Inhibitory regulation of visual processing and plasticity in visual cortex

视觉皮层视觉处理和可塑性的抑制调节

• 批准号: 8767487
• 负责人: SANDRA J KUHLMAN
• 金额: $ 37.2万
• 依托单位: CARNEGIE-MELLON UNIVERSITY
• 依托单位国家: 美国
• 财政年份: 2014
• 资助国家: 美国
• 起止时间: 2014-08-01 至 2019-06-30
• 项目状态: 已结题
• 来源: https://reporter.nih.gov/project-details/8767487
• 关键词: Adult; Age; Amblyopia; Autistic Disorder; Axon; Behavioral; Biological Assay; Cells; Cognitive; Data; Defect; Development; Disease; Electrophysiology (science); Environment; ErbB4 gene; Excitatory Synapse; Genetic; Image; Imaging technology; In Vitro; Ligands; Measures; Mediating; Modality; Molecular; Morphology; Mus; Neuregulins; Neurons; Parvalbumins; Pathway interactions; Pharmacogenetics; Phenotype; Process; Property; Recruitment Activity; Regulation; Relative (related person); Reporting; Role; Sampling; Schizophrenia; Sensory; Sensory Process; Shapes; Signal Pathway; Signal Transduction; Slice; Stimulus; Synapses; Techniques; Testing; Transgenic Mice; Transgenic Organisms; Vision; Visual; Visual Cortex; base; brain cell; calcium indicator; cell type; critical period; dark rearing; design; excitatory neuron; experience; improved; in vivo; inhibitory neuron; insight; learned behavior; optogenetics; orientation selectivity; postnatal; preference; public health relevance; receptive field; receptor; relating to nervous system; research study; response; statistics; synaptic inhibition; treatment strategy; two-photon; visual deprivation; visual process; visual processing

DESCRIPTION (provided by applicant): Cortical inhibitory circuits are critically important for processing of sensory information, for example, are required for controlling response gain across a wide range of stimulus intensities. Gain control is essential for all sensory modalities, and the cellular mechanisms mediating gain control may represent a canonical circuit arrangement used throughout the cortex to perform functions such as multimodal integration and cognitive tasks. An understanding of the local connectivity that drives inhibitory neuron activity during gain control is lacking. Previously progress was limited by an inability to identif and manipulate specific inhibitory cell types in-vivo. Here we will employ state-of-the-art two-photon imaging technology in combination with in-vivo electrophysiology and mouse transgenics to directly record and manipulate the neural activity of specific inhibitory cell types. Strikingly genetic perturbation of specific inhibitory cell subtypes reproduces many perceptual and behavioral deficits that characterize neurodevelopmental disease. Currently it is unknown how these well-defined molecular defects in inhibitory neurons early in development manifest as deficits in sensory encoding in the adult. Our strategy to bridge this gap is to (1) study experience-dependent maturation of a particularly important inhibitory cell type, the parvalbumin-expressing neuron (PV), and (2) precisely quantify the extent to which PV neurons regulate gain across postnatal development. Specifically, we will identify the local connectivity responsible for recruiting PV neurons in normal and visually deprived mice, using a combination of in-vivo two-photon imaging guided recording of identified cell types, pharmacogenetic and optogenetic manipulation, in addition to in-vitro slice electrophysiology. Next, using the same techniques we will assess the ability of PV neurons to develop and maintain their mature connectivity profile in a genetically compromised background. Finally, we will assay the impact of laminar-specific pharmacogenetic manipulation of PV neurons on gain control across development by measuring contrast saturation and contrast invariant tuning of orientation selectivity in excitatory neurons using the genetically encoded calcium indicator GCaMP6. Successful completion of these specific aims will reveal the molecular mechanisms that couple visual experience to the maturation of PV response properties and postnatal development of cortical network gain control.

描述(由申请人提供)：皮层抑制电路对于处理感觉信息至关重要，例如，对于控制广泛范围的刺激强度的反应增益是必需的。增益控制对所有感觉模式都是必不可少的，而调节增益控制的细胞机制可能代表了整个大脑皮层执行多模式整合和认知任务等功能的典型电路安排。对在增益控制过程中驱动抑制性神经元活动的局部连接缺乏了解。以前，由于无法在体内识别和操纵特定的抑制性细胞类型，进展受到限制。在这里，我们将使用最先进的双光子成像技术，结合体内电生理学和小鼠转基因技术，直接记录和操纵特定抑制细胞类型的神经活动。令人惊讶的是，特定抑制细胞亚型的遗传扰动会复制许多神经发育疾病的感知和行为缺陷。目前尚不清楚这些发育早期抑制性神经元中明确定义的分子缺陷是如何在成人中表现为感觉编码缺陷的。我们弥合这一差距的策略是：(1)研究一种特别重要的抑制性细胞类型--小白蛋白表达神经元(PV)的经验依赖性成熟，以及(2)精确量化PV神经元在出生后发育过程中调节增益的程度。具体地说，我们将结合体内双光子成像引导记录已识别的细胞类型、药物遗传学和光遗传学操作，以及体外切片电生理学，确定负责在正常和视觉剥夺小鼠中招募PV神经元的局部连接性。接下来，使用相同的技术，我们将评估PV神经元在基因受损的背景下发展和维持其成熟连接特征的能力。最后，我们将通过使用遗传编码的钙指示剂GCaMP6测量兴奋性神经元的对比度饱和和对比度不变的定向选择调节，来分析层流特异性的药物遗传操作对发育过程中获得控制的影响。这些特定目标的成功完成将揭示视觉经验与PV反应特性的成熟和出生后皮质网络获得控制的发展相结合的分子机制。