Native-state dynamics of the ubiquitin family: implications for function and evolution

Marianayagam, Neelan J.; Jackson, Sophie

doi:10.1098/rsif.2004.0025

Cited by 15 publications

(17 citation statements)

References 26 publications

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“…Generally, the first three PCs describe a consistent part of the protein dynamics, and they could be used as a reference subspace to analyze protein motion (30,63). The projection of frames of concatenated simulation into the subspace defined by three-first PCs was reported in Figure S1, confirming and clarifying results obtained from cluster analysis.…”

Section: Essential Dynamics and Samplingsupporting

confidence: 71%

A Conformational Analysis Study on the Melanocortin 4 Receptor Using Multiple Molecular Dynamics Simulations

Shahlaei

Mousavi

2015

Chem Biol Drug Des

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Taking into account the uncertainties involved in 3D model of biomolecule developed by homology modeling (HM), it is important to opportunely validate the initial structure before employing for different purposes such as drug design. Extended simulation times and the necessity of correct representation of interactions within the protein and the nearby molecules impose significant limitations on molecular dynamics (MD)-based refinement of structures developed by HM. Consequently, there is a pressing requirement for more efficient methods for HM and subsequent validation of developed structure. Multiple MD simulation runs are well suited for producing ensembles of structures. In this context, a computational investigation was presented to study the structure of melanocortin 4 receptor (MC4R) using molecular dynamics (MD) simulations in explicit phospholipids bilayer. Several MD runs with different initial velocities were employed to sample conformations in the neighborhood of the native structure of receptor, collecting trajectories spanning 0.21 ms. The coherence between the results, different structural analysis, and the convergence of parameters derived by principal component analysis (PCA) shows that an accurate description of the MC4R conformational space around the native state was achieved by multiple MD trajectories.

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Section: Essential Dynamics and Samplingsupporting

confidence: 71%

A Conformational Analysis Study on the Melanocortin 4 Receptor Using Multiple Molecular Dynamics Simulations

Shahlaei

Mousavi

2015

Chem Biol Drug Des

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“…This could be due to a lack of extensive characterization of conformational flexibility of native‐state in SUMO systems. Native‐state landscape of ubiquitin has been explored both by experimental as well as computational means, but only a few such reports are available in case of SUMO proteins …”

Section: Introductionmentioning

confidence: 99%

NMR characterization of conformational fluctuations and noncovalent interactions of SUMO protein from Drosophila melanogaster (dSmt3)

et al. 2019

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Structural heterogeneity in the native‐state ensemble of dSmt3, the only small ubiquitin‐like modifier (SUMO) in Drosophila melanogaster, was investigated and compared with its human homologue SUMO1. Temperature dependence of amide proton's chemical shift was studied to identify amino acids possessing alternative structural conformations in the native state. Effect of small concentration of denaturant (1M urea) on this population was also monitored to assess the ruggedness of near‐native energy landscape. Owing to presence of many such amino acids, especially in the β2‐loop‐α region, the native state of dSmt3 seems more flexible in comparison to SUMO1. Information about backbone dynamics in ns‐ps timescale was quantified from the measurement of 15N‐relaxation experiments. Furthermore, the noncovalent interaction of dSmt3 and SUMO1 with Daxx12 (Daxx729DPEEIIVLSDSD740), a [V/I]‐X‐[V/I]‐[V/I]‐based SUMO interaction motif, was characterized using Bio‐layer Interferometery and NMR spectroscopy. Daxx12 fits itself in the groove formed by β2‐loop‐α structural region in both dSmt3 and SUMO1, but the binding is stronger with the former. Flexibility of β2‐loop‐α region in dSmt3 is suspected to assist its interaction with Daxx12. Our results highlight the role of native‐state flexibility in assisting noncovalent interactions of SUMO proteins especially in organisms where a single SUMO isoform has to tackle multiple substrates single handedly.

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“…It generates a static picture of a protein and, in general, provides little information on protein dynamics. Experimentally, a number of different nuclear magnetic resonance (NMR) techniques have been used to obtain information on the molecular motions within proteins on different time scales [8]. The number of proteins on which such studies can be performed, however, is limited.…”

Section: Introductionmentioning

confidence: 99%

“…The use of computer simulations to probe protein internal motions, using existing structural information, is, therefore, proving extremely fruitful. However, in order to extract useful information about the dynamics observed during the course of these simulations, mathematical models must be employed [8].…”

Section: Introductionmentioning

confidence: 99%

Conformational flexibility decreased due to Y67F and F82H mutations in cytochrome c: Molecular dynamics simulation studies

Singh¹,

Prakash²,

Vasu

et al. 2009

Journal of Molecular Graphics and Modelling

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Native-state dynamics of the ubiquitin family: implications for function and evolution

Cited by 15 publications

References 26 publications

A Conformational Analysis Study on the Melanocortin 4 Receptor Using Multiple Molecular Dynamics Simulations

A Conformational Analysis Study on the Melanocortin 4 Receptor Using Multiple Molecular Dynamics Simulations

NMR characterization of conformational fluctuations and noncovalent interactions of SUMO protein from Drosophila melanogaster (dSmt3)

Conformational flexibility decreased due to Y67F and F82H mutations in cytochrome c: Molecular dynamics simulation studies

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