Lysine Side-Chain Dynamics in the Binding Site of Homeodomain/DNA Complexes As Observed by NMR Relaxation Experiments and Molecular Dynamics Simulations

Baird-Titus, Jamie M.; Thapa, Mahendra; Doerdelmann, Thomas; Combs, Kelly A.; Rance, Mark

doi:10.1021/acs.biochem.8b00195

Cited by 11 publications

(10 citation statements)

References 118 publications

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“…We believe that other interesting aspects of protein disorder can be brought to light by a combination of NMR experiments and carefully designed MD studies. In particular, such a synergistic approach can be used to investigate the molten-globule state of proteins, the so-called ''fuzzy complexes'' (including complexes of disordered proteins with nucleic acids), electrostatic encounter complexes, models of folding intermediates, chemically denatured proteins, interdomain linkers, peptides with significant helical propensity (potentially experiencing helix-coil transitions), proline-rich peptides, and other highly variable systems (112)(113)(114)(115)(116)(117)(118)(119)(120).…”

Section: Resultsmentioning

confidence: 99%

What Drives 15N Spin Relaxation in Disordered Proteins? Combined NMR/MD Study of the H4 Histone Tail

Kämpf

Izmailov

Rabdano

et al. 2018

Biophysical Journal

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Backbone ( 15 N) NMR relaxation is one of the main sources of information on dynamics of disordered proteins. Yet, we do not know very well what drives 15 N relaxation in such systems, i.e., how different forms of motion contribute to the measurable relaxation rates. To address this problem, we have investigated, both experimentally and via molecular dynamics simulations, the dynamics of a 26-residue peptide imitating the N-terminal portion of the histone protein H4. One part of the peptide was found to be fully flexible, whereas the other part features some transient structure (a hairpin stabilized by hydrogen bonds). The following motional modes proved relevant for 15 N relaxation. 1) Sub-picosecond librations attenuate relaxation rates according to S 2 $0.85-0.90. 2) Axial peptide-plane fluctuations along a stretch of the peptide chain contribute to relaxation-active dynamics on a fast timescale (from tens to hundreds of picoseconds). 3) 4/j backbone jumps contribute to relaxation-active dynamics on both fast (from tens to hundreds of picoseconds) and slow (from hundreds of picoseconds to a nanosecond) timescales. The major contribution is from polyproline II (PPII) 4 b transitions in the Ramachandran space; in the case of glycine residues, the major contribution is from PPII 4 (b) 4 rPPII transitions, in which rPPII is the mirror-image (right-handed) version of the PPII geometry, whereas b geometry plays the role of an intermediate state. 4) Reorientational motion of certain (sufficiently long-lived) elements of transient structure, i.e., rotational tumbling, contributes to slow relaxation-active dynamics on $1-ns timescale (however, it is difficult to isolate this contribution). In conclusion, recent advances in the area of force-field development have made it possible to obtain viable Molecular Dynamics models of protein disorder. After careful validation against the experimental relaxation data, these models can provide a valuable insight into mechanistic origins of spin relaxation in disordered peptides and proteins.

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Section: Resultsmentioning

confidence: 99%

What Drives 15N Spin Relaxation in Disordered Proteins? Combined NMR/MD Study of the H4 Histone Tail

Kämpf

Izmailov

Rabdano

et al. 2018

Biophysical Journal

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“…Baired et al [95] made use of the NMR/MD combination to characterize protein-DNA interactions at hand of lysine side-chain 15 N-relaxation measurements and comparison to lysine dihedral angles obtained from a molecular dynamics trajectory. Thus, they could quantify the residual conformational freedom of charged lysine amines in TF-DNA complexes.…”

Section: Combining Nmr and MD Simulationsmentioning

confidence: 99%

How to assess the structural dynamics of transcription factors by integrating sparse NMR and EPR constraints with molecular dynamics simulations

Kozak

Kurzbach

2021

Computational and Structural Biotechnology Journal

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“…Solution NMR studies of Arg and Lys side chains at the protein–DNA/RNA interfaces showed that basic side chains interacting with phosphate groups are generally more mobile than basic side chains interacting with nucleotide bases. 12 , 59 , 64 − 68 This difference in mobility may be related to steric restriction and other interactions in the grooves compared with those with the phosphate. More importantly, however, the dynamic equilibria between the CIP state and the solvent-separated ion pair (SIP) enhance the mobility of basic side chains forming ion pairs with phosphates ( Figure 4 A).…”

Section: Dynamics Of Macromolecular Ion Pairsmentioning

confidence: 99%

Dynamics of Ionic Interactions at Protein–Nucleic Acid Interfaces

Pettitt

Iwahara

2020

Acc. Chem. Res.

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Conspectus Molecular association of proteins with nucleic acids is required for many biological processes essential to life. Electrostatic interactions via ion pairs (salt bridges) of nucleic acid phosphates and protein side chains are crucial for proteins to bind to DNA or RNA. Counterions around the macromolecules are also key constituents for the thermodynamics of protein–nucleic acid association. Until recently, there had been only a limited amount of experiment-based information about how ions and ionic moieties behave in biological macromolecular processes. In the past decade, there has been significant progress in quantitative experimental research on ionic interactions with nucleic acids and their complexes with proteins. The highly negatively charged surfaces of DNA and RNA electrostatically attract and condense cations, creating a zone called the ion atmosphere. Recent experimental studies were able to examine and validate theoretical models on ions and their mobility and interactions with macromolecules. The ionic interactions are highly dynamic. The counterions rapidly diffuse within the ion atmosphere. Some of the ions are released from the ion atmosphere when proteins bind to nucleic acids, balancing the charge via intermolecular ion pairs of positively charged side chains and negatively charged backbone phosphates. Previously, the release of counterions had been implicated indirectly by the salt-concentration dependence of the association constant. Recently, direct detection of counterion release by NMR spectroscopy has become possible and enabled more accurate and quantitative analysis of the counterion release and its entropic impact on the thermodynamics of protein–nucleic acid association. Recent studies also revealed the dynamic nature of ion pairs of protein side chains and nucleic acid phosphates. These ion pairs undergo transitions between two major states. In one of the major states, the cation and the anion are in direct contact and form hydrogen bonds. In the other major state, the cation and the anion are separated by water. Transitions between these states rapidly occur on a picosecond to nanosecond time scale. When proteins interact with nucleic acids, interfacial arginine (Arg) and lysine (Lys) side chains exhibit considerably different behaviors. Arg side chains show a higher propensity to form rigid contacts with nucleotide bases, whereas Lys side chains tend to be more mobile at the molecular interfaces. The dynamic ionic interactions may facilitate adaptive molecular recognition and play both thermodynamic and kinetic roles in protein–nucleic acid interactions.

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Lysine Side-Chain Dynamics in the Binding Site of Homeodomain/DNA Complexes As Observed by NMR Relaxation Experiments and Molecular Dynamics Simulations

Cited by 11 publications

References 118 publications

What Drives 15N Spin Relaxation in Disordered Proteins? Combined NMR/MD Study of the H4 Histone Tail

What Drives 15N Spin Relaxation in Disordered Proteins? Combined NMR/MD Study of the H4 Histone Tail

How to assess the structural dynamics of transcription factors by integrating sparse NMR and EPR constraints with molecular dynamics simulations

Dynamics of Ionic Interactions at Protein–Nucleic Acid Interfaces

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