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C10 semi-peptoid beta-turn peptidomimetics: syntheses, characterization and biological studiesNnanabu, Ernest 02 June 2009 (has links)
Over the years, the Burgess group has been focusing on the preparation and
testing of small molecules that mimic protein secondary structures for protein-protein
interactions. The most successful compounds made are C10 peptide macrocycles that
effectively mimic β-turns and have given promising results from biological testing. These
peptide macrocycles have also been dimerized to give even more effective ligands for
protein-protein interaction.
The successes of the peptide macrocycles have enabled us to look into increasing
the chemical diversity of our libraries. This we believe will not only improve our ability
to obtain high affinity ligands for the receptors of interest, but will also allow us to
investigate other receptors. To achieve this, peptoids were incorporated into the C10
system to replace the peptides in the i+1 and i+2 positions. With the help of Microwave
irradiation, semi-peptoid macrocycles were synthesized with a total reaction time of less
than 2 h. These compounds were characterized and found to mimic β-turn, and show
promising biological activity towards the Insulin-like growth factor 1 receptor (IGF-IR).
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An investigation into the role of protein-ligand interactions on obligate and transient protein-protein interactionsQuinlan, Robert Jason 17 February 2005 (has links)
Protein-ligand and protein-protein interactions are critical to cellular function. Most cellular metabolic and signal tranduction pathways are influenced by these interactions, consequently molecular level understanding of these associations is an important area of biochemical research. We have examined the thermodynamics of several protein-protein associations and the protein-ligand interactions that mediate them.
Using Fluorescence Correlation Spectroscopy, we have examined the putative interaction between pig heart malate dehydrogenase (MDH) and citrate synthase (CTS). We demonstrate a specific, low-affinity interaction between these enzymes. The association is highly polyethylene glycol (PEG)-dependent, and at high concentrations of NaCl or PEG, non-specific aggregates are formed. We demonstrate that oxaloacetate, the intermediate common to both CTS and MDH, induces the association at concentrations below the Km of CTS, suggesting that the open conformation of CTS is involved in the association.
Using several biophysical techniques, we have examined the subunit associations of B. stearothermophilus phosphofructokinase (PFK). We demonstrate that the inhibitor bound conformation of the enzyme has reduced subunit affinity. The kinetics and thermodynamics of the phosphoenolpyrvuate (PEP)-induced dissociation of PFK have been quantified. Binding substrate, fructose-6-phosphate (F6P), stabilizes the enzyme to inhibitor-induced dissociation by 132-fold. These data suggest that subunit associations may play a role in the allosteric inhibition of PFK by PEP.
The thermodynamics of the protein-ligand associations and allosteric inhibition of E. coli phosphofructokinase have been examined using intrinsic fluorescence and hydrostatic pressure. Both ligand-binding affinity and PEP inhibition are diminished by pressure, whereas substrate-binding affinity for inhibitor-bound enzyme is pressure-insensitive. Larger entropic than enthalpic changes with pressure lead to the overall reduction in free energies.
Using a fluorescence-based assay, we have developed a series of baroresistant buffer mixtures. By combining a buffer with acid dissociation of negative volume with a buffer of positive volume, a pressure-resistant mixture is produced. Alteration of the molar ratio of the two component buffers yields mixtures that are pressure-insensitive at pH values around neutrality.
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Peptidomimetics to mimic protein-protein interactionsXia, Zebin 29 August 2005 (has links)
Quenched Molecular Dynamics (QMD) used to explore molecular conformations was developed to operate in Insight II platform for two simulation engines: CHARMm and Discover. Two scripts and procedures were written for molecular minimization, dynamics, minimization of each of several hundred conformers, and cut off. Experience with Insight II/Discover versus Quanta/CHARMm, and between Insight II/CHARMm versus Quanta/CHARMm has taught that the forcefield is the key factor in QMD studies. Protein A has been used for the purification of commercial antibodies, but it is expensive. Seven peptidomimetics of protein A were designed based on the hot-spots located at the helix-loop-helix region of protein A, and synthesized via solid phase using the Fmoc approach. These peptidomimetics were characterized by MS and NMR. The conformations of four peptidomimetics were studied by NMR and CD in water/hexafluoroisopropanol (pH 4). The CD and NMR data show that addition of hexafluoroisopropanol stabilizes their a-helical conformations. The structures of these peptidomimetics in solution were generated with Quanta/CHARMm using NMR data as limits for the QMD technique. Protein G has also been used to purify antibodies, but it is expensive too. A number of protein G mimics were designed as trivalent molecules. An efficient preparation of trivalent molecules having a useful primary amine arm has been developed through solid phase synthesis. The cheap, commercially available poly(propylene imine) dendrimers were used as scaffolds which allow multimerization of functionalized compounds. A small library of trivalent compounds were synthesized using this approach. A portion of compounds in this library were tested by Amersham Biosciences. The seven amino acid modified DAB-Am-4 exhibits strong binding to the IgG/Fab, and is a potential ligand for IgG purification. The interactions between neurotrophins (ie NGF and NT-3) and their receptors are typical drug targets. Fourteen second-generation peptidomimetics showing NGF-like or NT3-like activities in a preliminary bioassay, were resynthesized and tested again. Preliminary and retested data were compared. To access a direct binding assay, five fluorescently labeled peptidomimetics 41a-e were synthesized for a fluorescence activated cell sorting (FACScan) assay. Six monomeric precursors 42 and 43 were prepared on large scales for the library of bivalent turn analogs
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Structural characterization and domain dissection of human XAF1 protein, and application of solvent-exposed-amide spectroscopy in mapping protein-protein interfaceTse, Man-kit. January 2009 (has links)
Thesis (Ph. D.)--University of Hong Kong, 2010. / Includes bibliographical references (leaves 338-340). Also available in print.
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Characterization of protein interactors of Arabidopsis acyl-coenzyme a-binding protein 2Gao, Wei, January 2009 (has links)
Thesis (Ph. D.)--University of Hong Kong, 2010. / Includes bibliographical references (leaves 204-224). Also available in print.
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Structural characterization and domain dissection of human XAF1 protein, and application of solvent-exposed-amide spectroscopy in mapping protein-protein interface /Tse, Man-kit. January 2009 (has links)
Thesis (Ph. D.)--University of Hong Kong, 2010. / Includes bibliographical references (leaves 338-340). Also available online.
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Characterization of protein interactors of Arabidopsis acyl-coenzyme a-binding protein 2 /Gao, Wei, January 2009 (has links)
Thesis (Ph. D.)--University of Hong Kong, 2010. / Includes bibliographical references (leaves 204-224). Also available online.
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Development of a Bio-Molecular Fluorescent Probe Used in Kinetic Target-Guided Synthesis for the Identification of Inhibitors of Enzymatic and Protein-Protein Interaction TargetsNacheva, Katya Pavlova 01 January 2012 (has links)
Abstract
Fluorescent molecules used as detection probes and sensors provide vital information about the chemical events in living cells. Despite the large variety of available fluorescent dyes, new improved fluorogenic systems are of continued interest. The Diaryl-substituted Maleimides (DMs) exhibit excellent photophysical properties but have remained unexplored in bioscience applications. Herein we present the identification and full spectroscopic characterization of 3,4-bis(2,4-difluorophenyl)-maleimide and its first reported use as a donor component in Forster resonance energy transfer (FRET) systems. The FRET technique is often used to visualize proteins and to investigate protein-protein interactions in vitro as well as in vivo. The analysis of the photophysical properties of 3,4-bis(2,4-difluorophenyl)-maleimide revealed a large Stokes shift of 140 nm in MeOH, a very good fluorescence quantum yield in DCM (Ffl 0.61), and a high extinction coefficient ε(340) 48,400 M-1cm-1, thus ranking this molecule as superior over other reported moieties from this class. In addition, 3,4-bis(2,4-difluorophenyl)-maleimide was utilized as a donor component in two FRET systems wherein different molecules were chosen as suitable acceptor components - a fluorescent quencher (DABCYL) and another compatible fluorophore, tetraphenylporphyrin (TPP). It has been demonstrated that by designing a FRET peptide which contains the DM donor moiety and the acceptor (quencher) motif, a depopulation of the donor excited state occurred via intermolecular FRET mechanism, provided that the pairs were in close proximity. The Forster-Radius (R0) calculated for this FRET system was 36 % and a Forster-Radius (R0) of 26 % was determined for the second FRET system which contained TPP as an acceptor. The excellent photophysical properties of this fluorophore reveal a great potential for further bioscience applications. The 3,4-bis(2,4-difluorophenyl)-maleimide fluorescent moiety was also implemented in an alternative application targeting the enzyme carbonic anhydrase (CAs) are metalloenzymes that regulate essential physiologic and physio-pathological processes in different tissues and cells, and modulation of their activities is an efficient path to treating a wide range of human diseases. Developing more selective CA fluorescent probes as imaging tools is of significant importance for the diagnosis and treatment of cancer related disorders. The kinetic TGS approach is an efficient and reliable lead discovery strategy in which the biological target of interest is directly involved in the selection and assembly of the fragments together to generate its own inhibitors. Herein, we investigated whether the in situ click chemistry approach can be implemented in the design of novel CA inhibitors from a library of non-sulfonamide containing scaffolds, which has not been reported in the literature. In addition, we exploit the incorporation of the (recently reported by us) fluorescent moiety 3,4-bis(2,4-difluorophenyl)-maleimide) as a potential biomarker with affinity to CA, as well as two coumaine derivatives representing a newly discovered class of inhibitors. The screening of a set of library with eight structurally diverse azides AZ1-AZ8 and fifteen functionalized alkynes AK1-AK12 led to the identification of 8 hit combinations among which the most prominent ones were those containing the coumarine and fluorescent maleimide scaffolds. The syn- and anti-tirazole hit combinations, AK1AZ2, AK1AZ3, AK4AZ2, and AK4AZ3 were synthesized, and in a regioisomer-assignment co-injection test it was determined that the enzyme favored the formation of the anti-triazoles for all identified combinations. The mechanism of inhibition of these triazoles was validated by incubating the alkyne/azide scaffolds in the presence of Apo-CA (non-Zn containing) enzyme. It was demonstrated that the Zn-bound water/hydroxide was needed in order to hydrolyze the coumarins which generated the actual inhibitor, the corresponding hydroxycinnamic acid. The time dependent nature of the inhibition activity typical for all coumarine-based inhibitors was also observed for the triazole compounds whose inhibition constants (Ki) were determined in two independent experiments with pre-incubation times of 3 and 25 minutes, respectively. It was observed that the lower Ki values were determined, the longer the pre-incubations lasted. Thus, a novel type of coumarin-containing triazoles were presented as in situ generated hits which have the potential to be used as fluorescent bio-markers or other drug discovery applications.
The proteins from the Bcl-2 family proteins play a central role in the regualtion of normal cellular homeostasis and have been validated as a target for the development of anticancer agents. Herein, in a proof-of-concept study based on a previous kinetic TGS study targeting Bcl-XL, it was demonstrated that a multi-fragment kinetic TGS approach coupled with TQMS technology was successfully implemented in the identification of known protein-protein modulators. Optimized screening conditions utilizing a triple quadruple mass spectrometer in the Multiple Reaction Monitoring (MRM) mode was demonstrated to be very efficient in kinetic TGS hit identification increasing both the throughput and sensitivity of this approach. The multi-fragment incubation approach was studied in detail and it was concluded that 200 fragment combinations in one well is an optimal and practical number permitting good acylsulfonamide detectability. Subsequently, a structurally diverse liberty of forty five thio acids and thirty eight sulfonyl azides was screened in parallel against Mcl-1 and Bcl-XL, and several potential hit combinations were identified. A control testing was carried out by substituting Bcl-XL with a mutant R139ABcl-XL, used to confirm that the potential kinetic TGS hit combinations were actually forming at the protein's hot spot and not elsewhere on the protein surface. Although, the synthesis of all these kinetic TGS hit compounds is currently ongoing, preliminary testing of several acylsulfonamides indicate that they disrupt the Bcl-XL/Bim or Mcl-1/Bim interaction.
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Novel tools for the study of protein-protein interactions in pluripotent cellsMoncivais, Kathryn Lauren 15 January 2013 (has links)
Unnatural amino acids (UAAs) have been used in bacteria and yeast to pinpoint protein binding sites, identify binding partners, PEGylate proteins site-specifically (vs. randomly), and attach small molecule fluorophores to proteins. The process of UAA incorporation involves the manipulation of the genetic code, which is established by the proper function of aminoacyl tRNA synthetases (RSs) and their cognate transfer RNAs (tRNAs). It has been discovered that certain regions of RS proteins can either block or enable cross-species reactivity of RSs. In essence, a bacterial RS can function with a human tRNA by transferring the human CP1 region to the bacterial RS, and vice versa. This knowledge has been used to engineer a tRNA capable of recognizing a stop codon (tRNA*), rather than an amino acid codon, and a cognate RS capable of recognizing only tRNA* and no endogenous tRNAs. We have previously described the use of this methodology to engineer a UAA incorporation system capable of amber stop codon suppression in HEK293T cells. Since UAAs are so useful, and their use has now been enabled in mammalian systems, we applied UAA incorporation to pluripotent cells. Stem and pluripotent cells have been the focus of cutting edge research for years, but much of the work done on these cell lines is done in the ignorance of basic biological processes underlying differentiation, dedifferentiation, and tumorigenesis. In order to facilitate the study of these basic biological processes and enable more adept manipulation of differentiation, dedifferentiation, and tumorigenesis, the development and use of two separate UAA incorporation systems is described herein. The overarching goal of this project is to facilitate the study of protein-protein interactions in stem and pluripotent cells. Since we have also previously described the development of a mammalian two-hybrid system, the use of that system in pluripotent cells is also described. / text
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The role of electrostatic fields in Ras-effector binding and functionWalker, David Matthew 07 July 2014 (has links)
The organization of two or more biological macromolecules into a functioning assembly is critical for many biological functions to occur. This phenomenon is the result of subtle interplay between complimentary structural and electrostatic factors. While a growing protein data bank of solved protein structures provides experimental evidence for studying the structural factors that stabilize protein-protein interface, there has been little advance in experimental determination of the electrostatic contributions. This lack of experimental investigation into protein electrostatics results in an inability to describe or predict how protein-protein complexes are arranged and stabilized. This problem is addressed in this dissertation by use of vibrational Stark effect (VSE) spectroscopy in which the spectral transitions of a vibrational probe are directly related to the strength and direction of the electric fields in the vicinity of the probe. The work presented here details an approach using VSE spectroscopy coupled with molecular dynamics simulation (MD) to interpret the role that electrostatics play in organizing the signaling protein Ras' interactions with its downstream effectors Raf and Ral guanosine dissociation simulator (RalGDS). Each chapter describes a specific set of experiments and MD simulations designed to understand the nature of protein-protein interactions. In Chapter 3, changes in the absorption energy of the nitrile probe at nine positions along the Ras-Ral interface were compared to results of a previous study examining this interface with Ral-based probes, and a pattern of low electrostatic field in the core of the interface surrounded by a ring of high electrostatic field around the perimeter of the interface was found. The areas of conserved Stark shifts are used to help describe electrostatic factors that stabilize the Ras-Ral interface. In Chapter 4, VSE is used to describe an electrostatic origin to the binding tilt between complexes formed between Ras and its two effectors Raf and Ral. There are three regions of conserved Stark effect shifts upon docking with WT Ras between the two effectors, indicating that the docked complexes conserve electrostatic fields, resulting in different binding orientation of otherwise structurally similar proteins. Chapter 5 details the use of MD simulation in correlation with VSE data for 18 mutants of the Ras at the oncogenic position 61 site. The combination of experimental and simulations support the hypothesis that position 61 on Ras is used to coordinate an active site water molecule during native guanosine triphosphate (GTP) hydrolysis. / text
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