Graduate School of Natural Science and Technology, Okayama University, Okayama, Japan.
Neurobiology and Genetics, Theodor-Boveri Institute, Biocenter, University of Würzburg, Würzburg, Germany.
J Biol Rhythms. 2024 Oct;39(5):463-483. doi: 10.1177/07487304241263130. Epub 2024 Jul 31.
Animal circadian clocks play a crucial role in regulating behavioral adaptations to daily environmental changes. The fruit fly exhibits 2 prominent peaks of activity in the morning and evening, known as morning (M) and evening (E) peaks. These peaks are controlled by 2 distinct circadian oscillators located in separate groups of clock neurons in the brain. To investigate the clock neurons responsible for the M and E peaks, a cell-specific gene expression system, the GAL4-UAS system, has been commonly employed. In this study, we re-examined the two-oscillator model for the M and E peaks of by utilizing more than 50 Gal4 lines in conjunction with the line, which enables the restoration of the clock function in specific cells in the () null mutant background. Previous studies have indicated that the group of small ventrolateral neurons (s-LN) is responsible for controlling the M peak, while the other group, consisting of the 5 ventrolateral neuron (5 LN) and the three cryptochrome (CRY)-positive dorsolateral neurons (LN), is responsible for the E peak. Furthermore, the group of posterior dorsal neurons 1 (DN) is thought to also contain M and E oscillators. In this study, we found that Gal4 lines directed at the same clock neuron groups can lead to different results, underscoring the fact that activity patterns are influenced by many factors. Nevertheless, we were able to confirm previous findings that the entire network of circadian clock neurons controls M and E peaks, with the lateral neurons playing a dominant role. In addition, we demonstrate that 4 to 6 CRY-positive DN cells are sufficient to generate M and E peaks in light-dark cycles and complex free-running rhythms in constant darkness. Ultimately, our detailed screening could serve as a catalog to choose the best Gal4 lines that can be used to rescue in specific clock neurons.
动物生物钟在调节对日常环境变化的行为适应方面起着至关重要的作用。果蝇表现出明显的晨(M)和晚(E)两个活动高峰,这些高峰由位于大脑中不同时钟神经元群中的两个不同的生物钟振荡器控制。为了研究负责 M 和 E 高峰的时钟神经元,人们通常使用一种细胞特异性基因表达系统,即 GAL4-UAS 系统。在这项研究中,我们利用超过 50 条 Gal4 线,并结合 线,重新检查了 的 M 和 E 高峰的双振荡器模型,该线能够在 () null 突变背景下的特定细胞中恢复时钟功能。以前的研究表明,小腹外侧神经元(s-LN)群负责控制 M 高峰,而另一群由 5 个腹外侧神经元(5 LN)和 3 个隐色素(CRY)阳性背外侧神经元(LN)组成的神经元群负责控制 E 高峰。此外,认为后部背侧神经元 1 (DN)群也包含 M 和 E 振荡器。在这项研究中,我们发现针对同一时钟神经元群的 Gal4 线可能会导致不同的结果,这表明活动模式受到许多因素的影响。尽管如此,我们还是能够证实以前的发现,即整个生物钟神经元网络控制 M 和 E 高峰,外侧神经元起着主导作用。此外,我们证明了 4 到 6 个 CRY 阳性的 DN 细胞足以在光暗循环和恒定黑暗中的复杂自由运行节律中产生 M 和 E 高峰。最终,我们详细的筛选可以作为一个目录,选择最好的 Gal4 线,用于在特定的时钟神经元中拯救 。
