The construction of cDNA libraries from human single preimplantation embryos and their use in the study of gene expression during development.

Abstract

The construction and application of polymerase chain reaction (PCR)-based cDNA libraries from unfertilized human oocytes and single preimplantation-stage embryos are described. The purpose of these studies is to provide a readily available resource for the study of gene expression during human preimplantation development. Rapid, reproducible, and efficient procedures for the construction of PCR-based cDNA libraries from fewer than 10 cells were first developed in small populations of fibroblast cells. We then constructed cDNA libraries from eight unfertilized oocytes and single two-cell, -4-cell, -7-cell, and blastocyst-stage embryos. Differential display PCR using the libraries as template allows the analysis of stage-specific expression of embryonic genes. Genomic libraries are also prepared from parental samples (cumulus cells and sperm) corresponding to the individual embryo generating the cDNA library. The complexities (between 10(5) and 10(6) clones) of the human embryo libraries indicate that they may represent the entire active gene population at these early stages of human development. Nucleotide sequence analyses of random clones showed the presence of a variety of transcripts, such as the human transposable element. LINE-1, Alu repeat sequences, housekeeping genes, and tissue-specific genes, (e.g., alpha-globin, FMR-1, and interleukin-10). Also present at the expected frequency are the ubiquitous cytoskeletal elements, beta-actin, keratin-18, and alpha-tubulin. In addition to cDNAs corresponding to known expressed sequence tags (ESTs) in the GenBank and dbEST databases, a high proportion of novel sequences was also detected. Several cDNAs were detected only at specific stages of preimplantation development by the differential display analysis. PCR-based cDNA libraries from single human preimplantation embryos provide a new and important resource for the identification and study of novel genes or gene families. As such, they will increase our basic understanding of the molecular control of human development. In the clinical context, the libraries identify the time of onset of specific genes, and hence the diseases resulting from mutation of these genes, and provide information about new methods of preimplantation diagnosis. The molecular analysis of early gene transcription in human embryogenesis may be expected to lead to advances in contraception, assisted reproduction, and preimplantation genetic diagnosis.