Novel Computational Protein Design Algorithms with Applications to Cystic Fibrosis and HIV

Roberts, Kyle Eugene

January 2014

<p>Proteins are essential components of cells and are crucial for catalyzing reactions, signaling, recognition, motility, recycling, and structural stability. This diversity of function suggests that nature is only scratching the surface of protein functional space. Protein function is determined by structure, which in turn is determined predominantly by amino acid sequence. Protein design aims to explore protein sequence and conformational space to design novel proteins with new or improved function. The vast number of possible protein sequences makes exploring the space a challenging problem. </p><p>Computational structure-based protein design (CSPD) allows for the rational design of proteins. Because of the large search space, CSPD methods must balance search accuracy and modeling simplifications. We have developed algorithms that allow for the accurate and efficient search of protein conformational space. Specifically, we focus on algorithms that maintain provability, account for protein flexibility, and use ensemble-based rankings. We present several novel algorithms for incorporating improved flexibility into CSPD with continuous rotamers. We applied these algorithms to two biomedically important design problems. We designed peptide inhibitors of the cystic fibrosis agonist CAL that were able to restore function of the vital cystic fibrosis protein CFTR. We also designed improved HIV antibodies and nanobodies to combat HIV infections.</p> / Dissertation

Bioinformatics

Biophysics

Biochemistry

Continuous Rotamers

Cystic Fibrosis

HIV Neutralization

Peptide Inhibitors

Protein Design

Provable Algorithms

RNA Backbone Rotamers and Chiropraxis

Murray, Laura Weston

25 July 2007

RNA backbone is biologically important with many roles in reactions and interactions, but has historically been a challenge in structural determination. It has many atoms and torsions to place, and often there is less data on it than one might wish. This problem leads to both random and systematic error, producing noise in an already high-dimensional and complex distribution to further complicate data-driven analysis. With the advent of the ribosomal subunit structures published in 2000, large RNA structures at good resolution, it became possible to apply the Richardson laboratory's quality-filtering, visualization, and analysis techniques to RNA and develop new tools for RNA as well. A first set of 42 RNA backbone rotamers was identified, developed, and published in 2003; it has since been thoroughly overhauled in conjunction with the backbone group of the RNA Ontology Consortium to combine the strengths of different approaches, incorporate new data, and produce a consensus set of 46 conformers. Meanwhile, extensive work has taken place on developing validation and remodeling tools to correct and improve existing structures as well as to assist in initial fitting. The use of base-phosphate perpendicular distances to identify sugar pucker has proven very useful in both hand-refitting and the semi-automated process of using RNABC (RNA Backbone Correction), a program developed in conjunction with Dr. Jack Snoeyink's laboratory. The guanine riboswitch structure ur0039/1U8D, by Dr. Rob Batey's laboratory, has been collaboratively refit and rerefined as a successful test case of the utility of these tools and techniques. Their testing and development will continue, and they are expected to help to improve RNA structure determination in both ease and quality. / Dissertation

Biophysics, General

Biology, Bioinformatics

Chemistry, Biochemistry

RNA

RNA backbone

rotamers

base

phosphate perpendiculars

conformers

RNA structure

Struktur und Biosynthese von Collinolacton aus Streptomyces sp. und Beiträge zum Screening neuer Wirkstoffe / Structure and biosynthesis of collinolactone from Streptomyces sp. and contributions to the screening of new active agents

Hoffmann, Luise

03 May 2006

No description available.

540 Chemie

Mathematics and Computer Science

Streptomyceten

extremophile Mikroorganismen

Naturstoffe

chemisches Screening

Sekundärmetaboliten

Biosynthese

Collinolacton

NMR

Strukturaufklärung

Polyketide

Rotamere

Baeyer-Villiger-Monooxygenase

Cyclodecatrien

monoastraler Spindeltyp

1-O-Acylrhamnopyranoside

Shikimisäure Biosyntheseweg

streptomycetes

extremophilic microorganisms

natural products

chemical screening

secondary metabolites

biosynthesis

collinolactone

NMR

structure elucidation

polyketides

rotamers

Baeyer-Villiger monooxygenase

cyclodecatrien

mono-astral spindle

1-O-acylrhamnopyranosides

shikimi pathway

35.50

35.25

Phytochemical investigation of Acronychia species using NMR and LC-MS based dereplication and metabolomics approaches / Etude phytochimique d’espèces du genre Acronychia en utilisant des approches de déréplication et métabolomique basées sur des techniques RMN et SM

Kouloura, Eirini

28 November 2014

Les plantes médicinales constituent une source inexhaustible de composés (des produits naturels - PN) utilisé en médecine pour la prévention et le traitement de diverses maladies. L'introduction de nouvelles technologies et méthodes dans le domaine de la chimie des produits naturels a permis le développement de méthodes ‘high throughput’ pour la détermination de la composition chimique des extraits de plantes, l'évaluation de leurs propriétés et l'exploration de leur potentiel en tant que candidats médicaments. Dernièrement, la métabolomique, une approche intégrée incorporant les avantages des technologies d'analyse moderne et la puissance de la bioinformatique s’est révélé un outil efficace dans la biologie des systèmes. En particulier, l'application de la métabolomique pour la découverte de nouveaux composés bioactifs constitue un domaine émergent dans la chimie des produits naturels. Dans ce contexte, le genre Acronychia de la famille des Rutaceae a été choisi sur la base de son usage en médecine traditionnelle pour ses propriétés antimicrobienne, antipyrétique, antispasmodique et anti-inflammatoire. Nombre de méthodes chromatographiques modernes, spectrométriques et spectroscopiques sont utilisées pour l'exploration de leur contenu en métabolites suivant trois axes principaux constituant les trois chapitres de cette thèse. En bref, le premier chapitre décrit l’étude phytochimique d’Acronychia pedunculata, l’identification des métabolites secondaires contenus dans cette espèce et l'évaluation de leurs propriétés biologiques. Le deuxième chapitre vise au développement de méthodes analytiques pour l'identification des dimères d’acétophénones (marqueurs chimiotaxonomiques du genre) et aux stratégies utilisées pour la déréplication de ces différents extraits et la caractérisation chimique des composés par UHPLC-HRMSn. Le troisième chapitre se concentre sur l'application de méthodologies métabolomique (RMN et LC-MS) pour l'analyse comparative (entre les différentes espèces, origines, organes), pour des études chimiotaxonomiques (entre les espèces) et pour la corrélation des composés contenus avec une activité pharmacologique. / Medicinal plants constitute an unfailing source of compounds (natural products – NPs) utilised in medicine for the prevention and treatment of various deceases. The introduction of new technologies and methods in the field of natural products chemistry enabled the development of high throughput methodologies for the chemical composition determination of plant extracts, evaluation of their properties and the exploration of their potentials as drug candidates. Lately, metabolomics, an integrated approach incorporating the advantages of modern analytical technologies and the power of bioinformatics has been proven an efficient tool in systems biology. In particular, the application of metabolomics for the discovery of new bioactive compounds constitutes an emerging field in natural products chemistry. In this context, Acronychia genus of Rutaceae family was selected based on its well-known traditional use as antimicrobial, antipyretic, antispasmodic and anti-inflammatory therapeutic agent. Modern chromatographic, spectrometric and spectroscopic methods were utilised for the exploration of their metabolite content following three basic axes constituting the three chapters of this thesis. Briefly, the first chapter describes the phytochemical investigation of Acronychia pedunculata, the identification of secondary metabolites contained in this species and evaluation of their biological properties. The second chapter refers to the development of analytical methods for the identification of acetophenones (chemotaxonomic markers of the genus) and to the dereplication strategies for the chemical characterisation of extracts by UHPLC-HRMSn. The third chapter focuses on the application of metabolomic methodologies (LC-MS & NMR) for comparative analysis (between different species, origins, organs), chemotaxonomic studies (between species) and compound-activity correlations.

Produits naturels

Acronychia

Rutaceae

Acétophénones de type Acronychia

Dimères de phloroglucinol

Rotamères

Enantiomères

Diastereomères

Chromatographie supercritique (SFC)

Activité antibactérienne

Cytotoxicité

Activité anti-inflammatoire

Ionisation par électrospray (ESI)

Orbitrap

Métabolomique

Carbon-13 NMR

UPLC-ESI(±)-HRMS/MS

Analyse en composantes principales (ACP)

Sparse PLS (sPLS)

Natural products

Acronychia

Rutaceae

Acronychia-type acetophenones

Phloroglucinol dimers

Rotamers

Enantiomers

Diastereomers

Supercritical fluid chromatography (SFC)

Antibacterial activity

Cytotoxicity

Anti-inflammatory activity

Activity, electrospray ionization (ESI)

Multistage mass spectrometry

Orbitrap

Metabolomics

Carbon-13 NMR

UPLC-ESI(±)-HRMS/MS

Principal component analysis (PCA)

Partial least squares regression (PLS-r)

Orthogonal partial least squares (OPLS)

Sparse PLS (sPLS)

615.321