1. Peptide-matrix-mediated gene transfer of an oxygen-insensitive hypoxia-inducible factor-1[alpha] variant for local induction of angiogenesis
- Author
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Trentin, Diana, Hall, Heike, Wechsler, Sandra, and Hubbell, Jeffrey A.
- Subjects
DNA-ligand interactions -- Research ,Fibrin -- Structure ,Fibrin -- Research ,Neovascularization -- Research ,Science and technology - Abstract
Hypoxia-inducible factor (HIF) constitutes a target in therapeutic angiogenesis. HIF-1[alpha] functions as a sensor of hypoxia and induces expression of vascular endothelial growth factor (VEGF), which then induces angiogenesis. To explore the potential of HIF-1[alpha] gene therapy in stimulating wound healing, we delivered a gene encoding a stabilized form of HIF-1[alpha], lacking the oxygen-sensitive degradation domain, namely HIF-1[alpha][DELTA]ODD, by using a previously characterized peptide-based gene delivery vector in fibrin as a surgical matrix. The peptide vector consisted of multiple domains: (i) A cysteine-flanked lysine hexamer provided DNA interactions that were stable extracellularly but destabilized intracellularly after reduction of the formed disulfide bonds. This DNA-binding domain was fused to either (ii) a fibrin-binding peptide for entrapment within the matrix or (iii) a nuclear localization sequence for efficient nuclear targeting. The HIF-1[alpha][DELTA]ODD gene was expressed and translocated to the nucleus under normoxic conditions, leading to up-regulation of vascular endothelial growth factor (VEGF)-[A.sub.165] mRNA and protein levels in vitro. When the peptide-DNA nanoparticles entrapped in fibrin matrices were applied to full-thickness dermal wounds in the mouse (10 [micro]g per wound in 30/[micro]l of fibrin), angiogenesis was increased comparably strongly to that induced by VEGF-[A.sub.165] protein (1.25 [micro]g per wound in 30 [micro]l of fibrin). However, the maturity of the vessels induced by HIF-1[alpha][DELTA]ODD was significantly higher than that induced by VEGF-[A.sub.165] protein, as shown by stabilization of the neovessels with smooth muscle. Nonviral, local administration of this potent angiogenesis-inducing gene by using this peptide vector represents a powerful approach in tissue engineering and therapeutic angiogenesis. gene delivery | nonviral vector | polycation | fibrin
- Published
- 2006