Selective enhancement of gene transfer by steroid-mediated gene delivery.

The incorporation of transgenes into the host cells' nuclei is problematic using conventional nonviral gene delivery technologies. Here we describe a strategy called steroid-mediated gene delivery (SMGD), which uses steroid receptors as shuttles to facilitate the uptake of transfected DNA into the nucleus. We use glucocorticoid receptors (GRs) as a model system with which to test the principle of SMGD. To this end, we synthesized and tested several bifunctional steroid derivatives, finally focusing on a compound named DR9NP, consisting of a dexamethasone backbone linked to a psoralen moiety using a nine-atom chemical spacer. DR9NP binds to the GR in either its free or DNA-crosslinked form, inducing the translocation of the GR to the nucleus. The expression of transfected DR9NP-decorated reporter plasmids is enhanced in dividing cells: expression of steroid-decorated reporter plasmids depends on the presence of the GR, is independent of the transactivation potential of the GR, and correlates with enhanced nuclear accumulation of the transgene in GR-positive cells. The SMGD effect is also observed in cells naturally expressing GRs and is significantly increased in nondividing cell cultures. We propose that SMGD could be used as a platform for selective targeting of transgenes in nonviral somatic gene transfer.

Comparison of lipid-mediated and adenoviral gene transfer in human monocyte-derived macrophages and COS-7 cells.

Lipid-mediated transfection was compared to adenoviral-mediated gene transfer in COS-7 cells as well as human monocyte-derived macrophages (HMDM). For this purpose, we monitored enhanced green fluorescent protein (EGFP) expression by fluorescence microscopy and quantified gene transfer by competitive PCR. Transfection of COS-7 cells with a novel lipid formulation for DNA transfer was highly effective in COS-7 cells. On average, 30% of the cells were fluorescent 48 h after transfection. In HMDM, the same formulation resulted in the expression of EGFP in less than 0.5% of cells. We measured plasmid DNA by quantitative PCR in lipid-transfected macrophages and found that each macrophage contained on average 2 fg of plasmid DNA 24 h after transfection, that is, more than 400 molecules of plasmid DNA entered each cell. Despite the high level of reporter DNA in lipid transfected cells, expression of the fluorescent protein was suppressed in more than 99.5% of the macrophages. We also used adenoviral gene transfer to introduce the foreign DNA into both COS-7 cells and HMDM. Even though the multiplicity of infection was less than 30, expression of EGFP was observed in nearly all COS-7 cells and in more than 80% of HMDM 48 h after transfection. Despite major advances in the field of lipid-mediated transfection of HMDM, the lipid formulations that are available commercially cannot compete with the efficiency of adenoviral gene transfer.

Definition of a negative modulation domain in the human progesterone receptor.

The progesterone receptor (PR) occurs in two major forms, the full-length PRB and the amino-truncated PRA, which lacks 164 amino-terminal residues. PRB functions as a strong transcriptional activator of progesterone-responsive genes, whereas PRA is inactive in several cell types where it may even act as a trans-dominant repressor of PRB and other steroid receptors, like the glucocorticoid receptor or, reportedly, the estrogen receptor. We initially observed that a PR deleted of its entire amino domain (PR538-C) is incapable of trans-repressing PRB or glucocorticoid receptor, suggesting that a negative modulation domain must be contained in the region between position 165 and 538. After testing progressive deletion mutants and chimeras, we demonstrate that this negative modulating domain is confined within 120 residues in the amino-terminal region and that it contains a subdomain of 40 residues that is crucial for intermolecular transrepression. Duplication, deletion, and transplantation of the negative modulation domain show that the negative modulation domain has only a limited functional autonomy. In our hands, transrepression of estrogen receptor could not be substantiated, and, under our conditions, at least an equimolar concentration of PRA expression plasmid is required for transrepression. Our deletion studies reveal domains that correlate with strong homology patches between the amino-terminal domains of mammalian and avian PR.

The DNA-binding properties of an artificial 42-residue polypeptide derived from a natural repressor.

Bacteriophage 434 repressor recognizes the operator sequences ACAAG and ACAAT. As the same or similar sequences occur in the enhancer region of HIV-1, 434 repressor was a potential HIV enhancer-binding protein. We found that the interaction of the DNA-binding domain of 434 repressor with a 57-bp HIV enhancer DNA was very weak whereas a 42-residue construct, comprising the recognition helix and four copies of a positively charged segment of the repressor, bound strongly. The results of footprint and cell-free in vitro transcription studies showed that the 42-residue peptide bound preferably to the enhancer region of HIV-1 and acted as an artificial repressor. Replacement of an essential glutamine of the recognition helix by glutamic acid resulted in a partial shift of the sequence specificity of the 42-residue peptide.