Abstract
Methylation is an important issue in gene expression regulation and also in the fields of genetics and reproduction. In this study, we created fat-1 transgenic sheep, investigated the fine-mapping and the modulatory mechanisms of promoter methylation. Sheep fetal fibroblasts were transfected by pCAG-fat1-IRES-EGFP. Monoclonal cell line was screened as nuclear donor and carried out nuclear transfer (441 transgenic cloned embryos, 52 synchronism recipient sheep). Six offsprings were obtained. Expressions of exogenous genes fat-1 and EGFP were detectable in 10 examined tissues and upregulated omega-3 fatty acid content. Interestingly, more or less EGFP negative cells were detectable in the positive transgenic fetal skin cells. EGFP negative and positive cells were sorted by flow cytometry, and their methylation status in the whole promoter region (1701 nt) were investigated by bisulphate sequencing. The fine-mapping of methylation in CAG promoter were proposed. The results suggested that exogenous gene expression was determined by the methylation status from 721–1346 nt and modulated by methylation levels at 101, 108 and 115 nt sites in CAG promoter. To clarify the regulatory mechanism of methylation, examination of four DNA methyltransferases (DNMTs) demonstrated that hypermethylation of CAG promoter is mainly maintained by DNMT 1 in EGFP negative cells. Furthermore, investigation of the cell surface antigen CD34, CD45 and CD166 indicated that EGFP positive and negative cells belong to different types. The present study systematically clarified methylation status of CAG promoter in transgenic sheep and regulatory mechanism, which will provide research strategies for gene expression regulation in transgenic animals.
Highlights
Transgenic animal technology is one of the fastest growing biotechnology areas
The results demonstrated that hypermethylation of CAG promoter is mainly maintained by DNA methyltransferases (DNMTs) 1 in Enhanced green fluorescent protein (EGFP) negative cells, which prevent mRNA expression of exogenous gene
In pfat-1, artificial promoter CAG simultaneously drives mRNA expressions of fat-1 and EGFP linked by Internal ribosome entry site (IRES) sequence [20]
Summary
Transgenic animal technology is one of the fastest growing biotechnology areas. It is used to integrate exogenous genes into the animal genome by genetic engineering technology so that these genes can be inherited and expressed in offspring. Transgenic animal technology is in the process of revolutionizing the way we domesticate the livestock [1]. Further studies will allow transgenic technology to explore gene function, animal genetic improvement, bioreactor, animal disease model, and organ transplantation [2]. In vitro transfection of cultured differentiated cells combined with nuclear transfer is currently the most effective procedure producing transgenic animals. Improvements in the technology of producing transgenic farm animals are highly desirable because the economic advantages gained may benefit both biotechnology and basic research. The main barrier in transgenic animal production lies in identifying more efficient systems of transgenic delivery and better mechanisms to optimize the regulation of transgenic expression levels [3]
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