A Genetic Test for Drug-Induced Dyskinesia Risk Determination

药物引起的运动障碍风险测定的基因测试

• 批准号: 7291637
• 负责人: Abraham Kovoor
• 金额: $ 25.18万
• 依托单位: KOVOGEN
• 依托单位国家: 美国
• 财政年份: 2006
• 资助国家: 美国
• 起止时间: 2006-09-27 至 2009-07-31
• 项目状态: 已结题
• 来源: https://reporter.nih.gov/project-details/7291637
• 关键词: Adverse effects; Adverse reactions; Affect; Age; Alternative Therapies; Antiparkinson Agents; Antipsychotic Agents; Applications Grants; Award; Basal Ganglia; Behavioral; Brain; Bromocriptine; Cardiovascular Diseases; Cardiovascular system; Chronic; Clinical; Complication; Corpus striatum structure; Country; DNA Sequence; Data; Delusions; Development; Disease; Dopamine Agonists; Dopamine Receptor; Drug Formulations; Drug-Induced Dyskinesia; Dyskinetic syndrome; Economics; Family; Functional disorder; Generations; Genes; Genetic; Genetic Polymorphism; Genetic Variation; Genetic screening method; Hallucinations; Health; Homelessness; Impaired cognition; Incidence; Individual; Inferior; Investigation; Knockout Mice; Life; Marketing; Mental Health; Mental disorders; Motor; Movement; Movement Disorders; Muscle Rigidity; NIH Program Announcements; Neurodegenerative Disorders; Neurologist; Nucleic Acid Regulatory Sequences; Parkinson Disease; Patients; Pharmaceutical Preparations; Pharmacotherapy; Phase; Physicians; Play; Population; Predisposition; Prevalence; Price; Principal Investigator; Psyche structure; Psychiatrist; Psychotic Disorders; Publishing; RGS Proteins; RGS9 protein; RNA Splicing; Randomized; Research; Risk; Risk Estimate; Rodent Model; Role; Schizophrenia; Sequence Analysis; Side; Signal Pathway; Social isolation; Societies; Stigmata; Stratification; Suicide attempt; Symptoms; Tardive Dyskinesia; Testing; Thinking; Tremor; Withdrawal; abnormal involuntary movement; atypical antipsychotic; base; clinical efficacy; cost; design; diabetic; drug development; human subject; improved; research clinical testing; response; size; tool

DESCRIPTION (provided by applicant): The objective of this project is to develop a genetic test, involving the protein, RGS9, to identify patients that are at risk for developing tardive dyskinesia (TD) or L-DOPA induced dyskinesia (LID). Antipsychotic drugs have revolutionized the treatment of schizophrenia and psychotic disorders but a debilitating side-effect of "typical" antipsychotics is TD, an irreversible movement disorder of unknown pathophysiology. Unfortunately, the second generation "atypical" antipsychotics have their own serious cardiovascular and diabetic side-effects. LID is a similar unexplained motor side-effect of the treatment of Parkinson's disease with L-DOPA that can become so severely disabling as to negate any clinical benefit from L-DOPA therapy. While alternative therapy of Parkinson's disease with dopamine receptor agonists produces a lower incidence of motor complications, their clinical efficacy is inferior to L-DOPA. Thus there is an urgent need for tools to estimate dyskinesia risk in the pharmacotherapy of both psychoses and Parkinson's disease. Evidence exists for a genetic component in the susceptibility for TD and LID and the rationale for the present investigation is provided by data recently published by this principal investigator and others. These data suggest that RGS9 is a key factor in the development of TD and LID and include the following observations: 1) in brain, RGS9 is expressed specifically in the striatum, an important component of the basal ganglia loop that controls movement and is critical in the development of TD and LID, 2) RGS9 specifically modulates basal ganglia signaling pathways activated by dopamine receptors, which are principal targets of the typical antipsychotic and antiparkinsonian drugs and 3) the RGS9 knock-out mouse is the most representative rodent model for TD and LID. In Phase 1 the RGS9 gene and regulatory regions from individual patients will be examined to determine if polymorphisms (differences in DNA sequence among individuals) can be correlated to the development of TD or LID. The results will be utilized in subsequent phases to develop, validate and commercialize a valuable clinical test that can be used to estimate the risk for developing TD or LID. The test will assist psychiatrists in deciding between treatment with atypical antipsychotics and the cheaper typical drugs which can be administered in depot formulations for increased compliance. It could similarly help neurologists decide between L-DOPA and direct dopamine receptor agonists in the therapy of Parkinson's disease. Estimation of dyskinesia risk will be very valuable in the development of new antipsychotic and antiparkinsonian drugs: by enabling better stratification of human subject subsets in drug trial randomization designs it will reduce the size of test populations, reduce risk to human subjects, lower drug development costs and ultimately lower market pricing of new drugs. Movement disorders are common, serious and debilitating side effects of antipsychotic drugs which are used to treat schizophrenia and L-DOPA which is used to treat Parkinson's disease. This research will help to develop a genetic test that will estimate the risk of a developing these debilitating side effects in a patient by analyzing the gene for a protein, RGS9, that is important in the development of drug-induced movement disorders. Such a test will allow physicians to individualize therapy by assisting in the selection of drugs with the greatest benefit and least harm. In addition, the ability to estimate dyskinesia risk will be very valuable in the development of new and improved antipsychotic and antiparkinsonian drugs.

描述（由申请人提供）：该项目的目的是开发一种涉及RGS9蛋白的基因测试，以识别有发展为迟发性运动障碍（TD）或左旋多巴诱导的运动障碍（LID）风险的患者。抗精神病药物已经彻底改变了精神分裂症和精神障碍的治疗，但“典型”抗精神病药物的副作用是TD，这是一种病理生理未知的不可逆运动障碍。不幸的是，第二代“非典型”抗精神病药物有其严重的心血管和糖尿病副作用。LID与左旋多巴治疗帕金森氏症类似，是一种无法解释的运动副作用，它会严重致残，使左旋多巴治疗的临床效果失效。虽然多巴胺受体激动剂替代治疗帕金森病的运动并发症发生率较低，但其临床疗效不如左旋多巴。因此，在精神病和帕金森病的药物治疗中，迫切需要一种评估运动障碍风险的工具。有证据表明，TD和LID的易感性中存在遗传成分，本研究的基本原理是由该首席研究员和其他人最近发表的数据提供的。这些数据表明RGS9是TD和LID发展的关键因素，包括以下观察结果：1)在大脑中，RGS9在纹状体中特异性表达，纹状体是控制运动的基底节区环路的重要组成部分，在TD和LID的发展中起着至关重要的作用；2)RGS9特异性调节多巴胺受体激活的基底节区信号通路，而多巴胺受体是典型抗精神病和抗帕金森药物的主要靶点；3)RGS9敲除小鼠是TD和LID最具代表性的啮齿动物模型。在第一阶段，将检查个体患者的RGS9基因和调控区域，以确定多态性（个体之间DNA序列的差异）是否与TD或LID的发展相关。结果将在后续阶段用于开发、验证和商业化有价值的临床测试，可用于评估发展为TD或LID的风险。该测试将帮助精神科医生决定是使用非典型抗精神病药物治疗，还是使用更便宜的典型药物治疗，后者可以在储存配方中使用，以提高依从性。同样，它可以帮助神经科医生决定在帕金森病的治疗中使用左旋多巴还是直接多巴胺受体激动剂。对运动障碍风险的估计在开发新的抗精神病药物和抗帕金森药物中非常有价值：通过在药物试验随机化设计中对人类受试者亚群进行更好的分层，它将减少测试人群的规模，降低对人类受试者的风险，降低药物开发成本，最终降低新药的市场价格。运动障碍是用于治疗精神分裂症的抗精神病药物和用于治疗帕金森病的左旋多巴的常见、严重和使人衰弱的副作用。这项研究将有助于开发一种基因测试，通过分析一种蛋白质RGS9的基因来估计患者出现这些使人衰弱的副作用的风险，RGS9在药物引起的运动障碍的发展中很重要。这样的测试将允许医生通过帮助选择药物的最大利益和最小的危害个体化治疗。此外，评估运动障碍风险的能力将在开发新的和改进的抗精神病和抗帕金森药物中非常有价值。