoleucine, valine and glutamate appearance, and reduced (P < 0.05) net rates of threonine and glutamine depletion compared with normally inseminated oocytes. These data suggest that the net rates of depletion and uptake of amino acids by pig embryos vary between a) amino acids, b) the day of embryo development and, c) the type of embryos present at a given stage of development. The results also suggested that the net depletion and appearance rates of amino acids by early pig embryos might be more similar to those of the human than those of the mouse and cow.

The effect of oxygen tension on porcine embryonic development is dependent on embryo type.

Reducing oxygen concentration from atmospheric levels during in vitro culture generally, but not invariably, improves embryonic development across a range of species. Since the few published reports of such an action in the pig are contradictory--perhaps a consequence of the derivation of the embryos prior to culture--a study was performed to examine the effect of O2 tension during culture on three different types of porcine embryos, namely: in vivo flushed embryos, and in vitro matured oocytes either fertilized in vitro or parthenogenetically activated. In vivo embryos (n=208) were flushed at the 2-8 cell stage. Cumulus oocyte complexes (COCs) destined for IVF or parthenogenetic activation were derived from 2 to 6 mm, post-pubertal ovarian follicles and matured for 48 h in TCM-199. Parthenogenones were generated by activating denuded oocytes (n=573) with 10 mM calcium ionophore, followed by 2 mM DMAP prior to culture. The IVF embryos (n=971) were produced by fertilizing COCs (day 0) with fresh ejaculated semen in modified tris-based medium for 6 h before cumulus removal. All embryos were cultured in BECM-3 containing 12 mg/mL fatty-acid-free BSA up to day 4, followed by BECM-3 supplemented with 10% calf serum until day 7. The gas environment for IVM/IVF was 5% CO2 in air, while that for IVC was either 5% CO2 in air or 5% O2, 5% CO2 and 90% N2. Low O2 tension increased both day 7 blastocyst rates (high versus low O2, respectively; 9.3+/-2.9%: 26/280; 23.9+/-4.2%: 71/293; P<0.001) and total cell numbers (39.3+/-2.9, n=24 versus 61.2+/-7.7, n=61; P=0.01) of parthenogenetically activated embryos. In contrast, such a treatment neither affected blastocyst rates (89.3+/-6.9 versus 87.8+/-7.5) nor cell numbers (87.4+/-4.5 versus 87.7+/-4.8) of in vivo flushed embryos. The effect of reduced O2 concentration on IVF embryos was intermediate, since only cell numbers were improved (69.8+/-3.5, range=17-204, n=49; 88.5+/-5.8, range=28-216; n=66; P<0.01), equivalent to that recorded in in vivo flushed embryos. However, blastocyst rates were unaffected (10.7+/-1.4%: 51/486; 12.9+/-2.2%: 67/485). The effect, when present, of reducing O2 concentration from 20 to 5% was beneficial for pig in vitro embryonic development. The responses are apparently dependent on firstly, the manner by which the embryonic cell cycle is activated and secondly, the derivation of the tissue prior to placement into culture, if the observed resilience of in vivo embryos is independent of treatment duration.

Numerical chromosome errors in day 7 somatic nuclear transfer bovine blastocysts.

Day 7 bovine somatic nuclear transfer (NT) embryos reconstructed from granulosa cells were examined for numerical chromosome aberrations as a potential cause of the high embryonic and fetal loss observed in such embryos after transfer. The NT embryos were reconstructed using a zona-free manipulation method: half-cytoplasts were made from zona-free oocytes by bisection, after which two half-oocytes and one granulosa cell (serum-starved primary culture) were fused together and activated. The NT embryos were cultured in modified synthetic oviductal fluid containing essential and nonessential amino acids, myoinositol, sodium citrate, and 5% cattle serum in microwells for 7 days, at which time nuclei from all blastocysts were extracted and chromosome aberrations were evaluated using dual-color fluorescent in situ hybridization with bovine chromosome 6- and 7-specific probes. Five embryo clone families, consisting of 112 blastocysts reconstructed from five different primary granulosa cell cultures, were examined. Overall, the mean chromosome complement within embryos was 86.9 +/- 3.7% (mean +/- SEM) diploid, 2.6 +/- 0.5% triploid, 10.0 +/- 3.1% tetraploid, and 0.5 +/- 0.2% pentaploid or greater; the vast majority (>75%) of the abnormal nuclei were tetraploid. Completely diploid and mixoploid embryos represented 22.1 +/- 4.5% and 73.7 +/- 5.5%, respectively, of all clones. Six totally polyploid blastocysts, containing or=5N chromosome complements, respectively) between two clone families were different (P < 0.01), as were blastocyst yields between other clone families (P < 0.01). Blastocyst yield was not correlated to % total ploidy error between clone families, but an inverse relationship (P < 0.01) between blastocyst total cell number and total % chromosome abnormality was observed within embryos. Categorization of the blastocysts into three quality grades (good, medium, and poor) and comparison of the distribution of ploidies when classified into 0%, 0.1-5.0%, 5.1-10.0%, 10.1-15.0%, and 15.1-100% errors within embryos indicated that medium- and poor-grade embryos were different (P < 0.05) from good-quality, in vitro-produced embryos. In a separate study, 11 different granulosa cell cultures (that did not correspond to those used for NT) were evaluated and found to possess only 0.23 +/- 0.12% ploidy errors. These results demonstrate that 1) the percentage of ploidy errors in bovine NT blastocysts is inversely related to total blastocyst cell number, 2) the mixoploid condition is representative of the majority of embryos, 3) 100% polyploid NT blastocysts can exist, and 4) the ploidy errors seem not to be derived from the donor cells.