Interactions of Granisetron with an Agonist-Free 5-HT<sub>3A</sub> Receptor Model

Joshi, Prasad; Suryanarayanan, Asha; Hazai, Eszter; Schulte, Marvin K.; Maksay, Gábor; Bikádi, Zsolt

doi:10.1021/bi051676f

Cited by 29 publications

(41 citation statements)

References 31 publications

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“…For H185 a substitution to cysteine would also conserve its side-chain interactions as both residues are capable of hydrogen bonding. However, it was previously reported that mutations at this location reduce cell-surface expression, and the lower B max value we measured for granisetron (H185C = 123 ± 23 fmol mg −1 ; wild type = 4843 ± 512 fmol mg −1 ; paired samples, n = 4) is consistent with this (Joshi et al., 2006, Thompson et al., 2008). For tropisetron it is therefore possible that the absence of binding does not reveal interactions but, given the higher levels of non-specific binding, instead reveals expression levels that are below the threshold for detection.…”

Section: Discussionsupporting

confidence: 92%

The binding orientations of structurally-related ligands can differ; A cautionary note

et al. 2017

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Crystal structures can identify ligand-receptor interactions and assist the development of novel therapeutics, but experimental challenges sometimes necessitate the use of homologous proteins. Tropisetron is an orthosteric ligand at both 5-HT3 and α7 nACh receptors and its binding orientation has been determined in the structural homologue AChBP (pdbid: 2WNC). Co-crystallisation with a structurally-related ligand, granisetron, reveals an almost identical orientation (pdbid; 2YME). However, there is a >1000-fold difference in the affinity of tropisetron at 5-HT3 versus α7 nACh receptors, and α7 nACh receptors do not bind granisetron. These striking pharmacological differences prompt questions about which receptor the crystal structures most closely represent and whether the ligand orientations are correct. Here we probe the binding orientation of tropisetron and granisetron at 5-HT3 receptors by in silico modelling and docking, radioligand binding on cysteine-substituted 5-HT3 receptor mutants transiently expressed in HEK 293 cells, and synthetic modification of the ligands. For 15 of the 23 cysteine substitutions, the effects on tropisetron and granisetron were different. Structure-activity relationships on synthesised derivatives of both ligands were also consistent with different orientations, revealing that contrary to the crystallographic evidence from AChBP, the two ligands adopt different orientations in the 5-HT3 receptor binding site. Our results show that even quite structurally similar molecules can adopt different orientations in the same binding site, and that caution may be needed when using homologous proteins to predict ligand binding.

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Section: Discussionsupporting

confidence: 92%

The binding orientations of structurally-related ligands can differ; A cautionary note

et al. 2017

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“…How can we decide which docking position is relevant in binding? The docking vicinity of the distal piperazinyl tertiary amino group of compounds 2 and 32 to N128 is in agreement with the docking vicinity of the analogous granatane amino group of granisetron, a 5-HT 3 R antagonist (K i = 0.20 nM) [30], to N128 [27]. Overlapping docking positions of active and inactive derivatives were considered artefacts, while the similar dockings of the active ones support similar binding modes associated with high affinity.…”

Section: -Ht 3a R Modellingsupporting

confidence: 74%

“…This was based on the building of a homology model of 3A -type 5-HT receptors (5-HT 3A Rs), obtained from the electron microscopic structure of the nACh receptor with agonist-free binding cavities at 4 resolution [27]. This was based on the building of a homology model of 3A -type 5-HT receptors (5-HT 3A Rs), obtained from the electron microscopic structure of the nACh receptor with agonist-free binding cavities at 4 resolution [27].…”

Section: -Ht 3a R Modellingmentioning

confidence: 99%

“…The homology model of 5-HT 3A Rs based on the structure of nACh receptors with an agonist-free (empty) binding cavity [27] is an improvement compared to previous models involving an acetylcholine-binding protein [28] where, according to an emerging consensus, bound agonists "pull in" loop C to close the binding cavity. In contrast, the open binding cavity can accommodate 5-HT 3 RAs in more docking positions [27].…”

Section: -Ht 3a R Modellingmentioning

confidence: 99%

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Synthesis and Receptor Binding of New Thieno[2,3‐d]‐pyrimidines as Selective Ligands of 5‐HT₃Receptors

Modica¹,

Romeo

Salerno

et al. 2008

Archiv der Pharmazie

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With the aim to develop new potent and selective ligands of 5-HT(3)-type serotonin receptors and to acquire more information on their structure-affinity relationships, new thieno[2,3-d]pyrimidine derivatives 32-39 were synthesized and their binding to 5-HT(3) versus 5-HT(4 )receptors was studied. Some of these new compounds exhibit good affinity for cortical 5-HT(3) receptors, but not for 5-HT(4) receptors. Among these derivatives, 6-ethyl-4-(4-methyl-1-piperazinyl)-2-(methylthio)thieno[2,3-d]pyrimidine 32 is the most potent ligand (K(i) = 67 nM); it behaves as a competitive antagonist of the 5-HT(3) receptor function in the guinea pig colon. Its binding interactions with 5-HT(3A )receptors were analysed by using receptor modelling and comparative docking.

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“…Docking studies using homology models have found multiple energetically favorable poses of the antagonist granisetron within this binding site, and the orientation of the drug and the identities of the interacting residues are not constant across poses. 11–14 For example, Thompson et. al.…”

Section: Introductionmentioning

confidence: 99%

Ondansetron and Granisetron Binding Orientation in the 5-HT₃ Receptor Determined by Unnatural Amino Acid Mutagenesis

2012

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The serotonin type 3 receptor (5-HT3R) is a ligand-gated ion channel that mediates fast synaptic transmission in the central and peripheral nervous systems. The 5-HT3R is a therapeutic target, and the clinically available drugs ondansetron and granisetron inhibit receptor activity. Their inhibitory action is through competitive binding to the native ligand binding site, although the binding orientation of the drugs at the receptor has been a matter of debate. Here we heterologously express mouse 5-HT3A receptors in Xenopus oocytes and use unnatural amino acid mutagenesis to establish a cation-π interaction for both ondansetron and granisetron to tryptophan 183 in the ligand binding pocket. This cation-π interaction establishes a binding orientation for both ondansetron and granisetron within the binding pocket.

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Interactions of Granisetron with an Agonist-Free 5-HT_3A Receptor Model

Cited by 29 publications

References 31 publications

The binding orientations of structurally-related ligands can differ; A cautionary note

The binding orientations of structurally-related ligands can differ; A cautionary note

Synthesis and Receptor Binding of New Thieno[2,3‐d]‐pyrimidines as Selective Ligands of 5‐HT₃Receptors

Ondansetron and Granisetron Binding Orientation in the 5-HT₃ Receptor Determined by Unnatural Amino Acid Mutagenesis

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Interactions of Granisetron with an Agonist-Free 5-HT3A Receptor Model

Cited by 29 publications

References 31 publications

The binding orientations of structurally-related ligands can differ; A cautionary note

The binding orientations of structurally-related ligands can differ; A cautionary note

Synthesis and Receptor Binding of New Thieno[2,3‐d]‐pyrimidines as Selective Ligands of 5‐HT3 Receptors

Ondansetron and Granisetron Binding Orientation in the 5-HT3 Receptor Determined by Unnatural Amino Acid Mutagenesis

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Interactions of Granisetron with an Agonist-Free 5-HT_3A Receptor Model

Synthesis and Receptor Binding of New Thieno[2,3‐d]‐pyrimidines as Selective Ligands of 5‐HT₃Receptors

Ondansetron and Granisetron Binding Orientation in the 5-HT₃ Receptor Determined by Unnatural Amino Acid Mutagenesis