NMR approaches to understanding intramolecular and intermolecular interactions in proteins

Panova, Stanislava

January 2017

Inhibition of the intrinsically disordered proteins (IDP) is a recognized issue in drug research. Standard approaches, based on key-lock model, cannot be used in the absence of rigid structure and defined active site. Here a basic helix-loop-helix leucine zipper (bHLHZip) domain of c-Myc was studied, which is intrinsically disordered and prone to aggregation. Chemical denaturation of proteins is a widely accepted technique to study protein folding, but here this methodology was applied to IDP, observing its effect on the structural ensemble of c-Myc by NMR spectroscopy. Nonlinear chemical shift changes indicated cooperative unfolding of the helical structure of the part of the leucine zipper domain in parallel with the melting of the N-terminal helix. Paramagnetic relaxation enhancement (PRE) was used to probe long-range structure and revealed presence of long-range contacts. The following search for inhibitors can be directed to the search for ligands, locking c-Myc in its more compact conformation. Protein self-association is a problem typical for IDPs and intrinsic process for all proteins at high concentrations. It leads to increased viscosity, gelation and possible precipitation, which cause problems in protein manufacturing, stability and delivery. If protein drugs require high dosing, special approaches are needed. At high concentrations proteins experience conditions close to the crystal state, therefore interactions in solution could potentially coincide with crystal lattice contacts. A range of diverse methods is used to study this process, but the complexity of the mechanism makes it hard to build a reliable model. Here, the self-association of streptococcal Protein G (PrtG) was studied using Nuclear Magnetic Resonance (NMR) spectroscopy in solution. The properties of protein-protein interactions at high concentration, up to ~ 160 mg/ml, were studied at residue-level resolution. Residue specific information on protein dynamics was obtained using 15N relaxation measurements. The experiments were carried out at multiple concentrations. Variation in the rotational correlation time over these concentrations showed changes in the protein dynamics, which indicated weak protein-protein interactions occurring in solution. Pulsed-field gradient NMR spectroscopy was used to monitor translational diffusion coefficients in order to estimate the degree of protein self-association. Oligomer formation was also monitored by looking at variations in 1H and 15N amide chemical shifts. Better understanding of protein self-association mechanisms under different conditions could assist in developing methods to reduce the level of reversible protein self-association in solution at high protein concentrations.

540

Disorder Levels of c-Myb Transactivation Domain Regulate its Binding Affinity to the KIX Domain of CREB Binding Protein

Poosapati, Anusha

03 November 2017

Intrinsically disordered proteins (IDPs) do not form stable tertiary structures like their ordered partners. They exist as heterogeneous ensembles that fluctuate over a time scale. Intrinsically disordered regions and proteins are found across different phyla and exert crucial biological functions. They exhibit transient secondary structures in their free state and become folded upon binding to their protein partners via a mechanism called coupled folding and binding. Some IDPs form alpha helices when bound to their protein partners. We observed a set of cancer associated IDPs where the helical binding segments of IDPs are flanked by prolines on both the sides. Helix-breaking prolines are frequently found in IDPs flanking the binding segment and are evolutionarily conserved across phyla. Two studies have shown that helix flanking prolines modulate the function of IDPs by regulating the levels of disorder in their free state and in turn regulating the binding affinities to their partners. We aimed to study if this is a common phenomenon in IDPs that exhibit similar pattern in the conservation of helix flanking prolines. We chose to test the hypothesis in c-Myb-KIX : IDP-target system in which the disordered protein exhibits high residual helicity levels in its free state. c-Myb is a hematopoietic regulator that plays a crucial role in cancer by binding to the KIX domain of CBP. Studying the functional regulation of c-Myb by modulating the disorder levels in c-Myb and in IDPs in general provides a better understanding of the way IDPs function and can be used in therapeutic strategies as IDPs are known to be involved in regulating various cellular processes and diseases. To study the effect of conserved helix flanking prolines on the residual helicity levels of c-Myb and its binding affinity to the KIX domain of CBP, we mutated the prolines to alanines. Mutating prolines to alanines increased the helicity levels of c-Myb in its free state. This small increase in the helicity levels of a highly helical c-Myb showed almost no effect on the binding affinity between cMyb and KIX. We hypothesized that there is a helical threshold for coupled folding and binding beyond which helicity levels of the free state IDP have no effect on its binding to their ordered protein partner. To test this hypothesis, we mutated solvent exposed amino acid residues in c-Myb that reduce its overall helicity and studied its effect on the binding affinity between c-Myb and KIX. Over a broad range of reduction in helicity levels of the free state did not show an effect on the binding affinity but beyond a certain level, decrease in helicity levels showed pronounced effects on the binding affinity between c-Myb and KIX.

Coupled folding and binding

Intrinsically disordered proteins

Nuclear Magnetic Resonance Spectroscopy

transient helicity

Biochemistry

Biology

Biophysics

From Population to Single Cells: Deconvolution of Cell-cycle Dynamics

Guo, Xin

January 2012

<p>The cell cycle is one of the fundamental processes in all living organisms, and all cells arise from the division of existing cells. To better understand the regulation of the cell cycle, synchrony experiments are widely used to monitor cellular dynamics during this process. In such experiments, a large population of cells is generally arrested or selected at one stage of the cycle, and then released to progress through subsequent division stages. Measurements are then taken in this population at a variety of time points after release to provide insight into the dynamics of the cell cycle. However, due to cell-to-cell variability and asymmetric cell division, cells in a synchronized population lose synchrony over time. As a result, the time-series measurements from the synchronized cell populations do not accurately reflect the underlying dynamics of cell-cycle processes.</p><p>In this thesis, we introduce a deconvolution algorithm that learns a more accurate view of cell-cycle dynamics, free from the convolution effects associated with imperfect cell synchronization. Through wavelet-basis regularization, our method sharpens signal without sharpening noise, and can remarkably increase both the dynamic range and the temporal resolution of time-series data. Though it can be applied to any such data, we demonstrate the utility of our method by applying it to a recent cell-cycle transcription time course in the eukaryote <italic>Saccharomyces cerevisiae</italic>. We show that our method more sensitively detects cell-cycle-regulated transcription, and reveals subtle timing differences that are masked in the original population measurements. Our algorithm also explicitly learns distinct transcription programs for both mother and daughter cells, enabling us to identify 82 genes transcribed almost entirely in the early G1 in a daughter-specific manner.</p><p>In addition to the cell-cycle deconvolution algorithm, we introduce <italic>DOMAIN</italic>, a protein-protein interaction (PPI) network alignment method, which employs a novel <italic>direct-edge-alignment</italic> paradigm to detect conserved functional modules (e.g., protein complexes, molecular pathways) from pairwise PPI networks. By applying our approach to detect protein complexes conserved in yeast-fly and yeast-worm PPI networks, we show that our approach outperforms two widely used approaches in most alignment performance metrics. We also show that our approach enables us to identify conserved cell-cycle-related functional modules across yeast-fly PPI networks.</p> / Dissertation

Bioinformatics

Computer science

cell cycle

deconvolution

intrinsically disordered regions

protein-protein interaction

transcriptional program

Structure-function analysis of the acidic domain of the Arabidopsis Toc159 receptors

Richardson, Lynn

January 2008

Most chloroplast proteins are encoded in the nucleus and translated in the cytosol with an N-terminal transit peptide, which facilitates recognition by the receptors of the translocon at the outer membrane of chloroplasts (Toc). The Toc159 family of receptors in Arabidopsis thaliana are the primary chloroplast preprotein receptors. Members of this family differentially associate with either atToc33 or atToc34 (“at” designates the species of origin, Arabidopsis thaliana) to form structurally and functionally distinct Toc complexes; atToc159/33-containing complexes import photosynthetic preproteins, and atToc132(120)/34-containing complexes import non-photosynthetic, plastid house-keeping proteins. The Toc159 receptors are most variable in their N-terminal A-domain, suggesting that this domain may contribute to their functional specificity. The A-domain has structural properties characteristic of intrinsically unstructured protein (IUP) domains, including an abundance of acidic amino acid residues, aberrant mobility during SDS-PAGE and sensitivity to proteolysis. The overall objective of this study was to gain insight into the function of the A-domain. First, to investigate the role of the A-domain in the assembly of structurally distinct Toc complexes, full-length, truncated and domain-swapped variants of atToc159 and atToc132 were targeted in vitro to chloroplasts isolated from wild type (WT) Arabidopsis, and atToc33 and atToc34 null mutants (ppi1 and ppi3, respectively). Insertion of atToc132 was less efficient than atToc159, and was not affected by the removal or swapping of the A-domain. In contrast, removal of the A-domain of atToc159 resulted in decreased insertion, most notably into ppi1 chloroplasts, suggesting that the A-domain is important for insertion, especially into atToc34-containing complexes. These results indicate that the A-domain does play a role in targeting, and may also suggest different roles for the A-domain in targeting of atToc159 and atToc132. Second, a structural analysis of the A-domain of atToc132 and atToc159 was performed using CD and fluorescence spectroscopy to gain insight into their potential function(s). The A-domains were found to be unstructured at physiological pH, and their secondary structure increased with increasing temperature and decreasing pH, which are characteristics of IUPs. IUPs are commonly involved in protein-protein interactions, and their unstructured nature may suggest a role for the A-domains in binding transit peptides, accounting for the ability of the Toc159 receptors to differentially distinguish between a large number of diverse transit peptides that possess low sequence conservation.

chloroplast protein import

preprotein receptors

Toc complex

intrinsically unstructured protein

Biology

Structure-function analysis of the acidic domain of the Arabidopsis Toc159 receptors

Richardson, Lynn

January 2008

Most chloroplast proteins are encoded in the nucleus and translated in the cytosol with an N-terminal transit peptide, which facilitates recognition by the receptors of the translocon at the outer membrane of chloroplasts (Toc). The Toc159 family of receptors in Arabidopsis thaliana are the primary chloroplast preprotein receptors. Members of this family differentially associate with either atToc33 or atToc34 (“at” designates the species of origin, Arabidopsis thaliana) to form structurally and functionally distinct Toc complexes; atToc159/33-containing complexes import photosynthetic preproteins, and atToc132(120)/34-containing complexes import non-photosynthetic, plastid house-keeping proteins. The Toc159 receptors are most variable in their N-terminal A-domain, suggesting that this domain may contribute to their functional specificity. The A-domain has structural properties characteristic of intrinsically unstructured protein (IUP) domains, including an abundance of acidic amino acid residues, aberrant mobility during SDS-PAGE and sensitivity to proteolysis. The overall objective of this study was to gain insight into the function of the A-domain. First, to investigate the role of the A-domain in the assembly of structurally distinct Toc complexes, full-length, truncated and domain-swapped variants of atToc159 and atToc132 were targeted in vitro to chloroplasts isolated from wild type (WT) Arabidopsis, and atToc33 and atToc34 null mutants (ppi1 and ppi3, respectively). Insertion of atToc132 was less efficient than atToc159, and was not affected by the removal or swapping of the A-domain. In contrast, removal of the A-domain of atToc159 resulted in decreased insertion, most notably into ppi1 chloroplasts, suggesting that the A-domain is important for insertion, especially into atToc34-containing complexes. These results indicate that the A-domain does play a role in targeting, and may also suggest different roles for the A-domain in targeting of atToc159 and atToc132. Second, a structural analysis of the A-domain of atToc132 and atToc159 was performed using CD and fluorescence spectroscopy to gain insight into their potential function(s). The A-domains were found to be unstructured at physiological pH, and their secondary structure increased with increasing temperature and decreasing pH, which are characteristics of IUPs. IUPs are commonly involved in protein-protein interactions, and their unstructured nature may suggest a role for the A-domains in binding transit peptides, accounting for the ability of the Toc159 receptors to differentially distinguish between a large number of diverse transit peptides that possess low sequence conservation.

chloroplast protein import

preprotein receptors

Toc complex

intrinsically unstructured protein

Biology

Structure, Dynamics, and Evolution of the Intrinsically Disordered p53 Transactivation Domain

Borcherds, Wade Michael

01 January 2013

in numerous disease states, including cancers and neurodegenerative diseases. All proteins are dynamic in nature, occupying a range of conformational flexibilities. This inherent flexibility is required for their function, with ordered proteins and IDPs representing the least flexible, and most flexible, respectively. As such IDPs possess little to no stable tertiary or secondary structure, they instead form broad ensembles of heterogeneous structures, which fluctuate over multiple time scales. Although IDPs often lack stable secondary structure they can assume a more stable structure in the presence of their binding partners in a coupled folding binding reaction. The phenomenon of the dynamic behavior of IDPs is believed to confer several functional advantages but remains poorly understood. To that end the dynamic and structural properties of a family of IDPs - p53 transactivation domains (TAD) was measured and compared with the sequence divergence. Interestingly we were able to find stronger correlations between the dynamic properties and the sequence divergence than between the structure and sequence, suggesting that the dynamic properties are the primary trait being xiii conserved by evolution. These correlations were strongest within clusters of the IDPs that correlated with known protein binding sites. Additionally, we show strong correlations between the several available disorder predictors and the backbone dynamics of this family of IDPs. This indicates the potential of predicting the dynamic behavior of proteins, which may be beneficial in future drug design. The limited number of atomic models currently determined for IDPs hampers understanding of how their amino acid sequences dictate the structural ensembles they adopt. The current dearth of atomic models for IDPs makes it difficult to test the following hypotheses: 1. The structural ensembles of IDPs are dictated by local interactions. 2. The structural ensembles of IDPs will be similar above a certain sequence identity threshold. Based on the premise that sequence determines structure, structural ensembles were determined and compared for a set of homologous IDPs. Utilizing orthologues allows for the identification of important structural features and behaviors by virtue of their conservation. A new methodology of creating ensembles was implemented that broadly samples conformational space. This allowed us to find recurring local structural features within the structural ensembles even between the more distantly related homologues that were processed. This method of ensemble creation is also the first method to show convergence of secondary structural characteristics between discrete ensembles.

Dynamics

Evolution

Intrinsically Disordered Proteins

NMR

Structural biology

Structure

Biology

Biophysics

Investigations of Myelin Basic Protein, SH3 Proteins and the Oligodendrocyte Cytoskeleton during Maturation and Development

Smith, Graham

29 August 2012

The myelin basic protein (MBP) family arises from different transcription start sites of the Golli (gene of oligodendrocyte lineage) gene, with further variety generated by differential splicing. The “classic” MBP isoforms are peripheral membrane proteins that facilitate compaction of the mature myelin sheath, but also have multiple protein interactions. As an intrinsically disordered protein, MBP has proven to have complex structural and functional relationships with proteins in vitro including actin, tubulin, Ca2+-calmodulin, and multiple protein kinases. The investigations reported in this thesis were to further examine the multifunctionality, and protein:protein interactions of MBP with cytoskeletal and SRC homology 3 domain (SH3) proteins in cells using an oligodendrocyte (OLG) model system to better understand MBP’s contributions to membrane structure, formation, and elaboration in the developing OLG. A new function of MBP has been described showing that classic MBPs can modulate voltage operated calcium channels (VOCCs) by direct or indirect protein-protein interactions at the OLG cytoplasmic leaflet. These interactions contribute to global calcium homeostasis, and may play a complex developmental and spatiotemporal role in the regulation of oligodendrocyte precursor cell (OPC) migration and OLG differentiation. The importance of MBPs SH3 ligand binding domain within its central amino acid region was investigated with the protein-tyrosine kinase Fyn. Co-expression of MBP with a constitutively-active form of Fyn in OLGs resulted in membrane process elaboration, a phenomenon that was abolished by amino acid substitutions within MBP’s SH3-ligand domain. These results suggest that MBP’s SH3-ligand domain plays a key role, and may be required for proper membrane elaboration of developing OLGs. Lastly, interactions of MBP with the OLG cytoskeleton were investigated in OLGs transfected with fluorescently-tagged MBP, actin, tubulin, and zonula occludens 1 (ZO-1). MBP redistributes to distinct ‘membrane-ruffled’ regions of the plasma membrane where it had increased co-localization with actin and tubulin, and with the SH3-domain-containing proteins cortactin and ZO-1, when stimulated with PMA, a potent activator of the protein kinase C pathway. The results presented here advance our understanding regarding protein:protein interactions of MBP, and its multifunctionality in OLGs with regards to membrane formation and elaboration. / This work was supported by the Canadian Institutes of Health Research (MOP #86483, J.M.B. and G.H.), and Discovery Grants from the Natural Sciences and Engineering Research Council of Canada (NSERC, G.H., RG121541). G.S.T.S. was a recipient of a Doctoral Studentship from the Multiple Sclerosis Society of Canada

Single molecule studies of synuclein family of proteins and peptides with nanopores

2014 September 1900

Alpha-synuclein (AS) is a natively unfolded protein whose structure is extremely sensitive to its environment. The hallmark of Parkinson’s disease (PD) is aggregation and deposition of AS in inclusion bodies. Formation of misfolded AS monomers which are partially folded is the first and critical stage in fibrillation of AS and is a good target for designing therapeutic strategies. Characterization the biochemical properties of partially folded intermediates induced by fibrillization and anti- fibrillization agents will help to design drugs as new inhibitors of AS misfolding and aggregation. Nanopore analysis is an emerging technique for studying the molecular mechanism of protein misfolding. This technique was used to characterize the conformational change of AS in the presence of two groups of chemicals; anti-parkinsonian small molecules (dopamine and nicotine) and Parkinson’s developing toxin (Cu(II) and methamphetamine). Other biophysical techniques such as NMR spectroscopy and isothermal titration calorimentry (ITC) were able to confirm the nanopore analysis results and also to study other biophysical properties of the partially folded intermediates such as the binding constant of the interaction and the secondary structure content. The results from nanopore analysis showed that both groups of ligands shifted the blockade current peak of AS (centered at -86 pA) to lower blockade currents but in a different manner. Anti-parkinsonian drugs shifted the blockade current of AS to intermediate peaks between -40 to -80 pA but Parkinson developing toxins shifted the peak to a lower blockade current centered at -25 pA which suggests a more compact conformation. Thus nanopore analysis distinguished the different conformation induced by different ligands. Furthermore nanopore analysis with AS fragments showed that these ligands bind to different regions of AS. NMR spectroscopy of AS in the presence of dopamine and nicotine isomers was in agreement with the nanopore analysis and showed conformational changes of AS in a concentration dependent manner. CD spectroscopy results showed that the secondary structure of AS alone and in the presence of ligands was mostly random coil and suggests a loop formation model for the interaction of ligands with AS. The results of this thesis showed the application of nanopore analysis as a real-time and label-free technique to screen a library of ligands for designing misfolding inhibitors for PD treatment. The result of a synergic experiment with nicotine and caffeine showed that combination of these anti-parkinsonian small molecules would be a promising new drug for treatment of PD.

Solution NMR-based characterization of the structure of the outer mitochondrial membrane protein Tom40 and a novel method for NMR resonance assignment of large intrinsically disordered proteins

Yao, Xuejun

23 October 2013

No description available.

571.4

NMR spectroscopy

Membrane protein

Intrinsically Disordered Proteins

hydrogen/deuterium exchange

Tom40

Biologie (PPN619462639)

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