Ultrastructure of vitrified rabbit transgenic embryos.

The aim of the study was to determine the viability of rabbit transgenic (enhanced green fluorescent protein (EGFP)-positive) embryos cultured in vitro and compare with gene-microinjected (Mi) non-transgenic (EGFP-negative) embryos following vitrification. Non-microinjected and non-vitrified embryos were used as the control. Morphological signs of injury to embryo organelles were determined at the ultrastructural level using transmission electron microscopy (TEM). Morphometric evaluation was performed on cellular organelles using microphotographs obtained by TEM. Intact and Mi embryos recovered from in vivo fertilized eggs at 19-20 hours post coitum (hpc) were cultured for up to 72 hpc (morula stage), evaluated for the EGFP gene integration and then vitrified in 0.25 ml insemination straws in modified EFS (40% ethylene glycol + 18% Ficoll 70 + 0.3 M sucrose) vitrification solution. After 1-3 days the embryos were devitrified, a representative selection of embryos was analyzed by TEM and the remaining embryos were subjected to additional in vitro culture. Observations by TEM showed that the vitrified/warmed EGFP-positive and EGFP-negative embryos had a slight accumulation of cellular debris and lipid droplets compared with the control intact embryos. More severe changes were detected in the membrane structures of the treated embryos, mostly in the cytoplasmic envelope, trophoblastic microvilli, junctional contacts and mitochondria. We suggest that the higher proportion of deteriorated cell structures and organelles in the treated embryos may be due to the vitrification process rather than to mechanical violation (the gene-microinjection procedure), as a detailed inspection of ultrastructure revealed that most damage occurred in the cell membrane structures.

[The impact of exogenous luteinizing hormone on IVF/ICSI cycles parameters]. / Vplyv exogénneho luteinizacného hormónu na parametre IVF/ICSI cyklov.

OBJECTIVE: To evaluate the effect of exogenous luteinizing hormone on IVF/ICSI success. DESIGN: Retrospective clinical study. SETTING: 2nd Department of Gynaecology and Obstetrics, Medical Faculty and L. Pasteur University Hospital Kosice, Slovak Republic. METHODS: Individual parameters and clinical pregnancy rate of 232 IVF/ICSI cycles were compared in dependence on stimulation protocol (pure rFSH vs. rFSH and 75 IU rLH from S7). RESULTS: There was no statistically significant difference in IVF/ICSI success between individual groups and subgroups, but we demonstrated the increase in clinical pregnancy rate per ET in agonist cycles group with exogenous LH activity totally above 11% (27.6% vs. 38.6%), in patients under 35 years above 12% (30.4% vs. 42.6%) and in patients over 35 years above 14% (16.7% vs. 30.8%). In antagonist cycles group there was demonstrated the increase in clinical pregnancy rate only in women over 35 years - above 14% (13.3% vs. 30.8%). CONCLUSIONS: Despite of negative statistical analyses, from the clinical point of view we can strongly recommend the LH addition during COH, especially in agonist cycles and in older women.

Several aspects of animal embryo cryopreservation: anti-freeze protein (AFP) as a potential cryoprotectant.

With the development of embryo technologies, such as in vitro fertilization, cloning and transgenesis, cryopreservation of mammalian gametes and embryos has acquired a particular interest. Despite a certain success, various cryopreservation techniques often cause significant morphological and biochemical alterations, which lead to the disruption of cell organelles, cytoskeleton damages, cell death and loss of embryo viability. Ultrastructural studies confirm high sensitivity of the cell membrane and organelle membrane to freezing and thawing. It was found that many substances with low molecular weights have a protective action against cold-induced damage. In this concern, an anti-freeze protein (AFP) and anti-freeze glycoproteins (AFGPs), which occur at extremely high concentrations in fish that live in Arctic waters and protect them against freezing, may be of potential interest for cryostorage of animal embryos at ultra-low temperatures. This mini-review briefly describes several models of AFP/AFGP action to preserve cells against chilling-induced damages and indicates several ways to improve post-thaw developmental potential of the embryo.

Effect of vitrification technique and assisted hatching on rabbit embryo developmental rate.

The aim of the study was to determine the efficiency of two vitrification techniques followed by two assisted hatching (AH) techniques based on post-thaw developmental capacity of precompacted rabbit embryos and their ability to leave the zona pellucida (hatching) during in vitro culture. The total cell number and embryo diameter as additional markers of embryo quality after warming were evaluated. In vivo fertilized, in vitro cultured 8-12-cell rabbit embryos obtained from superovulated rabbit does were cryopreserved by two-step vitrification method using ethylene glycol (EG) as cryoprotectant or by one-step vitrification method with EG and Ficoll (EG+Ficoll). Thawed embryos were subjected to enzymatic or mechanical AH. Vitrified EG group showed significantly lower (P < 0.05) blastocyst rate (22.5%) and hatching rate (15%) than those vitrified with EG + Ficoll (63 and 63% resp.) and that of control (97 and 97% respectively). Significantly lower values of total cell number (P < 0.05) as well as embryo diameter (P < 0.01) in EG group compared with EG + Ficoll and control group were recorded. No significant difference was found in developmental potential of warmed embryos treated by either mechanical or enzymatic AH. The present study demonstrates that the EG + Ficoll vitrification protocol provides superior embryo survival rates over the EG vitrification protocol for 8-12-cell stage precompacted rabbit embryos. No positive effect of either mechanical or enzymatic AH on the post-thaw viability and quality of rabbit embryos in vitro was observed.

Post-thaw survival, cell death and actin cytoskeleton in gene-microinjected rabbit embryos after vitrification.

The aim of this study was to compare two vitrification procedures (VPs), using either ethylene glycol (EG) in combination with dimethylsulfoxide (DMSO, vitrification protocol (VPI)) or Ficoll 70 (vitrification protocol II (VPII)), for rabbit embryo cryopreservation based on their post-thaw survival, cell death and actin cytoskeleton. The pronuclear stage eggs were flushed from the oviducts of the slaughtered New Zealand White rabbit does 19-20h post coitum (hpc) and randomly divided into two groups: intact (control) and microinjected (Mi). Mi embryos or intact embryos were cultured for up to 72hpc (morula stage), and then vitrified using either VPI (VPI+Mi, VPI) or VPII (VPII+Mi, VPII). After 2-3 days at -196 degrees C, the embryos were thawed and cultured until 96-100hpc to assess their development to blastocyst, apoptotic rate (TUNEL assay) and state of actin cytoskeleton (phalloidine-TRITC). Mi procedure reduced blastocyst yield, but it was higher than in either vitrified (VPI) or Mi vitrified (VPI+Mi) embryos. VPI compromised, whereas VPII did not significantly affect blastocyst development compared to intact embryos. Mi and VP both affected the embryo quality increasing TUNEL-index and decreasing the ratio of embryos with high quality actin cytoskeleton compared to control. A higher apoptotic index was recorded in VPI group. A combination of Mi and VP induced an increase in apoptotic rate (10.35% and 7.54% for VPI+Mi and VPII+Mi, respectively) as compared to Mi alone (5.7%). Ratio of embryos belonging to best actin quality (grade I) was different among groups and most of the embryos with grade I actin were in intact (84%), Mi (71%) or VPII (70%) groups. A significantly lower number of embryos with grade I actin quality was observed in VPI (58%), VPI+Mi (54%) or VPII+Mi (66%). These observations indicate that of the vitrification schemes tested, the VPII using EG and ficoll 70 as cryoprotectants, was less harmful than VPI (EG combined with DMSO in vitrification medium).

Survival and ultrastructure of gene-microinjected rabbit embryos after vitrification.

Morphological signs of injury and subsequent regeneration following vitrification of either rabbit gene microinjected (Gene-Mi) or intact in vitro cultured embryos derived from in vivo fertilized eggs were evaluated by post-warming recovery in culture and analysed by transmission electron microscopy (TEM). The percentages of vitrified/warmed Gene-Mi embryos that reached the blastocyst stage (69%) and hatched (57%) did not differ significantly from those of intact embryos (78% and 56%, respectively). In contrast, in vitro development of embryos to the blastocyst stage among non-vitrified intact (96%) and Gene-Mi (90%) embryos compared with both the intact vitrified (78%) and Gene-Mi vitrified (69%) groups, as well as hatching rate (94%, 90% vs 56%, 57%, respectively) varied significantly (p < 0.001). Observations by TEM showed that the vitrified/warmed intact or Gene-Mi embryos without post-culture displayed severe degenerative changes among their cells. During 24 h of culture a proportion of the embryos were able to regenerate and complete the compaction process. Nevertheless the signs of previous injury were retained, such as swollen cytoplasmic organelles and remaining cellular debris in the perivitelline space. These observations indicate that the procedure of gene Mi does not significantly compromise embryo tolerance to cryopreservation and post-warming developmental ability. Severe changes in embryo morphology, observed at the ultrastructural level, can be attributed to a direct influence of the vitrification process rather than to the Mi procedure itself.