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  • About
  • The Global ETD Search service is a free service for researchers to find electronic theses and dissertations. This service is provided by the Networked Digital Library of Theses and Dissertations.
    Our metadata is collected from universities around the world. If you manage a university/consortium/country archive and want to be added, details can be found on the NDLTD website.
1

Synthesis and Screening of Peptide Libraries for Biological Applications

Trinh, Thi Ba 26 December 2014 (has links)
No description available.
2

Novel Bifunctional Ligands For Neuropathic Pain: Design and Synthesis of Overlapping Pharmacophores of Opioid and Melanocortin Ligands

Kulkarni, Vinod V. January 2012 (has links)
Biologically many disease states lead to changes in expressed proteins. Therefore, "system changes" that occur must be considered in any treatment for the disease. This new approach to drug design and discovery would be particularly applicable to the diseases that involve adaptive changes in the central nervous system, such as neuropathic pain. There is growing evidence that drugs behave differently in pathological states than in normal states, thus preventing their effectiveness in pathological disease states. Therefore, a new paradigm for drug design is needed. In recent years, the melanocortin-4 receptor (MC4R) found in the spinal cord and CNS has received growing attention as a therapeutic target. MC4R based agonist ligands produce anti-opioid effects, and researchers have shown that an antagonist of the MC4R can produce pronounced anti-allodynic effect. Opioid receptors have been the central and most efficacious targets sought after for relieving neuropathic pain. In our new approach, single peptide molecules are designed to interact with opioid receptors as an agonist, and as an antagonist at the MC4 receptor. For the treatment of pain, a series of linear and cyclic peptides based on the overlapping pharmacophores of endogenous melanocyte stimulating hormone and opioid ligands are designed through computational aided molecular modeling and synthesized. Throughout the studies the opioid pharmacophore is maintained towards the N-terminal while melanocortin pharmacophore is maintained towards the C-terminal. Cyclization of peptides has been the central synthetic feature in designing the bifunctional ligands. The use of microwave has been shown to be very efficient in cyclizing the peptides. Solvent, reagent, power and temperature conditions are established for the microwave application in aiding the macromolecules for cyclizing their side chain termini.
3

Development of Peptide Cyclization Strategies for Their Incorporation into One-Bead-One-Compound Peptide Libraries

Blair, Lauren Elizabeth January 2015 (has links)
Thesis advisor: Jianmin Gao / Thesis advisor: Eranthie Weerapana / Cyclic peptides provide a privileged scaffold when optimizing interactions with various biological targets. Their rigidified structure decreases the entropic cost of binding by preorganizing residues in a fixed conformation, which may enhance binding affinity. These molecules occupy a larger chemical space than typical small molecule drugs and may provide good candidates for inhibiting protein-protein interactions or being able to interact with previously undruggable targets. Given the benefits of these structures we aim to develop a one-bead-one-compound peptide library for screening against relevant biological targets. Herein we describe several routes to achieving cyclic peptides through side chain interactions and head-to tail amide bond linkages. Additional considerations for the development of the on resin library such as linker strategies and sequencing methods will be discussed. / Thesis (MS) — Boston College, 2015. / Submitted to: Boston College. Graduate School of Arts and Sciences. / Discipline: Chemistry.
4

The Development of Intrinsically Cell-Permeable Peptide Libraries Using mRNA Display

Abrigo, Nicolas A 01 January 2019 (has links)
Peptides are emerging as promising therapeutics due to their inhibitory affinity towards protein-protein interactions (PPI). However, peptides have been limited mainly by their poor bio-stability and lack of cell permeability. Efforts to generate drug-like peptides have led to the development of macrocyclic peptides, which exhibit improved stability. Yet, most macrocyclic peptides still require the assistance of a cell penetrating peptide (CPP) for cellular entry. High throughput technologies have been exceptional tools for the discovery of peptides to interrupt PPIs. This work details the recent advancements we have made to improve our high throughput technique, mRNA display, to yield more therapeutically relevant peptides to inhibit PPIs. Our advancements are focused on cell permeability, protease stability, and secondary structure for enhanced affinity. Here we develop and optimize a cyclic CPP that can be included in future mRNA display libraries. We also tested the ability of our CPP to deliver an impermeable peptide cargo into cells. We rationally designed and tested linear and cyclic peptides to improve affinity to the BRCA1 protein. We used computational work to complement our experimental results for our CPPs and BRCA1 inhibitors. We examined peptides that arose from a library containing a mix of linear, monocyclic, and bicyclic peptides constructed using orthogonal cyclization chemistries. We rationally designed cyclic peptides and tested their affinity against Hsp70. We proposed a novel selection strategy to find optimal CPP motifs.
5

Development of Peptide Binders : Applied to Human CRP, Carbonic Anhydrase (II, IX) and Lysine Demethylase 1

Yang, Jie January 2017 (has links)
In this thesis, a polypeptide binder concept is illustrated. By conjugation to a set of sixteen polypeptides, a small binding molecule can evolve into a polypeptide binder with increased affinity and selectivity. The concept was applied to 2-oxo-1,2-dihydroquinoline-8-carboxylic acid (DQ) and acetazolamide (AZM) for development of high affinity binders targeting human C-reactive protein (CRP) and human carbonic anhydrase (HCA) II and IX respectively. In addition, peptididic macrocycles were developed as inhibitors of lysine specific demethylase 1 (LSD1). CRP is a well-known biomarker of inflammation in humans and binders recognizing it are therefore of large interest as medical diagnostics. Until now, phosphocholine (PCh) and derivatives are the only known small molecule binders for CRP, but they have low μM affinity and bind CRP in a Ca2+ dependent manner. The small molecule DQ was designed as a CRP binder that is structurally unrelated to PCh. Its polypeptide conjugate, 4-C25l22-DQ, was demonstrated as a strong, Ca2+ independent binder for CRP, and had an affinity approximately three orders of magnitude higher than DQ itself. HCA IX is a protein that is interesting for diagnosis of cancer. AZM is a small molecule inhibitor of HCAs with a dissociation constant of 38 nM for HCA II and 3 nM for HCA IX. Interestingly, polypeptide conjugate 4-C10L17-AZM displayed stronger binding to both HCA II (KD 4 nM) and HCA IX (KD 90 pM). This result provided evidence that the binder concept can be applied also for small molecules which already have high affinity for their protein receptors. LSD1 is an enzyme that regulates the methylation of Lys 4 of histone 3 via a PPI-like interaction and which is of therapeutic interest in certain cancers. Based on the structures of two peptidic ligands bound to LSD1, we sequentially prepared truncated, mono-substituted and macroyclic peptides in order to develop reversible inhibitors of LSD1. Some stapled cyclic peptides bound to LSD1 with 10-fold higher affinity than the corresponding linear parent peptide. Changing the staple into a lactam further improved the binding potency and the best lactams inhibited the enzymatic activity of LSD1 at low μM Ki values.
6

SURE PROTEIN FOR PEPTIDE CYCLIZATION

Brianne S Nunez (11185875) 26 July 2021 (has links)
<div>Cyclic peptides are important sources of medicines. </div><div>They are advantageous compared to linear peptides because they possess lower flexibility, which allows for high-affinity target binding and enhanced proteolytic stability. Unfortunately, achieving head-to-tail cyclization of peptides is quite challenging, as it is hard to control efficiency and regiospecificity of peptide macrocyclization. Many have attempted to improve peptide cyclization, including the use of different synthetic reagents as well as synthetic techniques to allow amide-bond formation and promote cyclization. While these strategies have offered great potential solutions, the aim of this study is to explore an alternative strategy that utilizes biocatalysis as a method of achieving successful peptide cyclization. Biocatalysis is the use of enzymes as natural process catalysts under artificial in vitro conditions. Biocatalysis is often more environmentally friendly and safer compared to traditional organic synthesis methods. Non-ribosomal peptide synthetases (NRPSs) are one of the major sources of cyclic peptides in nature. These are systems of large multifunctional proteins are organized into functional domains that act as an assembly line to generate peptide natural products. Normally, the thioesterase domain is responsible for hydrolysis and cyclization of the peptide. Recently, a novel cyclase (SurE) that is physically discrete from the NRPS was discovered. Based on this unique quality, we hypothesized that SurE would be easier to express compared to thioesterase domains and, for this reason, SurE could be a fantastic biocatalyst for the cyclization of peptides. To test this, we designed and generated an expression vector for SurE. We then expressed and purified the SurE protein. We also synthesized three linear peptides of varying lengths. To test for SurE activity, we attempted to add N-acetylcysteamine (SNAC) to mimic its native substrate. Unfortunately, we were unable to successfully attach the SNAC to our linear peptide. To combat this issue, a new synthesis strategy is currently being developed. This work is currently ongoing in the Parkinson lab, with the aim being to test the SurE protein, as well as other PBP-like cyclases, on other modified linear peptides and demonstrate whether the protein has the ability to cyclase a wide scope of peptides.</div><div><br></div>

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