By virtue of its immediate contact with the circulating blood, the endothelium provides an attractive target for retroviral vector transduction for the purpose of gene therapy. To see whether efficient gene transfer and expression was feasible, rabbit aortic endothelial cells were infected with three Moloney murine leukemia virus-derived retroviral vectors. Two of these vectors carry genes encoding products that are not secreted: N2, containing only the selectable marker gene neoR, and SAX, containing both neoR gene and an SV40-promoted adenosine deaminase (ADA) gene. The third vector, G2N, contains a secretory rat growth hormone (rGH) gene and an SV40-promoted neoR gene. Infection with all three vectors resulted in expression of the respective genes. A high level of human ADA expression was observed in infected endothelial cell populations both before and after selection in G418. G2N-infected rabbit aortic endothelial cells that were grown on a synthetic vascular graft continued to secrete rGH into the culture medium. These studies suggest that endothelial cells may serve as vehicles for the introduction in vivo of functioning recombinant genes.
Nonimmortalized mouse mammary epithelial cells expressing Escherichia coli ,-galactosidase from a murine amphotropic packaged retroviral vector were injected into the epithelium-divested mammary fat pads of syngeneic mice. Mammary glands formed from the injected mammary epithelial cells contained ductal and lobular cells, both of which expressed 0-galactosidase when examined in situ more than 12 months later. These results indicate that stable recombinant gene expression can be achieved in vivo in the mammary gland without altering the growth properties of normal mammary epithelium.
Patients with chronic granulomatous disease (CGD) have recurrent infections resulting from a failure of phagocytic cells to produce superoxide. One third of CGD patients have an autosomal gene defect resulting in absence of p47phox protein, a cytoplasmic component critical to superoxide production by phagocytic cells. cDNA encoding p47phox has been cloned and recombinant p47phox (rp47phox) restores superoxide-generating activity to a cell-free assay containing cell membranes and cytosol from p47phox-deficient CGD neutrophils. The goal of the present study was to determine the feasibility of retrovirus mediated expression of rp47phox in the HL60 and U937 human hematopoietic cell lines, and in an Epstein-Barr virus transformed B- lymphocyte cell line (EBV-BCL) derived from a p47phox-deficient CGD patient. Normal EBV-BCL contain p47phox and generate small amounts of superoxide, while this CGD EBV-BCL lacks any detectable p47phox protein. Defective amphotropic retrovirus containing p47phox sequence inserted in the LXSN vector in sense and antisense orientations were used to transduce HL60, U937, and CGD EBV-BCL. p47phox mRNA sequence was detected in cells transduced with either sense or antisense retroviral constructs while rp47phox protein was detected only with the sense construct. The amount of rp47phox protein produced within these cells was greater than the native p47phox present in uninduced HL60 or U937 cells, but substantially less than that present in normal neutrophils, induced HL60 cells, or even normal EBV-BCL. Differentiation of transduced HL60 cells and the associated production of native p47phox in response to dimethyl sulfoxide was not affected. These studies demonstrate that retrovirus constructs can be used to mediate stable expression of rp47phox protein in human hematopoietic cell lines and can restore rp47phox protein within the cytosol of p47phox-deficient EBV-BCL from patients with CGD.
Patients with chronic granulomatous disease (CGD) have recurrent infections resulting from a failure of phagocytic cells to produce superoxide. One third of CGD patients have an autosomal gene defect resulting in absence of p47phox protein, a cytoplasmic component critical to superoxide production by phagocytic cells. cDNA encoding p47phox has been cloned and recombinant p47phox (rp47phox) restores superoxide-generating activity to a cell-free assay containing cell membranes and cytosol from p47phox-deficient CGD neutrophils. The goal of the present study was to determine the feasibility of retrovirus mediated expression of rp47phox in the HL60 and U937 human hematopoietic cell lines, and in an Epstein-Barr virus transformed B- lymphocyte cell line (EBV-BCL) derived from a p47phox-deficient CGD patient. Normal EBV-BCL contain p47phox and generate small amounts of superoxide, while this CGD EBV-BCL lacks any detectable p47phox protein. Defective amphotropic retrovirus containing p47phox sequence inserted in the LXSN vector in sense and antisense orientations were used to transduce HL60, U937, and CGD EBV-BCL. p47phox mRNA sequence was detected in cells transduced with either sense or antisense retroviral constructs while rp47phox protein was detected only with the sense construct. The amount of rp47phox protein produced within these cells was greater than the native p47phox present in uninduced HL60 or U937 cells, but substantially less than that present in normal neutrophils, induced HL60 cells, or even normal EBV-BCL. Differentiation of transduced HL60 cells and the associated production of native p47phox in response to dimethyl sulfoxide was not affected. These studies demonstrate that retrovirus constructs can be used to mediate stable expression of rp47phox protein in human hematopoietic cell lines and can restore rp47phox protein within the cytosol of p47phox-deficient EBV-BCL from patients with CGD.
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