Abstract
Peptide analogues derived from bioactive hormones such as somatostatin or certain growth factors have great potential as angiogenesis inhibitors for cancer applications. In an attempt to combat emerging drug resistance many FDA-approved anti-angiogenesis therapies are co-administered with cytotoxic drugs as a combination therapy to target multiple signaling pathways of cancers. However, cancer therapies often encounter limiting factors such as high toxicities and side effects. Here, we combined two anti-angiogenic epitopes that act on different pathways of angiogenesis into a single non-toxic cyclic peptide framework, namely MCoTI-II (Momordica cochinchinensis trypsin inhibitor-II), and subsequently assessed the anti-angiogenic activity of the novel compound. We hypothesized that the combination of these two epitopes would elicit a synergistic effect by targeting different angiogenesis pathways and result in improved potency, compared to that of a single epitope. This novel approach has resulted in the development of a potent, non-toxic, stable and cyclic analogue with nanomolar potency inhibition in in vitro endothelial cell migration and in vivo chorioallantoic membrane angiogenesis assays. This is the first report to use the MCoTI-II framework to develop a 2-in-1 anti-angiogenic peptide, which has the potential to be used as a form of combination therapy for targeting a wide range of cancers.
Highlights
The cyclic cystine knot (CCK), whereas for SFTI-1, stability results from the cyclic backbone and an extensive hydrogen-bonding network[11]
The anti-angiogenic epitopes chosen for this study included: β-turn-derived peptides from somatostatin (SST-0122 and SST-0223), which target the somatostatin receptor specific to neuroendocrine tumors; a pigment epithelium-derived factor (PEDF)[24,25,26], which targets the PEDF receptor for anti-inflammatory skin disorders and suppresses VEGF endothelial proliferation; and, an anti-VEGF-derived peptide from phage display, which inhibits the interaction of VEGF with the kinase domain receptor (KDR, VEGF-R2)[27,28,29]
The loops chosen for grafting in SFTI-1 and MCoTI-II were based on previous successful examples[18]; in some cases, additional loops were used to explore structure–function relationships
Summary
The cyclic cystine knot (CCK), whereas for SFTI-1, stability results from the cyclic backbone and an extensive hydrogen-bonding network[11]. Multi-targeted therapy is a new paradigm for developing the generation of cancer therapeutics, which emerged because conventional single-targeted therapies often encounter drug resistance issues[21] To address this issue we have grafted anti-angiogenic epitopes into different loops of cyclic disulfide-rich peptide frameworks to enable the design of potent dual-targeting angiogenesis inhibitors. The anti-angiogenic epitopes chosen for this study included: β-turn-derived peptides from somatostatin (SST-0122 and SST-0223), which target the somatostatin receptor specific to neuroendocrine tumors; a pigment epithelium-derived factor (PEDF)[24,25,26], which targets the PEDF receptor for anti-inflammatory skin disorders and suppresses VEGF endothelial proliferation; and, an anti-VEGF-derived peptide from phage display (polyR), which inhibits the interaction of VEGF with the kinase domain receptor (KDR, VEGF-R2)[27,28,29] These epitopes have been shown to inhibit cell proliferation, cell migration and tumor growth in in vitro and in vivo models with low micromolar and nanomolar inhibition[22,23,24,25,27,28]. This study resulted in the development of a promising dual-targeting angiogenesis inhibitor and proved the feasibility of using cyclic disulfide-rich frameworks for multiple loop grafting, which augurs well for the future use of these frameworks in designing peptide-based combination drug therapies for cancer patients
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