EPR Analysis of a Two-State Conformational Equilibrium in an N. pharaonis HAMP Domain - Activation/Deactivation of a Signaling Unit"

Doebber, Meike Anne

18 March 2009

The photosensitive unit triggering the negative phototaxis in the haloarchaeum Natronomonas pharaonis consists of the receptor sensory rhodopsin II (NpSRII) and its cognate transducer (NpHtrII) in a 2:2 stoichiometry. Upon light excitation, a structural rearrangement in the receptor initiates a displacement/rotation of the transducer helix TM2, which can be considered as starting event for the signal transduction. This signal is further transmitted to the cytoplasmic signaling domain through the signal transduction unit comprising two HAMP domains.Structural information already exists for the transmembrane region of this complex (crystal structure) as well as for the rod shaped cytoplasmic part of NpHtrII due to its high homologies with chemoreceptors. Moreover, the solution NMR structure of the isolated HAMP domain from A. fulgidus recently obtained shows a homodimeric, four-helical, parallel coiled-coil with an unusual interhelical packing, that is thought to propagate a signal by virtue of concerted helix rotations. Here, an electron paramagnetic resonance (EPR) investigation of site-directed spin labeled transducers in the NpSRII/NpHtrII complex has been carried out for structural and functional elucidation of the N. pharaonis HAMP. For this purpose, cw as well as pulse EPR techniques have been used in terms of mobility, accessibility and intra-transducer dimer distance analyses. Conformational changes induced by environmental inputs, namely salt, temperature and pH, give insight into the two-state equilibrium existing between a highly dynamic (dHAMP) and a more compact (cHAMP) conformation of this linker region.

SRII/HtrII

EPR

SDSL

membrane protein

HAMP

side chain dynamics

conformational equilibrium

29 - Physik, Astronomie

33.35

87.64

87.14

ddc:570

Auto-assemblage de la protéine bactérienne Hfq, actrice du métabolisme de l’ARN : rôle structural du domaine C-terminal. / Self-assembly of the bacterial protein Hfq, an actor of RNA metabolism : structural role of the C-terminal domain.

Malabirade, Antoine, Baptiste,

06 October 2017

La régulation de l’expression génique par des ARNs permet une réponse rapide et polyvalente des cellules à des changements environnementaux. Cependant, elle nécessite souvent des partenaires protéiques. La protéine bactérienne Hfq en est un bon exemple. Facteur de virulence, elle est présente chez une variété de procaryotes et intervient dans nombre de circuits de régulation. Structurellement, Hfq adopte un repliement caractéristique, le repliement Sm. Ainsi, Les feuillets β qui la constituent se regroupent et forment un hexamère toroïdal. Outre cette région N-terminale, il existe aussi parfois une région C-terminale (CTR) de séquence et de longueur variables. Chez E. coli, cette région comprend une trentaine de résidus et est prédite comme non-structurée. Jusqu’à présent, son rôle n’a été que peu étudié.Ce travail de thèse met en lumière de nouvelles pistes quant à la fonction du CTR. Nous avons constaté sa capacité à former des fibres amyloïdes, expliquant la formation de structures auto-assemblées in vivo. De plus, la protéine est capable de lier l’ADN et de le condenser fortement in vitro. Cette compaction est complètement dépendante de la présence du CTR, qui permet de ponter les brins d’ADN. Ce résultat suggère une nouvelle fonction de Hfq dans la structuration du chromosome. Enfin, nous avons démontré que ce domaine permet aussi à Hfq de s’assembler à la surface d’une bicouche lipidique, expliquant sa localisation membranaire. La désorganisation de la membrane qui en résulte pourrait permettre le passage d’ARNs dans le milieu extracellulaire, avec d’importantes implications sur la capacité de la bactérie à interagir avec ses voisines et son environnement. / RNA-based regulations of gene expression allow quick and versatile responses from cells to changing environmental conditions. However, these regulations are often protein-mediated. The bacterial protein Hfq is one of the most studied RNA-based regulation partner. Found in various prokaryotes, it is an important virulence factor involved in many cellular processes. Hfq’s structure resembles a torus, formed by multiple β-sheets. Apart from this N-terminal region (NTR), a supplemental C-terminal region (CTR) with variable lengths and sequences may exist in some species. In E. coli, this specific region measures around 30 residues and is predicted as intrinsically disordered. Few studies focused on Hfq-CTR until recently.This work highlights new potential roles for Hfq-CTR. First, this region is able to self-interact and forms amyloid fibers which explains the self-assembled Hfq superstructures observed in vivo. Second, the protein can bind and efficiently condense DNA in vitro, strengthening the suggested role of Hfq in shaping the bacterial chromosome. This compaction is fully dependent on the CTR which is responsible for DNA bridging. Third, the CTR also gives to Hfq the ability to self-assemble on a lipid bilayer, explaining its membrane-localized fraction observed in vivo. The subsequent membrane reorganization might facilitate the release of RNAs in the extracellular medium, with potential implications on bacterial communication and interaction with surrounding cells and environment.

Métabolisme de l'ARN

Fibres Amyloïdes

Compaction de l'ADN

Protéine membranaire

Dégradosome

E. coli

RNA metabolism

Amyloïd fibers

DNA compaction

Membrane protein

Degradosome

E. coli

Cytochrome c Oxidase from Rhodobacter sphaeroides: Oligomeric Structure in the Phospholipid Bilayer and the Structural and Functional Effects of a C-Terminal Truncation in Subunit III

Cvetkov, Teresa L.

13 July 2010

No description available.

Biochemistry

Biophysics

cytochrome c oxidase

membrane protein

oligomeric structure

cytochrome c oxidase subunit III

mitochondrial disease

phospholipids in protein structure

Fold recognition and alignment in the 'twilight zone'

Hill, Jamie Richard

January 2013

At present, the most accurate approach to predicting protein structure, comparative modelling, builds a model of a target sequence using known protein structures as templates. Comparative modelling becomes markedly less accurate in the ‘twilight zone’, where the target protein shares little sequence identity with all known templates. There are two main causes of this inaccuracy: first, it becomes difficult to identify good structural templates; second, it becomes difficult to determine which amino acids in the template are structurally equivalent to those in the target. These are problems of fold recognition and target-template alignment respectively. In this thesis, new approaches are developed to address both these problems. The alignment problem is investigated in the special case of membrane proteins. These are key modelling targets as they resist structure determination and are pharmaceutically important. The approach taken here is to use ‘environment specific substitution tables’ (ESSTs)– that is, to alter the alignment scoring system for each local environment of the template structure. We show how ESSTs can be made for membrane proteins, tested for robustness of construction, and used to infer the most important evolutionary pressures acting on protein structure. The incorporation of ESSTs into a multiple sequence alignment method leads to more accurate alignments of membrane proteins, and so to more accurate models. Recently, algorithms have been developed that predict contacts in protein structures from a multiple sequence alignment of homologous sequences. We explore the potential of these predictions for fold recognition by developing an algorithm that makes no use of amino acid identity, and so should be agnostic to the existence of a ‘twilight zone’. We show that whilst this is not the case, our method is complementary to state-of-the-art approaches.

572

Identifying key factors in two-dimensional crystal production and sample preparation for structure-function studies of membrane proteins by cryo-EM

Johnson, Matthew C.

12 January 2015

Electron crystallography of two-dimensional crystals is a structure-determination method well suited to the study of membrane protein structure-function. Two-dimensional crystals consist of ordered arrays of protein within reconstituted lipid bilayers, an arrangement that mimics the natural membrane environment. In this work we describe our recent progress in the use of this method with three different proteins, each providing a window into a separate paradigm in the electron crystallographic pipeline. Specific crystallization conditions for human leukotriene C₄ synthase (LTC₄S) have previously been determined, but our continued refinement of purification and crystallization has identified a number of additional parameters that greatly affect crystal size and quality, and we have developed a protocol to rapidly and reproducibly grow large, non-mosaic crystals of LTC₄S. The human gamma-glutamyl carboxylase (GGCX) has also been crystallized, but is sensitive to cryo-EM sample preparation conditions and we present here the successful reproduction of crystallization and refinement of cryo-EM sample preparation conditions. Lastly, we describe our crystallization screens with the Vibrio cholerae sodium-pumping NADH:ubiquinone reductase complex (Na⁺-NQR), and identify the factors critical to membrane reconstitution of the complex, a necessary first step towards crystallization. We also describe a semi-quantitative crystal screening protocol we have developed that provides quick and accurate method to assess two- dimensional crystallization trials, and discuss some general observations in optimization of membrane protein purification and two-dimensional crystallization for electron crystallography.

Membrane protein

Protein structure

Cryo-EM

Electron microscopy

Electron cryo-microscopy

Electron crystallography

Two-dimensional crystallization

LTC₄S

Leukotriene C₄ Synthase

Gamma-glutamyl carboxylase

GGCX

Plasma Membrane Plasticity of Xenopus laevis Oocyte Imaged with Atomic Force Microscopy

Schillers, Hermann, Danker, Timm, Schnittler, Hans-Joachim, Lang, Florian, Oberleithner, Hans

20 March 2014

Proteins are known to form functional clusters in plasma membranes. In order to identify individual proteins within clusters we developed a method to visualize by atomic force microscopy (AFM) the cytoplasmic surface of native plasma membrane, excised from Xenopus laevis oocyte and spread on poly-L-lysine coated glass. After removal of the vitelline membrane intact oocytes were brought in contact with coated glass and then rolled off. Inside-out oriented plasma membrane patches left at the glass surface were first identified with the lipid fluorescent marker FM1-43 and then scanned by AFM. Membrane patches exhibiting the typical phospholipid bilayer height of 5 nm showed multiple proteins, protruding from the inner surface of the membrane, with heights of 5 to 20 nm. Modelling plasma membrane proteins as spherical structures embedded in the lipid bilayer and protruding into the cytoplasm allowed an estimation of the respective molecular masses. Proteins ranged from 35 to 2,000 kDa with a peak value of 280 kDa. The most frequently found membrane protein structure (40/μm2) had a total height of 10 nm and an estimated molecular mass of 280 kDa. Membrane proteins were found firmly attached to the poly-L-lysine coated glass surface while the lipid bilayer was found highly mobile. We detected protein structures with distinguishable subunits of still unknown identity. Since X. laevis oocyte is a generally accepted expression system for foreign proteins, this method could turn out to be useful to structurally identify specific proteins in their native environment at the molecular level. / Dieser Beitrag ist mit Zustimmung des Rechteinhabers aufgrund einer (DFG-geförderten) Allianz- bzw. Nationallizenz frei zugänglich.

Lipiddoppelschicht

Membranprotein

Membranfluidität

Xenopus laevis Eizelle

Lipid bilayer

Membrane protein

Membrane fluidity

Molecular volume

Xenopus laevis oocyte

ddc:540

ddc:610

rvk:VA 1120

rvk:XA 10000

Periplasmic Delivery of Biologically Active Human Interleukin-10 in Escherichia coli via a Sec-Dependent Signal Peptide

Pöhlmann, Christoph, Brandt, Manuela, Mottok, Dorothea S., Zschüttig, Anke, Campbell, John W., Blattner, Frederick R., Frisch, David, Gunzer, Florian

18 March 2014

Interleukin-10 (IL-10) is a potent anti-inflammatory cytokine, with therapeutic applications in inflammatory bowel disease. For the in situ delivery of IL-10 by Escherichia coli as carrier chassis, a modified transporter was designed with the ability to secrete biologically active IL-10. De novo DNA synthesis comprised a 561-bp fragment encoding the signal sequence of the E. coli outer membrane protein F fused in frame to an E. coli codon-optimized mature human IL-10 gene under control of a T7 promoter. The construct was overexpressed in E. coli laboratory strains, E. coli BL21 (DE3) and E. coli MDS42:T7. The mean concentrations of human IL-10 in the periplasm and culture supernatant of E. coli BL21 (DE3) were 355.8 ± 86.3 and 5.7 ± 1.7 ng/ml, respectively. The molecular mass of the recombinant E. coli-derived human IL-10 was 19 kDa, while under non-reducing conditions the native IL-10 dimer could be demonstrated. Reduction of tumor necrosis factor-α secretion in lipopolysaccharide-stimulated mouse macrophages and detection of the activated form of the transcription factor signal transducer and activator of transcription protein 3 proved the biological activity of the bacteria-produced human IL-10. / Dieser Beitrag ist mit Zustimmung des Rechteinhabers aufgrund einer (DFG-geförderten) Allianz- bzw. Nationallizenz frei zugänglich.

bakteriellesTransportsystem

entzündliche Darmerkrankung

Außenmembran Protein F

Interleukin-10

Escherichia coli

Interleukin-10

Outer membrane protein F

Inflammatory bowel disease

Bacterial transport system

ddc:570

rvk:WA 15000

Biophysical studies of membrane protein structure and function

Dijkman, Patricia M.

January 2014

Membrane proteins play a key role in numerous physiological processes such as transport, energy transduction in respiratory and photosynthetic systems, and signal transduction, and are of great pharmaceutical interest, comprising more than 60% of known drug targets. However, crystallisation of membrane proteins, and G protein-coupled receptors (GPCRs) in particular, still relies heavily on the use of protein engineering strategies, which have been shown to hamper protein activity. Here, a range of biophysical methods were used to study the structure and function of two membrane proteins, a prokaryotic peptide transporter, PepT_So and a GPCR, neurotensin receptor 1 (NTS1), using different membrane reconstitution methods to study the proteins in a native-like environment. Firstly, using the pulsed electron paramagnetic resonance (EPR) method of double electron-electron resonance (DEER) the conformation of PepT_So reconstituted into lipid bilayers was assessed and compared to previous structural data obtained from crystallography and modelling. The influence of the membrane potential and the presence of substrate on the conformational heterogeneity of this proton-coupled transporter were investigated. Secondly, NTS1 purification was optimized for biophysical study. Cysteine mutants were created and a labelling protocol was developed and optimized for fluorophore and nitroxide labelling studies. NTS1 was then studied by continuous-wave EPR, to assess the influence of ligand on local protein dynamics, and to assess the structure of a receptor segment known as helix 8, that was proposed to be an α-helix, but was only observed to be helical in one of the NTS1 crystallographic studies. Ensemble and single-molecule Förster resonance energy transfer (FRET), and DEER were combined to study the dimerisation behaviour of NTS1, showing novel dynamics of the interfacial associations. Finally, the signalling mechanism of NTS1 was also investigated using microscale thermophoresis (MST) to assess the affinity of the receptor for G protein in vitro in the absence of ligand, or in the presence of agonist or antagonist. MST measurements were performed in detergent and in nanodiscs of different lipid compositions, to assess the influence of the lipid environment on receptor function. In summary, this thesis demonstrates the potential of biophysical techniques to study various aspects of membrane protein structure and function in native-like lipid systems, complementing e.g. structural data obtained from crystallographic studies with functional data for membrane proteins in more native environments, as well as shedding light on protein dynamics. The work presented here provides novel insights into PepTSo transport, and in particular into NTS1 structure, signalling, and oligomerisation, opening up several avenues for future research.

572

Etude de l'assemblage du système d'efflux membranaire MexAB-OprM impliqué dans la résistance aux antibiotiques chez Pseudomonas aeruginosa : caractérisation combinée par Microbalance à cristal de quartz avec mesure de dissipation et cryo-tomographie électronique

Trépout, Sylvain

08 December 2008

Pseudomonas aeruginosa est une bactérie Gram-négative qui présente une grande résistance aux antibiotiques, lui permettant de sévir dans le milieu hospitalier en infectant plus particulièrement les patients immunodéprimés. Cette résistance est principalement due au système d’efflux membranaire MexAB-OprM, capable d’exporter les antibiotiques en dehors de la cellule. Cette pompe à efflux est composée de trois protéines, MexA, MexB et OprM, incorporées dans les membranes internes et externes de la paroi bactérienne. Les structures de MexA, OprM et AcrB -une protéine présente chez E. coli, homologue de MexB- ont été déterminées individuellement par cristallographie des rayons X. Cependant, la structure du complexe entier, regroupant les trois protéines en interaction, ainsi que le mécanisme de cette pompe font toujours défaut. Le renforcement de nos connaissances structurales et fonctionnelles est donc capital pour lutter plus efficacement contre ces bactéries, par de nouvelles stratégies médicamenteuses. Ce travail porte sur l’étude de la structure et de la stœchiométrie de l’assemblage des protéines OprM et MexA au sein d’une membrane lipidique. La caractérisation du complexe OprM/MexA a été réalisée à l’aide de nouvelles techniques de caractérisation physico-chimique des surfaces, telle que la Microbalance à Cristal de Quartz avec Mesure de Dissipation (QCM-D), et par des méthodes d’imagerie, telles que la Cryo-Microscopie Electronique en Transmission (CryoMET) et la Cryo-Tomographie Electronique (CryoTE). En QCM-D, les mesures d’interaction entre OprM et MexA ont été réalisées sur support solide en contrôlant l’orientation d’OprM placée dans un environnement lipidique. Après ajout de la protéine MexA, la formation de complexes OprM/MexA a été mise évidence. Pour comprendre l’organisation de ce complexe, nous avons procédé à une étude comparative de l’organisation des protéines OprM, MexA et du complexe OprM/MexA incorporés dans une membrane lipidique, par CryoMET. Trois types d’organisation, respectivement spécifiques d’OprM, de MexA et du complexe OprM/MexA, ont été mis en évidence. Une analyse structurale de ces trois différents assemblages, pris en sandwich entre deux membranes lipidiques, a été menée par CryoTE. La reconstitution de la protéine OprM conduit à la formation de protéoliposomes, dû à des interactions intervenant entre les protéines OprM au niveau de leurs hélices périplasmiques. La protéine MexA s’organise sous forme d’une structure annulaire de 13 nm de hauteur au sein des membranes lipidiques, et d’une structure plus complexe de 26 nm de hauteur, résultant de l’empilement tête-bêche de deux structures annulaires de 13 nm. Ce travail révèle les dimensions exactes de l’assemblage formé par MexA, et permet de localiser à proximité des membranes les domaines non résolus dans la structure cristallographique. La reconstitution du complexe OprM/MexA révèle une disposition régulière des deux protéines dans les membranes lipidiques. Au sein des complexes, les protéines OprM sont présentes sous forme de trimères. Dans la membrane opposée, à l’aplomb d’une molécule d’OprM, MexA ne forme pas une structure annulaire similaire à celle décrite précédemment, indiquant un état d’oligomérisation différent de celui observé dans les assemblages MexA. Les densités de MexA sont compatibles avec la présence de quelques molécules de MexA. Cependant des structures annulaires de MexA, positionnées à l’aplomb de trois trimères d’OprM sont visibles. Notre étude montre que MexA adopte des structures oligomériques spécifiques en fonction de ses interactions avec les membranes lipidiques ou avec son partenaire OprM. / The structure determination of membrane protein in lipid environment can be carried out using cryo electron microscopy combined with the recent development of data collection and image processing. We describe a protocol to study assemblies or stacks of membrane protein reconstitued into a lipid membrane using both cryo electron tomography and single particle analysis which is an alternative approach to electron crystallography for solving 3D structure. We show the organization of the successive layers of OprM molecules revealing the protein-protein interactions between OprM molecules of two successive lipid bilayers.

Microscopie Electronique

Tomographie Electronique

Pseudomonas aeruginosa

Reconstitution membranaire

Protéines membranaires

Membrane protein

Cryo electron tomography

Single particle analysis

Multidrug efflux pump

L’hydrogénase [Ni-Fe] multi-tolérante d’Aquifex aeolicus : de l’immobilisation fonctionnelle à la biopile H2/O2

Ciaccafava, Alexandre

18 December 2012

Les hydrogénases sont les enzymes responsables de la conversion de l'H2. De part leur efficacité et spécificité vis-à-vis de l'oxydation de l'H2, elles apparaissent comme des biocatalyseurs potentiels dans les biopiles à combustible. Dans cet objectif, nous avons étudié l'immobilisation fonctionnelle sur diverses électrodes de l'hydrogénase membranaire tolérante à l'O2 de la bactérie hyperthermophile Aquifex aeolicus. Par une approche couplée d'électrochimie, de microscopie et de spectroscopie, il est montré que l'orientation de l'hydrogénase sur une électrode n'est pas contrôlée par des interactions électrostatiques mais hydrophobes. Ce contrôle est lié à l'environnement spécifique du dernier relais électronique en surface de l'enzyme. En particulier, l'hélice transmembranaire hydrophobe entourée de détergent est impliquée dans l'immobilisation. Cette orientation spécifique induit la nécessité d'un médiateur redox pour l'oxydation de l'H2 sur une interface hydrophobe. A contrario, l'hydrogénase adopte une multitude d'orientations sur surfaces chargées. Dans ces conditions, une connexion directe efficace des enzymes est obtenue, mais aussi l'augmentation du courant global par médiation de l'oxydation de l'H2. La définition des paramètres d'immobilisation de l'hydrogénase, a permis de développer des interfaces électrochimiques propres à l'augmentation des courants. En couplant une biocathode basée sur la bilirubin oxidase pour la réduction de l'O2, une biopile H2/O2 a été construite basée à l'anode sur l'hydrogénase d'Aquifex aeolicus. / Hydrogenases are the key enzymes for H2 conversion in many microorganisms. They present high specificity and efficiency towards H2 oxidations. Consequently, they appear as attracting biocatalysts in view of the development of biofuel cells. Within that goal, we have studied in this work the functional immobilization of O2-tolerant [NiFe] hydrogenase from the hyperthermophilic bacterium Aquifex aeolicus. Using electrochemistry, microscopy and spectroscopy, including PM-IRRAS, it is demonstrated that hydrogenase orientation on electrode interface is not controlled by electrostatic interactions but by hydrophobic interactions. The control of the orientation is driven by the environment of the last electron relay located at the surface of the enzyme. The hydrophobic transmembrane helix which is surrounded by neutral detergent is directly involved in the immobilization process. This specific orientation on hydrophobic interface induces the need for a redox mediator in order to achieve H2 oxidation. Conversely, hydrogenase adopts multiple orientations on charged interfaces. As a consequence, a direct and efficient connexion of enzymes is obtained, but also the increase in oxidation current is obtained due the mediated electrocatalysis. The determination of the best parameters for hydrogenase immobilization has allowed to develop new electrochemical interfaces, with increased current densities for H2 oxidation, and increased bioelectrode stability. By coupling a biocathode based on bilirubin oxidase for O2 reduction, a H2/O2 biofuel cell has been built with Aquifex aeolicus hydrogenase as the bioanode.

Hydrogénase

Hyperthermophile

Orientation

Protéine membranaire

Électrochimie

Pm-irras

Détergent

Oxydation de l’Hydrogène

Biopile à combustible

Hydrogenase

Hyperthermophile

Orientation

Membrane protein

Electrochemistry

Pm-irras

Detergent

Hydrogen oxidation

Biofuel cell