Characterization of Retinal VIP-Amacrine Cell Development During the Critical Period

IF 3.6 4区 医学 Q3 CELL BIOLOGY
Xuhong Zhang, Xiaoyu Wang, Yanqing Li, Yingying Zhang, Hong Zhu, Chen Xie, Yudong Zhou, Ye Shen, Jianping Tong
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Abstract

Retinal vasoactive intestinal peptide amacrine cells (VIP-ACs) play an important role in various retinal light-mediated pathological processes related to different developmental ocular diseases and even mental disorders. It is important to characterize the developmental changes in VIP-ACs to further elucidate their mechanisms of circuit function. We bred VIP-Cre mice with Ai14 and Ai32 to specifically label retinal VIP-ACs. The VIP-AC soma and spine density generally increased, from postnatal day (P)0 to P35, reaching adult levels at P14 and P28, respectively. The VIP-AC soma density curve was different with the VIP-AC spine density curve. The total retinal VIP content reached a high level plateau at P14 but was decreased in adults. From P14 to P16, the resting membrane potential (RMP) became more negative, and the input resistance decreased. Cell membrane capacitance (MC) showed three peaks at P7, P12 and P16. The RMP and MC reached a stable level similar to the adult level at P18, whereas input resistance reached a stable level at P21. The percentage of sustained voltage-dependent potassium currents peaked at P16 and remained stable thereafter. The spontaneous excitatory postsynaptic current and spontaneous inhibitory postsynaptic current frequencies and amplitudes, as well as charge transfer, peaked at P12 to P16; however, there were also secondary peaks at different time points. In conclusion, we found that the second, third and fourth weeks after birth were important periods of VIP-AC development. Many developmental changes occurred around eye opening. The development of soma, dendrite and electrophysiological properties showed uneven dynamics of progression. Cell differentiation may contribute to soma development whereas the changes of different ion channels may play important role for spine development.

Graphical Abstract

The second, third and fourth weeks after birth were important periods of VIP-AC development. VIP::Ai14 and VIP::Ai32 mice were used for soma and spine analysis, respectively. The developmental curves for VIP-AC soma have a distinct and longer platform, whereas the developmental curves for spine have a longer and smoother slopes. When the number of VIP-AC some is increasing, cell differentiation may play an important role. During the development of spine, the development of different ion channels is the most vital events. Kv-Ka represents the ion channels that conduct Ka, Kv-Kdr represents the ion channels that conduct Kdr, GABAR represents the inhibitory transmission and NMDAR represents the excitatory transmission. The events occur chronologically from left to right.

Abstract Image

关键期视网膜贵宾肾上腺素细胞的发育特征
视网膜血管活性肠肽杏仁核细胞(VIP-ACs)在各种视网膜光介导的病理过程中发挥着重要作用,这些病理过程与不同的眼部发育疾病甚至精神疾病有关。研究VIP-ACs的发育变化以进一步阐明其回路功能机制非常重要。我们用 Ai14 和 Ai32 培育了 VIP-Cre 小鼠,以特异性标记视网膜 VIP-AC。从出生后第 0 天到第 35 天,VIP-AC 的体节和脊柱密度普遍增加,分别在第 14 天和第 28 天达到成年水平。VIP-AC体节密度曲线与VIP-AC脊柱密度曲线不同。视网膜总的 VIP 含量在 P14 达到高水平,但在成年后有所下降。从 P14 到 P16,静息膜电位(RMP)变得更负,输入电阻下降。细胞膜电容(MC)在 P7、P12 和 P16 出现三个高峰。在 P18 时,静息膜电位和 MC 达到与成年期相似的稳定水平,而输入电阻在 P21 时达到稳定水平。持续电压依赖性钾电流的百分比在 P16 达到峰值,此后保持稳定。突触后自发兴奋性电流和突触后自发抑制性电流的频率和振幅以及电荷转移在P12至P16达到峰值,但在不同的时间点也有次生峰值。总之,我们发现出生后的第二、三和四周是 VIP-AC 发育的重要时期。许多发育变化发生在睁眼前后。体细胞、树突和电生理特性的发展呈现出不均衡的动态进展。图解摘要出生后第二、三和四周是VIP-AC发育的重要时期。小鼠VIP::Ai14和VIP::Ai32分别用于体节和脊柱的分析。VIP-AC体节的发育曲线具有明显且较长的平台,而脊柱的发育曲线则较长,且斜率较平滑。当 VIP-AC 某些细胞的数量增加时,细胞分化可能起着重要作用。在脊柱的发育过程中,不同离子通道的发育是最重要的事件。Kv-Ka 代表传导 Ka 的离子通道,Kv-Kdr 代表传导 Kdr 的离子通道,GABAR 代表抑制性传导,NMDAR 代表兴奋性传导。事件按时间顺序从左至右依次发生。
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来源期刊
CiteScore
7.70
自引率
0.00%
发文量
137
审稿时长
4-8 weeks
期刊介绍: Cellular and Molecular Neurobiology publishes original research concerned with the analysis of neuronal and brain function at the cellular and subcellular levels. The journal offers timely, peer-reviewed articles that describe anatomic, genetic, physiologic, pharmacologic, and biochemical approaches to the study of neuronal function and the analysis of elementary mechanisms. Studies are presented on isolated mammalian tissues and intact animals, with investigations aimed at the molecular mechanisms or neuronal responses at the level of single cells. Cellular and Molecular Neurobiology also presents studies of the effects of neurons on other organ systems, such as analysis of the electrical or biochemical response to neurotransmitters or neurohormones on smooth muscle or gland cells.
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