Salt-bridge Dynamics in Intrinsically Disordered Proteins: A trade-off between electrostatic interactions and structural flexibility

Salt Bridge ◽

Disordered Proteins ◽

Salt Bridges ◽

Trade Off ◽

Local Rigidity ◽

Wide Range ◽

AbstractIntrinsically Disordered Proteins (IDPs) are enriched in charged and polar residues; and, therefore, electrostatic interactions play a predominant role in their dynamics. In order to remain multi-functional and exhibit their characteristic binding promiscuity, they need to retain considerable dynamic flexibility. At the same time, they also need to accommodate a large number of oppositely charged residues, which eventually lead to the formation of salt-bridges, imparting local rigidity. The formation of salt-bridges therefore oppose the desired dynamic flexibility. Hence, there appears to be a meticulous trade-off between the two mechanisms which the current study attempts to unravel. With this objective, we identify and analyze salt-bridges, both as isolated as well as composite ionic bond motifs, in the molecular dynamic trajectories of a set of appropriately chosen IDPs. Time evolved structural properties of these salt-bridges like persistence, associated secondary structural ′order-disorder′ transitions, correlated atomic movements, contribution in the overall electrostatic balance of the proteins have been studied in necessary detail. The results suggest that the key to maintain such a trade-off over time is the continuous formation and dissolution of salt-bridges with a wide range of persistence. Also, the continuous dynamic interchange of charged-atom-pairs (coming from a variety of oppositely charged side-chains) in the transient ionic bonds supports a model of dynamic flexibility concomitant with the well characterized stochastic conformational switching in these proteins. The results and conclusions should facilitate the future design of salt-bridges as a mean to further explore the disordered-globular interface in proteins.

Salt-bridge dynamics in intrinsically disordered proteins: A trade-off between electrostatic interactions and structural flexibility

Biochimica et Biophysica Acta (BBA) - Proteins and Proteomics ◽

10.1016/j.bbapap.2018.03.002 ◽

2018 ◽

Vol 1866 (5-6) ◽

pp. 624-641 ◽

Cited By ~ 9

Author(s):

Sankar Basu ◽

Parbati Biswas

Keyword(s):

Salt Bridge ◽

Disordered Proteins ◽

Structural Flexibility ◽

Trade Off ◽

Bridge Dynamics

Sequence Specificity Despite Intrinsic Disorder: How a Disease-Associated Val/Met Polymorphism Shifts Tertiary Interactions in a Long Disordered Protein

10.26434/chemrxiv.8135777.v1 ◽

2019 ◽

Author(s):

Ruchi Lohia ◽

Reza Salari ◽

Grace Brannigan

Keyword(s):

Secondary Structure ◽

Disordered Proteins ◽

Sequence Specificity ◽

Specific Effects ◽

Heterogeneous Polymer ◽

Non Local ◽

Dynamics Simulations

<div>The role of electrostatic interactions and mutations that change charge states in intrinsically disordered proteins (IDPs) is well-established, but many disease-associated mutations in IDPs are charge-neutral. The Val66Met single nucleotide polymorphism (SNP) encodes a hydrophobic-to-hydrophobic mutation at the midpoint of the prodomain of precursor brain-derived neurotrophic factor (BDNF), one of the earliest SNPs to be associated with neuropsychiatric disorders, for which the underlying molecular mechanism is unknown. Here we report on over 250 μs of fully-atomistic, explicit solvent, temperature replica exchange molecular dynamics simulations of the 91 residue BDNF prodomain, for both the V66 and M66 sequence.</div><div>The simulations were able to correctly reproduce the location of both local and non-local secondary changes due to the Val66Met mutation when compared with NMR spectroscopy. We find that the local structure change is mediated via entropic and sequence specific effects. We show that the highly disordered prodomain can be meaningfully divided into domains based on sequence alone. Monte Carlo simulations of a self-excluding heterogeneous polymer, with monomers representing each domain, suggest the sequence would be effectively segmented by the long, highly disordered polyampholyte near the sequence midpoint. This is qualitatively consistent with observed interdomain contacts within the BDNF prodomain, although contacts between the two segments are enriched relative to the self-excluding polymer. The Val66Met mutation increases interactions across the boundary between the two segments, due in part to a specific Met-Met interaction with a Methionine in the other segment. This effect propagates to cause the non-local change in secondary structure around the second methionine, previously observed in NMR. The effect is not mediated simply via changes in inter-domain contacts but is also dependent on secondary structure formation around residue 66, indicating a mechanism for secondary structure coupling in disordered proteins. </div>

Intrinsically disordered caldesmon binds calmodulin via the “buttons on a string” mechanism

PeerJ ◽

10.7717/peerj.1265 ◽

2015 ◽

Vol 3 ◽

pp. e1265 ◽

Cited By ~ 6

Author(s):

Sergei E. Permyakov ◽

Eugene A. Permyakov ◽

Vladimir N. Uversky

Keyword(s):

Local Structure ◽

String Model ◽

Electrostatic Attraction ◽

Disordered Proteins ◽

Wild Type ◽

Tryptophan Residues ◽

Specific Packing ◽

We show here that chicken gizzard caldesmon (CaD) and its C-terminal domain (residues 636–771, CaD136) are intrinsically disordered proteins. The computational and experimental analyses of the wild type CaD136and series of its single tryptophan mutants (W674A, W707A, and W737A) and a double tryptophan mutant (W674A/W707A) suggested that although the interaction of CaD136with calmodulin (CaM) can be driven by the non-specific electrostatic attraction between these oppositely charged molecules, the specificity of CaD136-CaM binding is likely to be determined by the specific packing of important CaD136tryptophan residues at the CaD136-CaM interface. It is suggested that this interaction can be described as the “buttons on a charged string” model, where the electrostatic attraction between the intrinsically disordered CaD136and the CaM is solidified in a “snapping buttons” manner by specific packing of the CaD136“pliable buttons” (which are the short segments of fluctuating local structure condensed around the tryptophan residues) at the CaD136-CaM interface. Our data also show that all three “buttons” are important for binding, since mutation of any of the tryptophans affects CaD136-CaM binding and since CaD136remains CaM-buttoned even when two of the three tryptophans are mutated to alanines.

Supramolecular Fuzziness of Intracellular Liquid Droplets: Liquid–Liquid Phase Transitions, Membrane-Less Organelles, and Intrinsic Disorder

Molecules ◽

10.3390/molecules24183265 ◽

2019 ◽

Vol 24 (18) ◽

pp. 3265 ◽

Cited By ~ 12

Author(s):

Vladimir N. Uversky

Keyword(s):

Phase Transitions ◽

Liquid Phase ◽

Intrinsically Disordered Protein ◽

Disordered Proteins ◽

Bacterial Cells ◽

Liquid Droplets ◽

Wide Range ◽

Characteristic Features

Cells are inhomogeneously crowded, possessing a wide range of intracellular liquid droplets abundantly present in the cytoplasm of eukaryotic and bacterial cells, in the mitochondrial matrix and nucleoplasm of eukaryotes, and in the chloroplast’s stroma of plant cells. These proteinaceous membrane-less organelles (PMLOs) not only represent a natural method of intracellular compartmentalization, which is crucial for successful execution of various biological functions, but also serve as important means for the processing of local information and rapid response to the fluctuations in environmental conditions. Since PMLOs, being complex macromolecular assemblages, possess many characteristic features of liquids, they represent highly dynamic (or fuzzy) protein–protein and/or protein–nucleic acid complexes. The biogenesis of PMLOs is controlled by specific intrinsically disordered proteins (IDPs) and hybrid proteins with ordered domains and intrinsically disordered protein regions (IDPRs), which, due to their highly dynamic structures and ability to facilitate multivalent interactions, serve as indispensable drivers of the biological liquid–liquid phase transitions (LLPTs) giving rise to PMLOs. In this article, the importance of the disorder-based supramolecular fuzziness for LLPTs and PMLO biogenesis is discussed.

Chasing coevolutionary signals in intrinsically disordered proteins complexes

Scientific Reports ◽

10.1038/s41598-020-74791-6 ◽

2020 ◽

Vol 10 (1) ◽

Author(s):

Javier A. Iserte ◽

Tamas Lazar ◽

Silvio C. E. Tosatto ◽

Peter Tompa ◽

Cristina Marino-Buslje

Keyword(s):

Protein Interactions ◽

Disordered Proteins ◽

Protein Protein Interactions ◽

Contact Prediction ◽

Regulatory Processes ◽

Wide Range ◽

Predict Protein Structure ◽

Biological Interpretation

Abstract Intrinsically disordered proteins/regions (IDPs/IDRs) are crucial components of the cell, they are highly abundant and participate ubiquitously in a wide range of biological functions, such as regulatory processes and cell signaling. Many of their important functions rely on protein interactions, by which they trigger or modulate different pathways. Sequence covariation, a powerful tool for protein contact prediction, has been applied successfully to predict protein structure and to identify protein–protein interactions mostly of globular proteins. IDPs/IDRs also mediate a plethora of protein–protein interactions, highlighting the importance of addressing sequence covariation-based inter-protein contact prediction of this class of proteins. Despite their importance, a systematic approach to analyze the covariation phenomena of intrinsically disordered proteins and their complexes is still missing. Here we carry out a comprehensive critical assessment of coevolution-based contact prediction in IDP/IDR complexes and detail the challenges and possible limitations that emerge from their analysis. We found that the coevolutionary signal is faint in most of the complexes of disordered proteins but positively correlates with the interface size and binding affinity between partners. In addition, we discuss the state-of-art methodology by biological interpretation of the results, formulate evaluation guidelines and suggest future directions of development to the field.

A Family of Small Intrinsically Disordered Proteins Involved in Flagellum-Dependent Motility inSalmonella enterica

Journal of Bacteriology ◽

10.1128/jb.00415-18 ◽

2018 ◽

Vol 201 (2) ◽

Cited By ~ 2

Author(s):

Tamiko Oguri ◽

Youjeong Kwon ◽

Jerry K. K. Woo ◽

Gerd Prehna ◽

Hyun Lee ◽

...

Keyword(s):

Expression Profiles ◽

Functional Characterization ◽

Disordered Proteins ◽

Wild Type ◽

Content Type ◽

Cellular Pathway ◽

Small Proteins ◽

Wide Range

ABSTRACTBy screening a collection ofSalmonellamutants deleted for genes encoding small proteins of ≤60 amino acids, we identified three paralogous small genes (ymdF,STM14_1829, andyciG) required for wild-type flagellum-dependent swimming and swarming motility. TheymdF,STM14_1829, andyciGgenes encode small proteins of 55, 60, and 60 amino acid residues, respectively. A bioinformatics analysis predicted that these small proteins are intrinsically disordered proteins, and circular dichroism analysis of purified recombinant proteins confirmed that all three proteins are unstructured in solution. A mutant deleted for STM14_1829 showed the most severe motility defect, indicating that among the three paralogs, STM14_1829 is a key protein required for wild-type motility. We determined that relative to the wild type, the expression of the flagellin protein FliC is lower in the ΔSTM14_1829mutant due to the downregulation of theflhDCoperon encoding the FlhDC master regulator. By comparing the gene expression profiles between the wild-type and ΔSTM14_1829strains via RNA sequencing, we found that the gene encoding the response regulator PhoP is upregulated in the ΔSTM14_1829mutant, suggesting the indirect repression of theflhDCoperon by the activated PhoP. Homologs of STM14_1829 are conserved in a wide range of bacteria, includingEscherichia coliandPseudomonas aeruginosa. We showed that the inactivation of STM14_1829 homologs inE. coliandP. aeruginosaalso alters motility, suggesting that this family of small intrinsically disordered proteins may play a role in the cellular pathway(s) that affects motility.IMPORTANCEThis study reports the identification of a novel family of small intrinsically disordered proteins that are conserved in a wide range of flagellated and nonflagellated bacteria. Although this study identifies the role of these small proteins in the scope of flagellum-dependent motility inSalmonella, they likely play larger roles in a more conserved cellular pathway(s) that indirectly affects flagellum expression in the case of motile bacteria. Small intrinsically disordered proteins have not been well characterized in prokaryotes, and the results of our study provide a basis for their detailed functional characterization.

Ion Mobility Mass Spectrometry Uncovers the Impact of the Patterning of Oppositely Charged Residues on the Conformational Distributions of Intrinsically Disordered Proteins

Journal of the American Chemical Society ◽

10.1021/jacs.8b13483 ◽

2019 ◽

Vol 141 (12) ◽

pp. 4908-4918 ◽

Cited By ~ 21

Author(s):

Rebecca Beveridge ◽

Lukasz G. Migas ◽

Rahul K. Das ◽

Rohit V. Pappu ◽

Richard W. Kriwacki ◽

...

Keyword(s):

Mass Spectrometry ◽

Ion Mobility ◽

Disordered Proteins ◽

Ion Mobility Mass Spectrometry ◽

Charged Residues ◽

The Impact ◽

Ion Mobility Mass Spectrometry Uncovers the Impact of the Patterning of Oppositely Charged Residues on the Conformational Distributions of Intrinsically Disordered Proteins

10.26434/chemrxiv.7312277.v1 ◽

2018 ◽

Cited By ~ 2

Author(s):

Rebecca Beveridge ◽

Lukasz Migas ◽

Rahul Das ◽

Rohit Pappu ◽

Richard Kriwacki ◽

...

Keyword(s):

Mass Spectrometry ◽

Ion Mobility ◽

Disordered Proteins ◽

Ion Mobility Mass Spectrometry ◽

Conformational Heterogeneity ◽

Wild Type ◽

Charged Residues ◽

The global dimensions and amplitudes of conformational fluctuations of intrinsically disordered proteins are governed, in part, by the linear segregation versus clustering of oppositely charged residues within the primary sequence. Ion Mobility-Mass Spectrometry (IM-MS) affords unique advantages for probing the conformational consequences of the linear patterning of oppositely charged residues because it measures and separates proteins electrosprayed from solution on the basis of charge and shape. Here, we use IM-MS to measure the conformational consequences of charge patterning on the C-terminal intrinsically disordered region (p27 IDR) of the cell cycle inhibitory protein p27<sup>Kip1</sup>. We report the range of charge states and accompanying collisional cross section distributions for wild-type p27 IDR and two variants with identical amino acid compositions, k14 and k56, distinguished by the extent of linear mixing versus segregation of oppositely charged residues. Wild-type p27 IDR (k31) and k14 where the oppositely charged residues are more evenly distributed, exhibit a broad distribution of charge states. This is concordant with high degrees of conformational heterogeneity in solution. By contrast, k56 with linear segregation of oppositely charged residues, leads to limited conformational heterogeneity and a narrow distribution of charged states. Molecular dynamics simulations demonstrate that the interplay between chain solvation and intra-chain interactions (self-solvation) leads to conformational distributions that are modulated by salt concentration, with the wild-type sequence showing the most sensitivity to changes in salt concentration. These results suggest that the charge patterning within the wild-type p27 IDR may be optimized to sample both highly solvated and self-solvated conformational states.

The Effect of Multisite Phosphorylation on the Conformational Properties of Intrinsically Disordered Proteins

International Journal of Molecular Sciences ◽

10.3390/ijms222011058 ◽

2021 ◽

Vol 22 (20) ◽

pp. 11058

Author(s):

Ellen Rieloff ◽

Marie Skepö

Keyword(s):

Disordered Proteins ◽

Salt Bridges ◽

Local Contraction ◽

Charged Residues ◽

Common Strategy ◽

Disordered Peptides ◽

Dynamics Simulations ◽

The Impact

Intrinsically disordered proteins are involved in many biological processes such as signaling, regulation, and recognition. A common strategy to regulate their function is through phosphorylation, as it can induce changes in conformation, dynamics, and interactions with binding partners. Although phosphorylated intrinsically disordered proteins have received increased attention in recent years, a full understanding of the conformational and structural implications of phosphorylation has not yet been achieved. Here, we present all-atom molecular dynamics simulations of five disordered peptides originated from tau, statherin, and β-casein, in both phosphorylated and non-phosphorylated state, to compare changes in global dimensions and structural elements, in an attempt to gain more insight into the controlling factors. The changes are in qualitative agreement with experimental data, and we observe that the net charge is not enough to predict the impact of phosphorylation on the global dimensions. Instead, the distribution of phosphorylated and positively charged residues throughout the sequence has great impact due to the formation of salt bridges. In statherin, a preference for arginine–phosphoserine interaction over arginine–tyrosine accounts for a global expansion, despite a local contraction of the phosphorylated region, which implies that also non-charged residues can influence the effect of phosphorylation.

Charge fluctuation effects on the shape of flexible polyampholytes with applications to Intrinsically disordered proteins

10.1101/301911 ◽

2018 ◽

Author(s):

Himadri S. Samanta ◽

Debayan Chakraborty ◽

D. Thirumalai

Keyword(s):

Debye Length ◽

Disordered Proteins ◽

Radius Of Gyration ◽

Charge Fluctuation ◽

Net Charge ◽

X Ray Scattering ◽

Theoretical Predictions

Random polyampholytes (PAs) contain positively and negatively charged monomers that are distributed randomly along the polymer chain. The interaction between charges is assumed to be given by the Debye-Huckel potential. We show that the size of the PA is determined by an interplay between electrostatic interactions, giving rise to the polyelectrolyte (PE) effect due to net charge per monomer (σ), and an effective attractive PA interaction due to charge fluctuations, δσ. The interplay between these terms gives rise to non-monotonic dependence of the radius of gyration, Rg on the inverse Debye length, κ when PA effects are important . In the opposite limit, Rg decreases monotonically with increasing κ. Simulations of PA chains, using a charged bead-spring model, further corroborates our theoretical predictions. The simulations unambiguously show that conformational heterogeneity manifests itself among sequences that have identical PA parameters. A clear implication is that the phases of PA sequences, and by inference IDPs, cannot be determined using only the bare PA parameters (σ and δσ).The theory is used to calculate the changes in Rg on N, the number of residues for a set of Intrinsically Disordered Proteins (IDPs). For a certain class of IDPs, with N between 24 to 441, the size grows as Rg ~ N0.6, which agrees with data from Small Angle X-ray Scattering (SAXS) experiments.