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自闭症神经元

The Autistic Neuron
课程网址: http://videolectures.net/mitworld_bear_an/  
主讲教师: Mark Bear
开课单位: 麻省理工学院
开课时间: 2010-08-07
课程语种: 英语
中文简介:
这个自我描述的“基础神经科学家”承认他从未想过他会谈论自闭症,但正如马克熊回忆的那样,基础知识的数十年研究现在已经取得了对脑病的病因和治疗的重要见解,包括自闭症.Bear提供了这种发育障碍的入门指南,指出它的根源是生物学的,它是高度可遗传的,并且非常普遍:150人中有一人表达自闭症的一些症状。从严重减少的社会行为,语言异常,重复性运动,癫痫发作和精神发育迟滞到较为温和的阿斯伯格综合症,这些都是学术上成功的,但社会上很尴尬。对熊来说特别重要:自闭症的潜在遗传变化表现在神经元之间的有问题的交流中。为了解开自闭症,研究人员正在研究其临床异质性,“遗传风险架构”,以及它如何改变大脑连接和功能。接近自闭症的困难之一是各种基因突变可导致自闭症行为,并且仅鉴定了这些突变中的少数几种。熊自己一直在探索单一基因疾病,脆性X染色体综合征(约占完全自闭症病例的5%。)在脆性X中,FMR1基因被沉默,导致缺失的蛋白质作为关键参与神经元通讯的脑蛋白调节因子。没有FMR1,“刹车失踪”,并且蛋白质合成过多导致大脑功能发生改变。熊假设可能通过使系统恢复平衡来纠正脆弱X.他创造了这种疾病的小鼠模型,并发现通过减少对过量脑蛋白有反应的神经递质受体的数量,他可以改善或纠正脆性X缺陷。贝尔说,这些受体是“可药用的目标”,“如果治疗适用于苍蝇,鱼类或小鼠,它在人类中更有效,或者达尔文是错误的。”基于这项工作,制药公司正在设计化合物以在人体中进行测试。脆性X综合征的临床试验。此外,Bear指出,同事们发现其他与自闭症有关的突变也涉及蛋白质调节问题。 “这让我们感到兴奋,因为它看起来像是一种导致不同疾病突触功能障碍的常见途径,最终可能表现为自闭症。如果是这种情况,那么治疗这种疾病可能会在多种疾病中有效。“
课程简介: This self-described “basic neuroscientist” confesses he never thought he’d give a talk on autism, but as Mark Bear recounts, decades of research in the basics are now paying off with important insights into the etiology and treatment of brain disorders, including autism. Bear provides a primer on this developmental disorder, noting that its roots are biological, it is highly heritable, and astonishingly prevalent: one in 150 people express some of the symptoms of autism. These fall on a spectrum, from severely reduced social behavior, abnormal language, repetitive movements, seizures and mental retardation, to the milder Asperger’s Syndrome, where individuals are often academically successful, but socially awkward. Particularly significant to Bear: Autism’s underlying genetic changes manifest themselves in problematic communication between neurons. To unravel autism, researchers are examining its clinical heterogeneity, “genetic risk architecture,” and how it alters brain connections and function. One of the difficulties in approaching autism is that a variety of genetic mutations can result in autistic behaviors, and only a few of these mutations have been identified. Bear himself has been probing the single gene disorder, Fragile X syndrome (responsible for about 5% of the cases “of full-blown autism.”) In Fragile X, the FMR1 gene is silenced, leading to a missing protein that serves as a key regulator of brain proteins involved in neuron communication. Without FMR1, “the brakes are missing,” and there’s excessive protein synthesis leading to altered brain function. Bear hypothesized that it might be possible to correct Fragile X by bringing the system back in balance. He created mice models of the disease, and found that by reducing the number of neurotransmitter receptors that respond to the excessive brain proteins, he could ameliorate or correct Fragile X defects. These receptors are “druggable targets,” and, says Bear, “if the treatment works in fly, fish or mouse, it better work in humans or Darwin was wrong.” Based on this work, drug companies are devising compounds to test in human clinical trials of Fragile X syndrome. In addition, Bear notes, colleagues have discovered that other mutations connected with autism also involve protein regulation problems. “This gets us excited, because it looks like a common pathway that causes synaptic dysfunction in different diseases that may ultimately manifest as autism. If that’s the case, then treatment for the disorder may be efficacious in multiple disorders.”
关 键 词: 基础神经; 自闭症; 脑病
课程来源: 视频讲座网
最后编审: 2019-05-20:cwx
阅读次数: 100

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