Single Proteins under the Microscope: Conformations, Dynamics and Medicinal Therapies

Liu, Baoxu

20 June 2014

We applied single-molecule fluorescence (SMF) methods to probe the properties of individual fluorescent probes, and to characterize the proteins of interest to which these probes were attached. One remarkable advantage of SMF spectroscopy is the ability to investigate heterogeneous subpopulations of the ensemble, which are buried in ensemble averaging in other measurements. Other advantages include the ability to probe the entire dynamic sequences of a single molecule transitioning between different conformational states. For the purpose of having an extended observation of single molecules, while maintaining the native nanoscale surroundings, we developed an improved vesicle preparation method for encapsulating scarce biological samples. SMF investigations revealed that molecules trapped in vesicles exhibit nearly ideal single-emitter behavior, which therefore recommends the vesicle encapsulation for reproducible and reliable SMF studies. Hyperactive Signal-Transducer-and-Activator-of-Transcription 3 (STAT3) protein contributes significantly to human cancers, such as leukemia and lymphoma. We have proposed a novel therapeutic strategy by designing a cholesterol-based protein membrane anchor (PMA), to tether STAT3 to the cell membrane and thus inhibit unwanted transcription at the cell nucleus. We designed in vitro proof-of-concept experiments by encapsulating STAT3 and PMAs in phospholipid vesicles. The efficiency and the stability of STAT3 anchoring in the lipid membrane were interrogated via quantitative fluorescence imaging and multiparameter SMF spectroscopy. Our in vitro data paved the way for the in vivo demonstration of STAT3 inhibition in live cells, thus demonstrating that PMA-induced protein localization is a conceptually viable therapeutic strategy. The recent discovery of intrinsically disordered proteins (IDPs) highlights important exceptions to the traditional structure-function paradigm. SMF methods are very suited for probing the properties of such highly heterogeneous systems. We studied in detail the effects of electrostatics on the conformational disorder of an IDP protein, Sic1 from yeast, and found that the electrostatic repulsion is a major factor controlling the dimensions of Sic1. Based on our data we also conclude that a rod-like shape seems a better candidate than a random Gaussian chain to describe and predict the behavior of Sic1.

Intrinsically Disordered Protein

New Cancer Therapies

Protein Membrane Anchorage

0752

0786

0760

Characterization of Structural and Binding Properties of 4E-BP2

Lukhele, Sabelo

10 July 2013

Eukaryotic initiation factor-4E (eIF4E) controls the rate of cap-dependent translation initiation and is in turn exquisitely regulated by 4E-BPs. 4E-BP2 binds eIF4E with the highest affinity and is implicated in cancer, and metabolic and neurological disorders. Herein we use NMR, ITC and fluorescence to characterize 4E-BP2 structural and binding properties. Isolated 4E-BP2 is intrinsically disordered, but possesses some transient secondary structural propensities. eIF4E, however, is folded but has a disordered N-terminus. The eIF4E:4E-BP2 interaction is tight (Kd = 10-9 nM) and involves 4E-BP2 C-terminal and canonical binding regions, and the disordered eIF4E N-terminus. 4E-BP2 remains largely disordered upon binding to eIF4E. Noteworthy, high affinity interactions are not necessarily mediated by static structures, and 4E-BP2 binding is not the simple “disorder-to-order” transition observed in many interactions involving disordered proteins. This study offers molecular insights into 4E-BP2 functionality, and lays a foundation for development of novel therapies for cancer and neurological disorders.

Translation initiation

Intrinsically disordered protein

Eukaryotic initiation factor 4E

4E-BP2

NMR

Fluorescence

0487

Characterization of Structural and Binding Properties of 4E-BP2

Lukhele, Sabelo

10 July 2013

Eukaryotic initiation factor-4E (eIF4E) controls the rate of cap-dependent translation initiation and is in turn exquisitely regulated by 4E-BPs. 4E-BP2 binds eIF4E with the highest affinity and is implicated in cancer, and metabolic and neurological disorders. Herein we use NMR, ITC and fluorescence to characterize 4E-BP2 structural and binding properties. Isolated 4E-BP2 is intrinsically disordered, but possesses some transient secondary structural propensities. eIF4E, however, is folded but has a disordered N-terminus. The eIF4E:4E-BP2 interaction is tight (Kd = 10-9 nM) and involves 4E-BP2 C-terminal and canonical binding regions, and the disordered eIF4E N-terminus. 4E-BP2 remains largely disordered upon binding to eIF4E. Noteworthy, high affinity interactions are not necessarily mediated by static structures, and 4E-BP2 binding is not the simple “disorder-to-order” transition observed in many interactions involving disordered proteins. This study offers molecular insights into 4E-BP2 functionality, and lays a foundation for development of novel therapies for cancer and neurological disorders.

Translation initiation

Intrinsically disordered protein

Eukaryotic initiation factor 4E

4E-BP2

NMR

Fluorescence

0487

História evolutiva da subfamília FOXP : análise evolutiva molecular e estrutural em tetrápodes

Viscardi, Lucas Henriques

January 2015

A família gênica Forkhead P {FOXP) tem sido alvo de muitos estudos envolvendo evolução do cérebro e comportamento animal. Destacam-se particularmente as investigações com o gene FOXP2, que indicam que mudanças neste gene estariam associadas com a evolução da vocalização em algumas espécies de mamíferos, incluindo o Homo sapiens. Recentemente, estudos de desordem intrínseca de proteínas (IDPs) tem ganhado ênfase no contexto evolut ivo, visto que uma correlação posit iva entre regiões de desordem e altas taxas evolutivas tem sido observada. Através de um conjunto de abordagens que inclui predizer o conteúdo de desordem e os motivos lineares de interação, bem como as taxas evolutivas, buscamos desvendar a historia evolutiva dos genes da subfamília FOXP. Concentramos nossas análises sobre regiões desordenadas das proteínas FOXPl, FOXP2, FOXP3 e FOXP4 encontradas em 77 espécies de tetrápodes. Tais regiões proteicas são normalmente negligenciadas em estudos dessa natureza, pois se localizam fora de seus tra dicionais domínios conservados, normalmente associados à função principal da proteína. Sít ios apontados estando sob seleção positiva e relaxamento da restrição seletiva mostraram-se hotspots importantes para mudanças que podem impactar na capacidade de interação das proteínas. Encontramos que os maiores valores de w são mais prevalentes em regiões desordenadas que em ordenadas. Ainda, alto e similar valor de desordem (70%) foi encontrado nas 77 proteínas ortólogas de FOXPl , FOXP2, e FOXP4, indicando a manutenção de um "padrão geral" sobre um longo tempo evolutivo. Portanto, a variabilidade tanto de aminoácidos quanto de motivos lineares dentro das regiões de desordem foi marcante. A proteína FOXP3 apresentou menor nível de desordem (30%), mas signif icante sinal de seleção positiva em alguns sítios. Composição idênt ica de resíduo de aminoácido e/ou motivos lineares em espécies filogeneticamente distantes, indica clara convergência molecular, provavelmente associada a pressões seletivas similares. Sucessivamente, nossos achados mostraram uma clara diferença na composição de motivos lineares entre mamíferos e não mamíferos, dando suporte para a importância dos estudos de evolução da interatividade proteica para as compreensões de características taxa-específicas. / Forkhead Family P (FOXP) has been target of many studies about brain and behavior evo lution among species. FOXP2 receives special attention in academic society, due associations with vocalízation evolution in mammals, including Homo sapiens. Recently, intrinsically disorder proteins studies have gained emphasis in the evolutionary context, as positive correlation between disorder regions and higher evolutionary rate has been observed. Through a set of approaches, including disorder and linear motif predictions, as well as estimate evolutionary rates, we aimed to unveil the evolutionary history of FOXP subfamily genes. We focused our ana lysis over disordered regions of FOXPl, FOXP2, FOXP3 and FOXP4 proteins retrieved in 77 tetrapods. Such protein regions are usually neglected in studies of this nature, for being localized out of the traditional conserved domains, usua lly associated with the main function of the protein. Sites indicated as under relaxation of selective constrains or positive selection have shown to be important hotspots for changes that can impact in protein interaction capability. Higher w va lues are prevalent in disordered regions than in ordered ones. Still, high and similar disorder proportion (~70%) was found among 77 orthologues proteins of FOXPl, FOXP2 and FOXP4, indicating general pattern of disorder maintenance, along tetrapod's evolutionary tree. However, amino acid and linear motifs variability within disordered regions was observed. FOXP3 protein presented lower disorder leveis (~30%), when compared with other paralogues, but signal of positive selection was observed in some sites. ldentical composition of amino acid residues and/or linear motifs is, probably, associated with similar selective pressure. Successively, ou r results showed clear differences in linear motif composition between mammals and non-mammals, supporting the importance of evolutionary studies on protein interaction for the understanding of taxa-specifics characteristics.

Evolução molecular

Tetrapodes

lntrinsica lly disordered protein

Molecular evolution

Linear motifs

Forkhead domain

FOXP gene family

Elucidating the Molecular Dynamics, Structure and Assembly of Spider Dragline Silk Proteins by Nuclear Magnetic Resonance (NMR) Spectroscopy

January 2015

abstract: Spider dragline silk is an outstanding biopolymer with a strength that exceeds steel by weight and a toughness greater than high-performance fibers like Kevlar. For this reason, structural and dynamic studies on the spider silk are of great importance for developing future biomaterials. The spider dragline silk comprises two silk proteins, Major ampullate Spidroin 1 and 2 (MaSp1 and 2), which are synthesized and stored in the major ampullate (MA) gland of spiders. The initial state of the silk proteins within Black Widow MA glands was probed with solution-state NMR spectroscopy. The conformation dependent chemical shifts information indicates that the silk proteins are unstructured and in random coil conformation. 15N relaxation parameters, T1, T2 and 15N-{1H} steady-state NOE were measured to probe the backbone dynamics for MA silk proteins. These measurements indicate fast sub-nanosecond timescale backbone dynamics for the repetitive core of spider MA proteins indicating that the silk proteins are unfolded, highly flexible random coils in the MA gland. The translational diffusion coefficients of the spider silk proteins within the MA gland were measured using 1H diffusion NMR at 1H sites from different amino acids. A phenomenon was observed where the measured diffusion coefficients decrease with an increase in the diffusion delay used. The mean displacement along the external magnetic field was found to be 0.35 μm and independent of the diffusion delay. The results indicate that the diffusion of silk protein was restricted due to intermolecular cross-linking with only segmental diffusion observable. To understand how a spider converts the unfolded protein spinning dope into a highly structured and oriented in the super fiber,the effect of acidification on spider silk assembly was investigated on native spidroins from the major ampullate (MA) gland fluid excised from Latrodectus hesperus (Black Widow) spiders. The in vitro spider silk assembly kinetics were monitored as a function of pH with a 13C solid-state Magic Angle Spinning (MAS) NMR approach. The results confirm the importance of acidic pH in the spider silk self-assembly process with observation of a sigmoidal nucleation-elongation kinetic profile. The rates of nucleation and elongation and the percentage of β-sheet structure in the grown fibers depend on pH. The secondary structure of the major ampullate silk from Peucetia viridians (Green Lynx) spiders was characterized by X-ray diffraction (XRD) and solid-state NMR spectroscopy. From XRD measurement, β-sheet nano-crystallites were observed that are highly oriented along the fiber axis with an orientational order of 0.980. Compare to the crystalline region, the amorphous region was found to be partially oriented with an orientational order of 0.887. Further, two dimensional 13C-13C through-space and through-bond solid-state NMR experiments provide structural analysis for the repetitive amino acid motifs in the silk proteins. The nano-crystallites are mainly alanine-rich β-sheet structures. The total percentage of crystalline region is determined to be 40.0±1.2 %. 18±1 % of alanine, 60±2 % glycine and 54±2 % serine are determined to be incorporated into helical conformations while 82±1 % of alanine, 40±3 % glycine and 46±2 % serine are in the β-sheet conformation. / Dissertation/Thesis / Doctoral Dissertation Chemistry 2015

Chemistry

Biophysics

Analytical chemistry

Intrinsic Disordered Protein

NMR

Protein Dynamics

Protein Structure

Self Assembly

Spider Silk

História evolutiva da subfamília FOXP : análise evolutiva molecular e estrutural em tetrápodes

Viscardi, Lucas Henriques

January 2015

A família gênica Forkhead P {FOXP) tem sido alvo de muitos estudos envolvendo evolução do cérebro e comportamento animal. Destacam-se particularmente as investigações com o gene FOXP2, que indicam que mudanças neste gene estariam associadas com a evolução da vocalização em algumas espécies de mamíferos, incluindo o Homo sapiens. Recentemente, estudos de desordem intrínseca de proteínas (IDPs) tem ganhado ênfase no contexto evolut ivo, visto que uma correlação posit iva entre regiões de desordem e altas taxas evolutivas tem sido observada. Através de um conjunto de abordagens que inclui predizer o conteúdo de desordem e os motivos lineares de interação, bem como as taxas evolutivas, buscamos desvendar a historia evolutiva dos genes da subfamília FOXP. Concentramos nossas análises sobre regiões desordenadas das proteínas FOXPl, FOXP2, FOXP3 e FOXP4 encontradas em 77 espécies de tetrápodes. Tais regiões proteicas são normalmente negligenciadas em estudos dessa natureza, pois se localizam fora de seus tra dicionais domínios conservados, normalmente associados à função principal da proteína. Sít ios apontados estando sob seleção positiva e relaxamento da restrição seletiva mostraram-se hotspots importantes para mudanças que podem impactar na capacidade de interação das proteínas. Encontramos que os maiores valores de w são mais prevalentes em regiões desordenadas que em ordenadas. Ainda, alto e similar valor de desordem (70%) foi encontrado nas 77 proteínas ortólogas de FOXPl , FOXP2, e FOXP4, indicando a manutenção de um "padrão geral" sobre um longo tempo evolutivo. Portanto, a variabilidade tanto de aminoácidos quanto de motivos lineares dentro das regiões de desordem foi marcante. A proteína FOXP3 apresentou menor nível de desordem (30%), mas signif icante sinal de seleção positiva em alguns sítios. Composição idênt ica de resíduo de aminoácido e/ou motivos lineares em espécies filogeneticamente distantes, indica clara convergência molecular, provavelmente associada a pressões seletivas similares. Sucessivamente, nossos achados mostraram uma clara diferença na composição de motivos lineares entre mamíferos e não mamíferos, dando suporte para a importância dos estudos de evolução da interatividade proteica para as compreensões de características taxa-específicas. / Forkhead Family P (FOXP) has been target of many studies about brain and behavior evo lution among species. FOXP2 receives special attention in academic society, due associations with vocalízation evolution in mammals, including Homo sapiens. Recently, intrinsically disorder proteins studies have gained emphasis in the evolutionary context, as positive correlation between disorder regions and higher evolutionary rate has been observed. Through a set of approaches, including disorder and linear motif predictions, as well as estimate evolutionary rates, we aimed to unveil the evolutionary history of FOXP subfamily genes. We focused our ana lysis over disordered regions of FOXPl, FOXP2, FOXP3 and FOXP4 proteins retrieved in 77 tetrapods. Such protein regions are usually neglected in studies of this nature, for being localized out of the traditional conserved domains, usua lly associated with the main function of the protein. Sites indicated as under relaxation of selective constrains or positive selection have shown to be important hotspots for changes that can impact in protein interaction capability. Higher w va lues are prevalent in disordered regions than in ordered ones. Still, high and similar disorder proportion (~70%) was found among 77 orthologues proteins of FOXPl, FOXP2 and FOXP4, indicating general pattern of disorder maintenance, along tetrapod's evolutionary tree. However, amino acid and linear motifs variability within disordered regions was observed. FOXP3 protein presented lower disorder leveis (~30%), when compared with other paralogues, but signal of positive selection was observed in some sites. ldentical composition of amino acid residues and/or linear motifs is, probably, associated with similar selective pressure. Successively, ou r results showed clear differences in linear motif composition between mammals and non-mammals, supporting the importance of evolutionary studies on protein interaction for the understanding of taxa-specifics characteristics.

Evolução molecular

Tetrapodes

lntrinsica lly disordered protein

Molecular evolution

Linear motifs

Forkhead domain

FOXP gene family

Intrinsic Disorder Where You Least Expect It: The Incidence and Functional Relevance of Intrinsic Disorder in Enzymes and the Protein Data Bank

Deforte, Shelly

27 June 2016

Intrinsically disordered proteins (IDPs) and intrinsically disordered protein regions (IDPRs) exist as interconverting conformational ensembles, without a single fixed three-dimensional structure in vivo. The focus in the literature up to this point has been primarily on IDPs that are mostly or entirely disordered. Therefore, we have an incomplete understanding of the incidence and functional relevance of IDPRs in proteins that have regions of both order and disorder. This work explores these populations, by examining IDPRs in the Protein Data Bank (PDB) and in enzymes. By applying disorder prediction methods combined with an analysis of missing regions in crystal structure data, this work shows that enzymes have a similar incidence and length of IDPRs as do non-enzymes, and that these IDPRs are correlated with functions related to macromolecular metabolism, signaling, and regulation. Furthermore, extensive analyses of missing regions with conflicting information between multiple structures in the PDB show that, rather than experimental artifacts, this ambiguity most likely arises due to partially or conditionally disordered regions. This work documents the first proteome level study of protein intrinsic disorder in enzyme populations and demonstrates a novel way of analyzing missing regions in the PDB. Furthermore, an extensive literature search as part of this work provides information for 1127 IDPs with experimental evidence documented in the literature, 96 of which are enzymes. The results contained herein present a new model of the protein universe, where disorder is directed by evolution in both non-enzymes and enzymes to make the most of limited proteomes in complex organisms through complicated signaling networks and tightly controlled regulation.

intrinsically disordered protein

x-ray crystallography

structural biology

enzyme function

Bioinformatics

Medicine and Health Sciences

Molecular Biology

Toward a Molecular Mechanism of Phase Separation in Disordered Elastin-Like Proteins

Zhang, Yue

08 December 2017

Since the last decade, an increasing number of proteins have been shown to be capable of undergoing reversible liquid-liquid phase separation (LLPS) in response to an external stimulus, and the resulting protein-rich phase (coacervate) is considered as one of the main components of membrane-less organelles. Most of these proteins are intrinsically disordered proteins (IDPs) or contain intrinsically disordered regions. More importantly, LLPS often plays an important role in cellular signaling and development of cells and tissues. However, the molecular mechanisms underlying LLPS of proteins remain poorly understood. Elastin-like proteins (ELPs), a class of IDPs derived from the hydrophobic domains of tropoelastin, are known to undergo LLPS reversibly above a concentration-dependent transition temperature (TT), allowing ELPs to be a promising thermo-responsive drug delivery vector for treating cancer. Previous studies have suggested that, as temperature increases, ELPs experience an increased propensity for type II beta-turns. Our hypothesis is that the interaction is initiated at the beta-turn positions. In this work, integrative approaches including experimental and computational methods were employed to study the early stages of ELP phase separation. Using nuclear magnetic resonance spectroscopy (NMR), and paramagnetic relaxation enhancement (PRE), we have characterized structural properties of self-association in several ELPs. NMR chemical shifts suggest that ELPs adopt a beta-turn conformation even at temperatures below the TT. The intermolecular PRE reveals there is a stronger interaction between the higher beta-turn propensity regions. Building on this observation, a series of structural ensembles were generated for ELP incorporating differing amounts of beta-turn bias, from 1% to 90%. To mimic the early stages of the phase change, two monomers were paired, assuming preferential interaction at beta-turn regions. Following dimerization, the ensemble-averaged hydrodynamic properties were calculated for each degree of beta-turn bias, and results were compared with analytical ultracentrifugation (AUC) experiments at various temperatures. The ensemble calculation reveals that accessible surface area changes dramatically as oligomers are formed from monomers with a high beta-turn content. Together, these observations suggest a model where ELP self-association is initiated at beta-turn positions, where the driving force of phase separation is solvent exclusion due to changes in the hydrophobic accessible surface area.

NMR

PRE

hydrodynamic simulation

AUC

Monte-Carlo simulation

protein-protein interaction

disordered protein

EPR

The structural basis for lipid interactions of serum amyloid A

Frame, Nicholas

07 October 2019

Serum amyloid A (SAA) is a small, evolutionarily well-conserved, acute-phase protein best known as the protein precursor for amyloid A amyloidosis. During acute injury, infection, or inflammation, SAA plasma concentration rapidly rises 1000-fold, but the benefit of this dramatic increase is unclear. SAA functions in the innate immune response, cell signaling, and lipid homeostasis. Most SAA circulates on plasma high-density lipoproteins (HDL), where it reroutes HDL for lipid recycling. The aim of this dissertation is to provide a structural basis for understanding SAA-lipid interactions and to elucidate the structure-function relationship in this ancient protein. SAA is an intrinsically disordered protein that acquires ~50% helical structure when bound to lipids, and is ~80% helical in three available atomic-resolution x-ray crystal structures. We took advantage of these crystal structures of lipid-free SAA to propose the binding site for various lipids, including lipids in HDL. We postulated that SAA, as a monomer, binds lipids via two amphipathic helices, h1 and h3, that form a concave hydrophobic surface, and that the curvature of this surface defines the binding preference of SAA for HDL versus larger lipoproteins. Next, we used murine SAA1.1 and a membrane-mimicking model phospholipid, palmitoyl-oleoyl phosphocholine (POPC), to reconstitute SAA-lipid complexes and characterize their overall structure, stability and stoichiometry using an array of spectroscopic, electron microscopic, and biochemical methods. We observed preferential formation of ~10 nm particles that mimic HDL size, accompanied by the α-helical folding. To probe the local protein conformation and dynamics in these SAA-POPC particles, we used hydrogen-deuterium exchange mass spectrometry. Analysis of the amount and the kinetics of deuterium uptake clearly established h1 and h3 as the lipid-binding site. Moreover, we determined that SAA binding to lipid follows a mixed model that combines induced fit, promoting α-folding in h3, with conformational selection, stabilizing pre-existing conformations in h1 and around the h2-h3 linker. Taken together, our results provided the structural basis necessary for understanding SAA-lipid interactions, which are central to beneficial functions of SAA as a housekeeping molecule, and to its misfolding in amyloid. This research sets the stage for understanding SAA interactions with its numerous other functional ligands.

Biophysics

Intrinsically disordered protein

Lipoprotein nanoparticle

Protein-lipid binding

Protein structure

Molecular Dynamics of Folded and Disordered Polypeptides in Comparison with Nuclear Magnetic Resonance Measurement

Yu, Lei

15 August 2018

No description available.

Biophysics

Chemistry

Physical Chemistry

Molecular Dynamics

Nuclear Magnetic Resonance

Intrinsically Disordered Protein