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Vertebrate reproductive science and technology
RESEARCH ARTICLE

75 EPIGENETIC EFFECTS OF VITRIFICATION ON PRONUCLEAR DOMESTIC CAT EMBRYOS

J. H. Galiguis A , C. E. Pope A , M. N. Biancardi A , C. Dumas A , G. Wang B and M. C. Gómez A
+ Author Affiliations
- Author Affiliations

A Audubon Center for Research of Endangered Species, New Orleans, LA, USA;

B Departments of Microbiology and Immunology, Medicine, and Genetics, Louisiana State University Health Sciences Center, New Orleans, LA, USA

Reproduction, Fertility and Development 27(1) 131-131 https://doi.org/10.1071/RDv27n1Ab75
Published: 4 December 2014

Abstract

Vitrification remains a promising technique in the preservation of valuable genetic material; however, in the cat, success has varied. Live kittens have been produced from embryos vitrified at early cleavage stages, but phenotypic abnormalities in some kittens suggest possible epigenetic effects of the vitrification process. It has been reported that cryopreservation alters epigenetic events in somatic donor cells, which indirectly influences physical status of cloned offspring. However, extending post-warming in vitro culture of donor cells corrects these epigenetic modifications, resulting in normal embryos/clones. Accordingly, in the present study, vitrification was performed at the pronuclear stage to lengthen pretransfer culture time, and vitrified cat zygotes were assessed by analysing (1) histone acetylation/methylation, (2) global DNA methylation, (3) pluripotent gene expression, (4) in vitro development, and () in vivo viability. In vivo matured/IVF oocytes were vitrified in 15% dimethyl sulfoxide, 15% ethylene glycol, and 0.5 M sucrose at 16 h post-insemination (PI). After warming in 1.0 M sucrose at 38°C, embryos were fixed at 18 h or 40 h PI, and the nuclear intensity of either acetyl/dimethyl-H3K9 or 5-methylcytosine was determined by immunofluorescence. Results showed that at 18 h PI, mean H3K9ac intensity of vitrified embryos (11.8; n = 6) was higher than that of corresponding nonvitrified (fresh) controls (4.5; n = 6) and the fresh (3.2; n = 11) and vitrified (0.6; n = 7) 40-h groups (2-way ANOVA; P < 0.05). H3K9me2 in the fresh (36.9) and vitrified (32.5) 18-h embryos was similar but increased relative to both fresh (10.7) and vitrified (9.2) 40-h groups (P < 0.05). Mean DNA methylation (5MeC) in the fresh (31.6; n = 1) and vitrified (24.7; n = 3) 18-h groups was similar to that of the fresh 40-h group (19.8; n = 4) but higher than that of the vitrified 40-h group (15.0; n = 5; P < 0.05). To assess expression of POU5F1 and Nanog, qRT-PCR was performed on Day 8 blastocysts. Relative to controls (n = 9), mean POU5F1 and Nanog levels in vitrified blastocysts (n = 24) were 1.38- and 1.98-fold higher, respectively (one-way ANOVA; P > 0.05). In terms of in vitro development, Day 2 cleavage of vitrified zygotes (59%; n = 508) was similar to that of controls (66%; n = 340), but Day 8 blastocyst formation was reduced (9 v. 31%; t-test; P < 0.05). In vivo viability was assessed by oviducal transfer of 41 Day 1 embryos into 2 recipients. One pregnancy was established (50%), with 3 live kittens weighing 70, 79, and 131 g delivered without assistance on Day 65 of gestation. The 2 smaller kittens died within a few hours of birth, with the smallest exhibiting an umbilical hernia and organ exteriorization. The third kitten developed into a normal, healthy adult. In summary, mean H3K9me2, 5MeC, and POU5F1/Nanog expression of vitrified zygotes was similar to corresponding controls. H3K9ac increased at 18h PI as a result of vitrification, but was reduced after culture to 40 h PI. Although vitrified zygotes cleaved in vitro at rates similar to controls, blastocyst development was reduced. In vivo viability was demonstrated; however, postnatal survival of kittens produced was low.