Position-Independent Transgene Expression Mediated by Boundary Elements from the Apolipoprotein B Chromatin Domain

Abstract

The human apolipoprotein B (apoB) gene resides within a 47.5-kb chromatin domain that is flanked by sequences that bind to the nuclear matrix. These matrix attachment regions (MARs) are boundaries between nuclease-sensitive and -resistant chromatin. As domain boundaries are thought to function as insulator elements, shielding sequences between them from effects of neighboring chromatin, this raised the possibility that the apoB MARs have functions that could be assayed by transfection. To test this possibility, we examined effects of the apoB MARs on transgene expression in transiently and stably transfected rat and human hepatoma cells. The apoB MARs had no effects on expression of transiently transfected reporters, but they altered expression of stably integrated transgenes in dramatic and reproducible ways. Single integrated copies of transgenes that contained the apoB promoter and second intron enhancer, which are sufficient for high-level expression in transient assays, were expressed at low and variable levels in stable transfectant clones. In contrast, transgenes containing the apoB 5' and 3' MARs were expressed at levels nearly 200-fold higher than levels of the minimal reporters in stable transfectants, and expression was position independent. Transgenes that contained the apoB MARs and an additional 3.3 kb of apoB 5' flanking sequence were also expressed in an elevated, position-independent manner. Surprisingly, tandem transgene arrays in multicopy transfectants were transcriptionally inactive. These observations suggest that the apoB MARs function as insulator elements, shielding transgene expression from effects of neighboring chromatin domains.