Kristoffer R. Thomsen, Artemy Kolchinsky, Steen Rasmussen
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引用次数: 0
Abstract
Critical experimental design issues connecting energy transduction and
inheritable information within a protocell are explored and elucidated. The
protocell design utilizes a photo-driven energy transducer (a ruthenium
complex) to turn resource molecules into building blocks, in a manner that is
modulated by a combinatorial DNA-based co-factor. This co-factor molecule
serves as part of an electron relay for the energy transduction mechanism,
where the charge-transport rates depend on the sequence that contains an
oxo-guanine. The co-factor also acts as a store of inheritable information due
to its ability to replicate non-enzymatically through template-directed
ligation. Together, the energy transducer and the co-factor act as a metabolic
catalyst that produces co-factor DNA building blocks as well as fatty acids
(from picolinium ester and modified DNA oligomers), where the fatty acids
self-assemble into vesicles on which exterior surface both the co-factor (DNA)
and the energy transducer are anchored with hydrophobic tails. Here we use
simulations to study how the co-factor sequence determines its fitness as
reflected by charge transfer and replication rates. To estimate the impact on
the protocell, we compare these rates with previously measured metabolic rates
from a similar system where the charge transfer is directly between the
ruthenium complex and the oxo-guanine (without DNA replication and charge
transport). Replication and charge transport turn out to have different and
often opposing sequence requirements. Functional information of the co-factor
molecules is used to probe the feasibility of randomly picking co-factor
sequences from a limited population of co-factors molecules, where a good
co-factor can enhance both metabolic biomass production and its own replication
rate.
本研究探讨并阐明了原电池内连接能量转换和可遗传信息的关键实验设计问题。原电池的设计利用光驱动能量转换器(钌复合物)将资源分子转化为构件,转化方式由基于 DNA 的组合辅助因子调节。这种辅助因子分子是能量转换机制电子中继的一部分,其中电荷转移速率取决于含有缺氧鸟嘌呤的序列。该辅助因子还可以通过模板定向连接进行非酶促复制,从而起到储存可遗传信息的作用。能量转换器和辅助因子共同充当新陈代谢催化剂,产生辅助因子 DNA 构建块以及脂肪酸(来自吡啶甲酸酯和修饰的 DNA 寡聚体)。在这里,我们通过模拟来研究辅助因子序列如何通过电荷转移和复制率来决定其适应性。为了估算对原电池的影响,我们将这些速率与之前从类似系统中测得的代谢速率进行了比较,在该系统中,电荷转移直接发生在钌复合物和氧鸟嘌呤之间(没有 DNA 复制和电荷转移)。结果表明,复制和电荷转移有不同的序列要求,而且往往是相反的。辅助因子分子的功能信息被用来探究从有限的辅助因子分子群中随机挑选辅助因子序列的可行性。