Previous studies indicate that the Sigma-1 ligand 4-phenyl-1-(4-phenylbutyl) piperidine (PPBP) protects the brain from ischemia. Less clear is whether protection is mediated by agonism or antagonism of the Sigma-1 receptor, and whether drugs already in use for other indications and that interact with the Sigma-1 receptor might also prevent oxidative damage due to conditions such as cerebral ischemic stroke. The antipsychotic drug haloperidol is an antagonist of Sigma-1 receptors and in this study it potently protects against oxidative stress-related cell death in vitro at low concentrations. The protective potency of haloperidol and a number of other butyrophenone compounds positively correlate with their affinity for a cloned Sigma-1 receptor, and the protection is mimicked by a Sigma-1 receptor-selective antagonist (BD1063), but not an agonist (PRE-084). In vivo, an acute low dose (0.05 mg/kg s.c.) of haloperidol reduces by half the ischemic lesion volume induced by a transient middle cerebral artery occlusion. These in vitro and in vivo pre-clinical results suggest that a low dose of acutely administered haloperidol might have a novel application as a protective agent against ischemic cerebral stroke and other types of brain injury with an ischemic component.
The ability of sigma 1 receptors to interact with a huge range of drug structural classes coupled with its wide distribution in the body has contributed to it being implicated as a possible therapeutic target for a broad array of disorders ranging from substance abuse to depression to Alzheimer's disease. Surprisingly, the reported affinity values for some sigma 1 receptor ligands vary more than 50-fold. The potential of the sigma 1 receptor as a pharmacotherapeutic target prompted us to develop an unambiguous assay system for measuring the affinity of ligands to the cloned human sigma 1 receptor. In the course of characterizing this system and determining the true affinity values for almost three dozen compounds, it was discovered that some dopamine D 4 receptor selective compounds bind sigma 1 receptors with high affinity. A systematic analysis of haloperidol-like compounds revealed a clear structure-affinity relationship amongst clinically relevant butyrophenones. The antidepressant fluvoxamine, the drug of abuse methamphetamine, and the neurosteroid progesterone were amongst the many ligands whose interactions with sigma 1 receptor were confirmed with our screening assay.
We recently demonstrated that in the D4 dopamine receptor the aromatic microdomain that spans the interface of the second and third transmembrane (TM) domains influences the high affinity interactions of extremely D4-selective ligands possessing a 1,4-disubstituted aromatic piperazine/piperidine (1,4-DAP) structure. On the basis of their substructural features and patterns of sensitivity to mutations constructed in a D4 receptor background, the D4-selective 1,4-DAPs were categorized as having two distinct modes of binding that we named mode-1 and mode-3 [1]. Here we extend these findings of the ligand-receptor structure-affinity relationships for some of these highly D4-selective 1,4-DAPs by measuring the effect of the corresponding reciprocal TM2/TM3 mutations constructed in a D2 dopamine receptor background on the binding affinity of the para-halogenated mode-1 ligands L750,667 and FAUC213. The results indicate that the D2-V2.61F + FV3.28-3.29LM mutant binds L750,667 and FAUC213 with significantly increased affinity, i.e., its binding profile becomes more D4-like. These findings further support the assignment of the TM2/TM3 aromatic microdomain encompassing positions 2.61 and 3.28-3.29 as a 1,4-DAP D4-selectivity microdomain and highlights the importance of the precise emplacement of aromatics in this microdomain as key to the selective molecular recognition of L750,667 and FAUC213.
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