Your search keyword '"protein folding"' showing total 5,963 results

1. Abietane-Type Diterpenoids Inhibit Protein Tyrosine Phosphatases by Stabilizing an Inactive Enzyme Conformation

Author

Hjortness, Michael K, Riccardi, Laura, Hongdusit, Akarawin, Ruppe, Sophia, Zhao, Mengxia, Kim, Edward Y, Zwart, Peter H, Sankaran, Banumathi, Arthanari, Haribabu, Sousa, Marcelo C, De Vivo, Marco, and Fox, Jerome M

Subjects

Biochemistry and Cell Biology, Medicinal and Biomolecular Chemistry, Chemical Sciences, Biological Sciences, 5.1 Pharmaceuticals, Development of treatments and therapeutic interventions, Generic health relevance, Abietanes, Humans, Models, Molecular, Molecular Dynamics Simulation, Nuclear Magnetic Resonance, Biomolecular, Protein Domains, Protein Folding, Protein Kinase Inhibitors, Protein Tyrosine Phosphatase, Non-Receptor Type 1, Medical Biochemistry and Metabolomics, Biochemistry & Molecular Biology, Biochemistry and cell biology, Medical biochemistry and metabolomics, Medicinal and biomolecular chemistry

Abstract

Protein tyrosine phosphatases (PTPs) contribute to a striking variety of human diseases, yet they remain vexingly difficult to inhibit with uncharged, cell-permeable molecules; no inhibitors of PTPs have been approved for clinical use. This study uses a broad set of biophysical analyses to evaluate the use of abietane-type diterpenoids, a biologically active class of phytometabolites with largely nonpolar structures, for the development of pharmaceutically relevant PTP inhibitors. Results of nuclear magnetic resonance analyses, mutational studies, and molecular dynamics simulations indicate that abietic acid can inhibit protein tyrosine phosphatase 1B, a negative regulator of insulin signaling and an elusive drug target, by binding to its active site in a non-substrate-like manner that stabilizes the catalytically essential WPD loop in an inactive conformation; detailed kinetic studies, in turn, show that minor changes in the structures of abietane-type diterpenoids (e.g., the addition of hydrogens) can improve potency (i.e., lower IC50) by 7-fold. These findings elucidate a previously uncharacterized mechanism of diterpenoid-mediated inhibition and suggest, more broadly, that abietane-type diterpenoids are a promising source of structurally diverse-and, intriguingly, microbially synthesizable-molecules on which to base the design of new PTP-inhibiting therapeutics.

Published

2018

2. A Critical Role of Ser26 Hydrogen Bonding in Aβ42 Assembly and Toxicity

Author

Roychaudhuri, Robin, Huynh, Tien-Phat V, Whitaker, Taylor R, Hodara, Elisabeth, Condron, Margaret M, and Teplow, David B

Subjects

Neurodegenerative, Aging, Alzheimer's Disease including Alzheimer's Disease Related Dementias (AD/ADRD), Acquired Cognitive Impairment, Brain Disorders, Alzheimer's Disease, Dementia, Generic health relevance, Amino Acid Sequence, Amyloid beta-Peptides, Hydrogen Bonding, Peptide Fragments, Protein Conformation, Protein Folding, Medicinal and Biomolecular Chemistry, Biochemistry and Cell Biology, Medical Biochemistry and Metabolomics, Biochemistry & Molecular Biology

Abstract

Amyloid β-protein (Aβ) assembly is a seminal process in Alzheimer's disease. Elucidating the mechanistic features of this process is thought to be vital for the design and targeting of therapeutic agents. Computational studies of the most pathologic form of Aβ, the 42-residue Aβ42 peptide, have suggested that hydrogen bonding involving Ser26 may be particularly important in organizing a monomer folding nucleus and in subsequent peptide assembly. To study this question, we experimentally determined structure-activity relationships among Aβ42 peptides in which Ser26 was replaced with Gly, Ala, α-aminobutryic acid (Abu), or Cys. We observed that aliphatic substitutions (Ala and Abu) produced substantially increased rates of formation of β-sheet, hydrophobic surface, and fibrils, and higher levels of cellular toxicity. Replacement of the Ser hydroxyl group with a sulfhydryl moiety (Cys) did not have these effects. Instead, this peptide behaved like native Aβ42, even though the hydropathy of Cys was similar to that of Abu and very different from that of Ser. We conclude that H bonding of Ser26 is the factor most important in its contribution to Aβ42 conformation, assembly, and subsequent toxicity.

Published

2017

3. Slow Conformational Exchange between Partially Folded and Near-Native States of Ubiquitin: Evidence for a Multistate Folding Model.

Author

Adhada ST and Sarma SP

Subjects

Kinetics, Thermodynamics, Models, Molecular, Hydrogen-Ion Concentration, Urea chemistry, Humans, Ubiquitin chemistry, Protein Folding, Nuclear Magnetic Resonance, Biomolecular, Protein Conformation

Abstract

The mechanism by which small proteins fold, i.e., via intermediates or via a two-state mechanism, is a subject of intense investigation. Intermediate states in the folding pathways of these proteins are sparsely populated due to transient lifetimes under normal conditions rendering them transparent to a majority of the biophysical methods employed for structural, thermodynamic, and kinetic characterization, which attributes are essential for understanding the cooperative folding/unfolding of such proteins. Dynamic NMR spectroscopy has enabled the characterization of folding intermediates of ubiquitin that exist in equilibrium under conditions of low pH and denaturants. At low pH, an unlocked state defined as N' is in fast exchange with an invisible state, U″, as observed by CEST NMR. Addition of urea to ubiquitin at pH 2 creates two new states F ' and U ' , which are in slow exchange ( k F'→U' = 0.14 and k U'→F' = 0.28 s -1 ) as indicated by longitudinal ZZ-magnetization exchange spectroscopy. High-resolution solution NMR structures of F ' show it to be in an "unlocked" conformation with measurable changes in rotational diffusion, translational diffusion, and rotational correlational times. U ' is characterized by the presence of just the highly conserved N-terminal β1-β2 hairpin. The folding of ubiquitin is cooperative and is nucleated by the formation of an N-terminal β-hairpin followed by significant hydrophobic collapse of the protein core resulting in the formation of bulk of the secondary structural elements stabilized by extensive tertiary contacts. U ' and F ' may thus be described as early and late folding intermediates in the ubiquitin folding pathway.

Published

2024

4. Conformational and Structural Characterization of Knotted Proteins.

Author

Jeanne Dit Fouque K, Molano-Arevalo JC, Leng F, and Fernandez-Lima F

Subjects

Protein Folding, Protein Unfolding, Models, Molecular, Humans, Ion Mobility Spectrometry methods, Ubiquitin Thiolesterase chemistry, Ubiquitin Thiolesterase metabolism, Protein Conformation

Abstract

Knotted proteins are fascinating natural biomolecules whose backbones entangle themselves in a knot. Their particular knotted configurations provide them with a wide range of topological features. However, their folding/unfolding mechanisms, stability, and function are poorly understood. In the present work, native trapped ion mobility spectrometry-mass spectrometry (TIMS-MS) was used for characterizing structural features of two model knotted proteins: a Gordian 5 2 knot ubiquitin C-terminal hydrolase (UCH) and a Stevedore 6 1 knot (α-haloacid dehalogenase, DehI). Experimental results showed structural transitions of UCH and DehI as a function of solution composition (0-50% MeOH) and temperature ( T ∼20-95 °C). An increase in the protein charge states and collision cross sections (∼2750-8750 Å 2 and ∼3250-15,385 Å 2 for UCH and DehI, respectively) with the solution organic content (OC) and temperature suggested a three-step unfolding pathway with at least four structural transitions. Results also showed that the integrity of the UCH knot core was more resistant to thermal unfolding when compared to DehI; however, both knot cores can be disrupted with the increase in the solution OC. Additional enzymatic digestion experiments using carboxypeptidase Y combined with molecular dynamics simulations showed that the knot core was preserved between Glu20 and Glu188 and Arg89 and His304 residues for UCH and DehI, respectively, where disruption of the knot core led to structural collapse followed by unfolding events. This work highlights the potential of solution OC and temperature studies combined with native TIMS-MS for the comprehensive characterization of knotted proteins to gain a better understanding of their structural transitions.

Published

2024

5. Positioning the Intracellular Salt Potassium Glutamate in the Hofmeister Series by Chemical Unfolding Studies of NTL9

Author

Sengupta, Rituparna, Pantel, Adrian, Cheng, Xian, Shkel, Irina, Peran, Ivan, Stenzoski, Natalie, Raleigh, Daniel P, and Record, M Thomas

Subjects

Escherichia coli, Glutamic Acid, Kinetics, Protein Folding, Protein Interaction Domains and Motifs, Protein Unfolding, Ribosomal Proteins, Salts, Sodium Chloride, Thermodynamics, Medicinal and Biomolecular Chemistry, Biochemistry and Cell Biology, Medical Biochemistry and Metabolomics, Biochemistry & Molecular Biology

Abstract

In vitro, replacing KCl with potassium glutamate (KGlu), the Escherichia coli cytoplasmic salt and osmolyte, stabilizes folded proteins and protein-nucleic acid complexes. To understand the chemical basis for these effects and rank Glu- in the Hofmeister anion series for protein unfolding, we quantify and interpret the strong stabilizing effect of KGlu on the ribosomal protein domain NTL9, relative to the effects of other stabilizers (KCl, KF, and K2SO4) and destabilizers (GuHCl and GuHSCN). GuHSCN titrations at 20 ° C, performed as a function of the concentration of KGlu or another salt and monitored by NTL9 fluorescence, are analyzed to obtain R-values quantifying the Hofmeister salt concentration (m3) dependence of the unfolding equilibrium constant K(obs) [r-value = −d ln K(obs)/dm3 = (1/RT) dΔG(obs) ° /dm3 = m-value/RT]. r-Values for both stabilizing K+ salts and destabilizing GuH+ salts are compared with predictions from model compound data. For two-salt mixtures, we find that contributions of stabilizing and destabilizing salts to observed r-values are additive and independent. At 20 ° C, we determine a KGlu r-value of 3.22 m(−1) and K2SO4, KF, KCl, GuHCl, and GuHSCN r-values of 5.38, 1.05, 0.64, −1.38, and −3.00 m(−1), respectively. The KGlu r-value represents a 25-fold (1.9 kcal) stabilization per molal KGlu added. KGlu is much more stabilizing than KF, and the stabilizing effect of KGlu is larger in magnitude than the destabilizing effect of GuHSCN. Interpretation of the data reveals good agreement between predicted and observed relative r-values and indicates the presence of significant residual structure in GuHSCN-unfolded NTL9 at 20 ° C.

Published

2016

6. Examination of Glycosaminoglycan Binding Sites on the XCL1 Dimer

Author

Fox, Jamie C, Tyler, Robert C, Peterson, Francis C, Dyer, Douglas P, Zhang, Fuming, Linhardt, Robert J, Handel, Tracy M, and Volkman, Brian F

Subjects

Medical Microbiology, Biomedical and Clinical Sciences, HIV/AIDS, Infectious Diseases, Binding Sites, Chemokines, C, Glycosaminoglycans, HIV Infections, HIV-1, Heparin, Heparitin Sulfate, Humans, Models, Molecular, Point Mutation, Protein Binding, Protein Folding, Protein Multimerization, Medicinal and Biomolecular Chemistry, Biochemistry and Cell Biology, Medical Biochemistry and Metabolomics, Biochemistry & Molecular Biology, Biochemistry and cell biology, Medical biochemistry and metabolomics, Medicinal and biomolecular chemistry

Abstract

Known for its distinct metamorphic behavior, XCL1 interconverts between a canonical chemokine folded monomer (XCL1mon) that interacts with the receptor, XCR1, and a unique dimer (XCL1dim) that interacts with glycosaminoglycans and inhibits HIV-1 activity. This study presents the first detailed analysis of the GAG binding properties of XCL1dim. Basic residues within a conformationally selective dimeric variant of XCL1 (W55D) were mutated and analyzed for their effects on heparin binding. Mutation of Arg23 and Arg43 greatly diminished the level of heparin binding in both heparin Sepharose chromatography and surface plasmon resonance assays. To assess the contributions of different GAG structures to XCL1 binding, we developed a solution fluorescence polarization assay and correlated affinity with the length and level of sulfation of heparan sulfate oligosaccharides. It was recently demonstrated that the XCL1 GAG binding form, XCL1dim, is responsible for preventing HIV-1 infection through interactions with gp120. This study defines a GAG binding surface on XCL1dim that includes residues that are important for HIV-1 inhibition.

Published

2016

7. A Transient, Excited Species of the Autoinhibited α-State of the Bacterial Transcription Factor RfaH May Represent an Early Intermediate on the Fold-Switching Pathway.

Author

Cai M, Agarwal N, Garrett DS, Baber J, and Clore GM

Subjects

Nuclear Magnetic Resonance, Biomolecular, Peptide Elongation Factors metabolism, Peptide Elongation Factors chemistry, Peptide Elongation Factors genetics, Trans-Activators metabolism, Trans-Activators chemistry, Trans-Activators genetics, Models, Molecular, Escherichia coli genetics, Escherichia coli metabolism, DNA-Directed RNA Polymerases metabolism, DNA-Directed RNA Polymerases chemistry, DNA-Directed RNA Polymerases genetics, Protein Conformation, Escherichia coli Proteins chemistry, Escherichia coli Proteins metabolism, Escherichia coli Proteins genetics, Protein Folding

Abstract

RfaH is a two-domain transcription factor in which the C-terminal domain switches fold from an α-helical hairpin to a β-roll upon binding the ops -paused RNA polymerase. To ascertain the presence of a sparsely populated excited state that may prime the autoinhibited resting state of RfaH for binding ops -paused RNA polymerase, we carried out a series of NMR-based exchange experiments to probe for conformational exchange on the millisecond time scale. Quantitative analysis of these data reveals exchange between major ground (∼95%) and sparsely populated excited (∼5%) states with an exchange lifetime of ∼3 ms involving residues at the interface between the N-terminal and C-terminal domains formed by the β3/β4 hairpin and helix α3 of the N-terminal domain and helices α4 and α5 of the C-terminal domain. The largest 15 N backbone chemical shift differences are associated with the β3/β4 hairpin, leading us to suggest that the excited state may involve a rigid body lateral displacement/rotation away from the C-terminal domain to adopt a position similar to that seen in the active RNA polymerase-bound state. Such a rigid body reorientation would result in a reduction in the interface between the N- and C-terminal domains with the possible introduction of a cavity or cavities. This hypothesis is supported by the observation that the population of the excited species and the exchange rate of interconversion between ground and excited states are reduced at a high (2.5 kbar) pressure. Mechanistic implications for fold switching of the C-terminal domain in the context of RNA polymerase binding are discussed.

Published

2024

8. Phosphorylation by Protein Kinase C Weakens DNA-Binding Affinity and Folding Stability of the HMGB1 Protein.

Author

Wang X, Holthauzen LMF, Paz-Villatoro JM, Bien KG, Yu B, and Iwahara J

Subjects

Phosphorylation, Protein Stability, Humans, Protein Binding, Animals, Nuclear Magnetic Resonance, Biomolecular, Models, Molecular, Protein Domains, HMGB1 Protein metabolism, HMGB1 Protein chemistry, DNA metabolism, DNA chemistry, Protein Folding, Protein Kinase C metabolism, Protein Kinase C chemistry

Abstract

The HMGB1 protein typically serves as a DNA chaperone that assists DNA-repair enzymes and transcription factors but can translocate from the nucleus to the cytoplasm or even to extracellular space upon some cellular stimuli. One of the factors that triggers the translocation of HMGB1 is its phosphorylation near a nuclear localization sequence by protein kinase C (PKC), although the exact modification sites on HMGB1 remain ambiguous. In this study, using spectroscopic methods, we investigated the HMGB1 phosphorylation and its impact on the molecular properties of the HMGB1 protein. Our nuclear magnetic resonance (NMR) data on the full-length HMGB1 protein showed that PKC specifically phosphorylates the A-box domain, one of the DNA binding domains of HMGB1. Phosphorylation of S46 and S53 was particularly efficient. Over a longer reaction time, PKC phosphorylated some additional residues within the HMGB1 A-box domain. Our fluorescence-based binding assays showed that the phosphorylation significantly reduces the binding affinity of HMGB1 for DNA. Based on the crystal structures of HMGB1-DNA complexes, this effect can be ascribed to electrostatic repulsion between the negatively charged phosphate groups at the S46 side chain and DNA backbone. Our data also showed that the phosphorylation destabilizes the folding of the A-box domain. Thus, phosphorylation by PKC weakens the DNA-binding affinity and folding stability of HMGB1.

Published

2024

9. Increasing the Soluble Expression and Whole-Cell Activity of the Plastic-Degrading Enzyme MHETase through Consensus Design.

Author

Saunders JW, Damry AM, Vongsouthi V, Spence MA, Frkic RL, Gomez C, Yates PA, Matthews DS, Tokuriki N, McLeod MD, and Jackson CJ

Subjects

Phthalic Acids metabolism, Phthalic Acids chemistry, Hydrolases metabolism, Hydrolases genetics, Hydrolases chemistry, Solubility, Polyethylene Terephthalates metabolism, Polyethylene Terephthalates chemistry, Recombinant Proteins metabolism, Recombinant Proteins genetics, Recombinant Proteins chemistry, Protein Engineering methods, Protein Folding, Escherichia coli genetics, Escherichia coli metabolism, Bacterial Proteins metabolism, Bacterial Proteins genetics, Bacterial Proteins chemistry, Models, Molecular, Burkholderiales enzymology, Burkholderiales genetics, Burkholderiales metabolism

Abstract

The mono(2-hydroxyethyl) terephthalate hydrolase (MHETase) from Ideonella sakaiensis carries out the second step in the enzymatic depolymerization of poly(ethylene terephthalate) (PET) plastic into the monomers terephthalic acid (TPA) and ethylene glycol (EG). Despite its potential industrial and environmental applications, poor recombinant expression of MHETase has been an obstacle to its industrial application. To overcome this barrier, we developed an assay allowing for the medium-throughput quantification of MHETase activity in cell lysates and whole-cell suspensions, which allowed us to screen a library of engineered variants. Using consensus design, we generated several improved variants that exhibit over 10-fold greater whole-cell activity than wild-type (WT) MHETase. This is revealed to be largely due to increased soluble expression, which biochemical and structural analysis indicates is due to improved protein folding.

Published

2024

10. Multiple Structural States Exist Throughout the Helical Nucleation Sequence of the Intrinsically Disordered Protein Stathmin, As Reported by Electron Paramagnetic Resonance Spectroscopy

Author

Chui, Ashley J, López, Carlos J, Brooks, Evan K, Chua, Katherina C, Doupey, Tonia G, Foltz, Gretchen N, Kamel, Joseph G, Larrosa, Estefania, Sadiki, Amissi, and Bridges, Michael D

Subjects

Biochemistry and Cell Biology, Chemical Sciences, Biological Sciences, Amino Acid Sequence, Circular Dichroism, Electron Spin Resonance Spectroscopy, Humans, Intrinsically Disordered Proteins, Protein Folding, Protein Multimerization, Protein Stability, Protein Structure, Secondary, Protein Structure, Tertiary, Stathmin, Thermodynamics, Medicinal and Biomolecular Chemistry, Medical Biochemistry and Metabolomics, Biochemistry & Molecular Biology, Biochemistry and cell biology, Medical biochemistry and metabolomics, Medicinal and biomolecular chemistry

Abstract

The intrinsically disordered protein (IDP) stathmin plays an important regulatory role in cytoskeletal maintenance through its helical binding to tubulin and microtubules. However, it lacks a stable fold in the absence of its binding partner. Although stathmin has been a focus of research over the past two decades, the solution-phase conformational dynamics of this IDP are poorly understood. It has been reported that stathmin is purely monomeric in solution and that it bears a short helical region of persistent foldedness, which may act to nucleate helical folding in the C-terminal direction. Here we report a comprehensive study of the structural equilibria local to this region in stathmin that contradicts these two claims. Using the technique of electron paramagnetic resonance (EPR) spectroscopy on spin-labeled stathmin mutants in the solution-phase and when immobilized on Sepharose solid support, we show that all sites in the helical nucleation region of stathmin exhibit multiple spectral components that correspond to dynamic states of differing mobilities and stabilities. Importantly, a state with relatively low mobility dominates each spectrum with an average population greater than 50%, which we suggest corresponds to an oligomerized state of the protein. This is in contrast to a less populated, more mobile state, which likely represents a helically folded monomeric state of stathmin, and a highly mobile state, which we propose is the random coil conformer of the protein. Our interpretation of the EPR data is confirmed by further characterization of the protein using the techniques of native and SDS PAGE, gel filtration chromatography, and multiangle and dynamic light scattering, all of which show the presence of oligomeric stathmin in solution. Collectively, these data suggest that stathmin exists in a diverse equilibrium of states throughout the purported helical nucleation region and that this IDP exhibits a propensity toward oligomerization.

Published

2015

11. Differential Dynamics of Extracellular and Cytoplasmic Domains in Denatured States of Rhodopsin

Author

Dutta, Arpana, Altenbach, Christian, Mangahas, Sheryll, Yanamala, Naveena, Gardner, Eric, Hubbell, Wayne L, and Klein-Seetharaman, Judith

Subjects

Neurosciences, Amino Acid Sequence, Animals, COS Cells, Cell Membrane, Chlorocebus aethiops, Electron Spin Resonance Spectroscopy, HEK293 Cells, Humans, Models, Molecular, Molecular Sequence Data, Nuclear Magnetic Resonance, Biomolecular, Protein Denaturation, Protein Folding, Protein Structure, Secondary, Protein Structure, Tertiary, Rhodopsin, Medicinal and Biomolecular Chemistry, Biochemistry and Cell Biology, Medical Biochemistry and Metabolomics, Biochemistry & Molecular Biology

Abstract

Rhodopsin is a model system for understanding membrane protein folding. Recently, conditions that allow maximally denaturing rhodopsin without causing aggregation have been determined, opening the door to the first structural characterization of denatured states of rhodopsin by nuclear magnetic resonance (NMR) and electron paramagnetic resonance (EPR) spectroscopy. One-dimensional 1H NMR spectra confirm a progressive increase in flexibility of resonances in rhodopsin with increasing denaturant concentrations. Two-dimensional 1H-15N HSQC spectra of [15N]-α-lysine-labeled rhodopsin in which signals arise primarily from residues in the cytoplasmic (CP) domain and of [15N]-α,ε-tryptophan-labeled rhodopsin in which signals arise only from transmembrane (TM) and extracellular (EC) residues indicate qualitatively that EC and CP domains may be differentially affected by denaturation. To obtain residue-specific information, particular residues in EC and CP domains were investigated by site-directed spin labeling. EPR spectra of the spin-labeled samples indicate that the EC residues retain more rigidity in the denatured states than the CP residues. These results support the notion of residual structure in denatured states of rhodopsin.

Published

2014

12. Toxic Misfolded Transthyretin Oligomers with Different Molecular Conformations Formed through Distinct Oligomerization Pathways

Author

Anvesh K. R. Dasari, Sujung Yi, Matthew F. Coats, Sungsool Wi, and Kwang Hun Lim

Subjects

Protein Folding, Amyloid, Protein Conformation, Humans, Prealbumin, Amyloidogenic Proteins, Amyloidosis, Biochemistry

Abstract

Protein aggregation is initiated by structural changes from native polypeptides to cytotoxic oligomers, which form cross-β structured amyloid. Identification and characterization of oligomeric intermediates are critically important for understanding not only the molecular mechanism of aggregation but also the cytotoxic nature of amyloid oligomers. Preparation of misfolded oligomers for structural characterization is, however, challenging because of their transient, heterogeneous nature. Here, we report two distinct misfolded transthyretin (TTR) oligomers formed through different oligomerization pathways. A pathogenic TTR variant with a strong aggregation propensity (L55P) was used to prepare misfolded oligomers at physiological pH. Our mechanistic studies showed that the full-length TTR initially forms small oligomers, which self-assemble into short protofibrils at later stages. Enzymatic cleavage of the CD loop was also used to induce the formation of N-terminally truncated oligomers, which was detected in ex vivo cardiac TTR aggregates extracted from the tissues of patients. Structural characterization of the oligomers using solid-state nuclear magnetic resonance and circular dichroism revealed that the two TTR misfolded oligomers have distinct molecular conformations. In addition, the proteolytically cleaved TTR oligomers exhibit a higher surface hydrophobicity, suggesting the presence of distinct oligomerization pathways for TTR oligomer formation. Cytotoxicity assays also revealed that the cytotoxicity of cleaved oligomers is stronger than that of the full-length TTR oligomers, indicating that hydrophobicity might be an important property of toxic oligomers. These comparative biophysical analyses suggest that the toxic cleaved TTR oligomers formed through a different misfoling pathway may adopt distinct structural features that produce higher surface hydrophobicity, leading to the stronger cytotoxic activities.

Published

2023

13. Structural Dynamics of the Amyloid β-Protein Monomer Folding Nucleus

Author

Roychaudhuri, Robin, Yang, Mingfeng, Condron, Margaret M, and Teplow, David B

Subjects

Alzheimer's Disease including Alzheimer's Disease Related Dementias (AD/ADRD), Aging, Acquired Cognitive Impairment, Brain Disorders, Neurosciences, Alzheimer's Disease, Dementia, Neurodegenerative, Aetiology, 2.1 Biological and endogenous factors, Alzheimer Disease, Amino Acid Substitution, Amyloid beta-Peptides, Humans, Molecular Dynamics Simulation, Peptide Fragments, Protein Conformation, Protein Denaturation, Protein Folding, Protein Stability, Proteolysis, Medicinal and Biomolecular Chemistry, Biochemistry and Cell Biology, Medical Biochemistry and Metabolomics, Biochemistry & Molecular Biology

Abstract

Alzheimer's disease (AD) is linked to the aberrant assembly of the amyloid β-protein (Aβ). The (21)AEDVGSNKGA(30) segment, Aβ(21-30), forms a turn that acts as a monomer folding nucleus. Amino acid substitutions within this nucleus cause familial forms of AD. To determine the biophysical characteristics of the folding nucleus, we studied the biologically relevant acetyl-Aβ(21-30)-amide peptide using experimental techniques (limited proteolysis, thermal denaturation, urea denaturation followed by pulse proteolysis, and electron microscopy) and computational methods (molecular dynamics). Our results reveal a highly stable foldon and suggest new strategies for therapeutic drug development.

Published

2012

14. Functional Dynamics of the Folded Ankyrin Repeats of IκBα Revealed by Nuclear Magnetic Resonance

Author

Cervantes, Carla F, Markwick, Phineus RL, Sue, Shih-Che, McCammon, J Andrew, Dyson, H Jane, and Komives, Elizabeth A

Subjects

Biochemistry and Cell Biology, Biological Sciences, Amino Acid Sequence, Animals, Ankyrin Repeat, Deuterium Exchange Measurement, Humans, I-kappa B Kinase, Mice, Molecular Sequence Data, Nuclear Magnetic Resonance, Biomolecular, Peptide Fragments, Protein Binding, Protein Folding, Protein Structure, Secondary, Protein Structure, Tertiary, Sequence Alignment, Thermodynamics, Medicinal and Biomolecular Chemistry, Medical Biochemistry and Metabolomics, Biochemistry & Molecular Biology, Biochemistry and cell biology, Medical biochemistry and metabolomics, Medicinal and biomolecular chemistry

Abstract

Inhibition of nuclear factor kappaB (NF-kappaB) is mainly accomplished by IkappaB alpha, which consists of a signal response sequence at the N-terminus, a six-ankyrin repeat domain (ARD) that binds NF-kappaB, and a C-terminal PEST sequence. Previous studies with the ARD revealed that the fifth and sixth repeats are only partially folded in the absence of NF-kappaB. Here we report NMR studies of a truncated version of IkappaB alpha, containing only the first four ankyrin repeats, IkappaB alpha(67-206). This four-repeat segment is well-structured in the free state, enabling full resonance assignments to be made. H-D exchange, backbone dynamics, and residual dipolar coupling (RDC) experiments reveal regions of flexibility. In addition, regions consistent with the presence of micro- to millisecond motions occur periodically throughout the repeat structure. Comparison of the RDCs with the crystal structure gave only moderate agreement, but an ensemble of structures generated by accelerated molecular dynamics gave much better agreement with the measured RDCs. The regions showing flexibility correspond to those implicated in entropic compensation for the loss of flexibility in ankyrin repeats 5 and 6 upon binding to NF-kappaB. The regions showing micro- to millisecond motions in the free protein are the ends of the beta-hairpins that directly interact with NF-kappaB in the complex.

Published

2009

15. Functional dynamics of the folded ankyrin repeats of I kappa B alpha revealed by nuclear magnetic resonance.

Author

Cervantes, Carla F, Markwick, Phineus RL, Sue, Shih-Che, McCammon, J Andrew, Dyson, H Jane, and Komives, Elizabeth A

Subjects

Animals, Humans, Mice, Peptide Fragments, Deuterium Exchange Measurement, Nuclear Magnetic Resonance, Biomolecular, Sequence Alignment, Amino Acid Sequence, Ankyrin Repeat, Protein Structure, Secondary, Protein Structure, Tertiary, Protein Binding, Protein Folding, Thermodynamics, Molecular Sequence Data, I-kappa B Kinase, Nuclear Magnetic Resonance, Biomolecular, Protein Structure, Secondary, Tertiary, Medicinal and Biomolecular Chemistry, Biochemistry and Cell Biology, Medical Biochemistry and Metabolomics, Biochemistry & Molecular Biology

Abstract

Inhibition of nuclear factor kappaB (NF-kappaB) is mainly accomplished by IkappaB alpha, which consists of a signal response sequence at the N-terminus, a six-ankyrin repeat domain (ARD) that binds NF-kappaB, and a C-terminal PEST sequence. Previous studies with the ARD revealed that the fifth and sixth repeats are only partially folded in the absence of NF-kappaB. Here we report NMR studies of a truncated version of IkappaB alpha, containing only the first four ankyrin repeats, IkappaB alpha(67-206). This four-repeat segment is well-structured in the free state, enabling full resonance assignments to be made. H-D exchange, backbone dynamics, and residual dipolar coupling (RDC) experiments reveal regions of flexibility. In addition, regions consistent with the presence of micro- to millisecond motions occur periodically throughout the repeat structure. Comparison of the RDCs with the crystal structure gave only moderate agreement, but an ensemble of structures generated by accelerated molecular dynamics gave much better agreement with the measured RDCs. The regions showing flexibility correspond to those implicated in entropic compensation for the loss of flexibility in ankyrin repeats 5 and 6 upon binding to NF-kappaB. The regions showing micro- to millisecond motions in the free protein are the ends of the beta-hairpins that directly interact with NF-kappaB in the complex.

Published

2009

16. Crystal Structure of Escherichia coli Cytidine Triphosphate Synthetase, a Nucleotide-Regulated Glutamine Amidotransferase/ATP-Dependent Amidoligase Fusion Protein and Homologue of Anticancer and Antiparasitic Drug Targets † , ‡

Author

Endrizzi, James A, Kim, Hanseong, Anderson, Paul M, and Baldwin, Enoch P

Subjects

Biochemistry and Cell Biology, Biological Sciences, Amino Acid Sequence, Antineoplastic Agents, Antiparasitic Agents, Binding Sites, Carbon-Nitrogen Ligases, Crystallography, X-Ray, Cytidine Triphosphate, Escherichia coli Proteins, Glutamate Synthase, Guanosine Triphosphate, Models, Molecular, Molecular Sequence Data, Nucleotides, Protein Conformation, Protein Folding, Recombinant Fusion Proteins, Sequence Homology, Amino Acid, Structural Homology, Protein, Medicinal and Biomolecular Chemistry, Medical Biochemistry and Metabolomics, Biochemistry & Molecular Biology, Biochemistry and cell biology, Medical biochemistry and metabolomics, Medicinal and biomolecular chemistry

Abstract

Cytidine triphosphate synthetases (CTPSs) produce CTP from UTP and glutamine, and regulate intracellular CTP levels through interactions with the four ribonucleotide triphosphates. We solved the 2.3-A resolution crystal structure of Escherichia coli CTPS using Hg-MAD phasing. The structure reveals a nearly symmetric 222 tetramer, in which each bifunctional monomer contains a dethiobiotin synthetase-like amidoligase N-terminal domain and a Type 1 glutamine amidotransferase C-terminal domain. For each amidoligase active site, essential ATP- and UTP-binding surfaces are contributed by three monomers, suggesting that activity requires tetramer formation, and that a nucleotide-dependent dimer-tetramer equilibrium contributes to the observed positive cooperativity. A gated channel that spans 25 A between the glutamine hydrolysis and amidoligase active sites provides a path for ammonia diffusion. The channel is accessible to solvent at the base of a cleft adjoining the glutamine hydrolysis active site, providing an entry point for exogenous ammonia. Guanine nucleotide binding sites of structurally related GTPases superimpose on this cleft, providing insights into allosteric regulation by GTP. Mutations that confer nucleoside drug resistance and release CTP inhibition map to a pocket that neighbors the UTP-binding site and can accommodate a pyrimidine ring. Its location suggests that competitive feedback inhibition is affected via a distinct product/drug binding site that overlaps the substrate triphosphate binding site. Overall, the E. coli structure provides a framework for homology modeling of other CTPSs and structure-based design of anti-CTPS therapeutics.

Published

2004

17. Structural Plasticity Allows Calumenin-1 to Moonlight as a Ca 2+ -Independent Chaperone: Pb 2+ Enables Probing Alternate Inhibitory Conformation.

Author

Yadav MP, Narayanasamy S, and Aradhyam GK

Subjects

Humans, Endoplasmic Reticulum metabolism, Protein Folding, Binding Sites, Calcium metabolism, Lead, Molecular Chaperones metabolism

Abstract

Human calumenin-1 (HsCalu-1) is an endoplasmic reticulum (ER) and Golgi-resident Ca 2+ -binding protein of the hepta-EF-hand superfamily that plays a vital role in maintaining the cytoplasmic Ca 2+ concentration below toxic levels by interacting with Sarco/endoplasmic reticulum Ca 2+ -ATPase (SERCA) and ryanodine receptors (RyR), indicating its role in Ca 2+ homeostasis in the ER. HsCalu-1 seems to be able to exhibit structural plasticity to achieve its plethora of functions. In this study, we demonstrate that HsCalu-1 acts as a chaperone in both its intrinsically disordered state (apo form) and the structured state (Ca 2+ -bound form). HsCalu-1 chaperone activity is independent of Ca 2+ and Pb 2+ binding attenuating its chaperone-like activity. Incidentally, Pb 2+ binds to HsCalu-1 with lower affinity ( K D = 38.46 μM) (compared to Ca 2+ -binding), leading to the formation of a less-stable conformation as observed by a sharp drop in its melting temperature T m from 67 °C in the Ca 2+ -bound form to 43 °C in the presence of Pb 2+ . The binding site for Pb 2+ was mapped as being in the EF-Hand-234 domain of HsCalu-1, a region that overlaps with the Ca 2+ -dependent initiator of its functional fold. A change in the secondary and tertiary structure, leading to a less-stable but compact conformation upon Pb 2+ binding, is the mechanism by which the chaperone-like activity of HsCalu-1 is diminished. Our results not only demonstrate the chaperone activity by a protein in its disordered state but also explain, using Pb 2+ as a probe, that the multiple functions of calumenin are due to its ability to adopt a quasi-stable conformation.

Published

2024

18. Mapping Protein Structural Evolution upon Unfolding

Author

Veena Shankar Avadhani, Supratim Mondal, and Shibdas Banerjee

Subjects

Kinetics, Protein Denaturation, Protein Folding, Myoglobin, Protein Conformation, Ion Mobility Spectrometry, Cytochromes c, Thermodynamics, Muramidase, Hydrogen-Ion Concentration, Biochemistry

Abstract

In the past, many intensive attempts failed to capture or underestimated the copopulated intermediate conformers from the protein folding/unfolding reaction. We report a promising approach to kinetically trap, resolve, and quantify protein conformers that evolve during unfolding in solution. We conducted acid-induced unfolding of three model proteins (cytochrome

Published

2022

19. Reframing the Protein Folding Problem: Entropy as Organizer

Author

George D. Rose

Subjects

Protein Conformation, alpha-Helical, Protein Folding, education.field_of_study, Chemistry, Hydrogen bond, Population, Proteins, Hydrogen Bonding, Conformational entropy, Biochemistry, Folding (chemistry), Crystallography, Native state, Thermodynamics, Protein Conformation, beta-Strand, Protein Interaction Domains and Motifs, Protein folding, Protein stabilization, education, Conformational isomerism

Abstract

It has been a long-standing conviction that a protein's native fold is selected from a vast number of conformers by the optimal constellation of enthalpically favorable interactions. In marked contrast, this Perspective introduces a different mechanism, one that emphasizes conformational entropy as the principal organizer in protein folding while proposing that the conventional view is incomplete. This mechanism stems from the realization that hydrogen bond satisfaction is a thermodynamic necessity. In particular, a backbone hydrogen bond may add little to the stability of the native state, but a completely unsatisfied backbone hydrogen bond would be dramatically destabilizing, shifting the U(nfolded) ⇌ N(ative) equilibrium far to the left. If even a single backbone polar group is satisfied by solvent when unfolded but buried and unsatisfied when folded, that energy penalty alone, approximately +5 kcal/mol, would rival almost the entire free energy of protein stabilization, typically between -5 and -15 kcal/mol under physiological conditions. Consequently, upon folding, buried backbone polar groups must form hydrogen bonds, and they do so by assembling scaffolds of α-helices and/or strands of β-sheet, the only conformers in which, with rare exception, hydrogen bond donors and acceptors are exactly balanced. In addition, only a few thousand viable scaffold topologies are possible for a typical protein domain. This thermodynamic imperative winnows the folding population by culling conformers with unsatisfied hydrogen bonds, thereby reducing the entropy cost of folding. Importantly, conformational restrictions imposed by backbone···backbone hydrogen bonding in the scaffold are sequence-independent, enabling mutation─and thus evolution─without sacrificing the structure.

Published

2021

20. Quantitative NMR Study of Insulin-Degrading Enzyme Using Amyloid-β and HIV-1 p6 Elucidates Its Chaperone Activity

Author

Wenwei Zheng, Lalit Deshmukh, Spencer L Nelson, Bhargavi Ramaraju, and Rodolfo Ghirlando

Subjects

Protein Folding, Magnetic Resonance Spectroscopy, Proteolysis, Cleavage (embryo), Insulysin, gag Gene Products, Human Immunodeficiency Virus, Biochemistry, Article, Protein Aggregates, chemistry.chemical_compound, medicine, Insulin-degrading enzyme, chemistry.chemical_classification, Amyloid beta-Peptides, biology, medicine.diagnostic_test, Receptor–ligand kinetics, Kinetics, Enzyme, Monomer, Models, Chemical, chemistry, Polymerization, Chaperone (protein), biology.protein, Biophysics, Molecular Chaperones

Abstract

Insulin-degrading enzyme (IDE) hydrolyzes monomeric polypeptides, including amyloid-β (Aβ) and HIV-1 p6. It also acts as a nonproteolytic chaperone to prevent Aβ polymerization. Here we compare interactions of Aβ and non-amyloidogenic p6 with IDE. Although both exhibited similar proteolysis rates, the binding kinetics to an inactive IDE characterized using relaxation-based NMR were remarkably different. IDE and Aβ formed a sparsely populated complex with a lifetime of milliseconds in which a short hydrophobic cleavage segment of Aβ was anchored to IDE. Strikingly, a second and more stable complex was significantly populated with a subsecond lifetime owing to multiple intermolecular contacts between Aβ and IDE. By selectively sequestering Aβ in this nonproductive complex, IDE likely increases the critical concentration required for fibrillization. In contrast, IDE and p6 formed a transient, submillisecond complex involving a single anchoring p6 motif. Modulation of intermolecular interactions, thus, allows IDE to differentiate between non-amyloidogenic and amyloidogenic substrates.

Published

2021

21. Folding of Circularly Permuted and Split Outer Membrane Protein F via Electrostatic Interactions with Terminal Residues

Author

Woon Ju Song and Jaewon Lee

Subjects

Models, Molecular, Protein Folding, biology, Chemistry, Escherichia coli Proteins, Point mutation, Cell Membrane, Static Electricity, Membrane Proteins, Porins, Circular permutation in proteins, Electrostatics, biology.organism_classification, Biochemistry, In vitro, Folding (chemistry), Kinetics, Membrane protein, Gram-Negative Bacteria, Escherichia coli, Biophysics, Bacterial outer membrane, Bacteria, Bacterial Outer Membrane Proteins

Abstract

Membrane proteins are essential targets in drug design, biosensing, and catalysis. In this study, we explored the folding of engineered outer membrane protein F (OmpF), an abundant and functional β-barrel protein expressed in Gram-negative bacteria. We carried out circular permutation, splitting and self-complementation, and point mutation. The folding efficiency and kinetic analyses demonstrated that the N- and C-terminal residues of OmpF played critical roles in folding via electrostatic interactions with lipid headgroups. Our results indicate that native porins without charged terminal residues may be tightly downregulated to retain the integrity of the outer membrane, and this modification may facilitate the insertion and folding of modified membrane proteins under in vitro and in vivo conditions for various applications.

Published

2021

22. Spontaneous Refolding of Amyloid Fibrils from One Polymorph to Another Caused by Changes in Environmental Hydrophobicity

Author

Tatiana Quiñones-Ruiz, Manuel F. Rosario-Alomar, Maruda Shanmugasundaram, Muhammad M. Ali, and Igor K. Lednev

Subjects

Amyloid, Protein Folding, Tryptophan, Muramidase, Microscopy, Atomic Force, Biochemistry, Hydrophobic and Hydrophilic Interactions

Abstract

Here, we report a new phenomenon in which lysozyme fibrils formed in a solution of acetic acid spontaneously refold to a different polymorph through a disassembled intermediate upon the removal of acetic acid. The structural changes were revealed and characterized by deep-UV resonance Raman spectroscopy, nonresonance Raman spectroscopy, intrinsic tryptophan fluorescence spectroscopy, and atomic force microscopy. A PPII-like structure with highly solvent-exposed tryptophan residues predominates the intermediate aggregates before refolding to polymorph II fibrils. Furthermore, the disulfide (SS) bonds undergo significant rearrangements upon the removal of acetic acid from the lysozyme fibril environment. The main SS bond conformation changes from gauche-gauche-trans in polymorph I to gauche-gauche-gauche in polymorph II. Changing the hydrophobicity of the fibril environment was concluded to be the decisive factor causing the spontaneous refolding of lysozyme fibrils from one polymorph to another upon the removal of acetic acid. Potential biological implications of the discovered phenomenon are discussed.

Published

2022

23. A Stutter in the Coiled-Coil Domain of Escherichia coli Co-chaperone GrpE Connects Structure with Function

Author

Ishu Saraogi, Vaibhav V Karekar, Upasana S. Potteth, and Tulsi Upadhyay

Subjects

Coiled coil, biology, Chemistry, Mutant, medicine.disease_cause, Biochemistry, Nucleotide exchange factor, Co-chaperone, Förster resonance energy transfer, Chaperone (protein), biology.protein, medicine, Biophysics, Protein folding, Escherichia coli

Abstract

In bacteria, the co-chaperone GrpE acts as a nucleotide exchange factor and plays an important role in controlling the chaperone cycle of DnaK. The functional form of GrpE is an asymmetric dimer, consisting of a non-ideal coiled coil. Partial unfolding of this region during heat stress results in reduced nucleotide exchange and disrupts protein folding by DnaK. In this study, we elucidate the role of non-ideality in the coiled-coil domain of Escherichia coli GrpE in controlling its co-chaperone activity. The presence of a four-residue stutter introduces nonheptad periodicity in the GrpE coiled coil, resulting in global structural changes in GrpE and regulating its interaction with DnaK. Introduction of hydrophobic residues at the stutter core increased the structural stability of the protein. Using an in vitro FRET assay, we show that the enhanced stability of GrpE resulted in an increased affinity for DnaK. However, these mutants were unable to support bacterial growth at 42°C in a grpE-deleted E. coli strain. This work provides valuable insights into the functional role of a stutter in GrpE in regulating the DnaK-chaperone cycle during heat stress. More generally, our findings illustrate how stutters in a coiled-coil domain regulate structure-function trade-off in proteins.

Published

2021

24. Hyperphosphorylation of Human Osteopontin and Its Impact on Structural Dynamics and Molecular Recognition

Author

Szymon Żerko, Clara Conrad-Billroth, Wiktor Koźmiński, Borja Mateos, Robert Konrat, Gerald Platzer, Dorothea Anrather, Julian Holzinger, and Marco Sealey-Cardona

Subjects

Protein Folding, biology, Kinase, Chemistry, Protein Conformation, Hyperphosphorylation, Molecular Dynamics Simulation, Intrinsically disordered proteins, Biochemistry, Article, Molecular recognition, biology.protein, Biophysics, Phosphorylation, Humans, Protein phosphorylation, Osteopontin, Conformational ensembles

Abstract

Protein phosphorylation is an abundant post-translational modification (PTM) and an essential modulator of protein functionality in living cells. Intrinsically disordered proteins (IDPs) are particular targets of PTM protein kinases due to their involvement in fundamental protein interaction networks. Despite their dynamic nature, IDPs are far from having random-coil conformations but exhibit significant structural heterogeneity. Changes in the molecular environment, most prominently in the form of PTM via phosphorylation, can modulate these structural features. Therefore, how phosphorylation events can alter conformational ensembles of IDPs and their interactions with binding partners is of great interest. Here we study the effects of hyperphosphorylation on the IDP osteopontin (OPN), an extracellular target of the Fam20C kinase. We report a full characterization of the phosphorylation sites of OPN using a combined nuclear magnetic resonance/mass spectrometry approach and provide evidence for an increase in the local flexibility of highly phosphorylated regions and the ensuing overall structural elongation. Our study emphasizes the simultaneous importance of electrostatic and hydrophobic interactions in the formation of compact substates in IDPs and their relevance for molecular recognition events.

Published

2021

25. De Novo-Designed β-Sheet Heme Proteins

Author

Surajit Bhattacharjya, Areetha D'Souza, and School of Biological Sciences

Subjects

Protein Design, 0303 health sciences, Hemeprotein, Chemical Structures, biology, Heme binding, Chemistry, 030302 biochemistry & molecular biology, Protein design, Beta sheet, Biochemistry, Cofactor, 03 medical and health sciences, chemistry.chemical_compound, Protein structure, Chemistry::Analytical chemistry::Proteins [Science], biology.protein, Biophysics, Protein folding, Heme

Abstract

The field of de novo protein design has met with considerable success over the past few decades. Heme, a cofactor has often been introduced to impart a diverse array of functions to a protein, ranging from electron transport to respiration. In nature, heme is found to occur predominantly in α-helical structures over β-sheets, which has resulted in significant designs of heme-proteins utilizing coiled coil helices. By contrast, there are only a few known β-sheet proteins that bind heme and designs of β-sheets frequently result in amyloid-like aggregates. This review reflects on our success with designing a series of multi-stranded β-sheet heme binding peptides that are well folded both in aqueous and membrane-like environments. Initially, we designed a β-hairpin peptide that self-assembles to bind heme and performs peroxidase activity in membrane. The β-hairpin was optimized further to accommodate a heme binding pocket within multi-stranded β-sheets for catalysis and electron transfer in membranes. Furthermore, we de novo designed and characterized β-sheet peptides and mini-proteins soluble in aqueous environment capable of binding single and multiple hemes with high affinity and stability. Collectively, these studies highlight substantial progress made towards the design of functional β-sheets. Ministry of Education (MOE) Accepted version AS would like to thank Ministry of Education, Singapore and Nanyang Technological University for Graduate Research Scholarship.

Published

2021

26. Aromatic Interactions Drive the Coupled Folding and Binding of the Intrinsically Disordered Sesbania mosaic Virus VPg Protein

Author

Smita K. Nair, Khushboo Kumari, N. Megha Karanth, Handanahal S. Savithri, Kalyan S. Chakrabarti, Siddhartha P. Sarma, and Karuna Dixit

Subjects

Folding (chemistry), Protein structure, Protease, Residual dipolar coupling, Chemistry, Stereochemistry, medicine.medical_treatment, medicine, Protein quaternary structure, Protein folding, Intrinsically disordered proteins, Biochemistry, Protein tertiary structure

Abstract

The plant Sesbania mosaic virus [a (+)-ssRNA sobemovirus] VPg protein is intrinsically disordered in solution. For the virus life cycle, the VPg protein is essential for replication and for polyprotein processing that is carried out by a virus-encoded protease. The nuclear magnetic resonance (NMR)-derived tertiary structure of the protease-bound VPg shows it to have a novel tertiary structure with an α-β-β-β topology. The quaternary structure of the high-affinity protease-VPg complex (≈27 kDa) has been determined using HADDOCK protocols with NMR (residual dipolar coupling, dihedral angle, and nuclear Overhauser enhancement) restraints and mutagenesis data as inputs. The geometry of the complex is in excellent agreement with long-range orientational restraints such as residual dipolar couplings and ring-current shifts. A "vein" of aromatic residues on the protease surface is pivotal for the folding of VPg via intermolecular edge-to-face π···π stacking between Trp271 and Trp368 of the protease and VPg, respectively, and for the CH···π interactions between Leu361 of VPg and Trp271 of the protease. The structure of the protease-VPg complex provides a molecular framework for predicting sites of important posttranslational modifications such as RNA linkage and phosphorylation and a better understanding of the coupled folding upon binding of intrinsically disordered proteins. The structural data presented here augment the limited structural data available on viral proteins, given their propensity for structural disorder.

Published

2020

27. Electrostatic Modulation of Intramolecular and Intermolecular Interactions during the Formation of an Amyloid-like Assembly.

Author

Pillai M, Das A, and Jha SK

Subjects

Static Electricity, Amyloidogenic Proteins, DNA-Binding Proteins chemistry, Protein Folding, Protein Aggregates, Amyloid chemistry

Abstract

The mechanism of protein aggregation can be broadly viewed as a shift from the native-state stabilizing intramolecular to the aggregated-phase sustaining intermolecular interactions. Understanding the role of electrostatic forces on the extent of modulation of this switch has recently evolved as a topic of monumental significance as protein aggregation has lately been connected to charge modifications of an aging proteome. To decipher the distinctive role of electrostatic forces on the extremely complicated phase separation landscape, we opted for a combined in vitro-in silico approach to ascertain the structure-dynamics-stability-aggregability relationship of the functional tandem RRM domains of the ALS-related protein TDP-43 (TDP-43 tRRM ), under a bivariate solution condition in terms of pH and salt concentration. Under acidic pH conditions, the native TDP-43 tRRM protein creates an aggregation-prone entropically favorable partially unfolded conformational landscape due to enthalpic destabilization caused by the protonation of the buried ionizable residues and consequent overwhelming fluctuations of selective segments of the sequence leading to anti-correlated movements of the two domains of the protein. The evolved fluffy ensemble with a comparatively exposed backbone then easily interacts with incoming protein molecules in the presence of salt via typical amyloid-aggregate-like intermolecular backbone hydrogen bonds with a considerable contribution originating from the dispersion forces. Subsequent exposure to excess salt at low pH conditions expedites the aggregation process via an electrostatic screening mechanism where salt shows preferential binding to the positively charged side chain. The applied target observable-specific approach complementarity unveils the hidden information landscape of an otherwise complex process with unquestionable conviction.

Published

2023

28. Sequential Unfolding Mechanisms of Monomeric Caspases.

Author

Joglekar I and Clark AC

Subjects

Humans, Protein Denaturation, Protein Folding, Caspases

Abstract

Caspases are evolutionarily conserved cysteinyl proteases that are integral in cell development and apoptosis. All apoptotic caspases evolved from a common ancestor into two distinct subfamilies with either monomeric (initiators) or dimeric (effectors) oligomeric states. The regulation of apoptosis is influenced by the activation mechanism of the two subfamilies, but the evolution of the well-conserved caspase-hemoglobinase fold into the two subfamilies is not well understood. We examined the folding landscape of monomeric caspases from two coral species over a broad pH range of 3-10.5. On an evolutionary timescale, the two coral caspases diverged from each other approximately 300 million years ago, and they diverged from human caspases about 600 million years ago. Our results indicate that both proteins have overall high stability, ∼15 kcal mol -1 , near the physiological pH range (pH 6-8) and unfold via two partially folded intermediates, I 1 and I 2* , that are in equilibrium with the native and the unfolded state. Like the dimeric caspases, the monomeric coral caspases undergo a pH-dependent conformational change resulting from the titration of an evolutionarily conserved site. Data from molecular dynamics simulations paired with limited proteolysis and MALDI-TOF mass spectrometry show that the small subunit of the monomeric caspases is unstable and unfolds prior to the large subunit. Overall, the data suggest that all caspases share a conserved folding landscape, that a conserved allosteric site can be fine-tuned for species-specific regulation, and that the subfamily of stable dimers may have evolved to stabilize the small subunit.

Published

2023

29. Hydrogen Bonding Compensation on the Convex Solvent-Exposed Helical Face of IA 3 , an Intrinsically Disordered Protein.

Author

Dunleavy KM, Oi C, Li T, Secunda A, Jaufer AM, Zhu Y, Friedman L, Kim A, and Fanucci GE

Subjects

Solvents, Protein Structure, Secondary, Hydrogen Bonding, Amino Acid Sequence, Saccharomyces cerevisiae, Circular Dichroism, Trifluoroethanol pharmacology, Protein Folding, Intrinsically Disordered Proteins genetics

Abstract

Saccharomyces cerevisiae IA 3 is a 68 amino acid peptide inhibitor of yeast proteinase A (YPRA) characterized as a random coil when in solution, folding into an N-terminal amphipathic alpha helix for residues 2-32 when bound to YPRA, with residues 33-68 unresolved in the crystal complex. Circular dichroism (CD) spectroscopy results show that amino acid substitutions that remove hydrogen-bonding interactions observed within the hydrophilic face of the N-terminal domain (NTD) of IA 3 -YPRA crystal complex reduce the 2,2,2-trifluoroethanol (TFE)-induced helical transition in solution. Although nearly all substitutions decreased TFE-induced helicity compared to wild-type (WT), each construct did retain helical character in the presence of 30% (v/v) TFE and retained disorder in the absence of TFE. The NTDs of 8 different Saccharomyces species have nearly identical amino acid sequences, indicating that the NTD of IA 3 may be highly evolved to adopt a helical fold when bound to YPRA and in the presence of TFE but remain unstructured in solution. Only one natural amino acid substitution explored within the solvent-exposed face of the NTD of IA 3 induced TFE-helicity greater than the WT sequence. However, chemical modification of a cysteine by a nitroxide spin label that contains an acetamide side chain did enhance TFE-induced helicity. This finding suggests that non-natural amino acids that can increase hydrogen bonding or alter hydration through side-chain interactions may be important to consider when rationally designing intrinsically disordered proteins (IDPs) with varied biotechnological applications.

Published

2023

30. Folding of Staphylococcal Nuclease Induced by Binding of Chemically Modified Substrate Analogues Sheds Light on Mechanisms of Coupled Folding/Binding Reactions.

Author

Mori Y, Mizukami T, Segawa S, Roder H, and Maki K

Subjects

Ligands, Kinetics, Protein Conformation, Protein Folding, Micrococcal Nuclease metabolism

Abstract

Several proteins have been shown to undergo a shift in the mechanism of ligand binding-induced folding from conformational selection (CS; folding precedes binding) to induced fit (IF; binding precedes folding) with increasing ligand concentration. In previous studies of the coupled folding/binding reaction of staphylococcal nuclease (SNase) in the presence of a substrate analogue, adenosine-3',5'-diphosphate (prAp), we found that the two phosphate groups make important energetic contributions toward stabilizing its complex with the native protein as well as transient conformational states encountered at high ligand concentrations favoring IF. However, the structural contributions of each phosphate group during the reaction remain unclear. To address this question, we relied on fluorescence, nuclear magnetic resonance (NMR), absorption, and isothermal titration calorimetry to study the effects of deletion of the phosphate groups of prAp on the kinetics of ligand-induced folding, using a strategy analogous to mutational ϕ-value analysis to interpret the results. Kinetic measurements over a wide range of ligand concentrations, together with structural characterization of a transient protein-ligand encounter complex using 2D NMR, indicated that, at high ligand concentrations favoring IF, (i) the 5'-phosphate group interacts weakly with denatured SNase during early stages of the reaction, resulting in loose docking of the two domains of SNase, and (ii) the 3'-phosphate group engages in some specific contacts with the polypeptide in the transition state prior to formation of the native SNase-prAp complex.

Published

2023

31. Disruption of Spatial Proximities among Charged Groups in Equilibrium-Denatured States of Proteins Tracked Using Protein Charge Transfer Spectra.

Author

Priyadarshi A, Devi HM, and Swaminathan R

Subjects

Humans, Guanidine chemistry, Protein Structure, Secondary, Protein Denaturation, Circular Dichroism, Spectrometry, Fluorescence, Protein Folding

Abstract

The absorption and luminescence originating from protein charge transfer spectra (ProCharTS) depend on the proximity between multiple charged groups in a protein. This makes ProCharTS absorbance/luminescence intensity a sensitive probe for detecting changes in the protein structure, which alter the proximity among charged groups in the protein. In this work, ProCharTS absorbance of charge-rich proteins like human serum albumin (HSA), α 3 C, and α 3 W was used to monitor structural changes upon chemical denaturant-induced protein unfolding under equilibrium conditions. The denaturation midpoints were estimated using nonlinear regression analysis. For HSA, absorbance at 325 and 340 nm estimated the GdnHCl-induced denaturation midpoints to be 0.80 and 0.61 M, respectively. A similar analysis of α 3 C and α 3 W ProCharTS absorbance yielded denaturation midpoints of 0.88 and 0.86 M at 325 nm and 0.96 and 0.66 M at 340 nm, respectively. A previously reported molten globule-like state in the GdnHCl-induced HSA unfolding pathway was detected by the increase in HSA ProCharTS absorbance at 0.5 M GdnHCl. To validate the above results, protein unfolding was additionally monitored using conventional methods like circular dichroism (CD), Trp, and dansyl fluorescence. Our results suggest that disruption of charged amino acid sidechain contacts as revealed by ProCharTS occurs at lower denaturant concentrations compared to the loss of secondary/folded structure monitored by CD and fluorescence. Further, HSA ProCharTS absorbance at 315-340 nm revealed that tertiary contacts among charged residues were disrupted at lower GdnHCl concentrations compared to sequence adjacent contacts. Our data underscore the utility of ProCharTS as a novel label-free tool to track unfolding in charge-rich proteins.

Published

2023

32. Polyamines Mediate Folding of Primordial Hyperacidic Helical Proteins

Author

Liam M. Longo, Dragana Despotovic, Dan S. Tawfik, Tali Scherf, Einav Aharon, Ita Gruić-Sovulj, and Amit Kahana

Subjects

Protein Folding, Circular dichroism, Glutamic Acid, Context (language use), Biochemistry, Article, 03 medical and health sciences, chemistry.chemical_compound, Polyamines, Nuclear Magnetic Resonance, Biomolecular, 030304 developmental biology, 0303 health sciences, Circular Dichroism, Lysine, 030302 biochemistry & molecular biology, Proteins, Hydrogen-Ion Concentration, Folding (chemistry), Amino Acid Substitution, chemistry, Phosphodiester bond, Nucleic acid, Protein folding, Chemical chaperone, Polyamine, Peptides and proteins, Amines, Monomers, Organic polymers, Titration

Abstract

Polyamines are known to mediate diverse biological processes, and specifically to bind and stabilize compact conformations of nucleic acids, acting as chemical chaperones that promote folding by offsetting the repulsive negative charges of the phosphodiester backbone. However, whether and how polyamines modulate the structure and function of proteins remain unclear. In particular, early proteins are thought to have been highly acidic, like nucleic acids, due to a scarcity of basic amino acids in the prebiotic context. Perhaps polyamines, the abiotic synthesis of which is simple, could have served as chemical chaperones for such primordial proteins? We replaced all lysines of an ancestral 60-residue helix-bundle protein with glutamate, resulting in a disordered protein with 21 glutamates in total. Polyamines efficiently induce folding of this hyperacidic protein at submillimolar concentrations, and their potency scaled with the number of amine groups. Compared to cations, polyamines were several orders of magnitude more potent than Na+, while Mg2+ and Ca2+ had an effect similar to that of a diamine, inducing folding at approximately seawater concentrations. We propose that (i) polyamines and dications may have had a role in promoting folding of early proteins devoid of basic residues and (ii) coil–helix transitions could be the basis of polyamine regulation in contemporary proteins.

Published

2020

33. Conformational Dynamics of the Periplasmic Chaperone SurA

Author

Xianhui Hou, Bo Wu, Changwen Jin, Ziyu Yang, Moye Jia, Yunfei Hu, Meiping Zhao, Chunlai Chen, and Xiaogang Niu

Subjects

Models, Molecular, Protein Folding, Protein Conformation, Peptide binding, Isomerase, Biochemistry, Escherichia coli, Protein Interaction Domains and Motifs, Structural transition, Nuclear Magnetic Resonance, Biomolecular, biology, Chemistry, Escherichia coli Proteins, Periplasmic space, Peptidylprolyl Isomerase, Förster resonance energy transfer, Gain of Function Mutation, Chaperone (protein), Bacterial Outer Membrane Proteins, Periplasm, biology.protein, Biophysics, Carrier Proteins, Biogenesis, Molecular Chaperones, Protein Binding

Abstract

The periplasmic protein SurA is the primary chaperone involved in the biogenesis of bacterial outer membrane proteins and is a potential antibacterial drug target. The three-dimensional structure of SurA can be divided into three parts, a core module formed by the N- and C-terminal regions and two peptidyl-prolyl isomerase (PPIase) domains, P1 and P2. Despite the determination of the structures of several SurA-peptide complexes, the functional mechanism of this chaperone remains elusive and the roles of the two PPIase domains are yet unclear. Herein, we characterize the conformational dynamics of SurA by using solution nuclear magnetic resonance and single-molecule fluorescence resonance energy transfer methods. We demonstrate a "closed-to-open" structural transition of the P1 domain that is correlated with both chaperone activity and peptide binding and show that the flexible P2 domain can also occupy conformations that closely contact the NC core module. Our results offer a structural basis for the counteracting roles of the two PPIase domains in regulating the SurA chaperone activity.

Published

2020

34. Protein Modifications Critical for Myonectin/Erythroferrone Secretion and Oligomer Assembly

Author

Hui Zhang, David J. Clark, G. William Wong, Hannah C. Little, and Ashley N. Stewart

Subjects

Protein Folding, Glycosylation, Muscle Proteins, Hydroxylation, Biochemistry, Article, Mice, 03 medical and health sciences, chemistry.chemical_compound, Animals, Humans, Secretion, 0303 health sciences, Chemistry, Endoplasmic reticulum, 030302 biochemistry & molecular biology, Tunicamycin, Erythroferrone, HEK293 Cells, Secretory protein, Myonectin, Cytokines, Protein folding, Protein Multimerization

Abstract

Myonectin/erythroferrone (also known as CTRP15) is a secreted hormone with metabolic function and a role in stress erythropoiesis. Despite its importance in physiologic processes, biochemical characterization of the protein is lacking. Here, we show that multiple protein modifications are critical for myonectin secretion and multimerization. Abolishing N-linked glycosylation by tunicamycin, glucosamine supplementation, or glutamine substitutions of all four potential Asn glycosylation sites blocked myonectin secretion. Mass spectrometry confirmed that Asn-229 and Asn-281 were glycosylated, and substituting both Asn sites with Gln prevented myonectin secretion. Although Asn-319 is not identified as glycosylated, Gln substitution caused protein misfolding and retention in the endoplasmic reticulum. Of the four conserved cysteines, Cys-273 and Cys-278 were required for proper protein folding; Ala substitution of either site inhibited protein secretion. In contrast, Ala substitutions of Cys-142, Cys-194, or both markedly enhanced protein secretion, suggesting endoplasmic reticulum retention that facilitates myonectin oligomer assembly. Secreted myonectin consists of trimers, hexamers, and high-molecular weight (HMW) oligomers. The formation of higher-order structures via intermolecular disulfide bonds depended on Cys-142 and Cys-194; while the C142A mutant formed almost exclusively trimers, the C194A mutant was impaired in HMW oligomer formation. Most Pro residues within the short collagen domain of myonectin were also hydroxylated, a modification that stabilized the collagen triple helix. Inhibiting Pro hydroxylation or deleting the collagen domain markedly reduced the rate of protein secretion. Together, our results reveal key determinants that are important for myonectin folding, secretion, and multimeric assembly and provide a basis for future structure–function studies.

Published

2020

35. Cytoskeletal Drugs Modulate Off-Target Protein Folding Landscapes Inside Cells

Author

Caitlin M. Davis and Martin Gruebele

Subjects

Models, Molecular, Protein Folding, Lipoproteins, Vinblastine, Biochemistry, Cell Line, 03 medical and health sciences, chemistry.chemical_compound, Bacterial Proteins, Microtubule, Yeasts, Cytoskeletal drugs, Fluorescence Resonance Energy Transfer, Humans, Cytoskeleton, Actin, Cell Size, Antigens, Bacterial, 0303 health sciences, Protein Stability, Nocodazole, 030302 biochemistry & molecular biology, Proteins, Tubulin Modulators, Phosphoglycerate Kinase, chemistry, Cytoplasm, Borrelia burgdorferi, Biophysics, Target protein, Macromolecular crowding

Abstract

The dynamic cytoskeletal network of microtubules and actin filaments can be disassembled by drugs. Cytoskeletal drugs work by perturbing the monomer-polymer equilibrium, thus changing the size and number of macromolecular crowders inside cells. Changes in both crowding and nonspecific surface interactions ("sticking") following cytoskeleton disassembly can affect the protein stability, structure, and function directly or indirectly by changing the fluidity of the cytoplasm and altering the crowding and sticking of other macromolecules in the cytoplasm. The effect of cytoskeleton disassembly on protein energy landscapes inside cells has yet to be observed. Here we have measured the effect of several cytoskeletal drugs on the folding energy landscape of two FRET-labeled proteins with different in vitro sensitivities to macromolecular crowding. Phosphoglycerate kinase (PGK) was previously shown to be more sensitive to crowding, whereas variable major protein-like sequence expressed (VlsE) was previously shown to be more sensitive to sticking. The in-cell effects of drugs that depolymerize either actin filaments (cytochalasin D and latrunculin B) or microtubules (nocodazole and vinblastine) were compared. The crowding sensor protein CrH2-FRET verified that cytoskeletal drugs decrease the extent of crowding inside cells despite also reducing the overall cell volume. The decreased compactness and folding stability of PGK could be explained by the decreased extent of crowding induced by these drugs. VlsE's opposite response to the drugs shows that depolymerization of the cytoskeleton also changes sticking in the cellular milieu. Our results demonstrate that perturbation of the monomer-polymer cytoskeletal equilibrium, for example, during natural cell migration or stresses from drug treatment, has off-target effects on the energy landscapes of proteins in the cell.

Published

2020

36. NMR Spectroscopic Studies Reveal the Critical Role of the Isopeptide Bond in Forming the Otherwise Unstable SpyTag–SpyCatcher Mutant Complexes

Author

Nan Zhang, Wen-Bin Zhang, Wen-Hao Wu, Shenlin Wang, Xiao-Di Da, Jing Fang, Jing Liu, and Yajie Liu

Subjects

Gel electrophoresis, chemistry.chemical_classification, Circular dichroism, Isopeptide bond, Protein Stability, Stereochemistry, Chemistry, Circular Dichroism, Mutant, Sequence (biology), Nuclear magnetic resonance spectroscopy, Biochemistry, Cyclization, Covalent bond, Mutation, Protein folding, Peptides, Nuclear Magnetic Resonance, Biomolecular

Abstract

The interplay between protein folding and chemical reaction has been an intriguing subject. In this contribution, we report the study of SpyTag and SpyCatcher reactive mutants using a combination of sodium dodecyl sulfate-polyacrylamide gel electrophoresis, liquid chromatography and mass spectrometry, circular dichroism, and NMR spectroscopy. It was found that the wild-type SpyCatcher is well-folded in solution and docks with SpyTag to form an intermediate that promotes isopeptide bond formation. By contrast, the double mutant SpyCatcherVA is disordered in solution yet remains reactive toward SpyTag, forming a well-folded covalent complex. Control experiments using the catalytically inactive mutants further reveal the critical role of the isopeptide bond in stabilizing the otherwise loose SpyTag-SpyCatcherVA complex, amplifying the effect of the minute sequence disparity. We believe that the synergy between protein folding and isopeptide bonding is an effective way to enhance protein stability and engineer protein-protein interactions.

Published

2020

37. UbcH5 Interacts with Substrates to Participate in Lysine Selection with the E3 Ubiquitin Ligase CHIP

Author

Holly N Haver, Theodore Keppel, Kenneth Matthew Scaglione, Adam J. Kanack, Rachel E. Klevit, Rebekah L. Gundry, and Vinayak Vittal

Subjects

Models, Molecular, biology, HSC70-INTERACTING PROTEIN, Chemistry, Lysine, Ubiquitin-Protein Ligases, Ubiquitination, Substrate (chemistry), Chip, complex mixtures, Biochemistry, Article, Ubiquitin ligase, Cell biology, Residue (chemistry), Ubiquitin, Ubiquitin-Conjugating Enzymes, biology.protein, Humans, bacteria, Protein folding

Abstract

The E3 ubiquitin ligase C-terminus of Hsc70 interacting protein (CHIP) plays a critical role in regulating the ubiquitin-dependent degradation of misfolded proteins. CHIP mediates the ubiquitination of the α-amino-terminus of substrates with the E2 Ube2w and facilitates the ubiquitination of lysine residues with the E2 UbcH5. While it is known that Ube2w directly interacts with the disordered regions at the N-terminus of its substrates, it is unclear how CHIP and UbcH5 mediate substrate lysine selection. Here, we have decoupled the contributions of the E2, UbcH5, and the E3, CHIP, in ubiquitin transfer. We show that UbcH5 selects substrate lysine residues independent of CHIP, and that CHIP participates in lysine selection by fine-tuning the subset of substrate lysines that are ubiquitinated. We also identify lysine 128 near the C-terminus of UbcH5 as a critical residue for the efficient ubiquitin transfer by UbcH5 in both the presence and absence of CHIP. Together, these data demonstrate an important role of the UbcH5/substrate interactions in mediating the efficient ubiquitin transfer by the CHIP/UbcH5 complex.

Published

2020

38. Net Charge and Nonpolar Content Guide the Identification of Folded and Prion Proteins

Author

Miranda M. Mecha, Jenna H. Becker, Hanming Yang, Susanna K. Yaeger-Weiss, Theodore S. Jennaro, Gordon L. W. Winkler, and Silvia Cavagnero

Subjects

Models, Molecular, chemistry.chemical_classification, Protein Folding, Protein Conformation, Chemistry, Structural Classification of Proteins database, Intrinsically disordered proteins, Biochemistry, Prion Proteins, Amino acid, Intrinsically Disordered Proteins, Protein structure, Membrane protein, Proteome, Escherichia coli, Biophysics, Protein folding, Amino Acid Sequence, Hydrophobic and Hydrophilic Interactions, Peptide sequence, Algorithms

Abstract

The degree of hydrophobicity and net charge per residue are physical properties that enable the discrimination of folded from intrinsically disordered proteins (IDPs) solely on the basis of amino acid sequence. Here, we improve upon the existing classification of proteins and IDPs based on the parameters mentioned above by adopting the scale of nonpolar content of Rose et al. and by taking amino acid side-chain acidity and basicity into account. The resulting algorithm, denoted here as net charge nonpolar or NECNOP, enables the facile prediction of the folded and disordered status of proteins under physiologically relevant conditions with >95% accuracy, based on amino-acid sequence alone. The NECNOP approach displays a much-enhanced performance for proteins with >140 residues, suggesting that small proteins are more likely to have irregular charge and hydrophobicity features. NECNOP analysis of the entire Escherichia coli proteome identifies specific net charge and nonpolar regions peculiar to soluble, integral membrane, and non-integral membrane proteins. Surprisingly, protein net charge and hydrophobicity are found to converge to specific values as chain length increases, across the E. coli proteome. In addition, NECNOP plots enable the straightforward identification of protein sequences corresponding to prion proteins and promise to serve as a powerful predictive tool for the design of large proteins. In summary, NECNOP plots are a straightforward approach that improves our understanding of the relation between the amino acid sequence and three-dimensional structure of proteins as a function of molecular mass.

Published

2020

39. RNase T1 Refolding Assay for Determining Mitochondrial Cyclophilin D Activity: A Novel In Vitro Method Applicable in Drug Research and Discovery

Author

Ondrej Benek, Monika Schmidt, Kamil Musilek, Annamaria Haleckova, Michaela Vaskova, Jana Roubalova, and Lucie Zemanová

Subjects

Drug, 0303 health sciences, Chemistry, RNase P, media_common.quotation_subject, 030302 biochemistry & molecular biology, Isomerase, medicine.disease, Biochemistry, In vitro, Mitochondrial Cyclophilin, 03 medical and health sciences, Mitochondrial permeability transition pore, medicine, Protein folding, Reperfusion injury, media_common

Abstract

Human cyclophilin D is a mitochondrial peptidyl-prolyl isomerase that plays a role in regulating the opening of the mitochondrial permeability transition pore. It is considered a viable and promising molecular target for the treatment of diseases for which disease development is associated with pore opening, e.g., Alzheimer's disease or ischemia/reperfusion injury. Currently available and widely used in vitro methods based on Kofron's assay for determining cyclophilin D activity suffer from serious drawbacks and limitations. In this study, a completely novel approach for an in vitro assay of cyclophilin D activity using RNase T1 refolding is introduced. The method is simple and is more in line with the presumed physiological role of cyclophilin D in protein folding than Kofron's assay, which relies on a peptide substrate. The method is applicable for identifying novel inhibitors of cyclophilin D as potential drugs for the treatment of the diseases mentioned above. Moreover, the description of CypD activity in the in vitro RNase T1 refolding assay reveals new possibilities for investigating the role of cyclophilin D in protein folding in cells and may lead to a better understanding of its pathological and physiological roles.

Published

2020

40. Robust De Novo-Designed Homotetrameric Coiled Coils

Author

Caitlin L Edgell, Derek N. Woolfson, and Nigel J. Savery

Subjects

Coiled coil, Chemistry, Bristol BioDesign Institute, Protein domain, BrisSynBio, Sequence (biology), Biochemistry, Turn (biochemistry), Synthetic biology, Protein structure, Robustness (computer science), Biophysics, Protein folding

Abstract

De novo-designed protein domains are increasingly being applied in biotechnology, cell biology, and synthetic biology. Therefore, it is imperative that these proteins be robust to superficial changes; i.e., small changes to their amino acid sequences should not cause gross structural changes. In turn, this allows properties such as stability and solubility to be tuned without affecting structural attributes like tertiary fold and quaternary interactions. Reliably designed proteins with predictable behaviors may then be used as scaffolds to incorporate function, e.g., through the introduction of features for small-molecule, metal, or macromolecular binding, and enzyme-like active sites. Generally, achieving this requires the starting protein fold to be well understood. Herein, we focus on designing α-helical coiled coils, which are well studied, widespread, and often direct protein-protein interactions in natural systems. Our initial investigations reveal that a previously designed parallel, homotetrameric coiled coil, CC-Tet, is not robust to sequence changes that were anticipated to maintain its structure. Instead, the alterations switch the oligomeric state from tetramer to trimer. To improve the robustness of designed homotetramers, additional sequences based on CC-Tet were produced and characterized in solution and by X-ray crystallography. Of these updated sequences, one is robust to truncation and to changes in surface electrostatics; we call this CC-Tet*. Variants of the general CC-Tet* design provide a set of homotetrameric coiled coils with unfolding temperatures in the range from 40 to >95 °C. We anticipate that these will be of use in applications requiring robust and well-defined tetramerization domains.

Published

2020

41. Early Metastable Assembly during the Stress-Induced Formation of Worm-like Amyloid Fibrils of Nucleic Acid Binding Domains of TDP-43

Author

Santosh Kumar Jha and Meenakshi Pillai

Subjects

Amyloid, Protein Folding, Biochemistry, Biophysical Phenomena, Protein Structure, Secondary, Protein Aggregates, 03 medical and health sciences, Cytosol, Protein structure, Stress, Physiological, medicine, Side chain, Humans, Protein secondary structure, Cell Nucleus, 0303 health sciences, RNA recognition motif, Protein Stability, Chemistry, Amyotrophic Lateral Sclerosis, 030302 biochemistry & molecular biology, Neurodegeneration, medicine.disease, Protein tertiary structure, DNA-Binding Proteins, TDP-43 Proteinopathies, Biophysics, Nucleic acid, Protein folding, RNA Recognition Motif

Abstract

TDP-43 protein travels between the cytosol and the nucleus to perform its nucleic acid binding functions through its two tandem RNA recognition motif domains (TDP-43tRRM). When exposed to various environmental stresses, it forms abnormal aggregates in the cytosol of neurons, which are the hallmarks of amyotrophic lateral sclerosis and other TDP-43 proteinopathies. However, the nature of early structural changes upon stress sensing and the consequent steps during the course of aggregation are not well understood. In this study, we show that under low-pH conditions, mimicking starvation stress, TDP-43tRRM undergoes a conformational opening reaction linked to the protonation of buried ionizable residues and grows into a metastable oligomeric assembly (called the "low-pH form" or the "L form"). In the L form, the protein molecules have disrupted tertiary structure, solvent-exposed hydrophobic patches, and mobile side chains but the native-like secondary structure remains intact. The L form structure is held by weak interactions and has a steep dependence on ionic strength. In the presence of as little as 15 mM KCl, it fully misfolds and further oligomerizes to form a β-sheet rich "β form" in at least two distinct steps. The β form has an ordered, stable structure that resembles worm-like amyloid fibrils. The unstructured regions of the protein gain structure during L ⇌ β conversion. Our results suggest that TDP-43tRRM could function as a stress sensor and support a recent model in which stress sensing during neurodegeneration occurs by assembly of proteins into metastable assemblies that are precursors to the solid aggregates.

Published

2020

42. A Difference between

Author

I-Te, Chu, Claire J, Stewart, Shannon L, Speer, and Gary J, Pielak

Subjects

Protein Denaturation, Protein Folding, Macromolecular Substances, Polymers, Protein Conformation, Circular Dichroism, Proteins, Urea, Nuclear Magnetic Resonance, Biomolecular

Abstract

The high concentration of macromolecules in cells affects the stability of proteins and protein complexes via hard repulsions and chemical interactions, yet few studies have focused on chemical interactions. We characterized the domain-swapped dimer of the B1 domain of protein G in buffer and

Published

2022

43. Estimation of Effective Concentrations Enforced by Complex Linker Architectures from Conformational Ensembles

Author

Magnus Kjaergaard

Subjects

Models, Molecular, Molecular Weight, Protein Folding, Protein Domains, Protein Conformation, Molecular Conformation, Proteins, Ligands, Biochemistry, Catalysis, Enzymes

Abstract

Proteins and protein assemblies often tether interaction partners to strengthen interactions, to regulate activity through auto-inhibition or -activation, or to boost enzyme catalysis. Tethered reactions are regulated by the architecture of the tether, which defines an effective concentration of the interactor. Effective concentrations can be estimated theoretically for simple linkers via polymer models, but there is currently no general method for estimating effective concentrations for complex linker architectures consisting of both flexible and folded domains. We describe how effective concentrations can be estimated computationally for any protein linker architecture by defining a realistic conformational ensemble. We benchmark against prediction from a worm-like chain and values measured by competition experiments and find minor differences likely due to excluded volume effects. Systematic variation of the properties of flexible and folded segments shows that the effective concentration is mainly determined by the combination of the total length of flexible segments and the distance between the termini of the folded domains. We show that a folded domain in a disordered linker can increase the effective concentration beyond what can be achieved by a fully disordered linker by focusing the end-to-end distance at the appropriate spacing. This suggests that complex linker architecture may have advantages over simple flexible linkers and emphasizes that annotation as a linker should depend on the molecular context.

Published

2022

44. Double Mutant of Chymotrypsin Inhibitor 2 Stabilized through Increased Conformational Entropy

Author

Yulian Gavrilov, Simone Orioli, Kresten Lindorff-Larsen, A. Prestel, Felix Kümmerer, and Kaare Teilum

Subjects

Protein Folding, Magnetic Resonance Spectroscopy, PROTEINS, Protein Conformation, Entropy, Mutant, MOLECULAR SIMULATIONS, SIDE-CHAIN DYNAMICS, TRANSITION-STATE, Molecular Dynamics Simulation, Biochemistry, HYDROPHOBIC CORE MUTATIONS, Molecular dynamics, chemistry.chemical_compound, Amide, Native state, MODEL-FREE APPROACH, DEUTERIUM SPIN PROBES, Plant Proteins, Protein Stability, Conformational entropy, Amides, Folding (chemistry), MAGNETIC-RESONANCE RELAXATION, chemistry, Mutation, Biophysics, HYDROGEN-EXCHANGE, Peptides, Function (biology), ORDER PARAMETERS, Entropy (order and disorder)

Abstract

The conformational heterogeneity of a folded protein can affect both its function but also stability and folding. We recently discovered and characterized a stabilized double mutant (L49I/I57V) of the protein CI2 and showed that state-of-the-art prediction methods could not predict the increased stability relative to the wild-type protein. Here we have examined whether changed native state dynamics, and resulting entropy changes, can explain the stability changes in the double mutant protein, as well as the two single mutant forms. We have combined NMR relaxation measurements of the ps-ns dynamics of amide groups in the backbone and the methyl groups in the side-chains with molecular dynamics simulations to quantify the native state dynamics. The NMR experiments reveal that the mutations have different effects on the conformational flexibility of CI2: A reduction in conformational dynamics (and entropy) of the native state of L49I variant correlates with its decreased stability, while increased dynamics of the I57V and L49I/I57V variants correlates with their increased stability. These findings suggest that explicitly accounting for changes in native state entropy might be needed to improve the predictions of the effect of mutations on protein stability.

Published

2022

45. Why Are Gly31, Gly33, and Gly35 Highly Conserved in All Fluorescent Proteins?

Author

Tanya L. Schneider, Franceine S. Welcome, Christian Salguero, Sercan Durmus, Marc Zimmer, Justin Nwafor, and Rachel N. Glasser

Subjects

Protein Folding, Mutant, Amino Acid Motifs, Genetic Vectors, Green Fluorescent Proteins, Glycine, Gene Expression, Molecular Dynamics Simulation, medicine.disease_cause, Biochemistry, Green fluorescent protein, Molecular dynamics, Structure-Activity Relationship, medicine, Escherichia coli, Cloning, Molecular, Alanine, Mutation, Chemistry, Chromophore, Fluorescence, Sequence identity, Recombinant Proteins, Amino Acid Substitution, Thermodynamics, Protein Conformation, beta-Strand

Abstract

Green fluorescent protein (GFP)-like fluorescent proteins have been found in more than 120 species. Although the proteins have little sequence identity, Gly31, 33, and 35 are 87, 100, and 95% conserved across all species, respectively. All GFP-like proteins have a β-barrel structure composed of 11 β-sheets, and the 3 conserved glycines are located in the second β-sheet. Molecular dynamics (MD) simulations have shown that mutating one or more of the glycines to alanines most likely does not reduce chromophore formation in correctly folded immature fluorescent proteins. MD and protein characterization of alanine mutants indicate that mutation of the conserved glycines leads to misfolding. Gly31, 33, and 35 are essential to maintain the integrity of the β1-3 triad that is the last structural element to slot in place in the formation of the canonical fluorescent protein β-barrel. Glycines located in β-sheets may have a similar role in the formation of other non-GFP β-barrels.

Published

2021

46. Effects of Hydrostatic Pressure on the Thermodynamics of CspB-Bs Interactions with the ssDNA Template

Author

Samvel Avagyan and George I. Makhatadze

Subjects

Hydrostatic pressure, Temperature, Thermodynamics, DNA, Single-Stranded, Cold-shock domain, Biochemistry, Folding (chemistry), chemistry.chemical_compound, Volume (thermodynamics), chemistry, Bacterial Proteins, Bound state, Unfolded protein response, Hydrostatic Pressure, Protein folding, DNA, Bacillus subtilis, Protein Binding, Protein Unfolding

Abstract

Understanding the thermodynamic mechanisms of adaptation of biomacromolecules to high hydrostatic pressure can help shed light on how piezophilic organisms can survive at pressures reaching over 1000 atmospheres. Interaction of proteins with nucleic acids is one of the central processes that allow information flow encoded in the sequence of DNA. Here, we report the results of a study on the interaction of cold shock protein B from Bacillus subtilis (CspB-Bs) with heptadeoxythymine template (pDT7) as a function of temperature and hydrostatic pressure. Experimental data collected at different CspB-Bs:pDT7 ratios were analyzed using a thermodynamic linkage model that accounts for both protein unfolding and CspB-Bs:pDT7 binding. The global fit to the model provided estimates of the stability of CspB-Bs, ΔGProto, the volume change upon CspB-Bs unfolding, ΔVProt, the association constant for CspB-Bs:pDT7 complex, Kao, and the volume changes upon pDT7 single-stranded DNA (ssDNA) template binding, ΔVBind. The protein, CspB-Bs, unfolds with an increase in hydrostatic pressure (ΔVProt < 0). Surprisingly, our study showed that ΔVBind < 0, which means that the binding of CspB-Bs to ssDNA is stabilized by an increase in hydrostatic pressure. Thus, CspB-Bs binding to pDT7 represents a case of linked equilibrium in which folding and binding react differently upon an increase in hydrostatic pressure: protein folding/unfolding equilibrium favors the unfolded state, while protein-ligand binding equilibrium favors the bound state. These opposing effects set a "maximum attainable" pressure tolerance to the protein-ssDNA complex under given conditions.

Published

2021

47. Mutually Exclusive Formation of G-Quadruplex and i-Motif Is a General Phenomenon Governed by Steric Hindrance in Duplex DNA.

Author

Yunxi Cui, Deming Kong, Chiran Ghimire, Cuixia Xu, and Hanbin Mao

Subjects

*QUADRUPLEX nucleic acids, *BIOACTIVE compounds, *CELLULAR mechanics, *PROTEIN folding, *TELOMERES

Abstract

G-Quadruplex and i-motif are tetraplex structures that may form in opposite strands at the same location of a duplex DNA. Recent discoveries have indicated that the two tetraplex structures can have conflicting biological activities, which poses a challenge for cells to coordinate. Here, by performing innovative population analysis on mechanical unfolding profiles of tetraplex structures in double-stranded DNA, we found that formations of G-quadruplex and i-motif in the two complementary strands are mutually exclusive in a variety of DNA templates, which include human telomere and promoter fragments of hINS and hTERT genes. To explain this behavior, we placed G-quadruplex- and i-motif-hosting sequences in an offset fashion in the two complementary telomeric DNA strands. We found simultaneous formation of the G-quadruplex and i-motif in opposite strands, suggesting that mutual exclusivity between the two tetraplexes is controlled by steric hindrance. This conclusion was corroborated in the BCL-2 promoter sequence, in which simultaneous formation of two tetraplexes was observed due to possible offset arrangements between G-quadruplex and i-motif in opposite strands. The mutual exclusivity revealed here sets a molecular basis for cells to efficiently coordinate opposite biological activities of G-quadruplex and i-motif at the same dsDNA location. [ABSTRACT FROM AUTHOR]

Published

2016

48. Molecular Crowding Affects the Conformational Fluctuations, Peroxidase Activity, and Folding Landscape of Yeast Cytochrome c.

Author

Paul, Simanta Sarani, Sil, Pallabi, Chakraborty, Ritobrita, Haldar, Shubhasis, and Chattopadhyay, Krishnananda

Subjects

*PEROXIDASE, *CYTOCHROME c, *CULTURE media (Biology), *PROTEIN folding, *CONFORMATIONAL analysis, YEAST physiology

Abstract

To understand how a protein folds and behaves inside living cells, the effects of synthetic crowding media on protein folding, function, stability, and association have been studied in detail. Because the effect of excluded volume is more prominent in an extended state than in the native protein, a majority of these studies have been conducted in the unfolded state of different model proteins. Here, we have used fluorescence correlation spectroscopy (FCS) and other biophysical methods to investigate the effect of crowding agents Ficoll70 and Dextran70 on the nativelike state of cytochrome c from yeast. Yeast cytochrome c (y-cytc) contains a substantial expanded state in its native folded condition, which is present in equilibrium with a compact conformer in aqueous buffer. We have found that the crowding medium affects the native state equilibrium between compact and expanded states, shifting its population toward the compact conformer. As a result, the peroxidase activity of y-cytc decreases. Urea-induced protein stability measurements show that the compaction destabilizes the protein due to charge repulsions between similar charged clusters. Interestingly, the time constant of conformational fluctuations between the compact and expanded conformers has been found to increase in the crowded milieu, suggesting a crucial role of the solution microviscosity. [ABSTRACT FROM AUTHOR]

Published

2016

49. Role of Electrostatic Interactions in Binding of Peptides and Intrinsically Disordered Proteins to Their Folded Targets: 2. The Model of Encounter Complex Involving the Double Mutant of the c-Crk N-SH3 Domain and Peptide Sos.

Author

Tairan Yuwen, Yi Xue, and Skrynnikov, Nikolai R.

Subjects

*ELECTROSTATIC interaction, *PROTEIN binding, *PROTEIN-protein interactions, *PROTEIN folding, *GENETIC mutation

Abstract

In the first part of this work (paper 1, Xue, Y. et al. Biochemistry 2014, 53, 6473), we have studied the complex between the 10-residue peptide Sos and N-terminal SH3 domain from adaptor protein c-Crk. In the second part (this paper), we designed the double mutant of the c-Crk N-SH3 domain, W169F/Y186L, with the intention to eliminate the interactions responsible for tight peptide-protein binding, while retaining the interactions that create the initial electrostatic encounter complex. The resulting system was characterized experimentally by measuring the backbone and side-chain 15N relaxation rates, as well as binding shifts and 1HN temperature coefficients. In addition, it was also modeled via a series of ~5 μs molecular dynamics (MD) simulations recorded in a large water box under an Amber ff99SB*-ILDN force field. Similar to paper 1, we have found that the strength of arginine-aspartate and arginine-glutamate salt bridges is overestimated in the original force field. To address this problem we have applied the empirical force-field correction described in paper 1. Specifically, the Lennard-Jones equilibrium distance for the nitrogen-oxygen pair across Arg-to-Asp/Glu salt bridges has been increased by 3%. This modification led to MD models in good agreement with the experimental data. The emerging picture is that of a fuzzy complex, where the peptide "dances" over the surface of the protein, making transient contacts via salt-bridge interactions. Every once in a while the peptide assumes a certain more stable binding pose, assisted by a number of adventitious polar and nonpolar contacts. On the other hand, occasionally Sos flies off the protein surface; it is then guided by electrostatic steering to quickly reconnect with the protein. The dynamic interaction between Sos and the double mutant of c-Crk N-SH3 gives rise to only small binding shifts. The peptide retains a high degree of conformational mobility, although it is appreciably slowed down due to its (loose) association with the protein. Note that spin relaxation data are indispensable in determining the dynamic status of the peptide. Such data can be properly modeled only on a basis of bona fide MD simulations, as shown in our study. We anticipate that in future the field will move away from the ensemble view of protein disorder and toward more sophisticated MD models. This will require further optimization of force fields, aimed specifically at disordered systems. Efforts in this direction have been recently initiated by several research groups; the empirical salt-bridge correction proposed in our work falls in the same category. MD models obtained with the help of suitably refined force fields and guided by experimental NMR data will provide a powerful insight into an intricate world of disordered biomolecules. [ABSTRACT FROM AUTHOR]

Published

2016

50. Structural and Functional Significance of the N- and C-Terminal Appendages in Arabidopsis Truncated Hemoglobin.

Author

Mukhi, Nitika, Dhindwal, Sonali, Uppal, Sheetal, Kapoor, Abhijeet, Arya, Richa, Kumar, Pravindra, Kaur, Jagreet, and Kundu, Suman

Subjects

*PROTEIN folding, *HEMOGLOBINS, *ARABIDOPSIS, *PROTEIN-protein interactions, *MOLECULAR dynamics

Abstract

Plant hemoglobins constitute three distinct groups: symbiotic, nonsymbiotic, and truncated hemoglobins. Structural investigation of symbiotic and nonsymbiotic (class I) hemoglobins revealed the presence of a vertebrate-like 3/3 globin fold in these proteins. In contrast, plant truncated hemoglobins are similar to bacterial truncated hemoglobins with a putative 2/2 α-helical globin fold. While multiple structures have been reported for plant hemoglobins of the first two categories, for plant truncated globins only one structure has been reported of late. Here, we report yet another crystal structure of the truncated hemoglobin from Arabidopsis thaliana (AHb3) with two water molecules in the heme pocket, of which one is distinctly coordinated to the heme iron, unlike the only available crystal structure of AHb3 with a hydroxyl ligand. AHb3 was monomeric in its crystallographic asymmetric unit; however, dimer was evident in the crystallographic symmetry, and the globin indeed existed as a stable dimer in solution. The tertiary structure of the protein exhibited a bacterial-like 2/2 α-helical globin fold with an additional N-terminal α-helical extension and disordered C-termini. To address the role of these extended termini in AHb3, which is yet unknown, N- and C-terminal deletion mutants were created and characterized and molecular dynamics simulations performed. The C-terminal deletion had an insignificant effect on most properties but perturbed the dimeric equilibrium of AHb3 and significantly influenced azide binding kinetics in the ferric state. These results along with the disordered nature of the C-terminus indicated its putative role in intramolecular or intermolecular interactions probably regulating protein-ligand and protein-protein interactions. While the N-terminal deletion did not change the overall globin fold, stability, or ligand binding kinetics, it seemed to have influenced coordination at the heme iron, the hydration status of the active site, and the quaternary structure of AHb3. Evidence indicated that the N-terminus is the predominant factor regulating the quaternary interaction appropriate to physiological requirements, dynamics of the side chains in the heme pocket, and tunnel organization in the protein matrix. [ABSTRACT FROM AUTHOR]

Published

2016