FAD-Linked Autofluorescence and Chemically-Evoked Zinc Changes at Hippocampal Mossy Fiber-CA3 Synapses

Hippocampus - New Advances [Working Title] Pub Date : 2021-11-03 DOI:10.5772/intechopen.100898

Fatima M.C. Bastos, Carlos M. Matias, Ines O. Lopes, João P. Vieira, Rosa M. Santos, Luís M. Rosário, Rosa M. Quinta-Ferreira, M. Emília Quinta-Ferreira

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Abstract

Glutamatergic vesicles in hippocampal mossy fiber presynaptic boutons release zinc, which plays a modulatory role in synaptic activity and LTP. In this work, a fluorescence microscopy technique and the fluorescent probe for cytosolic zinc, Newport Green (NG), were applied, in a combined study of autofluorescence and zinc changes at the hippocampal mossy fiber-CA3 synaptic system. In particular, the dynamics of flavoprotein (FAD) autofluorescence signals, was compared to that of postsynaptic zinc signals, elicited both by high K+ (20 mM) and by tetraethylammonium (TEA, 25 mM). The real zinc signals were obtained subtracting autofluorescence values, from corresponding total NG-fluorescence data. Both autofluorescence and zinc-related fluorescence were raised by high K+. In contrast, the same signals were reduced during TEA exposure. It is suggested that the initial outburst of TEA-evoked zinc release might activate ATP-sensitive K+ (KATP) channels, as part of a safeguard mechanism against excessive glutamatergic action. This would cause sustained inhibition of zinc signals and a more reduced mitochondrial state. In favor of the “KATP channel hypothesis”, the KATP channel blocker tolbutamide (250 μM) nearly suppressed the TEA-evoked fluorescence changes. It is concluded that recording autofluorescence from brain slices is essential for the accurate assessment of zinc signals and actions.

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fad连接的自身荧光和化学诱发的海马苔藓纤维- ca3突触锌的变化

海马苔藓纤维突触前钮扣中的谷氨酸能小泡释放锌，锌在突触活性和LTP中起调节作用。本研究采用荧光显微技术和胞质锌荧光探针Newport Green (NG)，对海马苔藓纤维- ca3突触系统的自身荧光和锌的变化进行了联合研究。特别地，我们比较了黄蛋白(FAD)自身荧光信号与高K+ (20 mM)和四乙基铵(25 mM)诱导的突触后锌信号的动态。实际锌信号减去自身荧光值，从相应的总ng荧光数据。高K+提高了自身荧光和锌相关荧光。相比之下，同样的信号在TEA暴露期间减少了。这表明，茶引起的锌释放的初始爆发可能激活atp敏感的K+ (KATP)通道，作为防止过度谷氨酸作用的保护机制的一部分。这将导致锌信号的持续抑制和线粒体状态的进一步减少。支持“KATP通道假说”的是，KATP通道阻滞剂tolbuamide (250 μM)几乎抑制了tea引起的荧光变化。因此，记录脑切片的自身荧光对于准确评估锌的信号和作用是必要的。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Hippocampus - New Advances [Working Title]

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