Antigen-mediated growth control of hybridoma cells via a human artificial chromosome.

Human artificial chromosome (HAC) vectors possess several characteristics sufficient for the requirements of gene therapy vectors, including stable episomal maintenance and mediation of long-term transgene expression. In this study, we adopted an antigen-mediated genetically modified cell amplification (AMEGA) system employing an antibody/cytokine receptor chimera that triggers a growth signal in response to a cognate non-toxic antigen, and applied it to growth control of HAC-transferred cells by adding an antigen that differed from cytokines that may manifest pleiotropic effects. We previously constructed a novel HAC vector, 21 Delta qHAC, derived from human chromosome 21, housed in CHO cells. Here, we constructed an HAC vector harboring an ScFv-gp130 chimera responsive to fluorescein-conjugated BSA (BSA-FL) as well as a model transgene, enhanced green fluorescent protein (EGFP), in CHO cells. The modified HAC was transferred into interleukin (IL)-6-dependent hybridoma 7TD1 cells by microcell-mediated chromosome transfer, and the cells were subsequently found to show BSA-FL-dependent cell growth and sustained expression of EGFP in the absence of IL-6. The AMEGA system in combination with HAC technology will be useful for increasing the efficacy of gene therapy by conferring a growth advantage on the genetically modified cells.

Exogenous gene expression and growth regulation of hematopoietic cells via a novel human artificial chromosome.

A number of gene delivery systems are currently being developed for potential use in gene therapy. Here, we demonstrate the feasibility of 21deltaqHAC, a newly developed human artificial chromosome (HAC), as a gene delivery system. We first introduced a 21deltaqHAC carrying an EGFP reporter gene and a geneticin-resistant gene (EGFP-21deltaqHAC) into hematopoietic cells by microcell-mediated chromosome transfer. These HAC-containing hematopoietic cells showed resistance to geneticin, expressed EGFP and retained the ability to differentiate into various lineages, and the EGFP-21deltaqHAC was successfully transduced into primary hematopoietic cells. Hematopoietic cells harboring the EGFP-21deltaqHAC could still be detected at two weeks post-transplantation in immunodeficient mice. We also showed effective expansion of hematopoietic cells by introducing the 21deltaqHAC containing ScFvg, a gp130-based chimeric receptor that transmits growth signals in response to specific-antigen of this receptor. All of these results demonstrate the usefulness of HAC in gene therapy.

A novel human artificial chromosome vector provides effective cell lineage-specific transgene expression in human mesenchymal stem cells.

Mesenchymal stem cells (MSCs) hold promise for use in adult stem cell-mediated gene therapy. One of the major aims of stem cell-mediated gene therapy is to develop vectors that will allow appropriate levels of expression of therapeutic genes along differentiation under physiological regulation of the specialized cells. Human artificial chromosomes (HACs) are stably maintained as independent chromosomes in host cells and should be free from potential insertional mutagenesis problems of conventional transgenes. Therefore, HACs have been proposed as alternative implements to cell-mediated gene therapy. Previously, we constructed a novel HAC, termed 21 Deltapq HAC, with a loxP site in which circular DNA can be reproducibly inserted by the Cre/loxP system. We here assessed the feasibility of lineage-specific transgene expression by the 21Deltapq HAC vector using an in vitro differentiation system with an MSC cell line, hiMSCs, which has potential for osteogenic, chondrogenic, and adipogenic differentiation. An enhanced green fluorescent protein (EGFP) gene driven by a promoter for osteogenic lineage-specific osteopontin (OPN) gene was inserted onto the 21 Deltapq HAC and then transferred into hiMSC. The expression cassette was flanked by the chicken HS4 insulators to block promoter interference from adjacent drug-resistant genes. The EGFP gene was specifically expressed in the hiMSC that differentiated into osteocytes in coordination with the transcription of endogenous OPN gene but was not expressed after adipogenic differentiation induction or in noninduction culture. These results suggest that use of the HAC vector is suitable for regulated expression of transgenes in stem cell-mediated gene therapy.