Cai Xiaoli, Akber Mira, Spirov Alexander, Baumgartner Stefan
Department of Experimental Medical Sciences, Lund University, Lund, Sweden.
Computer Science Department, Stony Brook University, Stony Brook, NY, United States of America and Sechenov Institute of Evolutionary Physiology and Biochemistry, St. Petersburg, Russia.
PLoS One. 2017 Oct 3;12(10):e0185443. doi: 10.1371/journal.pone.0185443. eCollection 2017.
The Bicoid (Bcd) protein gradient in Drosophila serves as a paradigm for gradient formation in textbooks. The SDD model (synthesis, diffusion, degradation) was proposed to explain the formation of the gradient. The SDD model states that the bcd mRNA is located at the anterior pole of the embryo at all times and serves a source for translation of the Bicoid protein, coupled with diffusion and uniform degradation throughout the embryo. Recently, the ARTS model (active RNA transport, synthesis) challenged the SDD model. In this model, the mRNA is transported at the cortex along microtubules to form a mRNA gradient which serves as template for the production of Bcd, hence little Bcd movement is involved. To test the validity of the SDD model, we developed a sensitive assay to monitor the movement of Bcd during early nuclear cycles. We observed that Bcd moved along the cortex and not in a broad front towards the posterior as the SDD model would have predicted. We subjected embryos to hypoxia where the mRNA remained strictly located at the tip at all times, while the protein was allowed to move freely, thus conforming to an ideal experimental setup to test the SDD model. Unexpectedly, Bcd still moved along the cortex. Moreover, cortical Bcd movement was sparse, even under longer hypoxic conditions. Hypoxic embryos treated with drugs compromising microtubule and actin function affected Bcd cortical movement and stability. Vinblastine treatment allowed the simulation of an ideal SDD model whereby the protein moved throughout the embryo in a broad front. In unfertilized embryos, the Bcd protein followed the mRNA which itself was transported into the interior of the embryo utilizing a hitherto undiscovered microtubular network. Our data suggest that the Bcd gradient formation is probably more complex than previously anticipated.
果蝇中的双尾(Bcd)蛋白梯度是教科书中梯度形成的范例。提出了SDD模型(合成、扩散、降解)来解释梯度的形成。SDD模型指出,bcd mRNA始终位于胚胎的前极,是双尾蛋白翻译的来源,同时在整个胚胎中进行扩散和均匀降解。最近,ARTS模型(活性RNA运输、合成)对SDD模型提出了挑战。在这个模型中,mRNA沿着微管在皮层运输以形成mRNA梯度,该梯度作为产生Bcd的模板,因此几乎没有Bcd的移动。为了测试SDD模型的有效性,我们开发了一种灵敏的检测方法来监测早期核周期中Bcd的移动。我们观察到Bcd沿着皮层移动,而不是像SDD模型所预测的那样在一个宽阔的前沿向后方移动。我们使胚胎处于缺氧状态,在此期间mRNA始终严格位于顶端,而蛋白质可以自由移动,从而符合测试SDD模型的理想实验设置。出乎意料的是,Bcd仍然沿着皮层移动。此外,即使在更长时间的缺氧条件下,皮层Bcd的移动也很稀疏。用破坏微管和肌动蛋白功能的药物处理缺氧胚胎会影响Bcd的皮层移动和稳定性。长春花碱处理可以模拟理想的SDD模型,即蛋白质在整个胚胎中以宽阔的前沿移动。在未受精的胚胎中,Bcd蛋白跟随mRNA,而mRNA本身利用一个迄今未被发现的微管网络被运输到胚胎内部。我们的数据表明,Bcd梯度的形成可能比之前预期的更为复杂。
