SCRaMbLE generates designed combinatorial stochastic diversity in synthetic chromosomes
Yue Shen,Giovanni Stracquadanio,Yun Wang,Kun Yang,Leslie A. Mitchell,Leslie A. Mitchell,Yaxin Xue,Yizhi Cai,Tai Chen,Jessica S. Dymond,Kang Kang,Jianhui Gong,Xiaofan Zeng,Yongfen Zhang,Yingrui Li,Qiang Feng,Xun Xu,Jun Wang,Jun Wang,Jian Wang,Huanming Yang,Jef D. Boeke,Joel S. Bader +22 more
TL;DR: Synthetic chromosome rearrangement and modification by loxP-mediated evolution (SCRaMbLE) generates genome diversity in designated regions, reveals fitness constraints, and should scale to simultaneous evolution of multiple synthetic chromosomes.
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Abstract: Synthetic chromosome rearrangement and modification by loxP-mediated evolution (SCRaMbLE) generates combinatorial genomic diversity through rearrangements at designed recombinase sites. We applied SCRaMbLE to yeast synthetic chromosome arm synIXR (43 recombinase sites) and then used a computational pipeline to infer or unscramble the sequence of recombinations that created the observed genomes. Deep sequencing of 64 synIXR SCRaMbLE strains revealed 156 deletions, 89 inversions, 94 duplications, and 55 additional complex rearrangements; several duplications are consistent with a double rolling circle mechanism. Every SCRaMbLE strain was unique, validating the capability of SCRaMbLE to explore a diverse space of genomes. Rearrangements occurred exclusively at designed loxPsym sites, with no significant evidence for ectopic rearrangements or mutations involving synthetic regions, the 99% nonsynthetic nuclear genome, or the mitochondrial genome. Deletion frequencies identified genes required for viability or fast growth. Replacement of 3' UTR by non-UTR sequence had surprisingly little effect on fitness. SCRaMbLE generates genome diversity in designated regions, reveals fitness constraints, and should scale to simultaneous evolution of multiple synthetic chromosomes.
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Design of a synthetic yeast genome
Sarah M. Richardson,Sarah M. Richardson,Leslie A. Mitchell,Leslie A. Mitchell,Giovanni Stracquadanio,Giovanni Stracquadanio,Giovanni Stracquadanio,Kun Yang,Kun Yang,Jessica S. Dymond,James E. DiCarlo,Dongwon Lee,Cheng Lai Victor Huang,Srinivasan Chandrasegaran,Yizhi Cai,Yizhi Cai,Jef D. Boeke,Jef D. Boeke,Joel S. Bader,Joel S. Bader +19 more
TL;DR: Complete design of a synthetic eukaryotic genome, Sc2.0, a highly modified Saccharomyces cerevisiae genome reduced in size by nearly 8%, with 1.1 megabases of the synthetic genome deleted, inserted, or altered is described.
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Deep functional analysis of synII, a 770-kilobase synthetic yeast chromosome
Yue Shen,Yun Wang,Tai Chen,Feng Gao,Jianhui Gong,Dariusz Abramczyk,Roy Walker,Zhao Hongcui,Shihong Chen,Wei Liu,Yisha Luo,Carolin A. Müller,Adrien Paul-Dubois-Taine,Bonnie Alver,Giovanni Stracquadanio,Giovanni Stracquadanio,Leslie A. Mitchell,Zhouqing Luo,Yanqun Fan,Baojin Zhou,Bo Wen,Fengji Tan,Yujia Wang,Jin Zi,Ze-Xiong Xie,Bing-Zhi Li,Kun Yang,Sarah M. Richardson,Hui Jiang,Christopher E. French,Conrad A. Nieduszynski,Romain Koszul,Adele L. Marston,Ying-Jin Yuan,Jian Wang,Joel S. Bader,Joel S. Bader,Junbiao Dai,Jef D. Boeke,Xun Xu,Yizhi Cai,Huanming Yang +41 more
TL;DR: It is demonstrated that synII segregates, replicates, and functions in a highly similar fashion compared with its wild-type counterpart, and the iterative “design-build-test-debug” cycle methodology will facilitate progression of the Sc2.0 project in the face of the increasing synthetic genome complexity.
Recent advances in synthetic biology for engineering isoprenoid production in yeast
TL;DR: Recent advances in central carbon metabolism engineering to increase precursor supply, re-directing carbon flux for production of C10, C15, or C20 isoprenoids, and chemical decoration of high value diterpenoids (C20) are reviewed.
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Under pressure: evolutionary engineering of yeast strains for improved performance in fuels and chemicals production
TL;DR: Advances in research on synthetic regulatory circuits offer exciting possibilities to extend the applicability of evolutionary engineering to products of yeasts whose synthesis requires a net input of cellular energy.
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Precise control of SCRaMbLE in synthetic haploid and diploid yeast.
Bin Jia,Yi Wu,Bing-Zhi Li,Leslie A. Mitchell,Hong Liu,Shuo Pan,Juan Wang,Hao Ran Zhang,Nan Jia,Bo Li,Michael Shen,Ze-Xiong Xie,Duo Liu,Ying Xiu Cao,Xia Li,Xiao Zhou,Hao Qi,Jef D. Boeke,Ying-Jin Yuan +18 more
TL;DR: A genetic AND gate is constructed to enable precise control of the SCRaMbLE method to generate synthetic haploid and diploid yeast with desired phenotypes and is potentially a powerful tool for increasing the production of bio-based chemicals and for mining deep knowledge.
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