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Genome Size and the Evolution of New Genes03:21

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While every living organism has a genome of some kind (be it RNA, or DNA), there is considerable variation in the sizes of these blueprints. One major factor that impacts genome size is whether the organism is prokaryotic or eukaryotic. In prokaryotes, the genome contains little to no non-coding sequence, such that genes are tightly clustered in groups or operons sequentially along the chromosome. Conversely, the genes in eukaryotes are punctuated by long stretches of non-coding sequence.
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Other than maintaining genome stability via DNA repair, homologous recombination plays an important role in diversifying the genome. In fact, the recombination of sequences forms the molecular basis of genomic evolution. Random and non-random permutations of genomic sequences create a library of new amalgamated sequences. These newly formed genomes can determine the fitness and survival of cells. In bacteria, homologous and non-homologous types of recombination lead to the evolution of new...
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In a population that is not at Hardy-Weinberg equilibrium, the frequency of alleles changes over time. Therefore, any deviations from the five conditions of Hardy-Weinberg equilibrium can alter the genetic variation of a given population. Conditions that change the genetic variability of a population include mutations, natural selection, non-random mating, gene flow, and genetic drift (small population size).
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Daily Transfers, Archiving Populations, and Measuring Fitness in the Long-Term Evolution Experiment with Escherichia coli
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主体进化改善了复杂生长环境中的遗传电路功能.

Joanna T Zhang1,2, Andrew Lezia1,2, Philip Emmanuele1,2

  • 1Department of Bioengineering, University of California San Diego, La Jolla, California 92093, United States.

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概括
此摘要是机器生成的。

使用适应性实验室进化和定向突变发生来改造大肠杆菌菌株,以改善具有挑战性的环境中的遗传电路功能. 这种方法提高了合成生物学应用的细菌强度.

关键词:
适应性实验室进化的演变.电路设计 电路设计微流体学 在微流体学方面显微镜 显微镜是指使用显微镜.压力优化,应变优化

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科学领域:

  • 合成生物学 合成生物学
  • 微生物工程 微生物工程
  • 遗传电路设计的设计

背景情况:

  • 为复杂的环境设计细菌中可预测的遗传电路是一项挑战.
  • 工程遗传电路的稳定性对于实际应用至关重要.

研究的目的:

  • 在非传统的生长环境中增强大肠杆菌的强大的遗传电路行为.
  • 优化细菌宿主菌株以改善生长和基因电路性能.

主要方法:

  • 适应性实验室进化 (ALE) 适用于埃舍里希亚大肠杆菌MG1655和埃舍里希亚大肠杆菌Nissle.
  • 结合ALE与定向突变发生和高通量微流体查.
  • 采用单一碳源的最小介质和具有反应性氧物种 (ROS) 压力的复杂介质.

主要成果:

  • ALE改善了大肠杆菌MG1655.5中的种群控制电路的动态.
  • 在ROS压力下恢复电路功能和改善E. coliNissle的组件耐受性.
  • 在基因电路应用中证明了增强的细菌强度.

结论:

  • 适应性实验室进化和理性工程在具有挑战性的环境中提高了基因电路性能.
  • 这个框架优化了细菌宿主用于合成生物学应用.
  • 改造后的大肠杆菌菌株表现出更好的强度和基因电路功能.