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PEGylation of a proprotein convertase peptide inhibitor for vaginal route of drug delivery: In vitro bioactivity, stability and in vivo pharmacokinetics

Author:
Ho, Huiting, Nero, Tracy L., Singh, Harmeet, Parker, Michael W., Nie, Guiying
Source:
Peptides 2012 v.38 no.2 pp. 266-274
ISSN:
0196-9781
Subject:
HIV infections, Human immunodeficiency virus, absorption, animal models, blood serum, cell culture, cervix, chemical bonding, drugs, embryo implantation, females, medicinal properties, mice, pathogenicity, pharmacokinetics, pregnancy, uterus, vaginal mucosa, women
Abstract:
Uterine proprotein convertase (PC) 6 is critical for embryo implantation in mice and women. It is also one of the PC family members that play a vital role in HIV infectivity. We hypothesized that inhibiting PC6 in the female reproductive tract (vagina, cervix and uterus), may protect women from both pregnancy and HIV infection. One key requirement to prove this concept in an animal model is a vaginally deliverable PC6 inhibitor. Nona-d-arginine (Poly R) is a potent peptide PC inhibitor and is able to inhibit HIV in cell culture. We modified Poly R by PEGylation with different strategies and determined their biochemical properties in vitro and in vivo. PEGylation at the C-terminus, regardless of the PEG size (30kDa or 1239Da) did not compromise the inhibitory potency of Poly R. In contrast, PEGylation at both termini (1239Da) dramatically reduced its inhibitory activity. Poly R and C-PEGylated Poly Rs also showed equal potency in inhibiting a PC6-dependent cellular process critical for embryo implantation. Poly R and the equipotent C-PEGylated Poly Rs were further tested for their serum stability in vitro and pharmacokinetics in vivo following vaginal administration in mice. All Poly Rs were equally stable in mouse serum in vitro for 24h; C-PEGylated Poly Rs showed enhanced vaginal absorption and penetration across the vaginal mucosa/epithelium. This is the first report that C-terminal PEGylation significantly enhances the therapeutic properties of Poly R for vaginal drug delivery. Our findings also provide important insights into future design of Poly R derivatives.
Agid:
1054640