How Reactive are Druggable Cysteines in Protein Kinases?

Targeted covalent inhibitors (TCIs) have been successfully developed as high-affinity and selective inhibitors of enzymes of the protein kinase family. These drugs typically act by undergoing an electrophilic addition with an active-site cysteine residue, so design of a TCI begins with the identific...

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Veröffentlicht in:	Journal of chemical information and modeling 2018-09, Vol.58 (9), p.1935-1946
Hauptverfasser:	Awoonor-Williams, Ernest, Rowley, Christopher N
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Sprache:	eng
Schlagworte:	Binding sites Chemical reactions Computation Computer simulation Cysteine Gluten Inhibitors Kinases Molecular dynamics Mutation Proteins Residues Solvents
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container_end_page	1946
container_issue	9
container_start_page	1935
container_title	Journal of chemical information and modeling
container_volume	58
creator	Awoonor-Williams, Ernest Rowley, Christopher N
description	Targeted covalent inhibitors (TCIs) have been successfully developed as high-affinity and selective inhibitors of enzymes of the protein kinase family. These drugs typically act by undergoing an electrophilic addition with an active-site cysteine residue, so design of a TCI begins with the identification of a “druggable” cysteine. These electrophilic additions generally require deprotonation of the thiol to form a reactive anionic thiolate, so the acidity of the residue is a critical factor. Few experimental measurements of the pK a’s of druggable cysteines have been reported, so computational prediction could prove to be very important in selecting reactive cysteine targets. Here we report the computed pK a’s of druggable cysteines in selected protein kinases that are of clinical relevance for targeted therapies. The pK a’s of the cysteines were calculated using advanced computational methods based on all-atom replica-exchange thermodynamic integration molecular dynamics simulations in explicit solvent. We found that the acidities of druggable cysteines within protein kinases are diverse and elevated, indicating enormous differences in their reactivity. Constant-pH molecular dynamics simulations were also performed on selected protein kinases, and the results confirmed this varied range in the acidities of druggable cysteines. Many of these active-site cysteines have low exposure to solvent molecules, elevating their pK a values. Electrostatic interactions with nearby anionic residues also elevate the pK a’s of cysteine residues in the active site. The results suggest that some cysteine residues within kinase binding sites will be slow to react with a TCI because of their low acidity. Several oncogenic kinase mutations were also modeled and found to have pK a’s similar to that of the wild-type kinase.
doi_str_mv	10.1021/acs.jcim.8b00454
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These drugs typically act by undergoing an electrophilic addition with an active-site cysteine residue, so design of a TCI begins with the identification of a “druggable” cysteine. These electrophilic additions generally require deprotonation of the thiol to form a reactive anionic thiolate, so the acidity of the residue is a critical factor. Few experimental measurements of the pK a’s of druggable cysteines have been reported, so computational prediction could prove to be very important in selecting reactive cysteine targets. Here we report the computed pK a’s of druggable cysteines in selected protein kinases that are of clinical relevance for targeted therapies. The pK a’s of the cysteines were calculated using advanced computational methods based on all-atom replica-exchange thermodynamic integration molecular dynamics simulations in explicit solvent. We found that the acidities of druggable cysteines within protein kinases are diverse and elevated, indicating enormous differences in their reactivity. Constant-pH molecular dynamics simulations were also performed on selected protein kinases, and the results confirmed this varied range in the acidities of druggable cysteines. Many of these active-site cysteines have low exposure to solvent molecules, elevating their pK a values. Electrostatic interactions with nearby anionic residues also elevate the pK a’s of cysteine residues in the active site. The results suggest that some cysteine residues within kinase binding sites will be slow to react with a TCI because of their low acidity. 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Chem. Inf. Model</addtitle><description>Targeted covalent inhibitors (TCIs) have been successfully developed as high-affinity and selective inhibitors of enzymes of the protein kinase family. These drugs typically act by undergoing an electrophilic addition with an active-site cysteine residue, so design of a TCI begins with the identification of a “druggable” cysteine. These electrophilic additions generally require deprotonation of the thiol to form a reactive anionic thiolate, so the acidity of the residue is a critical factor. Few experimental measurements of the pK a’s of druggable cysteines have been reported, so computational prediction could prove to be very important in selecting reactive cysteine targets. Here we report the computed pK a’s of druggable cysteines in selected protein kinases that are of clinical relevance for targeted therapies. 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Chem. Inf. Model</addtitle><date>2018-09-24</date><risdate>2018</risdate><volume>58</volume><issue>9</issue><spage>1935</spage><epage>1946</epage><pages>1935-1946</pages><issn>1549-9596</issn><eissn>1549-960X</eissn><abstract>Targeted covalent inhibitors (TCIs) have been successfully developed as high-affinity and selective inhibitors of enzymes of the protein kinase family. These drugs typically act by undergoing an electrophilic addition with an active-site cysteine residue, so design of a TCI begins with the identification of a “druggable” cysteine. These electrophilic additions generally require deprotonation of the thiol to form a reactive anionic thiolate, so the acidity of the residue is a critical factor. Few experimental measurements of the pK a’s of druggable cysteines have been reported, so computational prediction could prove to be very important in selecting reactive cysteine targets. 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subjects	Binding sites Chemical reactions Computation Computer simulation Cysteine Gluten Inhibitors Kinases Molecular dynamics Mutation Proteins Residues Solvents
title	How Reactive are Druggable Cysteines in Protein Kinases?
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