Department of Pharmacology, Shantou University Medical College, Shantou, China.
Basic Medical Sciences, University of Arizona College of Medicine-Phoenix, Phoenix, AZ, USA.
J Neurosci Res. 2020 Oct;98(10):1968-1986. doi: 10.1002/jnr.24641. Epub 2020 Jun 28.
Microglia populate the early developing brain and mediate pruning of the central synapses. Yet, little is known on their functional significance in shaping the developing cortical circuits. We hypothesize that the developing cortical circuits require microglia for proper circuit maturation and connectivity, and as such, ablation of microglia during the cortical critical period may result in a long-lasting circuit abnormality. We administered PLX3397, a colony-stimulating factor 1 receptor inhibitor, to mice starting at postnatal day 14 and through P28, which depletes >75% of microglia in the visual cortex (VC). This treatment largely covers the critical period (P19-32) of VC maturation and plasticity. Patch clamp recording in VC layer 2/3 (L2/3) and L5 neurons revealed increased mEPSC frequency and reduced amplitude, and decreased AMPA/NMDA current ratio, indicative of altered synapse maturation. Increased spine density was observed in these neurons, potentially reflecting impaired synapse pruning. In addition, VC intracortical circuit functional connectivity, assessed by laser scanning photostimulation combined with glutamate uncaging, was dramatically altered. Using two photon longitudinal dendritic spine imaging, we confirmed that spine elimination/pruning was diminished during VC critical period when microglia were depleted. Reduced spine pruning thus may account for increased spine density and disrupted connectivity of VC circuits. Lastly, using single-unit recording combined with monocular deprivation, we found that ocular dominance plasticity in the VC was obliterated during the critical period as a result of microglia depletion. These data establish a critical role of microglia in developmental cortical synapse pruning, maturation, functional connectivity, and critical period plasticity.
小胶质细胞存在于早期发育的大脑中,并介导中枢突触的修剪。然而,它们在塑造发育中的皮质回路中的功能意义知之甚少。我们假设,发育中的皮质回路需要小胶质细胞来实现适当的回路成熟和连接,因此,在皮质关键期内清除小胶质细胞可能会导致长期的回路异常。我们从出生后第 14 天开始至 P28 给小鼠施用 PLX3397,一种集落刺激因子 1 受体抑制剂,该药物可耗尽视觉皮层 (VC) 中超过 75%的小胶质细胞。这种治疗方法很大程度上覆盖了 VC 成熟和可塑性的关键期 (P19-32)。在 VC 层 2/3 (L2/3) 和 L5 神经元中进行的膜片钳记录显示,mEPSC 频率增加,幅度减小,AMPA/NMDA 电流比降低,表明突触成熟发生改变。这些神经元中观察到的树突棘密度增加,可能反映了突触修剪受损。此外,通过激光扫描光刺激结合谷氨酸解笼,评估 VC 皮质内回路功能连接,发现其发生了显著改变。使用双光子纵向树突棘成像,我们证实,在 VC 关键期内清除小胶质细胞时,棘突消除/修剪减少。因此,减少的棘突修剪可能是 VC 回路的棘突密度增加和连接中断的原因。最后,通过单细胞记录结合单眼剥夺,我们发现,由于小胶质细胞耗竭,VC 中的眼优势可塑性在关键期内被消除。这些数据确立了小胶质细胞在发育性皮质突触修剪、成熟、功能连接和关键期可塑性中的关键作用。
