Mutant DISC 1 and Abnormal Neurodevelopment in Mental Illness

DISC 1 突变与精神疾病中的神经发育异常

• 批准号: 7655653
• 负责人: Mikhail V Pletnikov
• 金额: $ 41.66万
• 依托单位: JOHNS HOPKINS UNIVERSITY
• 依托单位国家: 美国
• 财政年份: 2009
• 资助国家: 美国
• 起止时间: 2009-05-15 至 2011-04-30
• 项目状态: 已结题
• 来源: https://reporter.nih.gov/project-details/7655653
• 关键词: Address; Affect; Applications Grants; Area; Attenuated; Behavioral; Binding; Brain; C-terminal; Candidate Disease Gene; Cerebral cortex; Defect; Dendrites; Development; Disease; Dominant-Negative Mutation; Equilibrium; Genes; Hippocampus (Brain); Human; Lead; Light; Mediating; Mental disorders; Modeling; Molecular; Mood Disorders; Mus; Mutation; Nature; Neurites; Neurons; Parahippocampal Gyrus; Pathogenesis; Pre-Clinical Model; Pregnancy; Prosencephalon; Proteins; Psyche structure; Schizophrenia; Staging; Structure; Study models; System; Testing; Tetanus Helper Peptide; Therapy Clinical Trials; Time; Transgenic Mice; Ursidae Family; Variant; Vertebral column; adult neurogenesis; analog; base; brain behavior; density; dentate gyrus; genetic pedigree; granule cell; hippocampal pyramidal neuron; insight; lateral ventricle; mouse model; mutant; neurobehavioral; neurodevelopment; postnatal; prenatal; research study

Schizophrenia is a devastating psychiatric illness arising in part from subtle defects in brain development. The Disrupted-ln-Schizophrenia-1 (DISC1) gene is an example of a strong candidate gene for studying the pathogenesis of schizophrenia and associated mental conditions with neurodevelopmental origin. A balanced translocation that segregates in a large Scottish pedigree with schizophrenia and other major mental illnesses causes a deletion of the DlSC1 gene, resulting in a truncated protein product that affects neurodevelopment. Despite of development of several DISC1 mouse models, the key questions regarding the timing of the prenatal vs. postnatal or lasting vs. reversible effects of mutant human (hDISC1) remained unanswered. We propose to identify the time windows of the effects of mutant hDISC1 by using our transgenic mouse model of inducible expression of mutant hDISC1 in forebrain areas. We hypothesize that the nature and magnitude of neuronal effects of mutant hDISC1 will depend on the time of expression of mutant hDISC1 during brain development, with more profound abnormalities resulting from expression during early gestation stages, compared to more subtle alterations resulting from expression during postnatal period and/or adulthood. Specific Aim 1 will perform quantitative analyses of the volumes of the lateral ventricles, cortex and hippocampus, dendrite arborization and spine density in pyramidal neurons of hippocampus and granule cells of the dentate gyrus of hippocampus as well as adult neurogenesis in the dentate gyrus of hippocampus. Specific Aim 2 will evaluate the time course of alterations in levels and distribution of endogenous Disc1 and Its interacting proteins, Lis1 and Ndel1, in hDISC1 transgenic mice. Significance: The application is anticipated to advance our understanding of when, where and how mutant DISC1 affects neurodevelopment with relevance to the pathogenesis of schizophrenia and mood disorders. Major mental illnesses have been suggested to arise in part from subtle defects in brain development, particularly development of the cerebral cortex, hippocampus and other forebrain structures (Weinberger, 1996; Lewis, 2002; Eastwood, 2004; Arnold, 2005). The concept of a neurodevelopmental origin of psychiatric diseases has received wide acceptance, although the evidence so far has been primarily indirect (Marenco, 2000). Until very recently an analysis of the pathogenic mechanisms has been impeded by a difficulty in identifying clear mutations in most candidate genes (Millar, 2004; Mackie, 2007). Recent studies of the Disrupted-In-Schizophrenia 1 (DISC1) gene indicate that It can be used as a model for studying aspects of schizophrenia and mood disorders (Ross, 2006; Porteous, 2006). We have demonstrated that expression of mutant human DISC1 (hDISC1) in forebrain neurons of transgenic mice leads to attenuated neurite outgrowth in primary neurons, mild enlargement of the lateral ventricles and selective behavioral alterations similar to some features of schizophrenia and related disorders (Ross, 2006; Pletnikov, 2008). We have shown that the effects of mutant hDISC1 may be mediated via its binding to endogenous mouse Disc1 and alterations in cellular distribution and/or decreased levels of endogenous Disc1 and Lis1, a DISC1 interacting protein involved in neurodevelopment (Gupta, 2002). These findings have suggested dominant-negative mechanisms of the mutant DISC1 effects (Pletnikov, 2007, 2008). Similar results have been demonstrated in transgenic mouse models with constitutive expression of mutant hDISC1, truncated mouse Disc1 or Inducible postnatal expression of a C-terminal fragment of the gene (Hikida, 2007; U, 2007; Shen, 2008). As the deleted C-terminal fragment is not a direct analog of a known variation of DISC1 in humans and can be expressed for a brief period of time during postnatal period only, key questions regarding effects of prenatal vs. postnatal expression or effects of short vs. long-lasting expression or effects of reversible expression cannot be addressed with the above models. We propose to use our model of inducible expression of mutant hDISC1 based on the Tet-off system to identify the time windows for the neurobehavioral effects of mutant hDISC1 and the underlying molecular mechanisms of those effects. This approach is expected to give valuable insights into the molecular underpinning of abnormal brain and behavior development to contribute to mental diseases and will shed more light on the critical time windows for schizophrenia and mood disorders. We hypothesize that the nature and magnitude of molecular and neuronal effects of mutant hDISC1 will depend on the time of expression of mutant hDISC1 during brain development. We predict that early effects of mutant DISC1 may lead to more profound neurodevelopmental abnormalities, whereas early or late postnatal effects of the protein could produce more subtle brain deficits. We hypothesize that mutant hDISC1 affects neurodevelopment via dominant-negative mechanisms by altering the functions of endogenous mouse Dics1, Lis1, and Ndel1.

精神分裂症是一种毁灭性的精神疾病，部分原因是大脑发育中的细微缺陷。DISC 1基因是研究精神分裂症发病机制和与神经发育起源相关的精神状况的强候选基因的一个例子。 一个平衡的易位，分离在一个大的苏格兰血统与精神分裂症和其他主要精神疾病导致DlSC 1基因的缺失，导致一个截短的蛋白质产物，影响神经发育。尽管开发了几种DISC 1小鼠模型，但关于突变体人（hDISC 1）的产前与产后或持久与可逆效应的时间的关键问题仍然没有答案。我们建议通过使用我们的转基因小鼠来确定突变hDISC 1效应的时间窗。 突变hDISC 1在前脑区域中的诱导表达的小鼠模型。 我们假设突变hDISC 1的神经元效应的性质和大小将取决于突变hDISC 1在大脑发育过程中的表达时间，与出生后和/或成年期表达引起的更微妙的变化相比，在妊娠早期表达引起的更深刻的异常。 具体目标1将对侧脑室、皮质和海马的体积、海马锥体神经元和海马齿状回颗粒细胞中的树突分支和棘密度以及海马齿状回中的成年神经发生进行定量分析。 具体目标2将评估hDISC 1转基因小鼠中内源性Disc 1及其相互作用蛋白Lis 1和Ndel 1的水平和分布变化的时间过程。 重要性：预计该应用程序将促进我们了解突变DISC 1何时，何地以及如何影响神经发育与精神分裂症和情绪障碍的发病机制。 严重的精神疾病被认为部分源于大脑发育的细微缺陷，特别是大脑皮层、海马体和其他前脑结构的发育（Weinberger，1996;刘易斯，2002; Eastwood，2004; Arnold，2005）。精神疾病的神经发育起源的概念已被广泛接受，尽管迄今为止的证据主要是间接的（Marenco，2000）。直到最近，致病机制的分析一直受到难以识别大多数候选基因中的明确突变的阻碍（Millar，2004; Mackie，2007）。最近对DISC 1基因的研究表明，DISC 1基因可作为研究精神分裂症和心境障碍的模型（Ross，2006; Porteous，2006）。 我们已经证明，在转基因小鼠的前脑神经元中表达突变的人DISC 1（hDISC 1）导致原代神经元中神经突生长减弱、侧脑室轻度扩大和选择性行为改变，类似于精神分裂症和相关疾病的一些特征（Ross，2006; Pletnikov，2008）。我们已经证明，突变hDISC 1的作用可能是通过其与内源性小鼠Disc 1的结合以及细胞分布的改变和/或内源性Disc 1和Lis 1（一种参与神经发育的DISC 1相互作用蛋白）水平的降低来介导的（Gupta，2002）。这些发现表明突变DISC 1效应的显性负性机制（Pletnikov，2007，2008）。在组成型表达突变型hDISC 1、截短型小鼠Disc 1或诱导型出生后表达基因C-末端片段的转基因小鼠模型中也证明了类似的结果（Hikida，2007; U，2007; Shen，2008）。由于缺失的C-末端片段不是人类DISC 1已知变异的直接类似物，并且只能在出生后短暂表达，因此无法用上述模型解决关于产前与出生后表达的影响或短期与长期表达的影响或可逆表达的影响的关键问题。我们建议使用我们的模型的诱导表达的突变hDISC 1的Tet-off系统的基础上，以确定的时间窗口突变hDISC 1的神经行为的影响和这些影响的潜在的分子机制。这种方法有望为异常大脑和行为发展的分子基础提供有价值的见解，以促进精神疾病，并将更多地揭示精神分裂症和情绪障碍的关键时间窗口。 我们假设突变hDISC 1的分子和神经元效应的性质和大小将取决于突变hDISC 1在大脑发育过程中表达的时间。我们预测，突变DISC 1的早期影响可能会导致更深刻的神经发育异常，而早期或晚期出生后的蛋白质的影响可能会产生更微妙的大脑缺陷。我们假设突变hDISC 1通过显性负调控机制改变内源性小鼠Dics 1、Lis 1和Ndel 1的功能来影响神经发育。