Sequeira Adolfo, Turecki Gustavo
McGill Group for Suicide Studies, Douglas Hospital, McGill University, Verdun, Quebec, Canada.
OMICS. 2006 Winter;10(4):444-54. doi: 10.1089/omi.2006.10.444.
Microarrays offer the possibility of screening in parallel virtually all genes expressed in a given tissue or to study the molecular signature associated with available treatments. As such, this technology has been increasingly used to investigate multifactorial and polygenic complex traits such as psychiatric disorders, in particular, schizophrenia and mood disorders. This review focuses on microarray studies investigating mood disorders. Study designs, methodologic approaches and limitations, subsequent follow-up strategies, and confirmation of results are discussed. Despite the apparent disparate and not always concordant results, it appears evident that this technology is a powerful and inevitable approach for the study of mood disorders, especially when phenotype-specific confounders are properly accounted for. Thus, alterations of mitochondrial, oligodendrocyte, and myelin related genes in bipolar disorder, of signaling and olidendroglial related genes in depression, and of GABA-glutamate related genes in depression and suicide have been observed and have confirmed new avenues for the study and the treatment of these complex disorders.
微阵列技术提供了一种可能性,即可以并行筛选给定组织中几乎所有表达的基因,或者研究与现有治疗方法相关的分子特征。因此,这项技术越来越多地被用于研究多因素和多基因复杂性状,如精神疾病,特别是精神分裂症和情绪障碍。本综述聚焦于研究情绪障碍的微阵列研究。讨论了研究设计、方法学方法和局限性、后续的随访策略以及结果的验证。尽管结果明显不同且并非总是一致,但显然这项技术是研究情绪障碍的一种强大且不可避免的方法,尤其是在能够恰当地考虑到表型特异性混杂因素的情况下。因此,已经观察到双相情感障碍中线粒体、少突胶质细胞和髓鞘相关基因的改变,抑郁症中信号传导和少突胶质细胞相关基因的改变,以及抑郁症和自杀中γ-氨基丁酸-谷氨酸相关基因的改变,这些都为研究和治疗这些复杂疾病开辟了新途径。