2-Carbomethoxy-3-aryl-8-oxabicyclo[3.2.1]octanes:  Potent Non-Nitrogen Inhibitors of Monoamine Transporters

Meltzer, Peter C.; Liang, Anna Y.; Blundell, Paul; González, Mario D.; Chen, Zhengming; George, Clifford; Madras, Bertha K.

doi:10.1021/jm9703045

Cited by 92 publications

(118 citation statements)

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“…It has long been thought that the nitrogen atom is needed for amine-containing drugs to bind to the biological target, 5 but Madras and colleagues have recently shown that the nitrogen atom may be replaced by either an oxygen atom 6,7 or a carbon atom (BK Madras et al, to be published), and the cocaine-like drugs will still selectively block the dopamine transporter target in vitro. (Although the nitrogen and oxygen atoms each have lone pair electrons which can form a hydrogen bond with the dopamine transporter, 5,7 the carbon atom does not, thus raising considerably interesting theoretical problems as to how such carbon-based molecules bind to the dopamine transporter.…”

Section: Chemistrymentioning

confidence: 99%

“…Thus, amphetamine has two forms, (+)-and (−)-, while methylphenidate has two asymmetric carbon atoms, resulting in four forms, wherein the mixed form (±)-threo-methylphenidate is used clinically. Although each stimulant contains a nitrogen atom which can bond to the dopamine transporter target, Madras and colleagues have shown that the nitrogen atom can be replaced by an oxygen atom 6,7 or a carbon atom (Madras et al, to be published) while still retaining the drug's potency in vitro.…”

Section: Behavioral Pharmacologymentioning

confidence: 99%

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Anti-hyperactivity medication: methylphenidate and amphetamine

Seeman¹,

1998

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How do 'stimulants' reduce hyperactivity in children and adults? How can drugs which raise extracellular dopamine result in psychomotor slowing of hyperactive children when dopamine is known to enhance motor activity, such as in Parkinson's disease? These apparent paradoxes are the focus of this brief review on the mechanism of action of stimulant medications used in the treatment of children, and of an increasing number of adults who meet diagnostic criteria for attention deficit hyperactivity disorder.

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Section: Chemistrymentioning

confidence: 99%

Section: Behavioral Pharmacologymentioning

confidence: 99%

Anti-hyperactivity medication: methylphenidate and amphetamine

Seeman¹,

1998

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“…Similarly modified methylphenidate analogs displayed DAT affinities indistinguishable from methylphenidate itself (Meltzer et al, 2003). In contrast, replacement of the basic tropane nitrogen with a neutral functional group (e.g., N-formyl group or oxygen atom) in the benztropine class of DAT inhibitors substantially reduced DAT binding affinity (Agoston et al, 1997;Meltzer et al, 1997;Simoni et al, 2001).…”

mentioning

confidence: 98%

“…On the other hand, a similar 8-oxa modification of WIN 35,428 sharply reduced binding affinity and DUIP at the DAT. This deficit was fully compensated for by further replacing the p-fluoro substituent of the C-3 phenyl group with a chloride atom (Madras et al, 1996) and further improved with a 3,4-dichloro substitution (Meltzer et al, 1997). Elimination of hydrogen bonding potential at the 8-position of WIN 35,428 by substitution of a carbon atom also substantially compromised affinity at the DAT.…”

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confidence: 99%

Recognition of Benztropine by the Dopamine Transporter (DAT) Differs from That of the Classical Dopamine Uptake Inhibitors Cocaine, Methylphenidate, and Mazindol as a Function of a DAT Transmembrane 1 Aspartic Acid Residue

Ukairo

Bondi

Newman

et al. 2005

J Pharmacol Exp Ther

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Binding of cocaine to the dopamine transporter (DAT) protein blocks synaptic dopamine clearance, triggering the psychoactive effects associated with the drug; the discrete drug-protein interactions, however, remain poorly understood. A longstanding postulate holds that cocaine inhibits DAT-mediated dopamine transport via competition with dopamine for formation of an ionic bond with the DAT transmembrane aspartic acid residue D79. In the present study, DAT mutations of this residue were generated and assayed for translocation of radiolabeled dopamine and binding of radiolabeled DAT inhibitors under identical conditions. When feasible, dopamine uptake inhibition potency and apparent binding affinity K i values were determined for structurally diverse DAT inhibitors. The glutamic acid substitution mutant (D79E) displayed values indistinguishable from wild-type DAT in both assays for the charge-neutral cocaine analog 8-oxa-norcocaine, a finding not supportive of the D79 "salt bridge" ligand-docking model. In addressing whether the D79 side chain contributes to the DAT binding sites of other portions of the cocaine pharmacophore, only inhibitors with modifications of the tropane ring C-3 substituent, i.e., benztropine and its analogs, displayed a substantially altered dopamine uptake inhibition potency as a function of the D79E mutation. A single conservative amino acid substitution thus differentiated structural requirements for benztropine function relative to those for all other classical DAT inhibitors. Distinguishing the precise mechanism of action of this DAT inhibitor with relatively low abuse liability from that of cocaine may be attainable using DAT mutagenesis and other structure-function studies, opening the door to rational design of therapeutic agents for cocaine abuse.Millions of individuals worldwide are addicted to cocaine, a public health crisis that also carries a substantial burden to society in the form of medical expenses, lost earnings, and increased crime associated with psychostimulant abuse. Although therapeutics including buprenorphine and methadone are clinically accessible to treat opiate abuse and addiction, no such Food and Drug Administration-approved medication is available for the treatment of cocaine addiction. Pharmacological and behavioral studies have established that the euphoric and addictive effects of cocaine are initiated by its binding to the dopamine transporter (DAT) protein, blocking clearance of dopamine from central nervous system synapses and thereby prolonging dopaminergic neurotransmission in brain areas associated with reward (Ritz et al., 1987). The DAT is therefore a logical target for development of medications for cocaine abuse. Elucidating the relationship between the DAT and its substrates and inhibitors is essential, especially regarding cocaine points of contact with the DAT protein relevant to its inhibition of dopamine uptake.Because dopamine and all classical DAT inhibitors possess a protonated nitrogen atom, a longstanding model for cocaine

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“…Overlap of high affinity inhibitor binding with the S1 site is supported by biochemical studies (38,44,47,55) and by recent structures of Drosophila (d) DAT and a LeuT/SERT hybrid co-crystallized with antidepressants (40,56). However, some DA transport inhibitors lack the charged nitrogen necessary to form the salt bridge with Asp-79 (57)(58)(59), suggesting that inhibitor binding can occur without this interaction and thus may not be limited to the S1 pocket (60). This possibility is supported by crystal structures of LeuT complexed at relatively low affinity with several selective serotonin uptake inhibitors (SSRIs) and tricyclic antidepressants (TCAs) in regions that overlap with S2 (16 -18, 56).…”

mentioning

confidence: 99%

Computational and Biochemical Docking of the Irreversible Cocaine Analog RTI 82 Directly Demonstrates Ligand Positioning in the Dopamine Transporter Central Substrate-binding Site

Dahal

Pramod

Sharma

et al. 2014

Journal of Biological Chemistry

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Background: Cocaine interaction with DAT was assessed using the irreversible binding cocaine analog RTI 82. Results: Molecular modeling and peptide mapping identify adduction of RTI 82 to Phe-319 and Phe-320 of rat DAT and human DAT, respectively. Conclusion: Tropane-based pharmacophores bind to DAT in the central substrate site. Significance: Mapping the cocaine-binding site reveals new insights for medication discovery.

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2-Carbomethoxy-3-aryl-8-oxabicyclo[3.2.1]octanes: Potent Non-Nitrogen Inhibitors of Monoamine Transporters

Cited by 92 publications

References 50 publications

Anti-hyperactivity medication: methylphenidate and amphetamine

Anti-hyperactivity medication: methylphenidate and amphetamine

Recognition of Benztropine by the Dopamine Transporter (DAT) Differs from That of the Classical Dopamine Uptake Inhibitors Cocaine, Methylphenidate, and Mazindol as a Function of a DAT Transmembrane 1 Aspartic Acid Residue

Computational and Biochemical Docking of the Irreversible Cocaine Analog RTI 82 Directly Demonstrates Ligand Positioning in the Dopamine Transporter Central Substrate-binding Site

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