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The Rational Investigation of Anti-Cancer Peptide Specificity using the Knob-Socket ModelPatel, Shivarni 01 January 2017 (has links) (PDF)
Cancer has been a pervasive and deadly problem for many years. No treatments have been developed that effectively destroy cancer cells while also keeping healthy cells safe. In this work, the knob-socket construct is used to analyze two systems involved in cancer pathways, the PDZ domain and the Bcl-BH3 complex. Application of the knob-socket model in mapping the packing surface topology (PST) allows a direct analysis of the residue groups important for peptide specificity and affinity in both of these systems. PDZ domains are regulatory proteins that bind the C-terminus of peptides involved in the signaling pathway of cancer progression. The domain includes five -strands, two -helices, and six coils/turns. In this study, the PST of all eight solved crystal structures of T-cell lymphoma invasion and metastasis 1 (Tiam1) PDZ domains are mapped to reveal details of ligand-domain binding pockets and packing interactions. Four main interactions were identified in the comparison of the PST maps and a consensus sequence was calculated using knob-socket interaction data. In the case of the Bcl-BH3 complex, binding of these two proteins prevents an unhealthy cell from undergoing apoptosis. In the knob-socket mapped protein-ligand interactions, the helical ligand consists of 8 to 10 residues that specifically interact with four helices on the binding protein: the N-terminus of Helix2, the main bodies of Helix3 and Helix4 and the C-terminus of Helix5. Among all of the interactions that were analyzed, there were three amino acids from the ligand, glycine, leucine, and isoleucine, that always packed into the hydrophobic groove that is key for ligand recognition. By using knob-socket analysis to map quaternary packing structure, it was possible to identify the quaternary-level protein interactions that define ligand specificity and binding strength. From this analysis, possible protein mimetics can be developed that could be used as cancer treatments.
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Rational design, characterization and in vivo studies of antibody mimics against HER2Su, Dan 01 January 2015 (has links)
Human Epidermal Growth Factor Receptor 2 (HER2) is a cell surface receptor tyrosine kinase and plays a role in the signal pathways leading to cell proliferation and differentiation. Overexpression of HER2 is found in various cancers including breast, ovarian, gastric, colon, and non-small-cell lung cancers, which makes it an attractive target for cancer therapy. Specific antibodies, peptides and small molecules are developed by scientists to bind with HER2 as therapeutical agents, dimerization inhibitors and biological makers. Among these molecules, antibodies showed excellent binding affinity and specificity toward HER2. However, uses of antibodies are limited by their high cost of production, long development time, limited ability to penetrate tumor tissue and immunogenicity. Many of these limitations are due to the high molecular weight of antibodies. Compared to antibodies, peptides and small molecule that selectively recognize HER2 have advantages in solubility, permeability and immunogenicity. So far, the design of all peptides and small molecules for binding with HER2 either utilize phage display technique or rely on computational screen of large library of millions of small molecules. These approaches all suffer from the drawbacks of tedious, labor intensive, and time consuming as well as uncertainty of outcome. In this study, it was hypothesized that a novel approach based on molecular interactions of HER2-Pertuzumab complex and Knob-Socket model can be developed to design antibody mimics for targeting HER2. All designed antibody mimics were simulated and docked with HER2 using Molecular Operating Environment (MOE) software to estimate binding energy and analyze the detail interaction map. A series of mimics were then synthesized and characterized. HER2 positive breast cancer cells MDA-MB-361 and ZR-75-1 were used in confocal microscopic and flow cytometric studies to evaluate the binding specificity of all antibody mimics to HER2 in vitro, while human embryonic kidney cell (HEK293) was used as control. After incubation with antibody mimics, high fluorescence intensities were observed on MDA-MB-361 and ZR-75-1 cells, while only background fluorescence were observed on HEK293 cells. Surface plasma resonance (SPR) studies showed that all antibody mimics bind to HER2 protein with KD value in range of 55.4 nM- 525.5 nM. Western blot technique was used to evaluate inhibition capability of antibody mimics on phosphorylation of HER2 downstream signaling Akt and MAPK pathways that were crucial for cell differentiation and survival. When treated with antibody mimics at 10µM for 24 h, more than 85% phosphorylation of Akt pathway was inhibited while phosphorylation of MAPK pathway was not affected. This finding proved that antibody mimics could bind to HER2 extracellular domain and selectively inhibit the dimerization between HER2 and HER3 to block phosphorylation of Akt pathway in a similar way as Pertuzumab. In addition, in vivo studies on tumor bearing nude mice were carried out to investigate the distribution and binding specificity of antibody mimics towards HER2 positive tumor after injecting through vein tail. Signal intensity ratio (SIR) of tumor to muscle revealed about 10-fold increase in tumor retention of HER2-PEP11 compared to the Cy7.5 carboxylic acid and Cy7.5-HER2-PEP22, which confirmed excellent in vivo binding specificity of antibody mimic HER2-PEP11 to HER2 positive tumor. In conclusion, this study demonstrated that a rational design of antibody mimics with both binding specificity and affinity towards HER2 based on the molecular interaction between Pertuzumab and HER2 and Knob-Socket model is feasible.
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Exploring the molecular architecture of proteins: Method developments in structure prediction and designChavan, Archana G. 01 January 2014 (has links) (PDF)
Proteins are molecular machines of life in the truest sense. Being the expressors of genotype, proteins have been a focus in structural biology. Since the first characterization and structure determination of protein molecule more than half a century ago1, our understanding of protein structure is improving only incrementally. While computational analysis and experimental techniques have helped scientist view the structural features of proteins, our concepts about protein folding remain at the level of simple hydrophobic interactions packing side-chain at the core of the protein. Furthermore, because the rate of genome sequencing is far more rapid than protein structure characterization, much more needs to be achieved in the field of structural biology. As a step in this direction, my dissertation research uses computational analysis and experimental techniques to elucidate the fine structural features of the tertiary packing in proteins. With these set of studies, the knowledge of the field of structural biology extends to the fine details of higher order protein structure.
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