生命网络的合成路线
导语
CRISPR-Cas 基因编辑工具将研究人员带入可以改变世界的合成生物学时代。对这些工具在生物学和医学领域取得的突破而感到兴奋之余,人们也会对它们在开放环境中应用时可能导致错误而感到担忧。研究人员不知道这些基因表达过程(包括基因调控和表观遗传修饰)、进化变化、生态系统相互作用和其他更高级的过程将如何影响自然界中被基因编辑的生物体的性状、适应性和对环境的影响。然而,在“基因驱动时代即将到来”的情况下,预测被编辑的性状或生物在异质、不断变化的环境中的传播、变化和影响尤为重要。为了预测Synthetic threads“合成线”对地球上的生命网络的影响,科学家们必须直面跨越多个生物组织层次的复杂系统相互作用。目前,研究人员缺乏相关的计划、基础设施和资金来让这个科学家在有或没有基因驱动改造的情况下追踪不断在开放环境中运动的新的合成生物。
研究领域:合成生物学,生物网络,生态系统,基因编辑
Mary E. Power | 作者
王帅 | 译者
赵雨亭 | 审校
邓一雪 | 编辑
1. 把基因、形状、生物体和生态系统关联起来:
预测所面临的挑战
研究人员利用自己的心智分离出来的系统实际上不仅包含在更大的系统中,而且还相互重叠、相互联系和相互作用。
Arthur Tansley, 1935 [8]
2. 从基因预测形状
长期以来,人们一直认为基因组中的基因序列是了解该生物体的生物学信息所需要的全部内容。最近,科学家们意识到还有另一个层面的控制信息:表观遗传修饰。
Joseph Ecker, 2020 [12]
3. 从基因和形状预测生物体的表现
4. 基因驱动
5. 从性状预测影响
6. 隐藏的调控过程,神秘的参与者
7. 性状影响的环境依赖性:固氮
8. 修补基因、生命体和生态系统:价值观
9. 在实验室之外得时刻小心谨慎:
追踪合成线在真实环境中的表现的重要性
研究人员想要转移、增强或沉默基因,以便让微生物为自己工作,使研究人员不必为自然选择而烦恼。研究人员将成为微生物代谢的创造者,并将设计微生物来满足研究人员的要求。研究人员有能力这样做,但这种能力似乎并没有使研究人员对微生物进化带来的潜在巨大后果有深入的理解,更不用说让他们能改变地球未来的发展轨迹。
Paul Falkowski [56]
只要保持警惕——通过实地监测——人们就会认识到变化。为什么我们熟知的世界会发生如此大的变化?
Robert T. Paine [96]
弗兰肯斯坦博士的罪行不在于他把狂妄自大和高科技结合起来创造了一种生物,而在于他抛弃了这种生物。[拉图尔随后引用了玛丽雪莱的弗兰肯斯坦:“记住,我是你的生物,”怪物抗议道,“我应该是你的亚当;但我更像是被你无缘无故从欢乐中驱赶的堕落的天使……我是仁慈且善良的;苦难使我变成了恶魔。让我快乐吧,我将再次贤德。”]
Bruno LaTour [97]
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来源:学术经纬 2021-07-15