Inhibiting Effects of a Cyclic Peptide CNGRC on Proliferation and Migration of Tumor Cells In Vitro

NGR Tumor-Homing Peptides: Structural Requirements for Effective APN (CD13) Targeting

Cyclic CNGRC (cCNGRC) peptides are very important targeting ligands for Aminopeptidase N (APN or CD13), which is overexpressed on the surface of many cancer cells. In this work we have (1) developed an efficient solid-phase synthesis and (2) tested on purified porcine APN and APN-expressing human cells two different classes of cCNGRC peptides: the first carrying a biotin affinity tag or a fluorescent tag attached to the carboxyl Arg-Cys-COOH terminus and the second with the tags attached to the amino H2N-Cys-Asn terminus. Carboxyl-terminus functionalized cCNGRC peptides 3, 6, and 8 showed good affinity for porcine APN and very good capacity to target and be internalized into APN-expressing cells. In contrast, amino-terminus functionalized cCNGRC peptides 4, 5, and 7 displayed significantly decreased affinity and targeting capacity. These results, which are in agreement with the recently reported X-ray structure of a cCNGRC peptide bound to APN showing important stabilizing interactions between the unprotected cCNGRC amino terminus and the APN active site, indicate that the carboxyl and not the amino-terminus of cCNGRC peptides should be used as a "handle" for the attachment of toxic payloads for therapy or isotopically labeled functions for imaging and nuclear medicine.

An antimicrobial peptide containing NGR motif has potent antitumor activity against CD13+ and CD13- tumor cells

Antimicrobial peptides (AMPs) with Asn-Gly-Arg (NGR) motif have potent cytotoxicity, preferably against tumor cells due to their binding to CD13 on tumor cells. However, the importance of αvβ3 expression for antitumor activity of AMPs containing NGR has not been clarified. This study was aimed at designing a new AMP containing NGR and testing their biological activity against different types of tumor cells with varying CD13 and αvβ3 expression. We first synthesized the new AMP containing NGR motif (CK21), which effectively entered into CD13+ HT-1080, but less into CD13- αvβ3+ MDA-MB-435 and further less into stable αvβ3-silencing MDA-MB-435 cells. Furthermore, CK21 displayed dose-dependent antiproliferation against these tumor cells and induced cell cycling arrest at G2/M phases and apoptosis of these tumor cells. In addition, CK21 inhibited the invasion of these tumor cells in vitro and inhibited the growth of implanted tumor cells in vivo. Particularly, the antitumor effect of CK21 in CD13+ HT-1080 was stronger than that of CD13- αvβ3+ MDA-MB-435 and much stronger than that of stable αvβ3-silencing MDA-MB-435. Our data indicated that the new AMPs containing NGR had potent antitumor activity against CD13+ or αvβ3+ tumor cells, preferably against CD13+ tumor cells, possibly through binding to CD13 or αvβ3 on tumor cells.

Radiolabeled NGR phage display peptide sequence for tumor targeting

The asparagine-glycine-arginine (NGR) peptide sequence found by phage display, was radiolabeled with technetium-99m and tested in different tumor models. Similar uptake occurred with ovarian and lung tumor cells. Biodistribution of the radiotracer revealed predominant renal excretion with more substantial uptake in animals bearing ovarian tumor cells. In contrast imaging studies indicated better visualization for lung tumor. NGR peptide was characterized as a promising diagnostic candidate, particularly for lung cancer. Improvements are envisaged using NGR combined with RGD as a heterodimer molecule.