The SET protein is a promising drug target in cancer therapy, because of its ability to inhibit the function of the tumor suppressor gene protein phosphatase 2A (PP2A). COG peptides, derived from apolipoprotein E (apoE), are potent antagonists of SET; they induce cytotoxicity in cancer cells upon binding to intracellular SET and modulate the nuclear factor kappa B (NF-κB) signaling pathway. However, the therapeutic potential of COG peptides is limited, because of their poor proteolytic stability and low bioavailability. In this study, the COG peptide, COG1410, was stabilized by grafting it onto the ultrastable cyclic peptide scaffold, Momordica cochinchinensis trypsin inhibitor-II (MCoTI-II). The grafted MCoTI-II peptides were cytotoxic to a cancer cell line and showed high stability in human serum. The most potent grafted MCoTI-II peptide inhibited lipopolysaccharide (LPS)-mediated activation of NF-κB in murine macrophages. Overall, this study demonstrates the application of the MCoTI-II scaffold for the development of stable peptide drugs for cancer therapy.
Glucose regulated protein 78 kDa (GRP78) is a recently emerged target for cancer therapy and a biomarker for cancer prognosis. Overexpression of GRP78 is observed in many types of cancers, with the cell-surface GRP78 being preferentially present in cancer cells and cancer blood vessel endothelial cells. Isthmin (ISM) is a secreted high-affinity proapoptotic protein ligand of cell-surface GRP78 that suppresses angiogenesis and tumor growth in mice. The C-terminal AMOP (adhesion-associated domain in MUC4 and other proteins) domain of ISM is critical in mediating its interaction with human umbilical vein endothelial cells (HUVECs). In this work, we report novel cyclic peptides harboring the RKD motif in the ISM AMOP domain that function as proapoptotic ligands of cell-surface GRP78. The most potent peptide, BC71, binds to GRP78 and converge to tumor in mice. Intravenous administration of BC71 suppressed xenograft tumor growth in mice as a single agent, with significant reduction in tumor angiogenesis and upsurge in apoptosis. Fluorescent-labeled BC71 accumulates in tumor in mice by targeting cell-surface GRP78. We show that BC71 triggers apoptosis via cell-surface GRP78 and activates caspase-8 and p53 signaling pathways in HUVECs. Using amide hydrogen-deuterium exchange mass spectrometry (HDXMS), we identified that BC71 preferentially binds to ATP-bound GRP78 via amino acid residues 244–257 of GRP78. Hence, BC71 serves as a valuable prototype for further development of peptidomimetic anticancer drugs targeting cell-surface GRP78 as well as PET imaging agents for cancer prognosis.
Structure-based drug design has led to the introduction of three drugs--oseltamivir (GS-4104), zanamivir (GG-167) and peramivir (RWJ-270201) which target the enzyme neuraminidase, for treatment of influenza infections. Using comparative docking studies we propose that more potent molecules against neuraminidase can be obtained by appending extra positively charged substituents at the C5 position of the oseltamivir skeleton. This provides an additional interaction with the enzyme and may overcome the problem of resistance encountered with these drugs. To get an insight into the transport and absorption of oseltamivir--the ethyl ester prodrug (GS-4104) as well as its mechanism of action, we have carried out 1H, 13C, 31P NMR, DSC and TEM studies on GS-4104 with model membranes prepared from DMPC/DPPC/POPC. These studies reveal that interactions between GS-4104 and the membrane are both electrostatic (involving H-bonding) and hydrophobic (involving the hydrophobic chain and cyclohexene ring of GS-4104) in nature. The prodrug is seen to increase the fluidity as well as stabilize the bilayer phase of the membrane. This property may be responsible for preventing viral entry into the cells by preventing fusion of the virus outer coat with the cell membrane.
As a part of our ongoing program of developing novel influenza virus inhibitors, some new derivatives of oseltamivir were prepared by modifying the amino group with glycyl, acetyl, benzyl and prolyl moieties. The interactions of these derivatives with neuraminidase have been probed by molecular modeling techniques. Further, the interaction of these derivatives with model membranes prepared from DPPC and the effect on the thermotropic behavior and polymorphism of the bilayers have been investigated by multinuclear NMR and DSC methods. Results indicate that the glycyl derivative of oseltamivir has the most profound effects on the membrane, compared to other derivatives and seems to be the most promising derivative for further pharmacological evaluation as a neuraminidase inhibitor.
The highly pathogenic influenza virus has caused many human fatalities and poses an increasing pandemic threat. Neuraminidase inhibitors such as oseltamivir and zanamivir have been widely used in the treatment and have gained remarkable success. Although, they are effective in prevention of influenza; the concern for drug resistance still remains a question. Recently, the availability of crystal structures of the enzyme gave a new trend to the structure based drug designing of neuraminidase inhibitors. The article reviews a detailed understanding of the structural features within neuraminidase enzyme which turnouts to be crucial for future drug development. In depth analysis for the newly proposed spots within the 150 and 430-loop regions in N1 makes it distinguishable among the subtypes. Further we have discussed the various computational studies carried out in optimizing the designing of neuraminidase inhibitors thereby providing new clues to modify the currently available drugs.
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