Please use this identifier to cite or link to this item: https://ir.swu.ac.th/jspui/handle/123456789/15020
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dc.contributor.authorBoonkusol D.
dc.contributor.authorGal A.B.
dc.contributor.authorBodo S.
dc.contributor.authorGorhony B.
dc.contributor.authorKitiyanant Y.
dc.contributor.authorDinnyes A.
dc.date.accessioned2021-04-05T04:32:21Z-
dc.date.available2021-04-05T04:32:21Z-
dc.date.issued2006
dc.identifier.issn1040452X
dc.identifier.other2-s2.0-33646442312
dc.identifier.urihttps://ir.swu.ac.th/jspui/handle/123456789/15020-
dc.identifier.urihttps://www.scopus.com/inward/record.uri?eid=2-s2.0-33646442312&doi=10.1002%2fmrd.20450&partnerID=40&md5=a57f4ad291f41ccc2ff48e31278d9ec0
dc.description.abstractThe analysis of differences in gene expression, responding to cryopreservation may explain some of the observed differences in further development of the preimplantation stage embryos. The aim of this study was to create a link, for the first time, between morphological/developmental observations and gene activity changes following cryopreservation of embryos. Efficiency of two vitrification methods, solid surface and in-straw vitrifications for pronuclear-stage mouse zygotes and 8-cell stage mouse embryos was compared based on morphological survival, blastocyst formation, and changes in embryonic gene expression. Both stages of embryos were vitrified by SSV using 35% ethylene glycol (EG) for vitrification solution (VS) and in-straw vitrification using 40% EG for VS. No significant differences were found between immediate survival rates of embryos vitrified by SSV and in-straw vitrification in both stages. Blastocyst rates were significantly higher with SSV and not significantly different from that of control. These results showed that SSV was more efficient than in-straw vitrification. Treatment with cytochalasin-b did not improve cryosurvival during SSV. The quantification of selected gene transcripts from single embryo (6 embryos/treatment group) were carried out by quantitative real-time RT-PCR. It was performed by adding 1/8 of each embryo cDNA to the PCR mix containing the specific primers to amplify housekeeping gene (β-actin), heat shock protein gene (Hsp70), genes related to oxidative stress (MnSOD and CuSOD), cold stress (CirpB, Rbm3), and cell-cycle arrest (Trp53). We found upregulation of all six stress-related genes at 3 hr post-warming in pronuclear stage embryos. Expression of these genes showed much higher level (2-33-fold) in in-straw vitrification than in in vitro control embryos. In SSV-treated embryos we could detect only slight changes (0.3-2-fold). At 10 hr post-warming, all genes were downregulated in embryos vitrified by in-straw method. In SSV-treated group expression of Hsp70 showed slight increase and Trp53 showed decrease. In contrast to pronuclear stage, there was no clear pattern of gene expression changes after vitrification in 8-cell stage embryos. Several genes were upregulated both at 3 and 10 hr post-warming. Moreover, we found upregulation of β-actin gene which we expected to use as a reference gene in in-straw treated embryos in both 3 and 10 hr post-warming, while in pronuclear stage embryos and in SSV treatment there was no effect on β-actin expression level. There was no difference in gene expression between blastocysts developed from fresh or vitrified embryos. In conclusion, the real-time RT-PCR method from single embryo opened new opportunities for the understranding of molecular events following cryopreservation. The upregulation of stress-related genes at 3 hr post-warming in pronuclear stage embryos might have been an early indicator of reduced viability following in-straw vitrification in good correlation with the developmental data to blastocyst stage. © 2006 Wiley-Liss, Inc.
dc.subjectbeta actin
dc.subjectcell cycle protein
dc.subjectcold stress protein
dc.subjectcomplementary DNA
dc.subjectcopper zinc superoxide dismutase
dc.subjectcytochalasin B
dc.subjectethylene glycol
dc.subjectheat shock protein 70
dc.subjectmanganese superoxide dismutase
dc.subjectprotein CirpB
dc.subjectprotein Rbm3
dc.subjectprotein Trp53
dc.subjectunclassified drug
dc.subjectvitrification solution
dc.subjectanimal cell
dc.subjectanimal experiment
dc.subjectanimal model
dc.subjectarticle
dc.subjectblastocyst
dc.subjectcell viability
dc.subjectcontrolled study
dc.subjectcorrelation analysis
dc.subjectcryopreservation
dc.subjectembryo
dc.subjectembryo development
dc.subjectfemale
dc.subjectgene expression
dc.subjectgene expression regulation
dc.subjectin straw vitrification
dc.subjectin vitro study
dc.subjectmouse
dc.subjectnonhuman
dc.subjectpreimplantation embryo
dc.subjectpriority journal
dc.subjectpronucleus
dc.subjectprotein expression
dc.subjectreal time polymerase chain reaction
dc.subjectreverse transcription polymerase chain reaction
dc.subjectsolid surface vitrification
dc.subjectsurvival rate
dc.subjectvitrification
dc.subjectwarming
dc.subjectzygote
dc.subjectAnimals
dc.subjectCryopreservation
dc.subjectEmbryo
dc.subjectEmbryo, Mammalian
dc.subjectFemale
dc.subjectGene Expression Profiling
dc.subjectGene Expression Regulation, Developmental
dc.subjectHumans
dc.subjectMice
dc.subjectSolutions
dc.subjectAnimalia
dc.subjectSugarcane streak virus
dc.titleGene expression profiles and in vitro development following vitrification of pronuclear and 8-cell stage mouse embryos
dc.typeArticle
dc.rights.holderScopus
dc.identifier.bibliograpycitationMolecular Reproduction and Development. Vol 73, No.6 (2006), p.700-708
dc.identifier.doi10.1002/mrd.20450
Appears in Collections:Scopus 1983-2021

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