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Expression, purification and characterisation of a knotted proteinMcNee, John James January 1997 (has links)
No description available.
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Redox regulation of protein phosphatase-1 and ER stress regulation of connective tissue growth factor in cardiomyocytesSingh, Simranjit 26 June 2017 (has links)
No description available.
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Ramanova optická aktivita biomolekul: od jednoduchých modelů ke komplexním systémům / Raman optical activity of biomolecules: From simple models to complex systemsPazderková, Markéta January 2015 (has links)
The aim of the thesis is to utilize Raman optical activity (ROA) to get unique information on peptide/protein conformation, which is otherwise difficult or even impossible to obtain. We have focused on investigation of amide and disulfide groups. Utilizing tailor-made model structures (rigid tricyclic spirodilactams with two interacting nonplanar amide groups), special model peptides and even biologically active molecules (neurohypophyseal hormones and their agonistic and antagonistic analogs, antimicrobial peptide lasiocepsin and its analogs having different disulfide pattern) we have traced specific spectral manifestation of nonplanar amides and disulfides. ROA results were supplemented by data obtained by complementary chiroptical methods - electronic (including vacuum UV - SRCD) and vibrational circular dichroism. When used in a concerted fashion, these techniques provide complex information on peptide/protein secondary structure. Where possible, experimental chiroptical data were compared to ab initio calculations. In chiroptical spectra we have found and interpreted signals reflecting nonplanarity of the amide group. Moreover, in ROA spectra we have identified signals due to S-S stretching vibrations which seem to reflect sense of the disulfide group torsion.
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Struktura a dynamika peptidů a proteinů v roztoku:aplikace Ramanovy optické aktivity / Structure and dynamics of peptides and proteins in solution: application of Raman optical activityProfant, Václav January 2017 (has links)
The thesis inquires the specific and advantageous applications of Raman optical activity (ROA) in wide range of diverse structural and conformational studies of biomolecules and other biologically important molecules. Our investigation was focused on several interconnected topics covering the fields of methodology, basic and applied research. The combination of experimental and theoretical approaches facilitated deeper understanding of studied phenomena, and allowed for the effects of solute-solvent interactions. High-quality spectra of model molecules in the C-H stretching region, acquired as a result of successful extension of ROA measurements to the whole region of fundamental molecular vibrations, enabled verification and further development of methods for ROA spectra simulations encompassing anharmonic corrections. Utilizing spirodilactams with highly nonplanar amide groups, we have traced the specific ROA spectral manifestations of amide nonplanarity. In case of antimicrobial peptide lasiocepsine, we have successfully simulated ROA signals of S-S stretching vibrations which contrary to current belief do not seem to reflect sense of the S-S group torsion. In larger molecular systems, we have better understood the process of the formation of stable polyproline II conformation and proved that ROA may...
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Computational Analyses of Protein Structure and Immunogen DesignPatel, Siddharth January 2015 (has links) (PDF)
The sequence of a polypeptide chain determines its structure which in turns determines its function. A protein is stabilized by multiple forces; hydrophobic interaction, electrostatic interactions and hydrogen bond formation between residues. While the above forces are non-covalent in nature the protein structure is also stabilized by disulfide bonds. Structural features such as naturally occurring cavities in proteins also affect its stability. Studying factors which affect a protein’s structural stability helps us understand complex sequence-structure-function relationships, the knowledge of which can be applied in areas such as protein engineering.
The work presented in this thesis deals with various and diverse aspects of protein structure. Chapter 1 gives an overall introduction on the topics studied in this thesis. Chapter 2 focuses on a unique, non-regular, structural feature of proteins, viz. protein cavities. Cavities directly affect the packing density of the protein. It has been shown that large to small cavity creating mutations destabilize the protein with the extent of destabilization being proportional to the size of cavity created. On the other hand, small to large cavity filling mutations have been shown to increase protein stability. Tools which analyze protein cavities are thus important in studies pertaining to protein structure and stability. The chapter presents two methods which detect and calculate cavity volumes in proteins. The first method, DEPTH 2.0, focuses on accurate detection and volume calculation of cavities. The second method, ROBUSTCAVITIES, focuses on detection of biologically relevant cavities in proteins.
We then study another aspect of protein structure – the disulfide bond. Disulfide bonds confer stability to the protein by decreasing the entropy of the unfolded state. Previous studies which attempted to engineer disulfides in proteins have shown mixed results. Previously, disulfide bonds in individual secondary structures were characterized. Analysis of disulfides in α-helices and antiparallel β-strands yielded important common features of such bonds. In Chapter 3 we present a review of these studies. We then use MODIP; a tool that identifies amino acid pairs which when mutated to cysteines will most likely form a disulfide bond, to analyze disulfide bonds in parallel β-strands.
A direct way to analyze sequence-structure relationships is via mutating individual residues, evaluating the effect on stability and activity of the protein and inferring its effect on protein structure. Saturation mutagenesis libraries, where all possible mutations are made at every position in the protein contain a huge amount of information pertaining to the effect of mutations on structure. Making such libraries and screening them has been an extremely resource intensive process. We combine a fast inverse PCR based method to rapidly generate saturation mutagenesis libraries with the power of deep sequencing to derive phenotypes of individual mutants without any large scale screening. In Chapter 4 we present an Illumina data analysis pipeline which analyzes sequencing data from a saturation mutagenesis library, and derives individual mutant phenotypes with high confidence.
In Chapter 5 we apply the insights derived from structure-function studies and apply it to the problem of protein engineering, specifically immunogen design. The Human Immunodeficiency Virus adopts various strategies to evade the host immune system. Being able to display the conserved epitopes which elicit a broadly neutralizing response is the first step towards an effective vaccine. Grafting such an epitope onto a foreign scaffold will mitigate some of the key HIV defenses. We develop a computational protocol which grafts the broadly neutralizing antibody b12 epitope on scaffolds selected from the PDB. This chapter also describes the only experimental work presented in this thesis viz. cloning, expressing and screening the epitope-scaffolds using Yeast Surface Display. Our epitope-scaffolds show modest but specific binding. In a bid to improve binding, we make random mutant libraries of the epitope-scaffolds and screen them for better binders using FACS. This work is on-going and we aim to purify our epitope-scaffolds, characterize them biophysically and eventually test their efficacy as immunogens.
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