Can animal performance be predicted from short-term grazing processes?

Despite all the biotic and abiotic factors affecting foraging by ruminants, there is a common and fundamental process, which is bite gathering. We hypothesised that because the mechanics of bite formation dominate the foraging process, changes in short-term bite mass are reflected in longer-term animal performance across a wide range of sward conditions. We focus at the meal level of foraging, using experiments in which the effect of abiotic factors and digestive constrains are minimised, making intake rate the main currency. We estimated bite mass across a wide range of structural challenges to large-herbivore foraging in a long-term experiment with heterogeneous native grasslands. A conceptual model was developed for average daily gain, where energy gain and energy costs were proximate causal variables. Energy gain was a function of diet quality and components of daily intake rate, where bite mass was the main component estimated. In turn, components of intake rate were determined by sward structure and bodyweight. Energy costs were a function of bodyweight and abiotic conditions. Finally, sward structure, bodyweight and abiotic conditions were determined by experimental treatments, seasons and years. Then, the conceptual model was translated into statistical models that included variables measured or estimated, and coefficients representing all links in the conceptual model. Weight gain was a function of bite mass, forage characteristics, and animal and abiotic conditions. Models were set up to test whether forage and stocking conditions affected monthly gain beyond the effects through bite mass, after correcting for abiotic factors. Forage mass, height and disappearance did help predict monthly gain after bite mass was included in the model, which supported our hypothesis. However, stocking treatments and season had significant effects not incorporated in bite mass. Although the model explained 77.9% of liveweight gain variation, only 35.2% was due to fixed effects, with 10.8% accounted by bite mass and its interactions. Concomitant experiments showed that sward structure (first with sward height and the second with tussock cover) does determine bite mass and short-term intake rate in the complex native grasslands we studied. Yet, other temporal varying components of monthly gain not correlated with bite mass, temperature or wind, added most of the observed variation in monthly animal performance. Part of the model failure to account for variation in performance may be related to a significant and temporally variable grazing of tussocks. We used a bite mass model that assumed no tussock grazing. In light of these results and a parallel experiment, we conclude that tussock grazing must be incorporated in future versions of the model.

Intracytoplasmic sperm injection improves in vitro embryo production from poor quality bovine oocytes

The objective was to use subzonal sperm injection (SUZI) to understand sperm penetration patterns and to use intracytoplasmic sperm injection (ICSI) to improve production of bovine embryos using poor quality gametes. In experiment 1, poor versus good quality oocytes were fertilized with sperm from two bulls, A and B, with poor and good sperm vigor, respectively. The blastocyst rate was higher for good versus poor quality oocytes (23.3% vs. 11.1%, P < 0.05), regardless of the bull used. There was no significant difference in blastocyst rate for bull A (low vigor) regardless of oocyte quality, and for bull B (high vigor), blastocyst rate was better for good versus poor quality oocytes (25.7% vs. 9.2%, P < 0.05). In experiment 2, poor quality oocytes were subjected to SUZI. The oocyte penetration rate was lower for bull A than for bull B (29.6% vs. 53.8%, P < 0.05), when SUZI was performed within 1 hour after sperm processing. However, when SUZI was performed 2 to 3 hours after sperm processing, penetrating capacity was similar between bulls, but for bull B, penetrating capacity significantly decreased after 3 hours of sperm processing. In an attempt to overcome sperm penetrating disorders, poor and good quality oocytes were subjected to ICSI (experiment 3). Irrespective of the bull or of the oocyte quality grade, there were no differences in cleavage or blastocyst rates. Both bulls had distinct IVF embryo production rates, which we inferred were because of particular individual sperm characteristics. In conclusion, ICSI was an effective means to achieve in vitro production of bovine embryos with gametes of variable quality.

55 EFFECT OF FUSION-ACTIVATION INTERVAL AND EMBRYO AGGREGATION ON IN VITRO AND IN VIVO DEVELOPMENT OF CLONED BOVINE EMBRYOS PRODUCED BY HANDMADE CLONING

Despite the apparent success of cloning by somatic cell nuclear transfer (SCNT), the efficiency in development to term remains low, with a high rate of losses occurring throughout pregnancy due to faulty reprogramming and conceptus abnormalities. As the ideal fusion-activation interval for optimal nuclear reprogramming after cloning is still ill-defined, the aim of this study was to determine the effect of 2 distinct fusion-activation intervals and embryo aggregation on in vitro development of cloned bovine embryos. Bovine COCs from slaughterhouse ovaries were used after IVM for the production of cloned embryos by handmade cloning, according to our established procedures (Ribeiro et al. 2009 Cloning Stem Cells, in press). Following cumulus and zona removal, oocytes were manually bisected, with hemi-cytoplasts selected by DNA staining. Two hemi-cytoplasts and an adult skin somatic cell were attached and fused with a 15V AC pre-pulse for 5 s, followed by a double 1.2 kV cm-1 DC pulse for 20 μs. Reconstructed embryos were activated in ionomycin exactly at 2 or 4 h post-fusion (2 hpf or 4 hpf), followed by an incubation in 6-DMAP for 4 h. Cloned embryos from both fusion-activation intervals were in vitro-cultured in the well of the well (WOW) system for 7 days, allocating one (1 × 100%) or two (2 × 100%) cloned embryos per WOW. Grade 1 Day-7 blastocysts were transferred to synchronous recipients. Cleavage (Day 2) and blastocyst (Day 7) rates, on a per WOW basis, and pregnancy (Days 30 and 150) rates were compared using the chi-square or the Fisher test, with results from 9 replications summarized in Table 1. Increasing the fusion-activation interval to 4 h decreased cleavage but not blastocyst rates in 1 × 100% embryos. Also, blastocyst rates were lower in 1 × 100% embryos activated 2 h post-fusion. In general, cleavage and blastocysts rates for 2 × 100% embryos (91.5 and 46.0%) were higher than for 1 × 100% embryo counterparts (74.4 and 31.3%), respectively, regardless of the activation time. In addition, blastocyst rates for 4 hpf-activated embryos (50.3%), based on cleavage, were higher than for 2 hpf-activated embryos (38.3%), irrespective of the aggregation scheme. Nonetheless, despite differences in in vitro development, pregnancy rates and conceptus development in the first half of pregnancy were similar between groups. A longer fusion-activation interval (4 hpf) or embryo aggregation (2 × 100%) increased blastocyst yield but did not improve in vivo development and pregnancy maintenance following the transfer to female recipients in cattle. Table 1.In vitro and in vivo development of cloned bovine embryos This study was supported by FAPESP and CAPES, Brazil.

72 PREGNANCY OUTCOME AFTER OVIDUCTAL TRANSFER OF ZONA-FREE 1-CELL-STAGE PORCINE EMBRYOS PRODUCED BY HANDMADE CLONING

The pig is an important animal model for the study of human diseases. An important step for better use of this species in biomedical research is to obtain genetically identical individuals by procedures such as somatic cell nuclear transfer (SCNT). As the in vitro culture environment is usually sub-optimal for embryo development, the oviductal transfer of cloned embryos at the 1-cell stage may be more efficient for the establishment of pregnancies. However, the transfer at such an early stage usually requires the presence of zona pellucida or agar embedding to protect embryos from the recipient’s immune system (Loi et al. 1999 Livest. Prod. Sci. 60, 281-294). This study aimed to evaluate the developmental viability of 1-cell-stage porcine handmade cloned embryos directly transferred to the oviduct of female recipients without the zona pellucida or agar embedding. After 40 h of IVM in TCM-199 +10% follicular fluid, COCs obtained from sows were denuded, selected for the presence of a polar body (459/689), and submitted to a 0.2% pronase solution in 25% fetal bovine serum (FBS) for partial zona removal, followed by rinses in manipulation medium and pure FBS. Subsequent to oocyte splitting by manual bisection in a 5 μg mL-1 cytochalasin B solution (CCB), hemi-oocytes (87.1%) were screened under fluorescent microscopy using Hoechst 33 342 stain, resulting in 57.6% enucleated halves (461/800). A somatic cell culture established from a fetal clone pig biopsy (Adam et al. 2007 Oncogene 26, 1038-1045) at passage 4 was used for embryo reconstruction, which was done in a 0.05% phytohemagglutinin (PHA) solution, by sticking 2 cytoplasts and a somatic cell in a linear orientation. Reconstructed couplets, rinsed in calcium- and magnesium-free fusion medium, were electrofused in a fusion chamber after exposure to a 30-V AC pulse for 20 s for alignment, followed by two 24-μs-long DC fusion pulses of 1.3 kV cm-1. Fused couplets (154/214) were exposed for 10 min to a solution containing 5 μg mL-1 CCB and 10 μg mL-1 cycloheximide, followed by electrical activation (two 24-μs-long DC pulses of 0.9 kV cm-1) in fusion medium containing calcium and magnesium. Activated embryos were cultured in vitro for 12 h in 500 μL of PZM-3 medium in the well of the well (WOW) system, in a plastic bag filled with gas mixture (90% N2, 5% O2, 5% CO2), at 38.5°C. Then, a total of 70 and 80 non-agar-embedded, zona-free 1-cell-stage cloned porcine embryos were transferred directly to the oviducts of a sow and a gilt, respectively, both synchronous at approximately 12 h before ovulation. The recipient sow was diagnosed pregnant by ultrasonography on Day 66 of gestation. Although the sow was diagnosed open on Day 72, this study demonstrates that the transfer of 1-cell-stage zona-free embryos directly to the oviduct of a synchronous sow can result in pregnancy.

101 EFFECT OF NITROCOOLER NEGATIVE PRESSURE AND RECOVERY INTERVAL ON CRYOTOLERANCE OF BOVINE IN VITRO-PRODUCED EMBRYOS

Exposing bovine embryos and porcine oocytes to hydrostatic pressure has been shown to increase cryosurvival, possibly by a resulting expression of stress tolerance proteins. This study aimed to evaluate the effect of the negative pressure stress condition (a 5-min-long embryo exposure to a negative pressure) and the interval between vacuum exposure and vitrification (40 min or 2 h) on survival of bovine in vitro-produced (IVP) embryos. The negative pressure was achieved with the same apparatus used previously for the cryopreservation of embryos (Nitrocooler; Mezzalira et al. 2009 Reprod. Fert. Dev. (1) 134), in which a negative pressure (vacuum) is applied to liquid nitrogen to increase the cooling rate through the slush phenomenon, except that in this study, the vacuum was applied to the chamber without liquid nitrogen, at room temperature. Grades 1 and 2 bovine IVP expanded blastocysts were allocated to 1 of 5 experimental groups: embryos in vitro-cultured as fresh (control) or after vitrification (Vitri); and embryos subjected to the negative pressure for 5 min and then in vitro-cultured as fresh (NP-fresh) or after vitrification performed 40 min (NP-Vitri-40 min) or 2 h (NP-Vitri-2h) following the vacuum exposure. Embryos were vitrified in pulled glass micropipettes in a solution with 20% ethylene glycol + 20% dimethylsulfoxide + 20% fetal bovine serum and rewarmed in decreasing sucrose concentrations (Mezzalira et al. 1999 Acta Scientiae Veterinariae 27 262-262). In vitro culture was carried out in all treatments for 72 h for the assessment of re-expansion and hatching rates (Table 1), which were analyzed by the chi-square test, for P < 0.05. No differences in re-expansion rates were observed between groups. However, the vitrification of embryos after 2 h of exposure to a 5-min-long negative pressure (NP-Vitri-2h) improved embryo survival expressed by a higher hatching rate than for embryos vitrified without vacuum exposure (Vitri) or after 40 min following the 5-min-long exposure to vacuum. In addition, hatching rates in group NP-Vitri-2h were similar to those for fresh embryos (control and NP-fresh). Our results indicated that a short exposure of embryos to a negative pressure can improve cryotolerance following vitrification, which is dependent on the time interval between NP exposure and cryopreservation. Bovine IVP embryos should be allowed to recover for at least 2 h after NP exposure before the increase in cryotolerance is achieved. Table 1.Effect of negative pressure on re-expansion and hatching rates of fresh and vitrified

54 IN VITRO DEVELOPMENT OF BOVINE CLONED EMBRYOS PRODUCED BY HANDMADE CLONING FROM DISTINCT CELL CULTURE CONFLUENCES AND AGGREGATION SCHEMES

The coordination of the cell cycle of the donor nucleus and the recipient cytoplasm is thought to be one of the major essential factors needed for successful development of cloned embryos and offspring from somatic cell populations. Cell cycle synchronization protocols used for somatic cell nuclear transfer (SCNT) vary in preference among groups, with the confluence inhibition by contact appearing to be one of the most widely used methods today. However, the relationship between the level of cell confluence in a culture dish at or near the plateau phase of growth and blastocyst yield following cloning by SCNT still needs to be better characterized. The aim of this study was to examine the effect of 3 distinct cell culture confluences before nuclear transfer and embryo aggregation on in vitro development of clone bovine embryos. In vitro-matured bovine COC were used for the production of clone embryos by handmade cloning, according to our established procedures (Ribeiro et al. 2009 Cloning Stem Cells 11). Oocytes were manually bisected following cumulus and zona removal. After selection of hemi-cytoplasts by DNA staining, 1 (50%) or 2 (100%) enucleated hemi-cytoplasts were paired with an adult Nelore skin somatic cell and then electrofused (15 V AC pre-pulse for 5 s, followed by a double 1.2 kV cm-1 DC pulse for 20 μs). Cells were selected from 1 out of 3 distinct culture confluences: (1) 70 to 80%; (2) 80 to 90%; and (3) >90%; assessed by morphological evaluation before the SCNT procedure. Reconstructed clone embryos and groups of zona-intact oocytes (parthenote controls) were activated in ionomycin and 6-DMAP. Clone embryos (100%) and hemi-embryos (50%) reconstructed from the 3 groups underwent IVC in the well of the well (WOW) system for 7 days, allocating 1 embryo (1 × 100%) or aggregating two hemi-embryos (2 × 50%) per WOW. After 11 replications, cleavage (Day 2) and blastocyst (Day 7) rates, on a per WOW basis, were compared using the chi-square test. Results are summarized in Table 1. Cleavage rates were similar for all groups. The aggregation scheme did not appear to have influenced, either positively or negatively, the developmental outcome to the blastocyst stage. However, blastocyst rates increased nonlinearly (7.0, 17.5, and 29.4%) with the increase in cell confluence. A highly confluent cell culture has already been shown to have a greater proportion of cells in G0/G1 than cycling cells at the log phase (>91% v. 59%; Sun et al. 2008 Zygote 16, 111-116). However, blastocyst development in this study was lower than anticipated for cells in the early plateau phase (70 to 80%), when predicting such development based on the expected G0/G1 proportion in that cell population. Table 1.In vitro development of bovine cloned embryos from distinct cell culture confluences and aggregation scheme This study was supported by FAPESP and CAPES/Brazil.

69 EFFECTS OF CELL TYPE, PRE-ACTIVATION PROTOCOL, AND CULTURE CONDITIONS ON DEVELOPMENT OF PORCINE HANDMADE CLONED EMBRYOS

Despite the rather successful and widespread use of cloning in various species, distinct cell types from the same species and even the same genotype display differences in blastocyst yield. Moreover, variations in the protocol for embryo production can influence development to the blastocyst stage and subsequent fetal development. The aim of this study was to evaluate the effect of 2 cell types and 2 embryo pre-activation protocols with or without the presence of FCS in the in vitro culture medium on development of handmade pig cloned embryos to the blastocyst stage. Cumulus-oocyte complexes recovered from sow ovaries were in vitro-matured for 38 to 40 h. Denuded matured oocytes selected by the presence of a polar body had the zona pellucida removed in a 0.2% protease HEPES-buffered solution +25% FCS, followed by manual bisection and UV screening of enucleated halves using Hoechst stain. Clone embryo reconstruction was performed using a phytohemoagglutinin solution to adhere 2 cytoplasts and a somatic cell. Adipocyte-derived mesenchymal stem cells (ADMSC) from a Yorkshire pig or granulosa cells (GC) from an Ossabaw pig were used as nuclear donors. Following electrical fusion, couplets were pretreated with a brief exposure to cytochalasin B (CB) or cytochalasin B + cycloheximide (CB+CX) in the presence of serum before the electrical activation (Naruse et al. 2007 Theriogenology 68, 709-716; Du et al. 2009 Reprod. Fertil. Dev. 21, 114). Activated embryos were in vitro-cultured in the well of the well (WOW) system, with 2 embryos per microwell, for 7 days in PZM-3 medium +0.3% BSA in the presence (FBS+) or absence (FBS-) of 10% FCS. Cleavage (Day 2, chi-square test) and blastocyst (Day 7, Fisher test) rates, on a per WOW basis, were compared for a level of significance of 5%. Our preliminary data indicate that the presence of serum in the IVC affected cleavage and blastocyst yield in a cell-type-dependent manner. The presence of serum enhanced the blastocyst yield for ADMSC, whereas for GC, only the absence of serum allowed any blastocyst development. The cell type and the pre-activation protocol did not appear to affect cleavage and embryo development to the blastocyst stage. Despite the low number of replications, our results reinforce the importance of optimizing the embryo production system taking into consideration the individual requirements for distinct cell types, procedures, and culture conditions. Table 1.Effects of cell type, pre-activation process and in vitro culture (IVC) medium on development of handmade pig cloned embryos

47 EFFECT OF THE TYPE OF CYTOPLASTS, SOURCE OF KARYOPLASTS, AND ACTIVATION PROCESS ON IN VITRO DEVELOPMENT OF BOVINE CLONE EMBRYOS

As the recipient cytoplast plays a key role in nuclear reprogramming after somatic cell nuclear transfer (SCNT), the aim of this study was to compare the type of cytoplast/karyoplast [metaphase II (MII) oocyte, early zygote, somatic cells] and the chemical (CA) or sperm-mediated/spontaneous activation (SA) on in vitro development of bovine SCNT embryos produced by handmade cloning (HMC). After 17 h of in vitro maturation, a group of cumulus–oocyte complexes (COCs, n = 945) was manually bisected following zona removal and segregated as enucleated (MII hemi-Cyt) or non-enucleated (MII hemi-Kar). Another group of COCs was in vitro-fertilized, and, 4 h after the onset of IVF, zona-free zygotes with 2 polar bodies (n = 490) were manually bisected under fluorescent light to obtain IVF hemi-Cyt and IVF hemi-Kar. A somatic cell (SC) culture from an adult cow was used for HMC procedures (SC Kar). In 5 replications, experimental groups were composed of: zona-intact MII oocytes (parthenote control, PG); zona-intact zygotes (IVF control); MII Cyt + MII Cyt + SC Kar (SCNT control); IVF Cyt + MII Cyt + SC Kar (G1); MII Cyt + IVF Kar (G2); IVF Cyt + IVF Kar (G3); IVF Cyt + IVF Cyt + SC Kar (G4); and MII Cyt + MII Kar (G5). Following reconstruction and electrofusion, groups G1 to G5 were further divided into 2 sub-groups each, 1 being chemically activated (ionomycin/6-DMAP) along with the control groups PG and SCNT, whereas the others were cultured to verify sperm-mediated (G1 to G4) or spontaneous (G5) activation. Embryos were in vitro-cultured in the WOW system for 7 days. Cleavage (Day 2) and blastocyst (Day 7) rates were compared by the chi-square and Fisher tests, respectively. Cleavage rates in G1-SA, G2-SA, and G3-SA were lower than in their CA counterparts, which were similar to controls (Table 1). Such decrease in cleavage in G1-SA and G2-SA may be caused by the manipulation process rather than by sperm-mediation, since the observed rates were very similar to the G5-SA group. Cleavage in G3 and G4 were also similar to controls, most likely due to the fusion of 2 sperm-activated IVF hemi-Cyt. Blastocyst rates were generally higher in CA than in SA sub-groups except for G4, for which SA benefited from 2 sperm-activated cytoplasts. The lower blastocyst yield in SA sub-groups may reflect at least 2 possible mechanisms: an increased level of heteroplasmy (G1 and G2), potentially caused by an insufficient sperm-activated IVF hemi-Cyt or by a blocking effect imposed by the M-phase-derived hemi-Cyt, and/or a disruption in karyokinetic events caused by the manipulation in sperm-activated IVF hemi-Kar (G2 and G3). In G4, both mechanisms were probably attenuated by the use of 2 sperm-activated IVF hemi-Cyt and a SC-kar, analogous to conditions in the SCNT and G5 groups. Table 1.Effect of cytoplast type and activation process on in vitro development of bovine SCNT embryos This study was supported by a grant from CAPES/Brazil.

69 A HOMEMADE N2 SUPERCOOLING DEVICE (NITROCOOLER) ENHANCES VIABILITY AFTER VITRIFICATION OF BOVINE OOCYTES BUT NOT OF IN VITRO-PRODUCED EMBRYOS

Increasing the cooling rate is a common strategy to enhance vitrification efficiency of bovine oocytes and in vitro-produced (IVP) embryos. Under vacuum conditions, liquid N2 (LN2) temperature decreases, increasing the cooling rate during the vitrification procedure. However, commercially available brands of equipment to supercool nitrogen are expensive. The aim of this study was to verify the effectiveness of a low-cost homemade nitrogen supercooling apparatus (Nitrocooler) for vitrification of bovine oocytes and IVP embryos. The device consists of a vacuum pump coupled to a close-tight-lidded flask with a styrofoam cup filled with 300 mL of LN2. After 5 to 7 min of vacuum pumping, LN2 goes through the slushing phenomenon, turning solid. After the lid is opened, the N2 turns liquid again, but in a stable, supercooled physical state lasting for approximately 10 min, boiling off when objects are plunged into it. Nitrocooler was tested for vitrified oocytes (Experiment I), vitrified oocytes in different containers (Experiment II), and embryos in 2 different vitrification solutions (Experiment III). In Experiment I (Ciência Rural, 2006 36, 1501–1506), immature (IM, n = 172) or in vitro-matured (IVM, n = 174) oocytes were exposed to 10% ethylene glycol (EG) + 10% DMSO for 30 s, followed by 20% EG + 20% DMSO + 0.5 m sucrose for 20 s, loaded in open-pulled straws (OPS), and plunged into LN2 or Nitrocooler-pumped LN2. For both IM (8.8%) and IVM (10.6%) oocytes, Nitrocooler-pumped LN2 increased blastocyst rates (Bonferroni, P < 0.05). In Experiment II, 1454 oocytes were vitrified using Nitrocooler after loading in different containers: stainless steel straws (SSS), beveled-tip straws (BTS), open-OPS, and glass-pulled straws (GPS). Greater blastocyst rates were obtained in the SSS (10.2%) and the GPS (8.0%) treatments, both being greater than the BTS (6.1%) and OPS (6.1%) containers (Tukey, P < 0.05). In Experiment III (Acta Sci. Vet. 2006 34, 77–82), 195 IVP bovine blastocysts were vitrified with or without Nitrocooler under 2 different cryoprotectant solutions: 10% EG + 10% DMSO or 10% EG + 10% propylene glycol (PROP). Hatching rates using Nitrocooler for EG + DMSO (50.2%) or EG + PROP (54.0%) were similar (ANOVA, P > 0.05) to normal atmosphere rates using EG + DMSO (50.1%) or EG + PROP (56.0%). Under these experimental conditions, our results suggest that the greater cooling rates obtained favored an increase in oocyte viability after vitrification, whereas no such beneficial effects were detected for vitrified IVP embryos. In conclusion, Nitrocooler was proven effective as a low-cost device to supercool LN2, increasing viability after vitrification of bovine oocytes, but not of IVP embryos. Table 1.Effect of Nitrocooler apparatus on cryopreservation of bovine oocytes and embryos

50 EFFECT OF AGGREGATION OR FUSION ON DEVELOPMENT AND CELL NUMBER OF BOVINE EMBRYOS PRODUCED BY HANDMADE CLONING AND PARTHENOGENESIS

Cloning by somatic cell nuclear transfer has been associated with developmental abnormalities, with the level of heteroplasmy imposed by cell fusion being one of many potential determining factors. As the cytoplast exerts a key role in nuclear reprogramming, embryo aggregation is an alternative to minimize such negative effects during cloning. The aim of this study was to determine the effect of fusion of hemi-cytoplasts or aggregation of hemi-embryos on in vitro development and cell number of clone and parthenote embryos. Bovine cumulus–oocyte complexes (COCs) from slaughterhouse ovaries, after 17 h of IVM, were used for the production of parthenotes by chemical activation, and clone embryos by handmade cloning (HMC) (Vajta et al. 2003 Biol. Reprod. 68, 571–578). Following cumulus and zona removal, oocytes were manually bisected, followed by segregation of nucleated and enucleated hemi-cytoplasts by fluorescence using Hoechst stain. One or two enucleated hemi-cytoplasts were paired with an adult skin somatic cell from primary cultures (>90% confluence) and fused using a 25V AC pre-pulse, followed by a single 1.2 kV cm–1 DC pulse for 10 μs. Reconstructed clone structures and groups of zona-intact oocytes and nucleated hemi-cytoplasts were chemically activated in ionomycin and 6-DMAP. Clone and parthenote structures were in vitro-cultured in the WOW system (Vajta et al. 2000 Mol. Reprod. Dev. 55, 256–264) for 7 days, as follows: (G1) clone embryos reconstructed by aggregation of two hemi-embryos per WOW; or (G2) one embryo (two hemi-cytoplasts + cell) perWOW; and parthenote embryos composed of (G3) zona-intact oocytes cultured in wells; or aggregation of one (G4), two (G5), three (G6), or four (G7) nucleated hemi-cytoplasts per WOW. Fusion, cleavage (Day 2), and blastocyst (Day 7) rates, evaluated on a per WOW basis, were compared by the chi-square test (8 replications). Total cell number estimated by fluorescence (Hoechst stain) in blastocysts was analyzed by the Student t-test. Fusion rates of one hemi-cytoplast + cell (G1; 275/592, 46.5%) were lower than for two hemi-cytoplasts + cell (G2; 264/337, 78.3%). Cleavage rates were lower in G1 and G4 and higher in G6 and G7 than G2 and G3. A significant linear increase in blastocyst rates was observed in G5, G6, and G7. Total cell numbers were lower in parthenotes than in clones, except in G6 and G7. The lower fusion and cleavage rates after the aggregation of two clone hemi-embryos (G1) caused nearly a 50% reduction in the overall cloning efficiency. In addition, the aggregation of parthenogenetic hemi-embryos increased cleavage and blastocyst rates and cell number. However, aggregation of hemi structures did not improve blastocyst yield or cell number on a hemi-cytoplast basis. Table 1. In vitro development of parthenote or clone bovine embryos This work was supported by funding from CAPES/Brazil.