Etude fonctionnelle de l'acétylcholinestérase : régulation de la catalyse par la région de la porte arrière, et recherche d'un partenaire non-catalytique endogène : Mise en évidence et caractérisation d'une nouvelle cible de la fasciculine, distincte de l'acétylcholinestérase

Mondielli, Grégoire

19 December 2011

Les trois projets que j’ai développés au cours de ma thèse s’inscrivent dans un même contexte, celui de l’étude de l’acétylcholinestérase (AChE) et des molécules apparentées à l’AChE au plan structural ou fonctionnel. Existence, identification et caractérisation du fonctionnement d’une « porte arrière » dans l’AChE. Caractérisation de la « protéine X », un récepteur non AChE de la fasciculine. Recherche d’un partenaire protéique endogène de l’AChE dans le cerveau de rat. / The three projects I developed during my thesis are related to the study of acetylcholinesterase (AChE) and of molecules related to AChE in their function or structure. Existence, identification and characterization of the functioning of a back door in AChE. Characterization of “protein X”, a non-AChE receptor for fasciculin. Search for an endogenous proteic partner of AChE in rat brain.

Acétylcholinestérase

Adhésion cellulaire

Biochimie

Catalyse

Cerveau

Fasciculine

Inhibition

Organe électrique

Relation structure-fonction

Pharmacologie

Acetylcholinesterase

Cellular adhesion

Biochemistry

Catalysis

Brain

Fasciculin

Inhibition

Electric organ

Structure-function relationship

Pharmacology

Axonal homeostasis of VGLUT1 synaptic vesicles in mice / Homéostasie axonale des vésicules synaptiques des neurones excitateurs VGLUT1 chez la souris

Zhang, Xiaomin

14 December 2016

Les vésicules synaptiques (VSs) sont essentielles pour la neurotransmission. Les recherches actuelles se focalisent sur la caractérisation de leur contenu en neurotransmetteurs, leur cinétique de libération, leur distribution et leur mobilité. Les VS ne sont pas présentes exclusievement en paquet dans les boutons présynaptiques mais sont echangées de façon dynamique avec le reste de l’axone dans un super-contingent (super-pool). Notre laboratoire a précédement montré que le transporteur vésiculaire de glutamate de type 1 (VGLUT1) jouerait un rôle dans la régulation du super-pool. Mon projet de thèse se focalise sur la mobilité des VS dans les axones. En premier lieu, j’ai généré une souris gain de fonction VGLUT1mEos2 afin d'étudier la mobilité des VSs et de mieux caractériser le super-pool. Ensuite j’ai engagé une étude des relation entre la structure de VGLUT1 et ses fonctions afin d’identifier les signatures moléculaires responsable de la régulation de la taille du super-pool. J’ai identifié le second motif poly-proline à l’extremité C-terminale de VGLUT1 comme étant nécessaire et suffisante pour induire une diminution de la taille du super-pool des VSs. Pour conclure mes travaux de thèse ont contribué à la compréhension du rôle de VGLUT1 dans la régulation de la mobilité des VSs et à fournir les outils nécessaires pour de futures investigations concernant la physiologie du super-pool. / Synaptic vesicles (SVs) are essential for neurotransmission, and more efforts are needed for better understanding their neurotransmitter content, release kinetics, distribution and mobility. SVs are not only clustered in presynaptic boutons, but also dynamically shared among multiple en passant presynaptic boutons, a phenomenon named SV super‐pool. Previous work from our laboratory suggested that the Vesicular GLUtamate Transporter 1 (VGLUT1) may play a role in regulating SV super-­pool size beyond loading glutamate into SV. My Ph.D project is focused on SVs mobility in axons. Firstly, I generated a VGLUT1mEos2 knock-in (KI) mouse line, which provides extended possibilities to study the SV trafficking and characterize SV super‐pool. Secondly, I engaged in a thorough VGLUT1 structure‐function analysis. I identified that VGLUT1 tends to cluster SVs in the presynaptic boutons and reduce SVs exchange with the super‐pool via the second poly‐proline motif of its C­‐terminus. Overall, my Ph.D work contributes to the knowledge of the role of VGLUT1 in regulating SVs mobility and provides new tools for the further investigations on SV super-­pool physiology.

Mobilité des vésicules synaptiques

VGLUT1

Super-pool

Imagerie en temps réel

Analyse structure-fonction

Synaptic vesicle mobility

VGLUT1

Super-pool

Live imaging

Structure-function analyses

Estudos estruturais e funcionais de diidroorotato desidrogenases / Structural and functional studies of dihydroorotate dehydrogenase

Carvalho, Sheila Gonçalves do Couto

28 March 2008

As enzimas diidroorotato desidrogenases (DHODHs) são flavo-enzimas que catalisam a oxidação do diidroorotato em orotato na quarta etapa da biossíntese de novo de nucleotídeos de pirimidina. Durante a rápida proliferação celular em mamíferos, a via de salvação de pirimidinas é insuficiente para suprir deficiências na síntese de nucleotídeos. Além disso, certos parasitas não possuem a via de salvação e contam somente com a biossíntese de novo para a produção de nucleotídeos. Por esta razão, DHODH se tornou um excelente alvo na busca por inibidores que interrompam a síntese de nucleotídeos. As enzimas DHODHs de E. coli (EcDHODH) e de X. fastidiosa (XfDHODH) são membros da classe 2 das DHODHs e encontram-se associadas à membrana citoplasmática através de uma extensão em seu N-terminal, enquanto que DHODH de T. cruzi (TcDHODH), membro da classe 1 de DHODHs, é uma proteína citosólica. Neste trabalho, usamos uma combinação de metodologias de biologia molecular e bioquímica com técnicas espectroscópicas para obter informações estruturais e funcionais acerca da enzima DHODH. Assim, Ressonância Paramagnética Eletrônica (RPE) associada à marcação de spin sítio dirigida (SDSL) e simulação espectral foram empregadas para estudar a interação da EcDHODH com modelos de membrana. Mudanças na dinâmica estrutural das vesículas induzidas pela enzima foram monitoradas via marcadores de spin localizados em diferentes posições ao longo da cadeia acil de fosfolipídios. Além disso, técnicas de DNA recombinante e mutações sítio dirigidas foram utilizadas para produzir mutantes de EcDHODH no qual um sondas paramagnéticas foram seletivamente ligadas em resíduos localizados na extensão N-terminal da proteína para experimentos subseqüentes de RPE-SDSL. Esses são os primeiros experimentos de marcação de spin sítio dirigida realizados no Brasil e com os quais monitoramos a dinâmica experimentada na região do N-terminal. Além disso, várias tentativas foram feitas para se expressar e purificar a enzima XfDHODH e a estabilidade estrutural da enzima TcDHODH na presença de um de seus inibidores naturais, o orotato, foi monitorada através de experimentos de Dicroísmo Circular (CD). / Dihydroorotate dehydrogenases (DHODHs) are flavin-containing enzymes which catalyse the conversion of (S)-dihydroorotate to orotate, in the fourth step of the de novo biosynthesis of pyrimidine nucleotides. In rapidly proliferating mammalian cells, pyrimidine salvage pathway is insufficient to overcome deficiencies for nucleotide synthesis. Moreover certain parasites lack salvage enzymes, relying solely on the de novo pathway to produce nucleotides. Thus, DHODH has turned out an excellent target to the development of inhibitors that block nucleotide biosynthesis. E. coli DHODH (EcDHODH) and X. fastidiosa DHODH (XfDHODH) are class 2 DHODHs found associated to cytosolic membranes through an N-terminal extension, whereas T. cruzi DHODH (TcDHODH) is a class 1 DHODH localizated in the cytoplasm. In the present work, we used a combination of molecular biology and biochemical methodologies with spectroscopic techniques to obtain structural and functional information on DHODH. On one hand, Electronic Paramagnetic Resonance (EPR) associated with Site-directed Spin Labeling (SDSL) and spectral simulation were employed to study the interaction of EcDHODH with vesicles. Changes in vesicle dynamic structure induced by the enzyme were monitored via spin labels located at different positions along the phospholipid acyl chain and via spin labels located at enzyme specific positions. On the other hand, DNA techniques and site-directed mutagenesis were used to produce mutants of EcDHODH where a nitroxide spin probe was selectively attached to some residues located at the protein N-terminal extension for subsequent EPR-SDSL experiments. These are the first site-directed spin labeling experiments performed in Brazil and the spectra allowed us to monitor dynamics experienced by those residues at the EcDHODH N-terminal domain. Furthermore, molecular biology and biochemical assays were employed with the objective of expressing and purifying XfDHODH and Circular Dichroism (CD) was utilized to probe the structural stability of TcDHODH in the presence of its natural inhibitor (orotate).

Dihydroorotate dehydrogenase

Diidroorotato desidrogenase

Interação proteína-membrana

Marcação de spin sítio dirigida

Membrane-protein inteaction

Relação estrutura-função

Site-directed spin labeling

Structure-function relationship

Structure-function studies of membrane proteins by site-specific incorporation of unnatural amino acids / Etudes structure-fonction de protéines membranaires par incorporation spécifique d'acides aminés non naturels

Tian, Meilin

20 June 2017

Les protéines membranaires comme les récepteurs, les canaux ioniques et les transporteurs possèdent des rôles cruciaux dans les processus biologiques tels que la signalisation physiologique et les fonctions cellulaires. La description dynamique et fonctionnelle des structures protéiques est fondamentale pour comprendre la plupart des processus concernant les macromolécules biologiques. L'incorporation, dans des protéines, d'acides aminés non naturels (Uaas) possédant des propriétés physiques ou chimiques spécifiques fournit un puissant outil pour définir la structure et la dynamique de protéines complexes. Ces sondes permettent le suivi et la détection en temps réel de la conformation des récepteurs et des complexes de signalisation. Les approches d'expansion du code génétique ont permis l'incorporation d'Uaas servant de sondes dans des protéines avec une précision moléculaire. L'expansion héréditaire du code génétique peut permettre d'étudier la biologie des protéines de manière systémique.Avec cette stratégie, des Uaas capables de photopontage ont été utilisés pour étudier la relation structure/fonction des Protéines G Couplées aux Récepteurs (GPCR), telles que l'identification de la liaison du ligand ou des interactions protéine-protéine, en détectant les changements dynamiques avec les Uaas spectroscopiques et l'étiquetage bioorthogonal. Sur la base d'applications relativement bien établies d'Uaa dans les GPCR, ici, les analyses fonctionnelles sont combinées à l'incorporation génétique d'un Uaa photosensible spécifique au site, p-azido-L-phénylalanine (AzF) dans d'autres protéines membranaires, pour détecter la protéine, les changements conformationnels et les interactions protéiques. Contrairement à d’autres molécules photosensibles qui permettent aux protéines de répondre à la lumière, l'insertion des Uaas directement dans la chaine d’acides aminés offre des possibilités uniques pour le photo-contrôle de la protéine. Les aspects dynamiques de l'allostérie sont plus difficiles à visualiser que les modèles structuraux statiques. Une stratégie photochimique est présentée pour caractériser la dynamique des mécanismes allostériques des récepteurs NMDA neuronaux (NMDAR). Ces récepteurs appartiennent à la famille des canaux ioniques activés par le glutamate et portent la transmission synaptique excitatrice rapide associée à l'apprentissage et à la mémoire. En combinant le balayage AzF et un test fonctionnel résistant à la lumière, nous avons pu apporter des éléments permettant de mieux comprendre la dynamique des interfaces NTD (N-Terminal Domain des NMDAR) ainsi qu’un nouveau mécanisme de régulation allostérique, améliorant notre compréhension de la base structurale du mécanisme d’activation et de modulation des récepteurs NMDA.Outre l'incorporation de l’Uaa photopontant AzF dans les récepteurs neuronaux pour détecter l'effet fonctionnel, AzF a été appliqué pour piéger des interactions faibles et transitoires entre protéines dans un transporteur d'acides aminés LAT3, impliqué dans le cancer de la prostate. Les techniques de dépistage ont été établies en appliquant un photo-cross-linker positionné dans la protéine pour examiner les interactions entre LAT3 et les interacteurs inconnus et fournir des indices d'identification des partenaires de liaison.Dans l'ensemble, ce travail dévoile de nouvelles informations sur la modulation allostérique de l'activité du récepteur NMDA et sur les interactions protéines-protéines.. Les résultats pourraient fournir de nouvelles informations structurales et fonctionnelles et guider le dépistage de composés thérapeutiques pour des maladies associées au dysfonctionnement de ces protéines membranaires. / Membrane proteins including receptors, channels and transporters play crucial roles in biological processes such as physiological signaling and cellular functions. Description of dynamic structures and functions of proteins is fundamental to understand most processes involving biological macromolecules. The incorporation of unnatural amino acids (Uaas) containing distinct physical or chemical properties into proteins provides a powerful tool to define the challenging protein structure and dynamics. These probes allow monitoring and real-time detection of receptor conformational changes and signaling complexes. The genetic code expansion approaches have enabled the incorporation of Uaas serving as probes into proteins with molecular precision. Heritable expansion of the genetic code may allow protein biology to be investigated in a system-wide manner.With this strategy, photocrosslinking Uaas have been used to study GPCR structure/function relationship, such as identifying GPCR-ligand binding or protein-protein interactions, detecting dynamic changes with spectroscopic Uaas and bioorthogonal labeling. Based on relatively well-established applications of Uaa in GPCRs, here, functional assays are combined with the site-specific genetic incorporation of a photo-sensitive Uaa, p-azido-L-phenylalanine (AzF) into other membrane proteins, to probe protein conformational changes and protein interactions. Unlike photo-sensitive ligands that enable proteins in response to light, the site-specific insertion of light-sensitive Uaas facilitates directly light-sensitive proteins. Dynamic aspects of allostery are more challenging to visualize than static structural models. A photochemical strategy was presented to characterize dynamic allostery of neuronal NMDA receptors (NMDARs), which belong to the ionotropic glutamate receptor channel family and mediate the fast excitatory synaptic transmission associated with learning and memory. By combining AzF scanning and a robust light-induced functional assay the dynamics of NMDAR N-terminal domain (NTD) interfaces and novel allosteric regulation mechanism were uncovered, improving our understanding of the structural basis of NMDAR gating and modulation mechanism.Besides incorporation of photo-cross-linker AzF into neuronal receptors to detect the functional effect, AzF was used to trap transient and weak protein-protein interactions in an amino acid transporter LAT3, which is critical in prostate cancer. Screening technique was established by applying genetically encoded photo-cross-linker to examine interactions between LAT3 and unknown interactors and provide clues to identify the binding partners.Overall, the work reveals new informations about the allosteric modulation of channel activity and proteins interactions. These light-sensitive proteins facilitated by site-specific insertion of light-sensitive Uaas enable profiling diversity of proteins. The results will provide novel structural and functional information and may guide screening of therapeutic compounds for diseases associated with malfunctioning of these membrane proteins.

Acides aminés non naturels

Expansion du code génétique

Structure / fonction des protéines

Récepteur NMDA

Protéine photosensible

Protéines membranaires

Unnatural amino acids (Uaas)

Genetic code expansion

Structure/function of membrane protein

572.6

Étude cristallographique du domaine catalytique de l’intégrase du virus RAV-1 (rous associated virus type 1) et découverte d’une nouvelle interface de dimérisation / The crystallographic study of the catalytic core domain of the avian rous associated virus type 1 (rav-1) integrase reveals a novel dimeric assembly

Ballandras, Allison

30 November 2010

Au cours du cycle réplicatif des rétrovirus, l’ADN viral rétro-transcrit est intégré dans l’ADN de la cellule hôte par l’intégrase virale (IN). L’IN possède un rôle clé dans le cycle rétroviral et représente une cible thérapeutique majeure pour le traitement des infections par le virus de l’immunodéficience humaine (VIH). L’IN est constituée de trois domaines (N-terminal, central et C-terminal) connectés par des boucles flexibles, qui la rendent difficilement cristallisable. Le Dr. C. Ronfort (Equipe Rétrovirus et Intégration Rétrovirale) et le Pr. P. Gouet (Laboratoire de BioCristallographie) collaborent depuis 2002 sur l’IN du Rous Associated Virus type 1 (RAV-1). Mes travaux de thèse s’inscrivent dans le cadre de cette collaboration. Il s’agissait de mener une étude cristallographique et moléculaire du domaine central de l’IN du RAV-1 pour pouvoir, ensuite, modéliser des mutants d’intérêt identifiés par l’équipe du Dr. C. Ronfort. Pour ce faire, le fragment protéique a été surproduit et purifié. Sa structure cristallographique a été résolue à une résolution de 1,8 Å. L’examen de cette structure révèle que le dimère de l’IN du RAV-1 peut s’assembler suivant une nouvelle interface moléculaire stabilisée par trois paires d’hélices α. Cet assemblage se caractérise également par la présence d’un étroit sillon basique à sa surface. Par des expériences in vitro de biochimie et in silico de docking, nous avons montré que ce sillon était susceptible de fixer un brin d’ARN. D’autre part, nos données expérimentales permettent d’expliquer comment les conditions de cristallisation, ainsi que la substitution d’un acide aminé de surface, favorisent la formation soit de ce nouvel arrangement dimérique, soit de l’arrangement dimérique classique. Ainsi, l’ensemble des données obtenues au cours de cette thèse suggère que l’intégrase possède des propriétés structurales modulables, lui permettant d’intervenir dans plusieurs étapes du cycle rétroviral en présence d’ADNdb (intégration) ou d’ARNsb (rétro-transcription et/ou encapsidation du génome ARN viral) / During the replicative cycle of retroviruses, the retrotranscribed viral DNA is integrated into the host chromosome by the viral integrase protein (IN). The integration reaction is essential for the viral life cycle. Therefore, IN is a key target for antiretroviral drug design to treat HIV infection. IN consists of three domains (N-terminal, central and Cterminal) connected by flexible loops, making the enzyme difficult to crystallize. Dr C. Ronfort (Team Retrovirus and Retroviral Integration) and Pr P. Gouet (BioCrystallography Laboratory) collaborate since 2002 in Lyon to study IN from the Rous Associated Virus type 1 (RAV-1). My thesis work lies within this collaboration. Its objective was to perform crystallographic and molecular studies of the central domain of RAV-1 IN and of mutants of interest identified by the team of Dr C. Ronfort. In this aim, the IN fragment has been overexpressed and purified. Its crystal structure has been solved to a resolution of 1.8 Å. The observation of this structure reveals that the RAV-1 IN can exhibit a novel dimeric arrangement with a molecular interface stabilized by three pairs of facing α-helices. This arrangement is also characterized by the presence of a basic narrow groove at its surface. Thanks to biochemical in vitro experiments and in silico docking studies, we have shown that this median groove could allow the binding of a linear singlestranded RNA. Moreover, our experimental data can explain how the crystallization conditions as well as the mutation of a specific residue located at the surface of the enzyme favor either this novel dimeric arrangement or the classical dimeric interface. Therefore, the data obtained during this thesis suggest that IN exhibits modular structural properties, allowing it to operate in several distinct steps of the retroviral cycle in presence of dsDNA (integration) or ssRNA (reverse transcription and/or encapsidation of the retroviral RNA genome)

Intégrase

Avian Leukemia Virus

Catalytic Core Domain

Interface dimérique

Cristallographie

Relation structure-fonction

Integrase

Avian Leukemia Virus

Catalytic Core Domain

Dimeric interface

Crystallography

Structure-function link

579.2

Theory and Applications of Network Structure of Complex Dynamical Systems

Chetty, Vasu Nephi

01 March 2017

One of the most powerful properties of mathematical systems theory is the fact that interconnecting systems yields composites that are themselves systems. This property allows for the engineering of complex systems by aggregating simpler systems into intricate patterns. We call these interconnection patterns the "structure" of the system. Similarly, this property also enables the understanding of complex systems by decomposing them into simpler parts. We likewise call the relationship between these parts the "structure" of the system. At first glance, these may appear to represent identical views of structure of a system. However, further investigation invites the question: are these two notions of structure of a system the same? This dissertation answers this question by developing a theory of dynamical structure. The work begins be distinguishing notions of structure from their associated mathematical representations, or models, of a system. Focusing on linear time invariant (LTI) systems, the key technical contributions begin by extending the definition of the dynamical structure function to all LTI systems and proving essential invariance properties as well as extending necessary and sufficient conditions for the reconstruction of the dynamical structure function from data. Given these extensions, we then develop a framework for analyzing the structures associated with different representations of the same system and use this framework to show that interconnection (or subsystem) structures are not necessarily the same as decomposition (or signal) structures. We also show necessary and sufficient conditions for the reconstruction of the interconnection (or subsystem) structure for a class of systems. In addition to theoretical contributions, this work also makes key contributions to specific applications. In particular, network reconstruction algorithms are developed that extend the applicability of existing methods to general LTI systems while improving the computational complexity. Also, a passive reconstruction method was developed that enables reconstruction without actively probing the system. Finally, the structural theory developed here is used to analyze the vulnerability of a system to simultaneous attacks (coordinated or uncoordinated), enabling a novel approach to the security of cyber-physical-human systems.

linear systems theory

dynamical structure function

network semantics

system structure

network reconstruction

subsystem structure

signal structure

network vulnerability

Computer Sciences

Developing script-specific recognition ability - the case of learners of Japanese

Toyoda, Etsuko

Unknown Date

Reading non-alphabetic script can be a serious challenge to second language (L2) learners with alphabetic backgrounds. Many L2 learners of Japanese or Chinese who are fluent in speaking the language do not necessarily acquire an advanced-level reading ability. The aim of my thesis was to investigate the development of L2 word recognition ability, one of the most important abilities that learners need to develop for efficient reading, among English-speaking learners of Japanese. By analysing the results of behavioural tests and a verbal protocol administered to both L1 and L2 readers of Japanese, the study described the changes in developing L2 learners’ kanji recognition skills and their awareness of the structure and function of characters at the different stages of L2 exposure. / The overall findings suggest that the changes in processing patterns demonstrated by the participants in the present study may be fundamentally similar to those of L1 children, which have been found to be similar regardless of the types of script involved. The changes in L2 readers’ developing kanji recognition were accounted for by the transformation of the internal processing system; this transformation seems to occur by continuous link formation through learning corresponding information, and information processing based on the learned information. The process of transformation, which is affected by the frequency of exposure and the amount of practice, and therefore appears to be item-based, generally progresses on a stage-based developmental trajectory; the processing begins with local and incomplete information and progresses via intentional and analytical processing to develop into sophisticated attention-free processing. / Although the developmental trajectory may be universal, the findings of the present study suggest that, when L1 and L2 are orthographically distant, L2 readers repeat the developmental phases due to lack of their ability to process script-specific information. L2 readers with alphabetic backgrounds cannot simply transfer the recognition skills and awareness that they have acquired in their L1 in the new environment of character recognition. The findings of the study suggest that script-specific recognition skills and awareness develop over time as the L2 readers’ internal processing system undergoes successive transformations. By identifying several critical skills and awareness, the present study has discussed the possibility of enhancing character recognition ability with the use of explicit instruction at critical moments.

Structural Transitions in Helical Peptides : The Influence of Water – Implications for Molecular Recognition and Protein Folding

Lignell, Martin

January 2009

Fluctuations in protein structure are vital to function. This contrasts the dominating structure-function paradigm, which connects the well-defined three-dimensional protein structure to its function. However, catalysis is observed in disordered enzymes, which lack a defined structure. Disordered proteins are involved in molecular recognition events as well. The aim of this Thesis is to describe the structural changes occuring in protein structure and to investigate the mechanism of molecular recognition. Protein architecture is classified in a hierarchical manner, that is, it is categorized into primary, secondary, and tertiary levels. One of the major questions in biology today is how proteins fold into a defined three-dimensional structure. Some protein folding models, like the framework model, suggest that the secondary structure, like α-helices, is formed before the tertiary structure. This Thesis raises two questions: First, are structural fluctuations that occur in the protein related to the folding of the protein structure? Second, is the hierarchic classification of the protein architecture useful to describe said structural fluctuations? Kinetic studies of protein folding show that important dynamical processes of the folding occur on the microsecond timescale, which is why time-resolved fluorescence spectroscopy was chosen as the principal method for studying structural fluctuations in the peptides. Time-resolved fluorescence spectroscopy offers a number of experimental advantages and is useful for characterizing typical structural elements of the peptides on the sub-microsecond timescale. By observing the fluorescence lifetime distribution of the fluorescent probe, which is a part of the hydrophobic core of a four-helix bundle, it is shown that the hydrophobic core changes hydration state, from a completely dehydrated to a partly hydrated hydrophobic core. These fluctuations are related to the tertiary structure of the four-helix bundle and constitute structural transitions between the completely folded four-helix bundle and the molten globule version. Equilibrium unfolding of the four-helix bundle, using chemical denaturants or increased temperature, shows that the tertiary structure unfolds before the secondary structure, via the molten globule state, which suggests a hierarchic folding mechanism of the four-helix bundle. Fluctuations of a 12 amino acid long helical segment, without tertiary structure, involve a conformational search of different helical organizations of the backbone. Binding and recognition of a helix-loop-helix to carbonic anhydrase occurs through a partly folded intermediate before the final tertiary and bimolecular structure is formed between the two biomolecules. This confirms the latest established theory of recognition that the binding and the folding processes are coupled for the binding molecules.

protein dynamics

protein folding

molten globule

time-resolved fluorescence spectroscopy

CD spectroscopy

molecular recognition

structure-function paradigm

Chemical physics

Kemisk fysik

Measurement of High-Q2 Neutral Current Cross-sections with Longitudinally Polarised Positrons with the ZEUS Detector

Stewart, Trevor

07 January 2013

The cross sections for neutral current (NC) deep inelastic scattering (DIS) in e+p collisions with a longitudinally polarised positron beam are measured at high momentum transfer squared (Q2 > 185 GeV2) at the ZEUS detector at HERA. The HERA accelerator provides e+-p collisions at a centre-of-mass energy of 318 GeV, which allows the weak contribution to the NC process to be studied at high Q2. The measurements are based on a data sample with an integrated luminosity of 135.5 pb-1 collected with the ZEUS detector in 2006 and 2007. The single differential NC cross sections dsigma/dQ2, dsigma/dx and dsigma/dy and the reduced cross section are measured. The structure function xF3 is determined by combining the e+p NC reduced cross sections with the previously measured e-p measurements. The interference structure function xF 3^gamma,Z is extracted at Q2 = 1500 GeV2. The cross-section asymmetry between the positive and negative polarisation of the positron beam is measured and the parity violation effects of the electroweak interaction are observed. The predictions of the Standard Model of particle physics agree well with the measurements.

Deep Inelastic scattering

DIS

neutral current

NC

electroweak

SM

High energy physics

positron

proton

structure function

physics

cross section

longitudinally polarised

lepton

0798

STRUCTURE AND PROPERTIES OF CRUCIFERIN: INVESTIGATION OF HOMOHEXAMERIC CRUCIFERIN EXPRESSED IN ARABIDOPSIS

2013 June 1900

The structure of 11S cruciferin has been solved; however, how the individual subunits contribute to its physico-chemical and functional properties are not well known. The cruciferin isoforms in Arabidopsis thaliana, CRUA, CRUB, and CRUC, were investigated with respect to their molecular structures and the relationship of structural features to the physico-chemical and functional properties of cruciferin using homology modeling and various analytical techniques. Comparison of these models revealed that hydrophobicity and electrostatic potential distribution on the surface of the CRUC homotrimer had more favorable interfacial, solubility, and thermal properties than those of CRUA or CRUB. Flavor binding and pepsin digestion were associated with hypervariable regions (HVRs) and center core regions, respectively, moreso for CRUA and CRUB homotrimers than for CRUC. Chemical imaging of a single cell area in wild type (WT) and double-knockout seeds (CRUAbc, CRUaBc, and CRUabC) using synchrotron FT-IR microscopy (amide I band, 1650 cm-1, νC=O) showed that seed storage proteins were concentrated in the cell center and protein storage vacuoles, whereas lipids were closer to the cell wall. Secondary structure components of proteins of double-knockout lines did not show major differences. Changes in protein secondary structure components of pepsin-treated CRUabC (CRUC) mutant were minimal, indicating low enzyme accessibility. A three-step chromatographic procedure allowed isolation of the hexameric form of cruciferin with high purity (>95%). Fourier transform infrared (FT-IR) and circular dichroism (CD) spectroscopic analysis of the secondary structure of these proteins revealed cruciferins were folded into higher order secondary structures; 44−50% β-sheets and 7−9% α-helices. The relative subunit ratio was approximately 1:3:6 (CRUA:CRUB:CRUC) in the WT cruciferin. The Tm values of purified cruciferin at pH 7.4 (μ = 0.0) were in the order of WT = CRUA = CRUB < CRUC. The order of surface hydrophobicity as determined by ANS (1-anilinonaphthalene-8-sulfonate) probe binding was CRUA > CRUB = WT >> CRUC. Intrinsic fluorescence studies revealed a compact molecular structure for the CRUC homohexamer compared to the CRUA and CRUB homohexamers. The order of emulsion forming abilities was CRUA = CRUB > WT > CRUC (no emulsion formation) and the order of heat-induced network structure strength was WT > CRUA = CRUB > CRUC (no gel formation). The inability of CRUC to form gels or emulsions may be attributed to its low surface hydrophobicity and molecular compactness. At pH 2.0, CRUC hexamers dissociated into trimers which allowed the formation of an O/W emulsion and heat-induced network structures. Solubility of cruciferin as a function of pH at low ionic strength gave two minima around pH 4 and 7.4 yielding a “W” shape solubility profile deviating from the typical “U” or “V” shape solubility profile of other 11S globulins. The high ionic strength (μ = 0.5) was not favorable for emulsification, heat-induced gel formation, or solubilization for all cruciferins. Furthermore, the CRUA and CRUB homohexamers exhibited rapid pepsinolysis, while the CRUC homohexamer and WT heterohexamer were digested more slowly. Although fairly well conserved regions were found in the primary structure of these three cruciferin subunits, differences were found in the hypervariable regions and extended loop regions resulting in slight differences in 3D structures and interactions that occur during association to form superstructures, such as hexamers. These differences were reflected in the physico-chemical and techno-functional properties of hexamers and trimers composed of each subunit. In silico predictions for certain functionalities were highly correlated with empirical data from laboratory experiments.