Characterization of Retinal VIP-Amacrine Cell Development During the Critical Period.
Xuhong ZhangXiaoyu WangYanqing LiYingying ZhangHong ZhuChen XieYu-Dong ZhouYe ShenJianping TongPublished in: Cellular and molecular neurobiology (2024)
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.
Keyphrases
- optical coherence tomography
- diabetic retinopathy
- acute coronary syndrome
- optic nerve
- artificial intelligence
- metabolic syndrome
- stem cells
- type diabetes
- heart rate
- preterm infants
- skeletal muscle
- machine learning
- risk assessment
- insulin resistance
- young adults
- mesenchymal stem cells
- deep learning
- climate change
- heart rate variability