Computational And Experimental Studies On Protein Structure, Stability And Dynamics

Adkar, Bharat V

10 1900

The work in this thesis focuses on the study of three main aspects of proteins, viz, Protein structure, stability, and dynamics. Chapter 1 is a general introduction to the topics studied in this thesis. Chapter 2 deals with the first aspect, i.e., protein structure in which we describe an approach to use saturation mutagenesis phenotypes to guide protein structure prediction. Chapters 3 and 4 discuss how to increase protein stability using surface electrostatics, and Chapter 5 details a method to predict whether a proline substitution in a given protein would be stabilizing or destabilizing. Hence, Chapters 3-5 can be associated with the second aspect, i.e., protein stability. The third aspect, namely protein dynamics, is dealt with in Chapters 6 and 7 which study conformational dynamics of adenylate kinase. Protein structure prediction is a difficult problem with two major bottlenecks, namely, generation of accurate models and the selection of the most appropriate models from a large pool of decoys. In Chapter 2, the problem of model discrimination is addressed using mutant phenotype information derived from saturation mutagenesis library. A library of ~1500 single-site mutants of the E. coli toxin CcdB (Controller of Cell Division or Death B) has been previously constructed in our lab. The pooled library was characterized in terms of individual mutant phenotypes at various expression levels which were derived from the relative populations of mutants at each expression level. The relative populations of mutants were estimated using deep sequencing. Mutational tolerances were derived from the phenotypic data and were used to define an empirical parameter which correlated with a structural parameter, residue depth. We further studied how this new parameter can be used for model discrimination. Increasing protein stability in a rational way is a challenging problem and has been addressed by various approaches. One of the most commonly used approaches is optimization of protein core residues. Recently, optimization of protein surface electrostatics has been shown to be a useful approach for increasing stability of proteins. In Chapter 3, from analyses of a dataset of ~1750 non-homologues proteins, we show that proteins having a pI away from physiological pH, possess a significant fraction of unfavorably placed charged amino acids on their surface. One way to increase protein stability in such cases might be to alter these surface charges. This hypothesis was validated experimentally by making charge reversal mutations at putative unfavorable positions on the surface of maltose binding protein, MBP. The observed stabilization can potentially be increased by combining multiple individually stabilizing mutations. Different combinations of such mutations were made and tested in Chapter 4 to decide which mutants can be combined to achieve net stabilization. Ideas were tested through systematic experimentation which involved generation of two-site, three-site, and four-site mutations. A maximum increase in melting temperature (Tm) of 3-4 °C over wild-type protein was achieved upon combination of individually stabilizing mutants. Proline (Pro) has two special stereo-chemical properties when it is a part of a polypeptide chain. First the φ value of Pro has a very constrained distribution and second, Pro lacks an amide hydrogen. Due to these properties, introduction of Pro might perturb stability/activity of the protein. In Chapter 5 we describe a procedure to accurately predict the effects of Pro introduction on protein stability. Pro scanning mutagenesis was carried out on the model protein CcdB and the in vivo activity of the individual mutants was also examined. A decision tree was constructed, using the special stereo-chemical properties of Pro to maximize correlation of predicted phenotype with the in vivo activity. Binary classification as perturbing or non-perturbing of every Pro substitution was possible using the decision tree. The performance of the decision tree was assessed on various test systems, and the average accuracy was found to be ~75%. The role of conformational dynamics in enzyme catalysis has been explored in great detail in the literature. In Chapter 6, with the help of very long (350 ns), fully atomistic, explicit solvent molecular dynamics simulations, we studied conformational dynamics of adenylate kinase. We found the existence of a relatively stable state which lies intermediate between the open and closed conformations of the enzyme. The finding was further confirmed by computing a two dimensional configurational free energy surface when motions along each of the two movable domains (LID and NMP) are considered as reaction coordinates. We also discussed possible roles of the intermediate state during enzyme catalysis. The role of water in stabilization of intermediate states was also discussed. In Chapter 7, we studied dynamical coupling between LID and NMP domains of adenylate kinase during domain opening. Our observation suggests that the LID domain should start opening prior to the NMP domain. On the domain opening trajectory, the free energy surface of LID domain was found to be very rugged. We discuss a possible role of water in the ruggedness of the domain motions. The Appendix contains 3 supplementary parts of the thesis. Appendix I is a mutant dataset obtained from 454 sequencing analysis. It includes the normalized number of reads per mutation at each expression level along with mutational sensitivity score. Appendix II is parameters used for one of the electrostatic calculations. Appendix III contains a list of PDB ids used for database analysis in surface electrostatics work discussed in Chapter 3.

Proteins

Protein Structure

Protein Stability

Protein Dynamics

Protein Surface Electrostatics

Adenylate Kinase

Proline Mutations

Biochemistry

Conception de nouvelles méthodes de ligation peptidique native et mise au point de nouvelles stratégies d'assemblages séquentielles pour la synthèse totale de protéines / Novel native peptide ligation methods and sequential assembly strategies for protein total synthesis

Raibaut, Laurent

27 November 2013

Les peptides et les protéines jouent un rôle central dans les processus biologiques. Les méthodes de production de ces molécules se sont fortement développées dans le but de déterminer leur structure, comprendre leurs fonctions et développer de nouvelles thérapies. En particulier, la synthèse chimique des protéines s’est fortement développée dans les années 1960 avec l’introduction de la chimie peptidique en phase solide (SPPS) par B. Merrifield. Depuis les années 1990, la combinaison de méthodes de ligation chimique natives et de stratégies d’assemblage séquentielles et convergentes ont permis la synthèse de nombreuses protéines. Cependant, la synthèse de protéines de haut poids moléculaires reste un défi synthétique. Il est donc important de développer de nouveaux systèmes de ligation chimique et des stratégies d’assemblage plus performantes. Une nouvelle méthode de ligation native, la ligation SEA, repose sur la capacité des segments bis(2-sulfanylethyl)amido (SEA) à réagir en milieu aqueux avec des cystéinyl peptides. Différents outils chimiques basés sur l’utilisation du groupement SEA ont été développés dans cette thèse. La première partie de ce manuscrit présente une méthode d’assemblage séquentiel de segments peptidiques en solution s’effectuant du N-terminal vers le C-terminal. Cette méthode a permis la synthèse du domaine N-terminal du facteur de croissance des hépatocytes (HGF). Afin de surmonter les limitations de l’assemblage en solution, la seconde partie de cette thèse porte sur le développement d’un procédé de synthèse de protéines par ligation native séquentielle en phase solide du N-terminal vers le C-terminal. Enfin, une dernière partie exploite la réactivité des segments bis(2-selanylethyl)amido (SeEA) et leur potentiel pour la synthèse de nouveaux échafaudages peptidiques. / Peptides and proteins play a crucial role in all fundamental biological processes. Chemical methods have been developed for the production of peptide and proteins which allows understanding their structures, functions and the development of novel therapies. In particular, the introduction of the Solid Phase Peptide Synthesis (SPPS) by Merrifield in the 60s, followed by the emergence of peptide ligation methods in the 90s have opened the way to the preparation of synthetic proteins. Recently, the developments of sequential and convergent assembly methods give access to large synthetic proteins. However, the synthesis of high molecular weight proteins remains a challenging task. Therefore, it is necessary to develop novel peptide ligation methods and assembly scheme strategies. Central to this PhD work is the recently developed bis(2-sulfanylethyl)amido (SEA) native peptide ligation method. The first part of this manuscript describes an efficient sequential assembly method in the N-to-C direction for protein synthesis in solution which was used for producing a functional N domain of Hepatocyte Growth Factor‎ (HGF). We next examined also a solid phase method for the sequential native ligation of unprotected peptide segments in the N-to-C direction to overcome the limitations in solution. The last part of the manuscript reports the chemicals properties of bis(2-selanylethyl)amido (SeEA) peptide segments and their usefulness for building novel peptide scaffolds.

Ligations chimiques natives

Thioester

Biosynthèse de protéines

Proline

Protéine du pronto-oncogène c-met

Facteur de croisssance des hépatocytes

Diastereoselective multicomponent [3+2] and [4+2] cycloadditions

Selva, Verónica

18 April 2018

En esta tesis doctoral se ha estudiado los iluros de azometino generados in situ en reacciones de cicloadición 1,3-dipolar y diferentes dipolarófilos para la síntesis multicomponente (libre de metales) de derivados de indolizidina a partir de pipecolinatos, aldehídos y dipolarofilos de forma térmica, y también a partir de ácido pipecólico de forma descarboxilada. También se ha estudiado la reacción de cicloadición 1,3-dipolar térmica multicomponente entre iluros de azometino no activados generados in situ a partir de aminas, aldehídos aromáticos y alquenos electrofílicos para generar derivados de pirrolidina.Además, se describe la síntesis de pirrolizidinas diastereoméricamente enriquecidas a partir de nitroprolinatos enantioméricamente puros a través de una cicloadición 1,3- dipolar multicomponente catalizada por una sal de plata y, por otro lado, una reacción de Amina-Aldehído-Dienófilo (AAD) para sintetizar estructuras ciclohex-2-en-1-ilprolinato como diastereoisómero enantiopuro único de forma multicomponente y libre de metales.

Multicomponent

1,3-Dipolar Cycloaddition

Pyrrolidine

Proline

Diels-Alder

Diastereoselective

Química Orgánica

Resurrection of Organophosphorus-Aged Acetylcholinesterase via Mannich Bases Derived from Proline

Ward, Nathan Andrew

January 2019

No description available.

Biochemistry

Chemistry

Organic Chemistry

organophosphorus

resurrection

proline

Mannich bases

resurrection of acetylcholinesterase

organophosphorus-aged

OP-aged AChE

Azomethine Ylides for the Synthesis of Antibiotics, Enantioselective Prolinates and a Graphene-supported Catalyst

Ferrándiz-Saperas, Marcos

15 June 2020

En esta tesis doctoral se ha estudiado la reacción 1,3-dipolar con iluros de azometino y diferentes dipolarófilos para la síntesis de compuestos ópticamente activos, usando diferentes complejos metálicos compuestos por sales de plata y cobre y diversos ligandos quirales. También se ha estudiado la reacción 1,3-dipolar térmicamente para la funcionalización de grafeno, y posterior uso de dicha funcionalización como soporte de un complejo metálico, el cual fue empleado en catálisis heterogénea.

1,3-Dipolar cycloaddition

Diastereoselective

Enantioselective

Pyrrolidine

Proline

Graphene

Catalyst

Química Orgánica

An Exploration into Transient Nanostructures: Spiropyran-based Non-equilibrium Self-assembling Systems

Reardon, Thomas Joseph

12 September 2022

No description available.

Chemistry

Self-assembly

dissipative

spiropyran

nanotubes

proline

aldol condensation

organocatalysis

transient

Construction and Characterization of T7 Bacteriophages Harboring Apidaecin-Derived Sequences

Ludwig, Tobias, Hoffmann, Ralf, Krizsan, Andor

16 January 2024

The global spread of multi- and pan-resistant bacteria has triggered research to identify novel strategies to fight these pathogens, such as antimicrobial peptides and, more recently, bacteriophages. In a proof-of-concept study, we have genetically modified lytic T7Select phages targeting Escherichia coli Rosetta by integrating DNA sequences derived from the proline-rich antimicrobial peptide, apidaecin. This allowed testing of our hypothesis that apidaecins and bacteriophages can synergistically act on phage-sensitive and phage-resistant E. coli cells and overcome the excessive cost of peptide drugs by using infected cells to express apidaecins before cell lysis. Indeed, the addition of the highly active synthetic apidaecin analogs, Api802 and Api806, to T7Select phage-infected E. coli Rosetta cultures prevented or delayed the growth of potentially phage-resistant E. coli Rosetta strains. However, high concentrations of Api802 also reduced the T7Select phage fitness. Additionally, plasmids encoding Api802, Api806, and Api810 sequences transformed into E. coli Rosetta allowed the production of satisfactory peptide quantities. When these sequences were integrated into the T7Select phage genome carrying an N-terminal green fluorescent protein (GFP-) tag to monitor the expression in infected E. coli Rosetta cells, the GFP–apidaecin analogs were produced in reasonable quantities. However, when Api802, Api806 and Api810 sequences were integrated into the T7Select phage genome, expression was below detection limits and an effect on the growth of potentially phage-resistant E. coli Rosetta strains was not observed for Api802 and Api806. In conclusion, we were able to show that apidaecins can be integrated into the T7Select phage genome to induce their expression in host cells, but further research is required to optimize the engineered T7Select phages for higher expression levels of apidaecins to achieve the expected synergistic effects that were visible when the T7Select phages and synthetic Api802 and Api806 were added to E. coli Rosetta cultures.

info:eu-repo/classification/ddc/610

ddc:610

Structural Elements that Regulate Interactions between the Extracellular and Transmembrane Domains of Human Nucleoside Triphosphate Diphosphohydrolase 3

Gaddie, Keith J.

January 2009

No description available.

Biochemistry

NTPDase3

conserved proline residues

conserved polar residues

oligomerization

transmembrane domain

intra-protein signal transduction

Determining the mechanism of elongation factor P -dependent regulation of gene expression

Elgamal, Sara

January 2015

No description available.

Microbiology

Genetics

Biochemistry

Elongation factor P

Ribosome profiling

Protein Translation

pausing

Proline

Design and Study of Novel Antimicrobial Peptides with Proline Substitution

He, Jing

January 2009

No description available.

Biochemistry

antimicrobial peptides

amphipathic beta-sheet forming

proline substitution

bacterial biofilm