隐花色素的秘密:光感受器、时钟蛋白和磁传感器

Q3 Medicine

Neuroforum Pub Date : 2021-06-24 DOI:10.1515/nf-2021-0006

Rabea Bartölke, Heide Behrmann, Katharina Görtemaker, C. Yee, Jingjing Xu, E. Behrmann, K. Koch

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引用次数: 2

摘要

鸟类眼睛中的一类被称为隐色素的光激活蛋白被认为是主要的磁传感器，允许夜间迁徙的鸣禽利用地球磁场进行数千公里的导航。隐色素是从修复dna的光解酶进化而来的，它将来自光的能量重新定向，为各种其他功能提供能量:作为光感受器，作为昼夜节律时钟的调节器，在某些物种中，最有可能是作为磁场的传感器。虽然磁场对隐花色素的量子效应已经得到了详细的研究，但关于隐花色素作为主要受体蛋白的信号级联几乎一无所知。两种不同的筛选方法已经确定了潜在的相互作用伙伴，表明涉及视觉光传导途径，视觉循环，钾通道或谷氨酸受体，但需要更多的开创性研究来解开负责转导磁信号的信号级联。

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The secrets of cryptochromes: photoreceptors, clock proteins, and magnetic sensors

Abstract A class of light-activated proteins in the eyes of birds, called cryptochromes, are thought to act as the primary magnetic sensors allowing night-migratory songbirds to navigate over thousands of kilometers using the earth’s magnetic field. Having evolved from DNA-repairing photolyases, cryptochromes have redirected the energy from light to fuel a variety of other functions: as photoreceptors, as regulators of the circadian clock – and, in some species, most likely as sensors of the magnetic field. While the quantum effects of magnetic fields on cryptochromes are already being studied in detail, almost nothing is known about the signaling cascade involving cryptochrome as the primary receptor protein. Two different screening methods have identified potential interaction partners that suggest an involvement of the visual phototransduction pathway, the visual cycle, potassium channels or glutamate receptors, but more pioneering research is needed to unravel the signaling cascade responsible for transducing the magnetic signal.

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来源期刊

Neuroforum NEUROSCIENCES-

CiteScore

1.70

自引率

0.00%

发文量

期刊介绍： Neuroforum publishes invited review articles from all areas in neuroscience. Readership includes besides basic and medical neuroscientists also journalists, practicing physicians, school teachers and students. Neuroforum reports on all topics in neuroscience – from molecules to the neuronal networks, from synapses to bioethics.