Synapse-specific diversity of distinct postsynaptic GluN2 subtypes defines transmission strength in spinal lamina I.

IF 2.8 4区 医学 Q2 NEUROSCIENCES Frontiers in Synaptic Neuroscience Pub Date : 2023-01-01 DOI:10.3389/fnsyn.2023.1197174
Graham M Pitcher, Livia Garzia, A Sorana Morrissy, Michael D Taylor, Michael W Salter
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引用次数: 1

Abstract

The unitary postsynaptic response to presynaptic quantal glutamate release is the fundamental basis of excitatory information transfer between neurons. The view, however, of individual glutamatergic synaptic connections in a population as homogenous, fixed-strength units of neural communication is becoming increasingly scrutinized. Here, we used minimal stimulation of individual glutamatergic afferent axons to evoke single synapse resolution postsynaptic responses from central sensory lamina I neurons in an ex vivo adult rat spinal slice preparation. We detected unitary events exhibiting a NMDA receptor component with distinct kinetic properties across synapses conferred by specific GluN2 subunit composition, indicative of GluN2 subtype-based postsynaptic heterogeneity. GluN2A, 2A and 2B, or 2B and 2D synaptic predominance functioned on distinct lamina I neuron types to narrowly, intermediately, or widely tune, respectively, the duration of evoked unitary depolarization events from resting membrane potential, which enabled individual synapses to grade differentially depolarizing steps during temporally patterned afferent input. Our results lead to a model wherein a core locus of proteomic complexity prevails at this central glutamatergic sensory synapse that involves distinct GluN2 subtype configurations. These findings have major implications for subthreshold integrative capacity and transmission strength in spinal lamina I and other CNS regions.

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不同突触后GluN2亚型的突触特异性多样性决定了脊髓I板的传递强度。
突触后对突触前谷氨酸释放的统一反应是神经元间兴奋性信息传递的基本基础。然而,个体谷氨酸突触连接在群体中是同质的、固定强度的神经通讯单位的观点正变得越来越仔细。在此,我们在离体成年大鼠脊髓切片制备中,使用对单个谷氨酸能传入轴突的最小刺激来唤起中央感觉层I神经元的单突触分解突触后反应。我们检测到单一事件显示NMDA受体组分具有不同的突触动力学性质,这是由特定GluN2亚基组成赋予的,表明GluN2亚型基于突触后异质性。GluN2A、2A和2B,或2B和2D突触优势作用于不同类型的I层神经元,分别对静息膜电位诱发的单一去极化事件的持续时间进行狭窄、中等或广泛的调节,从而使单个突触在时间模式传入输入中对不同的去极化步骤进行分级。我们的结果导致了一个模型,其中蛋白质组学复杂性的核心位点在这个涉及不同GluN2亚型配置的谷氨酸中枢感觉突触中普遍存在。这些发现对脊髓I层和其他中枢神经系统区域的阈下整合能力和传递强度具有重要意义。
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来源期刊
CiteScore
7.10
自引率
2.70%
发文量
74
审稿时长
14 weeks
期刊最新文献
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