Protein folding without loops and charges

Kurnik, Martin

January 2012

Going down the folding funnel, proteins may sample a wide variety of conformations, some being outright detrimental to the organism. Yet, the vast majority of polypeptide molecules avoid such pitfalls. Not only do they reach the native minimum of the energy landscape; they do so via blazingly fast, biased, routes. This specificity and speed is remarkable, as the surrounding solution is filled to the brim with other molecules that could potentially interact with the protein and in doing so stabilise non-native, potentially toxic, conformations. How such incidents are avoided while maintaining native structure and function is not understood.  This doctoral thesis argues that protein structure and function can be separated in the folding code of natural protein sequences by use of multiple partly uncoupled factors that act in a concerted fashion. More specifically, we demonstrate that: i) Evolutionarily conserved functional and regulatory elements can be excised from a present day protein, leaving behind an independently folded protein scaffold. This suggests that the dichotomy between functional and structural elements can be preserved during the course of protein evolution. ii) The ubiquitous charges on soluble protein surfaces are not required for protein folding in biologically relevant timescales, but are critical to intermolecular interaction. Monomer folding can be driven by hydrophobicity and hydrogen bonding alone, while functional and structural intermolecular interaction depends on the relative positions of charges that are not required for the native bias inherent to the folding mechanism. It is possible that such uncoupling reduces the probability of evolutionary clashes between fold and function. Without such a balancing mechanism, functional evolution might pull the carpet from under the feet of structural integrity, and vice versa. These findings have implications for both de novo protein design and the molecular mechanisms behind diseases caused by protein misfolding. / <p>At the time of the doctoral defense, the following paper was unpublished and had a status as follows: Paper 2: Manuscript.</p>

protein folding

folding cooperativity

protein aggregation

protein charges

protein engineering

Étude de la thermodynamique et de la coopérativité du repliement des protéines par haute pression / Study of the thermodynamics and cooperativity of protein folding by high pressure

Fossat, Martin

15 December 2016

Ce travail de thèse ce concentre sur l’étude des protéines par l’usage de haute pression. Les articles présentés ici sont précéder d’une introduction présentant les différents modèles physiques utilisés pour décrire le repliement des protéines, une introduction posant les bases de la thermodynamique, ainsi que l’origine de la stabilité thermodynamique des protéines dans leur état plies. Il y a trois sujets principaux aborder dans ce mémoire. Le premier est l’étude de la coopérativité du repliement et du paysage de repliement de la protéine à répétition PP32 (Anp32a) a travers l’utilisation de la pression a différentes températures. La seconde étude concerne l’investigation de l’origine de l’expansivité thermique des protéines pliées grâce à l’utilisation de RMN haute pression et de la protéine très bien caractérisée Staphylococcal Nuclease (SNase) et de certaine de ses mutantes. Finalement, un dernier article sur la stabilité sous pression de la variant TC5b de la mini protéine model tryptophan-cage grâce une combinaison de RMN et de simulations moléculaires tout-atomes en « replica exchange ». / This thesis work focuses on the study of protein though the use of high pressure. There are three main points subject that are being inquired here. The first is the study of cooperativity and folding landscape of a repeat protein (Anp32a) though the use high pressure denaturation at different temperatures. The second concerns the investigation of the determinant of thermal expansivity in the folded state of protein using high pressure NMR, and the well characterized Staphylococcal Nuclease (SNase) and some of its mutants. Finally, a last article on the pressure stability of the model mini protein Tryptophan cage variant Tc5b by a combination of high pressure NMR and full atomic replica exchange simulations.

Dépliement des protéines

Thermodynamique des protéines

Cooperativite de repliement

Haute pression

Simulation moleculaire

Rmn

Proteins unfolding

Thermodynamic of proteins

Folding Cooperativity

High pressure

Molucular Dynamic Simulations

Nmr