Structural modelling of transmembrane domains

Kelm, Sebastian

January 2011

Membrane proteins represent about one third of all known vertebrate proteins and over half of the current drug targets. Knowledge of their three-dimensional (3D) structure is worth millions of pounds to the pharmaceutical industry. Yet experimental structure elucidation of membrane proteins is a slow and expensive process. In the absence of experimental data, computational modelling tools can be used to close the gap between the numbers of known protein sequences and structures. However, currently available structure prediction tools were developed with globular soluble proteins in mind and perform poorly on membrane proteins. This thesis describes the development of a modelling approach able to predict accurately the structure of transmembrane domains of proteins. In this thesis we build a template-based modelling framework especially for membrane proteins, which uses membrane protein-specific information to inform the modelling process.Firstly, we develop a tool to accurately determine a given membrane protein structure's orientation within the membrane. We offer an analysis of the preferred substitution patterns within the membrane, as opposed to non-membrane environments, and how these differences influence the structures observed. This information is then used to build a set of tools that produce better sequence alignments of membrane proteins, compared to previously available methods, as well as more accurate predictions of their 3D structures. Each chapter describes one new piece of software or information and uses the tools and knowledge described in previous chapters to build up to a complete accurate model of a transmembrane domain.

572.696

Deciphering the Mechanism of E. coli tat Protien Transport: Kinetic Substeps and Cargo Properties

Whitaker, Neal William 1982-

14 March 2013

The Escherichia coli twin-arginine translocation (Tat) system transports fully folded and assembled proteins across the inner membrane into the periplasmic space. The E. coli Tat machinery minimally consists of three integral membrane proteins: TatA, TatB and TatC. A popular model of Tat translocation is that cargo first interacts with a substrate binding complex composed of TatB and TatC and then is transported across the inner membrane through a channel comprised primarily of TatA. The most common method for observing the kinetics of Tat transport, a protease protection assay, lacks the ability to distinguish between individual transport sub-steps and is limited by the inability to observe translocation in real-time. Therefore, a real-time FRET based assay was developed to observe interactions between the cargo protein pre-SufI, and its initial binding site, the TatBC complex. The cargo was found to first associate with the TatBC complex, and then, in the presence of a membrane potential (∆psi), migrate away from the initial binding site after a 20-45 second delay. Since cargo migration away from the TatBC complex was not directly promoted by the presence of a ∆psi, the delay likely represents some preparatory step that results in a transport competent translocon. In addition, the Tat system has long been identified as a potential biotechnological tool for protein production. However, much is still unknown about which cargos are suitable for transport by the Tat system. To probe the Tat system’s ability to transport substrates of different sizes and shapes, 18 different cargos were generated using the natural Tat substrate pre-SufI as a base. Transport efficiencies for these cargos indicate that not only is the Tat machinery’s ability to transport substrates determined by the protein’s molecular weight, as well as by its dimensions. In total, these results suggest a dynamic translocon that undergoes functionally significant, ∆psi-dependent changes during translocation. Moreover, not every protein cargo can be directed through the Tat translocon by a Tat signal peptide, and this selectivity is not only related to the overall size of the protein, but also dependent on shape.

Protein Translocation

Protein Targeting

Protein Secretion

Protein Export

Membrane Proteins

Intracellular Trafficking

Escherichia coli

Structure and function of nitrate and nitrite transporters, NrtA and NitA, from Aspergillus nidulans

Symington, Vicki F.

January 2009

Membrane proteins play an integral role in the control of ion transport across the cell membrane in biological systems. However, due to experimental constraints, structural and functional data available for these proteins is limited, especially considering their importance. In this study, two membrane proteins which transport nitrate and nitrate into the model filamentous ascomycete Aspergillus nidulans were investigated. Work on the twelve trans-membrane domain nitrate transport protein NrtA is well established. As a member of the major facilitator super family (MFS) the role of signature sequences characteristic of this family have previously been studied. Here, a series of point mutations were made to facilitate an understanding of key residues in the nitrate binding domain, the first nitrate signature motif and residues of the unique fungal central-loop domain. Using an expanded alignment package, the proposed secondary structure of NrtA was enhanced and used as a starting point for mutagenesis. Alanine scanning mutagenesis showed that glycine residues in the conserved nitrate nitrite porter (NNP) motif were critical for NrtA function. Two asparagines in the NNP were investigated; N160 and N168. N168 was found to be critical for NrtA function as all mutants were devoid of growth on nitrate solid agar medium though they expressed in the membrane to varying degrees. The nitrate binding site has been studied previously, revealing the interaction of conserved arginine residues with the anion as it traverses the bilayer. Though it was thought that mutations of residue T83 to a small, charge neutral, amino acid would substitute for no alteration to enzyme kinetics in mutant T83S was found when using ¹³NO₃⁻. Another major part of this thesis examined NitA which is part of a distinct nitrite transport family to NrtA (the Formate Nitrite Transporters, FNT). A mutagenesis approach targeted NitA residues conserved amongst homologous proteins. Residues in position D88 in an alignment of homologues were conserved in terms of charge. Mutagenesis of D88 revealed that maintaining charge at this position was essential for NitA function, likely due to a role in salt-bridge formation during conformational changes. Mutations to asparagine, glutamine, serine and valine showed reduced growth on agar though the protein was expressed to approximately wild-type levels. Nitrite uptake assays using a ¹³NO₂⁻ tracer were performed on D88N, D88E and D88Q and all showed wild-type Km and Vmax. Finally, the role of conserved asparagine residues found throughout NitA was investigated by mutagenesis. Expression studies revealed that mutants created in N122 and N246, changed to aspartic acid, lysine, glutamine and serine were generally not present in the membrane and thus did not grow on nitrite agar. However, mutations in N173 (in Tm 4) and N214 (in Tm 5), which are conserved in > 95 % of NitA homologues, showed varying degrees of growth and expression. Both of these residues are located in FNT signature motifs, so it is likely that they are involved with conformational changes or protein dynamics.

572

Probes for bacterial ion channels

Swallow, Isabella Diane

January 2014

Using three complementary approaches, this work sought to tackle the widespread problem of antibiotic resistance. To circumvent the resistance mechanisms developed by bacteria, it is necessary to establish drug candidates that act on novel therapeutic targets, such as the ion channels used by bacteria to modulate homeostasis. Examples include the potassium efflux channel, Kef, and the mechanosensitive channel of small conductance, MscS, which are not found in humans. How these targets function must be well understood before drug candidates can be developed, as such, their identification and investigation is often accompanied by the evolution of the analytical techniques used to study them. Membrane protein mass spectrometry is one technique showing potential in the study of ion channels. However, spectra can be clouded by the detergents used to solubilise ion channels from their native membranes. Undertaken herein was the synthesis of some fluorescent glycolipid detergents, which it was hypothesised could be encouraged to dissociate from ion channels via laser-induced excitation within the gas phase of a mass spectrometer, thereby improving the clarity with which spectra can be obtained. For Kef, an unconfirmed mechanism of action had previously been proposed. To explore the suggestion that sterically-demanding central residues are important for channel activation, solid phase peptide synthesis was used to isolate three tripeptide analogues of N-ethylsuccinimido glutathione, a known activator with a high affinity for Kef. A competition fluorescence assay suggested these tripeptides bound to Kef with an affinity lower than predicted, allowing the conclusion that a more detailed assessment of the steric bulk required for activation was necessary before a mechanism of action could be confirmed. Lysophosphatidylcholine has been shown to activate MscS, although it is not known how. Affinity chromatography between MscS and lysophosphatidylcholine was proposed as a means by which specific binding interactions could be investigated. For this technique an amino-derivative of lysophosphatidylcholine was necessary and its challenging synthesis is also detailed herein.

547

A semisynthetic protein nanoreactor for single-molecule chemistry

Lee, Joongoo

January 2015

The covalent chemistry of individual reactants bound within a protein nanopore can be monitored by observing the ionic current flow through the pore, which acts as a nanoreactor responding to bond-making and bond-breaking events. However, chemistry investigated in this way has been largely confined to the reactions of thiolates, presented by the side chains of cysteine residues. The introduction of unnatural amino acids would provide a large variety of reactive side chains with which additional single-molecule chemistry could be investigated. An efficient method to incorporate unnatural amino acid is semisynthesis, which allows site-specific modification with a chemically-defined functional group. However, relatively little work has been done on engineered membrane proteins. This deficiency stems from attributes inherent to proteins that interact with lipid bilayer, notably the poor solubility in aqueous buffer. In the present work, four different derivatives α-hemolysin (αHL) monomer were obtained either by two- or three-way native chemical ligation. The semisynthetic αHL monomers were successfully refolded to heptameric pores and used as nanoreactors to study single-molecule chemistry. The semisynthetic pores show similar biophysical properties to native αHL pores obtained from an in vitro transcription and translation technique. Interestingly, when αHL pores with one semisynthetic subunit containing a terminal alkyne group were used to study Cu(I)-catalyzed azide-alkyne cycloaddition, a long-lived intermediate in the reaction was directly observed.

572

Electrochemical investigations of H2-producing enzymes

Goldet, Gabrielle

January 2009

Hydrogenases are a family of enzyme that catalyses the bidirectional interconversion of H⁺ and H₂. There are two major classes of hydrogenases: the [NiFe(Se)]- and [FeFe]-hydrogenases. Both of these benefit from characteristics which would be advantageous to their use in technological devices for H₂ evolution and the generation of energy. These features are explored in detail in this thesis, with a particular emphasis placed on defining the conditions that limit the activity of hydrogenases when reducing H⁺ to produce H₂. Electrochemistry can be used as a direct measure of enzymatic activity; thus, Protein Film Electrochemistry, in which the protein is adsorbed directly onto the electrode, has been employed to probe catalysis by hydrogenases. Various characteristics of hydrogenases were probed. The catalytic bias for H₂ production was interrogated and the inhibition of H₂ evolution by H₂ itself (a major drawback to the use of some hydrogenases in technological devices to produce H₂) was quantified for a number of different hydrogenase. Aerobic inactivation of hydrogenases is also a substantial technological limitation; thus, inactivation of both H₂ production and H₂ oxidation by O₂ was studied in detail. This was compared to inhibition of hydrogenases by CO so as to elucidate the mechanism of binding of diatomic molecules and determine the factors limiting inactivation. This allows for a preliminary proposal for the genetic redesigning of hydrogenases for biotechnological purposes to be made. Finally, preliminary investigation of the binding of formaldehyde, potentially at a site integral to proton transfer, opens the field for further research into proton transfer pathways, the structural implications thereof and their importance in catalysis.

572.7

Pushing the boundaries : molecular dynamics simulations of complex biological membranes

Parton, Daniel L.

January 2011

A range of simulations have been conducted to investigate the behaviour of a diverse set of complex biological membrane systems. The processes of interest have required simulations over extended time and length scales, but without sacrifice of molecular detail. For this reason, the primary technique used has been coarse-grained molecular dynamics (CG MD) simulations, in which small groups of atoms are combined into lower-resolution CG particles. The increased computational efficiency of this technique has allowed simulations with time scales of microseconds, and length scales of hundreds of nm. The membrane-permeabilizing action of the antimicrobial peptide maculatin 1.1 was investigated. This short α-helical peptide is thought to kill bacteria by permeabilizing the plasma membrane, but the exact mechanism has not been confirmed. Multiscale (CG and atomistic) simulations show that maculatin can insert into membranes to form disordered, water-permeable aggregates, while CG simulations of large numbers of peptides resulted in substantial deformation of lipid vesicles. The simulations imply that both pore-forming and lytic mechanisms are available to maculatin 1.1, and that the predominance of either depends on conditions such as peptide concentration and membrane composition. A generalized study of membrane protein aggregation was conducted via CG simulations of lipid bilayers containing multiple copies of model transmembrane proteins: either α-helical bundles or β-barrels. By varying the lipid tail length and the membrane type (planar bilayer or spherical vesicle), the simulations display protein aggregation ranging from negligible to extensive; they show how this biologically important process is modulated by hydrophobic mismatch, membrane curvature, and the structural class or orientation of the protein. The association of influenza hemagglutinin (HA) with putative lipid rafts was investigated by simulating aggregates of HA in a domain-forming membrane. The CG MD study addressed an important limitation of model membrane experiments by investigating the influence of high local protein concentration on membrane phase behaviour. The simulations showed attenuated diffusion of unsaturated lipids within HA aggregates, leading to spontaneous accumulation of raft-type lipids (saturated lipids and cholesterol). A CG model of the entire influenza viral envelope was constructed in realistic dimensions, comprising the three types of viral envelope protein (HA, neuraminidase and M2) inserted into a large lipid vesicle. The study represents one of the largest near-atomistic simulations of a biological membrane to date. It shows how the high concentration of proteins found in the viral envelope can attenuate formation of lipid domains, which may help to explain why lipid rafts do not form on large scales in vivo.

616.203019

The molecular basis for ER tubule formation

Brady, Jacob Peter

January 2015

Integral membrane proteins of the DP1 and reticulon families are responsible for maintaining the high membrane curvature required for both smooth ER tubules and the edges of ER sheets. Mutations in these proteins lead to motor neurone diseases such as hereditary spastic paraplegia. Reticulon/DP1 proteins contain Reticulon Homology Domains (RHD) that have unusually long (≈30 aa) hydrophobic segments and are proposed to adopt intramembrane helical hairpins that stabilise membrane curvature. I have uncovered the secondary structure and dynamics of the DP1 protein Yop1p and identified a C-terminal conserved amphipathic helix that on its own interacts strongly with negatively charged membranes and is necessary for membrane tubule formation. Analyses of DP1 and reticulon family members indicate that most, if not all, contain C-terminal sequences capable of forming amphipathic helices. Together, these results indicate that amphipathic helices play a previously unrecognised role in RHD membrane curvature stabilisation. This work paves the way towards full structure determination of Yop1p by solution state NMR and marks the first high structural resolution study on an RHD protein.

572.8

Estudo de interações entre subunidades do exossomo e com outras proteínas celulares em Saccharomyces cerevisiae / Study of interactions between exosome subunits and other cellular proteins in Saccharomyces cerevisae

Fernando Alexis Gonzales Zubiate

31 August 2001

Em Saccharomyces cerevisiae, Rrp43p é uma proteína que faz parte do exossomo, um complexo multiproteíco que atua no processamento de snoRNAs, snRNAs e rRNAs e na degradação de mRNA. O exossomo está envolvido nesses processos através de uma ação 3\'→5\' exonucleolítica. Este complexo é composto por onze subunidades em S. cerevisiae e cada uma dessas subunidades tem uma ação predominante nos diferentes processos em que o complexo participa. Por estar envolvido diretamente na maturação dos rRNAs e alguns snoRNAs e snRNAs, assim como na degradação de mRNAs, o exossomo tem um papel importante no controle de expressão gênica. Com o objetivo de entender melhor a função da subunidade do exossomo Rrp43p, e conseqüentemente do complexo, nas modificações do RNA, realizamos estudos de interação entre proteínas através do método de \"two hybrid\", que permite analisar interações in vivo entre duas proteínas, convertendo-se assim, em uma ferramenta importante nestes estudos. Utilizando Rrp43p como \" isca\" estudamos interações com outras proteínas expressas em Saccharomyces cerevisiae, na procura de proteínas envolvidas em alguns eventos de processamento de RNA, que pudessem ajudar a esclarecer em maior detalhe o papel do exossomo na célula. Também examinamos interações da Rrp43p com os demais componentes do exossomo para determinar a possível estrutura deste complexo. Os resultados obtidos demonstram que Rrp43p interage com somente uma outra subunidade do exossomo, Rrp46p. A força desta interação, quando quantificada através do nível de expressão de um gene repórter, é compatível com o fato dessas proteínas formarem parte de um complexo. Estes dados constituem resultados inéditos a respeito da interação entre subunidades do exossomo. Os resultados evidenciam também a interação entre Rrp43p e uma proteína com função ainda não caracterizada em levedura (aqui denominada 137p). Esta interação foi detectada através do sistema do duplo híbrido, e depois confirmada por co-imunoprecipitação. A determinação da função desta nova proteína poderá ampliar as ferramentas de estudo da função e controle de atividade de Rrp43p e do exossomo. / In the yeast Saccharomyces cerevisiae, Rrp43p is one of the eleven subunits of the exosome, a complex involved in the processing of snoRNAs, snRNAs and rRNAs, and in mRNA degradation. The exosome participates in these processes through a 3\'-to-5\' exonucleolytic activity. Each of the eleven subunits is predominately active in one or few of the processes in which the complex takes part. Since the exosome is involved directly in rRNAs, and in some snRNAs and snoRNAs maturation, as well as in mRNA degradation, it plays an important role on the control of gene expression. Aiming to a better understanding of the Rrp43p subunit function on RNA processing, we started a screening for Rrp43p-interacting proteins through the yeast two hybrid system. In this study we expected to find proteins interacting with Rrp43p, which were involved in some aspects of RNA processing, and would improve the current knowledge on the exosome function. In order to obtain more information about the complex structure, we have also studied the interactions between Rrp43p and the other exosome subunits. The results shown here demonstrate that Rrp43p interacts with only one other exosome subunit, Rrp46p. These results can help elucidate the final exosome structure. We also found the interaction of Rrp43p with a protein of yet uncharacterized function (here named 137p). This interaction, identified in the two hybrid system, was also confirmed through co-immunoprecipitation analysis, and the study of 137p function might bring new insights on Rrp43p function and control.

Biologia molecular

Exossomo

Interação

Proteína

Proteínas da membrana (Estudo)

RNA

Saccharomyces

Exosome

Interaction

Membrane proteins (Study)

Molecular biology

Protein

RNA

Saccharomyces

Bioestimulação da proteína de membrana Na,K-ATPase por laser de baixa intensidade: atividade e propriedades estruturais / Biostimulation of the membrane protein Na, K-ATPase by low intensity laser: activity and structural properties

Campos, Gustavo Scanavachi Moreira

26 September 2014

A Na, K-ATPase é uma proteína que realiza o transporte ativo de cátions, se encontra na membrana plasmática de praticamente todas células animais e é formada por três subunidades: (110 kDa), (50 kDa) e (10 kDa). Neste trabalho, realizou-se a extração da proteína Na,K-ATPase de rim de coelho que foi preparada em 3 diferentes condições (i) fração de membrana rica em Na,K-ATPase; (ii) solubilizada e purificada em C12E8 e (iii) reconstituída em DPPC: DPPE lipossomo (1:1 lipídio:lipídio, 1:3 lipídio:proteína). Através de medidas de Espalhamento de Luz Dinâmico (DLS), Espectroscopia de Absorção (ABS) e Espalhamento de Raio-X a Baixos Ângulos (SAXS), associadas à medidas de atividade enzimática, constatou-se que a amostra de Na,K-ATPase solubilizada e purificada em C12E8 é constituida por diferentes agregados/oligômeros em solução. Com o intuito de eliminar os grandes agregados/oligômeros da amostra realizou-se a filtração (poro de 220 nm) e a adição do surfactante dodecil sulfato de sódio (SDS) e ambos procedimentos foram capazes de eliminar as populações de grandes agregados e/ou grandes oligômeros. A retirada destas populações pelo filtro promoveu um aumento de atividade específica da enzima. Já o SDS deve promover alterações conformacionais na estrutura da proteína que causam a inativação da mesma. Investigou-se variações de atividade da Na, K-ATPase através da irradiação da proteína presente em fração de membrana e reconstituída em lipossomo por meio de três lasers de baixa intensidade com comprimentos de onda diferentes: = 532 nm (5 mW), = 650 nm (50 mW) e = 780 nm (50 mW). Demonstrou-se que a variação da atividade enzimática depende do valor de dose de energia depositada, independe do comprimento de onda estudado neste intervalo e retorna para o nível basal após 6 horas. / The Na, K-ATPase is an active cation transporter protein, which is found in the plasma membrane of virtually all animal cells and it is comprised of three subunits: (110 kDa), (50 kDa) and (10 kDa). In this work, we performed the extraction of protein Na, K-ATPase from the kidney of adult rabbit for three different enzyme preparations (i) membrane-bound fraction; (ii) C12E8 solubilized and purified and (iii) reconstituted in DPPC: DPPE liposome (1: 1 - lipid: lipid, 1:3 - lipid:protein). Dynamic Light Scattering (DLS), Absorption Spectroscopy (ABS) and Small Angle X-ray Scattering (SAXS) were employed, associated with enzyme activity measurements. The results revealed that Na, K-ATPase C12E8-solubilized and purified is composed by different aggregates/oligomers. With the aim of eliminating large aggregates/oligomers from the protein sample, filtration (pore size 220 nm) and surfactant sodium dodecyl sulfate (SDS) addition were used. Both procedures were able to eliminate populations composed of large aggregates and/or large oligomers. The removal of these populations by the filter promoted an increase in the specific activity of the enzyme. On the other hand, SDS must promote conformational changes in the protein structure that inactivate thereof. Finally, here we also investigated variations of Na, K-ATPase activity present in the membrane-bound fraction and reconstituted in liposome under irradiation of three low-intensity lasers with different wavelengths: = 532 nm (5mW), = 650 nm (50 mW) and = 780 nm (50 mW). The results give support to the conclusion that the change in the enzymatic activity depends upon the amount of energy dose deposited, it is independent of the wavelength in the studied range and returns to the basal level after 6 hours.

Biofísica

Biophysics

Condensed matter physics

Física

Física da matéria condensada

Laser de estado sólido

Membrane Proteins

Physics

Proteínas da membrana

Solid state laser