Laboratory of Molecular Pharmacology, HUN-REN Institute of Experimental Medicine, Budapest, Hungary.
Pharmacology and Drug Safety Research, Gedeon Richter Plc, Budapest, Hungary.
Br J Pharmacol. 2024 Dec;181(24):5094-5109. doi: 10.1111/bph.17348. Epub 2024 Sep 20.
Tetrabenazine (TBZ), used for treating hyperkinetic disorders, inhibits vesicular monoamine transporter-2 (VMAT-2), which sequesters monoamines into vesicles for exocytosis. However, our knowledge of the effect of TBZ on monoaminergic transmission is limited. Herein, we provide neurochemical evidence regarding the effect of VMAT-2 inhibition on vesicular neurotransmitter release from the prefrontal cortex (PFC) and striatum (STR) (brain regions involved in characteristic TBZ treatment side effects). The interaction between TBZ and MDMA was also assessed regarding motor behaviour in mice.
Vesicular storage capacity and release of [H]-noradrenaline ([H]-NA), [H]-dopamine ([H]-DA), [H]-serotonin ([H]-5-HT), and [H]-acetylcholine ([H]-ACh) was studied in mouse PFC and STR ex vivo slice preparations using electrical field stimulation. Additionally, locomotor activity was assessed in vehicle-treated mice and compared with that of MDMA, TBZ, and co-administered animals (n = 6) using the LABORAS system.
TBZ lowered the storage capacity and inhibited the vesicular release of [H]-NA and [H]-DA from the PFC, and [H]-DA and [H]-5-HT from the STR in a concentration-dependent manner. Unlike vesamicol (vesicular ACh uptake inhibitor), TBZ failed to inhibit the vesicular release of [H]-ACh from the PFC. When the vesicular storage of the investigated monoamines was inhibited by TBZ in the PFC and STR, MDMA induced the release of transmitters through transporter reversal; MDMA dose dependently increased locomotor activity in vivo.
Our observations provide neurochemical evidence explaining the mechanism of VMAT-2 inhibitors in the brain and support the involvement of dopaminergic and noradrenergic transmission in hyperkinetic movement disorders.
用于治疗运动障碍的四苯嗪(TBZ)抑制囊泡单胺转运体-2(VMAT-2),后者将单胺类物质隔离到囊泡中以进行胞吐。然而,我们对 TBZ 对单胺能传递的影响知之甚少。在此,我们提供神经化学证据,说明 VMAT-2 抑制对前额叶皮层(PFC)和纹状体(STR)(涉及 TBZ 治疗副作用的特征性脑区)中囊泡神经递质释放的影响。还评估了 TBZ 和 MDMA 之间的相互作用,以及对小鼠运动行为的影响。
使用电刺激,在离体脑片制备中研究了 [H]-去甲肾上腺素 ([H]-NA)、[H]-多巴胺 ([H]-DA)、[H]-5-羟色胺 ([H]-5-HT) 和 [H]-乙酰胆碱 ([H]-ACh) 的囊泡储存容量和释放。此外,使用 LABORAS 系统评估了载体处理小鼠的运动活性,并将其与 MDMA、TBZ 和共同给药动物(n=6)的运动活性进行了比较。
TBZ 以浓度依赖的方式降低了 PFC 中 [H]-NA 和 [H]-DA 的储存容量并抑制了其囊泡释放,以及 STR 中 [H]-DA 和 [H]-5-HT 的囊泡释放。与囊泡抑制剂(囊泡 ACh 摄取抑制剂)不同,TBZ 未能抑制 PFC 中 [H]-ACh 的囊泡释放。当 TBZ 抑制 PFC 和 STR 中研究的单胺类物质的囊泡储存时,MDMA 通过转运体反向诱导递质释放;MDMA 体内剂量依赖性地增加运动活性。
我们的观察结果提供了神经化学证据,解释了 VMAT-2 抑制剂在大脑中的作用机制,并支持多巴胺能和去甲肾上腺素能传递在运动障碍中的参与。
