227 CONSTRUCTION OF STAGE-SPECIFIC cDNA MICROARRAY, AND ANALYSIS OF IN VITRO PRODUCED PRE-IMPLANATION STAGE BOVINE EMBRYOS FOR DEVELOPMENTAL COMPETENCE
S. Mamo A , C.A. Sargent B , N.A. Affara B , K. Wimmers C , S. Ponsuksili C , M. Gilles A and K. Schellander AA Institute of Animal Breeding Sciences, University of Bonn, Bonn, Germany
B Department of Pathology, University of Cambridge, Cambridge, UK
C Molecular Biology Research Division, Research Institute for the Biology of Farm Animals, Dummerstorf, Germany. Email: lilykacha@hotmail.com
Reproduction, Fertility and Development 17(2) 264-264 https://doi.org/10.1071/RDv17n2Ab227
Submitted: 1 August 2004 Accepted: 1 October 2004 Published: 1 January 2005
Abstract
Microarray technology currently has wide acceptance as a research tool in the study of gene expression profiling, mainly as a result of its use for monitoring the expression profiles of thousands of genes in a single experiment. However, its use in analyzing gene expression in the pre-implantation stage of bovine embryo development has been limited for reasons such as the large amount of RNA required and the lack of bovine specific cDNA clone collections (Smith L and Greenfield A 2003 Hum. Mol. Genet. 12, 1–8). In this study, with the objectives of producing pre-implantation-stage-specific bovine cDNA clones and examining the developmental competence, eighty-two selected target clones of pre-implantation-stage-specific genes were prepared and spotted on the glass slide. Embryos were produced in vitro and mRNAs were isolated from contrasting probes of good quality matured oocytes and blastocyst-stage embryos using a Dynabead mRNA isolation kit by following the manufacturer's instructions. First-strand cDNA syntheses were primed with T7 Oligo d(T)21 primer, followed by random primed second-strand syntheses using a DOP master kit (Roche Diagnostics, Mannheim, Germany) and global amplification using the same primers used for the first- and second-strand syntheses. In vitro transcription was performed to amplify the RNA by using the AmpliScribe T7 transcription kit (EPICENTRE Technologies, Oldendorf, Germany), and the amplified RNA (aRNA) was purified using a RNeasy Mini kit (Qiagen, Hilden, Germany). Finally, the results of different RNA amplifications (aRNA) were tested by hybridization on microarrays and also using real-time PCR techniques. With these analyses, the sufficiency of the yield and linearity of amplification procedures were confirmed. Three micrograms each of aRNA were labelled with Cy3 and Cy5 dyes and hybridized to the array. After overnight incubation at 42°C, the slides were sequentially washed and scanned using an ArrayWorx biochip reader (Applied Precision, Marlborough, UK), and quantifications as well as all analyses were carried out using different TIGR software modules (Saeed AI et al. 2003 Biotechniques 34(2), 374–378). Analyses of the results of repeated hybridizations showed that 35 genes (43%), which belong to different functional groups, were differentially expressed between the two stages. Further independent analyses using real-time PCR confirmed the results of 25 genes. Hence, it is possible to conclude that the established methods can be used for large scale gene expression analysis, and the identified genes can be potential candidates for characterizing developmental competence.