Department of Genetics and Evolution, University of Geneva, 30 quai Ernest Ansermet, CH-1211 Geneva-04, Switzerland.
Dev Genes Evol. 2013 Mar;223(1-2):39-52. doi: 10.1007/s00427-012-0411-y. Epub 2012 Jul 26.
The freshwater Hydra polyp provides a unique model system to decipher the mechanisms underlying adult regeneration. Indeed, a single cut initiates two distinct regenerative processes, foot regeneration on one side and head regeneration on the other side, the latter relying on the rapid formation of a local head organizer. Two aspects are discussed here: the asymmetric cellular remodeling induced by mid-gastric bisection and the signaling events that trigger head organizer formation. In head-regenerating tips (but not in foot ones), a wave of cell death takes place immediately, leading the apoptotic cells to transiently release Wnt3 and activate the β-catenin pathway in the neighboring cycling cells to push them through mitosis. This process, which mimics the apoptosis-induced compensatory proliferation process deciphered in Drosophila larvae regenerating their discs, likely corresponds to an evolutionarily conserved mechanism, also at work in Xenopus tadpoles regenerating their tail or mice regenerating their skin or liver. How is this process generated in Hydra? Several studies pointed to the necessary activation of the extracellular signal-regulated kinase (ERK) 1-2 and mitogen-activated protein kinase (MAPK) pathways during early head regeneration. Indeed inhibition of ERK 1-2 or knockdown of RSK, cAMP response element-binding protein (CREB), and CREB-binding protein (CBP) prevent injury-induced apoptosis and head regeneration. The current scenario involves an asymmetric activation of the MAPK/CREB pathway to trigger injury-induced apoptosis in the interstitial cells and in the epithelial cells a CREB/CBP-dependent transcriptional activation of early genes essential for head-organizing activity as wnt3, HyBra1, and prdl-a. The question now is how bisection in the rather uniform central region of the polyp can generate this immediately asymmetric signaling.
淡水水螅水螅提供了一个独特的模型系统,用于破译成年再生背后的机制。事实上,一次切割会引发两种不同的再生过程,一侧是足再生,另一侧是头再生,后者依赖于局部头组织者的快速形成。这里讨论两个方面:中肠二分诱导的不对称细胞重塑和触发头组织者形成的信号事件。在头再生尖端(而不是足再生尖端),立即发生一波细胞死亡,导致凋亡细胞短暂释放 Wnt3,并激活邻近循环细胞中的 β-连环蛋白途径,推动它们通过有丝分裂。这个过程模拟了在再生其盘的果蝇幼虫中解析的凋亡诱导的补偿性增殖过程,可能对应于一种进化上保守的机制,也在再生其尾巴的非洲爪蟾幼体或再生其皮肤或肝脏的小鼠中起作用。这个过程在水螅中是如何产生的?几项研究指出,在早期头部再生过程中,细胞外信号调节激酶(ERK)1-2 和丝裂原激活蛋白激酶(MAPK)途径的必要激活。事实上,ERK 1-2 的抑制或 RSK、cAMP 反应元件结合蛋白(CREB)和 CREB 结合蛋白(CBP)的敲低可防止损伤诱导的细胞凋亡和头部再生。目前的情况涉及 MAPK/CREB 途径的不对称激活,以触发间质细胞中的损伤诱导细胞凋亡,以及上皮细胞中 wnt3、HyBra1 和 prdl-a 等早期基因的 CREB/CBP 依赖性转录激活,这些基因对于头组织活性至关重要。现在的问题是,在水螅相当均匀的中央区域进行二分法如何产生这种立即不对称的信号。
