LCR/MEL: a versatile system for high-level expression of heterologous proteins in erythroid cells.

We have used the human globin locus control region (LCR) to assemble an expression system capable of high-level, integration position-independent expression of heterologous genes and cDNAs in murine erythroleukaemia (MEL) cells. The cDNAs are inserted between the human beta-globin promoter and the second intron of the human beta-globin gene, and this expression cassette is then placed downstream of the LCR and transfected into MEL cells. The cDNAs are expressed at levels similar to those of the murine beta-globin in the induced MEL cells. Heterologous genomic sequences can also be expressed at similar levels when linked to to the LCR and beta-globin promoter. In addition we demonstrate that, after induction of differentiation, MEL cells are capable of secreting heterologous proteins over a prolonged time period, making this system suitable for use in continuous production systems such as hollow fibre bioreactors. The utility of the LCR/MEL cell system is demonstrated by the expression of growth hormone at high levels (greater than 100 mg/l) 7 days after induction. Since the expression levels seen do not depend upon gene amplification and are independent of the integration position of the expression cassette, it is possible to obtain clones with stable high-level expression within 3-4 weeks after transfection.     

Structure and function of the murine beta-globin locus control region 5' HS-3.

We previously identified the murine homologue of the human beta-globin Locus Control Region (LCR) 5' HS-2. The lambda clone containing murine 5' HS-2 extends approximately 12 kb upstream from this site; here, we report the sequence of this entire upstream region. The murine homologue of 5' HS-3 is located approximately 16.0 kb upstream from the mouse epsilon y-globin gene, but no region homologous to human 5' HS-4 was present in our clone. Using a reporter system consisting of a human gamma-globin promoter driving the neomycin phosphotransferase gene (gamma-neo), we tested murine LCR fragments extending from -21 to -9 kb (with respect to the epsilon y-globin gene cap site) for activity in classical enhancer and integration site assays in K562 and MEL cells. 5' HS-2 behaved as a powerful enhancer and increased the number of productive integration events (as measured by a colony assay) in both K562 and MEL cells. 5' HS-3 had no activity in K562 cells or in transiently transfected MEL cells, but was nearly as active as 5' HS-2 in the MEL cell colony assay. Two additional tests confirmed the identification of murine 5' HS-3: first, a DNA fragment containing 5' HS-3 confers copy number-dependent, integration-site independent inducibility on a linked beta-globin gene in the MEL cell environment. Secondly, a strong DNAseI hypersensitive site maps to the location of the 5' HS-3 functional core in chromatin derived from MEL cells. Collectively, these data suggest that we have identified the murine homologue of human 5' HS-3, and that this site is functional when integrated into the chromatin of MEL cells but not K562 cells. 5' HS-3 may therefore contain information that contributes to the development-specific expression of the beta-like globin genes.