Characterization of cysteine thiol modifications based on protein microenvironments and local secondary structures

Bhatnagar, Akshay; Bandyopadhyay, Debashree

doi:10.1002/prot.25424

Cited by 17 publications

(18 citation statements)

References 74 publications

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“…These different pathways do not necessarily take place in the same cellular and protein environment. Thus, it is especially difficult to describe the microenvironment properties driving the specificity of S -nitrosylation sites ( 4 , 14 , 119 , 120 ).…”

Section: Computational Structural and Chemical Studies Of Smentioning

confidence: 99%

Computational Structural Biology of S-nitrosylation of Cancer Targets

et al. 2018

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Nitric oxide (NO) plays an essential role in redox signaling in normal and pathological cellular conditions. In particular, it is well known to react in vivo with cysteines by the so-called S-nitrosylation reaction. S-nitrosylation is a selective and reversible post-translational modification that exerts a myriad of different effects, such as the modulation of protein conformation, activity, stability, and biological interaction networks. We have appreciated, over the last years, the role of S-nitrosylation in normal and disease conditions. In this context, structural and computational studies can help to dissect the complex and multifaceted role of this redox post-translational modification. In this review article, we summarized the current state-of-the-art on the mechanism of S-nitrosylation, along with the structural and computational studies that have helped to unveil its effects and biological roles. We also discussed the need to move new steps forward especially in the direction of employing computational structural biology to address the molecular and atomistic details of S-nitrosylation. Indeed, this redox modification has been so far an underappreciated redox post-translational modification by the computational biochemistry community. In our review, we primarily focus on S-nitrosylated proteins that are attractive cancer targets due to the emerging relevance of this redox modification in a cancer setting.

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Section: Computational Structural and Chemical Studies Of Smentioning

confidence: 99%

Computational Structural Biology of S-nitrosylation of Cancer Targets

et al. 2018

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“…However, the pK a value can be significantly affected by the microenvironment of the cysteine (Bhatnagar & Bandyopadhyay, 2018;Klomsiri et al, 2011). For example, metal-binding enzymatic cysteines were shown to exhibit a lower range of pK a values (8.1 AE 2.2) when buried in a hydrophobic cluster (Bhatnagar & Bandyopadhyay, 2018). Furthermore, BME exhibits decreased stability as the pH increases, which can lead to the formation of covalent adducts with surface cysteines (Wingfield, 1995).…”

Section: Discussionmentioning

confidence: 99%

Crystal structure of human CRM1, covalently modified by 2-mercaptoethanol on Cys528, in complex with RanGTP

2021

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CRM1 is a nuclear export receptor that has been intensively targeted over the last decade for the development of antitumor and antiviral drugs. Structural analysis of several inhibitor compounds bound to CRM1 revealed that their mechanism of action relies on the covalent modification of a critical cysteine residue (Cys528 in the human receptor) located in the nuclear export signal-binding cleft. This study presents the crystal structure of human CRM1, covalently modified by 2-mercaptoethanol on Cys528, in complex with RanGTP at 2.58 Å resolution. The results demonstrate that buffer components can interfere with the characterization of cysteine-dependent inhibitor compounds.

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“…63 The keyword sea- The feature, pKa, has been identified as one of the important parameters for cysteine function predictions. 51,54 However, pKa computed using PROPKA has a predefined value of 99.99 for disulphide connectivity. This fixed pKa value for disuphide from PROPKA makes the deep learning model circular in nature.…”

Section: Test Dataset Generationmentioning

confidence: 99%

“…Earlier we have annotated four cysteine functions, namely, disulphide, thioether, metal-binding, and sulphenylation, based on protein structural properties, like, buried fraction, quantitative microenvironment descriptor (rHpy), secondary structure, and pKa values. [54][55][56] Only these four modifications were chosen because of their abundance in PDB crystal structures. Inspired by these functional annotations of cysteine, here we propose a deep neural network-based model, DeepCys, that exploits six different protein features, and predict any one of these four different cysteine modifications.…”

Section: Introductionmentioning

confidence: 99%

DeepCys: Structure‐based multiple cysteine function prediction method trained on deep neural network: Case study on domains of unknown functions belonging to COX2 domains

et al. 2021

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Cysteine (Cys) is the most reactive amino acid participating in a wide range of biological functions. In-silico predictions complement the experiments to meet the need of functional characterization. Multiple Cys function prediction algorithm is scarce, in contrast to specific function prediction algorithms. Here we present a deep neural network-based multiple Cys function prediction, available on web-server (DeepCys) (https://deepcys.herokuapp.com/). DeepCys model was trained and tested on two independent datasets curated from protein crystal structures. This prediction method requires three inputs, namely, PDB identifier (ID), chain ID and residue ID for a given Cys and outputs the probabilities of four cysteine functions, namely, disulphide, metal-binding, thioether and sulphenylation and predicts the most probable Cys function. The algorithm exploits the local and global protein properties, like, sequence and secondary structure motifs, buried fractions, microenvironments and protein/ enzyme class. DeepCys outperformed most of the multiple and specific Cys function algorithms. This method can predict maximum number of cysteine functions. Moreover, for the first time, explicitly predicts thioether function. This tool was used to elucidate the cysteine functions on domains of unknown functions belonging to cytochrome C oxidase subunit-II like transmembrane domains.

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Characterization of cysteine thiol modifications based on protein microenvironments and local secondary structures

Cited by 17 publications

References 74 publications

Computational Structural Biology of S-nitrosylation of Cancer Targets

Computational Structural Biology of S-nitrosylation of Cancer Targets

Crystal structure of human CRM1, covalently modified by 2-mercaptoethanol on Cys528, in complex with RanGTP

DeepCys: Structure‐based multiple cysteine function prediction method trained on deep neural network: Case study on domains of unknown functions belonging to COX2 domains

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