在果蝇后肠中,加速的细胞周期使器官能够在发育时间限制内进行再生。
Accelerated cell cycles enable organ regeneration under developmental time constraints in the Drosophila hindgut.
机构信息
Department of Cell Biology, Duke University School of Medicine, Durham, USA.
Department of Pharmacology & Cancer Biology, Duke University School of Medicine, Durham, USA.
出版信息
Dev Cell. 2021 Jul 26;56(14):2059-2072.e3. doi: 10.1016/j.devcel.2021.04.029. Epub 2021 May 20.
Abstract
Individual organ development must be temporally coordinated with development of the rest of the organism. As a result, cell division cycles in a developing organ occur on a relatively fixed timescale. Despite this, many developing organs can regenerate cells lost to injury. How organs regenerate within the time constraints of organism development remains unclear. Here, we show that the developing Drosophila hindgut regenerates by accelerating the mitotic cell cycle. This process is achieved by decreasing G1 length and requires the JAK/STAT ligand unpaired-3. Mitotic capacity is then terminated by the steroid hormone ecdysone receptor and the Sox transcription factor Dichaete. These two factors converge on regulation of a hindgut-specific enhancer of fizzy-related, a negative regulator of mitotic cyclins. Our findings reveal how the cell-cycle machinery and cytokine signaling can be adapted to accomplish developmental organ regeneration.
摘要
个体器官的发育必须与机体的其他部分在时间上协调一致。因此,发育器官中的细胞分裂周期发生在相对固定的时间尺度上。尽管如此,许多发育中的器官可以再生因损伤而丢失的细胞。器官如何在机体发育的时间限制内进行再生尚不清楚。在这里,我们发现果蝇的后肠通过加速有丝分裂细胞周期来进行再生。这个过程是通过减少 G1 长度来实现的,需要 JAK/STAT 配体 unpaired-3。有丝分裂能力随后被类固醇激素蜕皮激素受体和 Sox 转录因子 Dichaete 终止。这两个因素集中在 fizzy-related 的后肠特异性增强子的调节上,fizzy-related 是有丝分裂周期蛋白的负调节剂。我们的研究结果揭示了细胞周期机制和细胞因子信号如何适应完成发育器官的再生。
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