Analysis of the evolution of chromosome abnormalities in human embryos from Day 3 to 5 using CGH and FISH.

The use of interphase fluorescent in situ hybridization (FISH) has shown that a large number of human embryos exhibit chromosomal abnormalities in vitro. The most common abnormality is mosaicism which is seen in up to 50% of preimplantation embryos at all stages of development. In this study, comparative genomic hybridization (CGH) was used to analyse 1-2 cells biopsied on Day 3 of development while the rest of the embryo was cultured until Day 5. Embryos were spread on Day 5 and analysed by FISH using probe combinations that varied depending on the CGH result, to investigate the progress of any abnormalities detected on Day 3. A total of 37 frozen-thawed embryos were analysed in this study. One gave no CGH or FISH results and was excluded from analysis. Six embryos failed to give any FISH result as they were degenerating on Day 5. Thirty embryos provided results from both techniques. According to the CGH results, the embryos were divided into two groups; Group 1 had a normal CGH result (13 embryos) and Group 2 an abnormal CGH result (17 embryos). For Group 1, three embryos showed normal CGH and FISH results, while 10 embryos were mosaic after FISH analysis, with various levels of abnormalities. For Group 2, FISH showed that all embryos were mosaic or completely chaotic. The combination of CGH and FISH enabled the thorough investigation of the evolution of mosaicism and of the mechanisms by which it is generated. The main two mechanisms identified were whole or partial chromosome loss and gain. These were observed in embryos examined on both Day 3 and 5.

Detailed FISH analysis of day 5 human embryos reveals the mechanisms leading to mosaic aneuploidy.

BACKGROUND: Fluorescence in situ hybridization (FISH) analysis has shown that human embryos display a high level of chromosomal mosaicism at all preimplantation stages. The aim of this study was to investigate the mechanisms involved by the use of two probes for each of three autosomes at different loci and to determine the true level of aneuploid mosaicism by excluding FISH artefacts. METHODS: Embryos were cultured in two different types of medium: group I were cultured in standard cleavage medium for up to day 5 and group II were cultured from day 3 to day 5 in blastocyst medium. Three rounds of FISH were performed. In round 1, the probes used were 1pTel, 11qTel and 18CEP; in round 2, the probes used were 1satII/III, 11CEP and 18qTel; in round 3, the probes used were 18CEP, XCEP and YCEP. RESULTS: A total of 21 embryos were analysed in each group. The FISH results revealed one uniformly diploid and 20 mosaic embryos for group I, and two uniformly diploid and 19 mosaic embryos for group II. The predominant type of mosaicism was diploid/aneuploid. The use of two different probes per autosome was able to distinguish FISH artefacts affecting 5% of nuclei from true single cell anomalies. CONCLUSIONS: Post-zygotic chromosome loss was the most common mechanism leading to aneuploidy mosaicism for both groups, followed by chromosome gain, with fewer examples of mitotic non-disjunction.