Generating complex patterns of gene expression without regulatory circuits

Synthetic biology has successfully advanced our ability to design complex, time-varying genetic circuits executing precisely specified gene expression patterns. However, such circuits usually require regulatory genes whose only purpose is to regulate the expression of other genes. When designing very small genetic constructs, such as viral genomes, we may want to avoid introducing such auxiliary gene products. To this end, here we demonstrate that varying only the placement and strengths of promoters, terminators, and RNase cleavage sites in a computational model of a bacteriophage genome is sufficient to achieve solutions to a variety of basic expression patterns. We discover these solutions by computationally evolving genomes to reproduce desired target expression patterns. Our approach shows non-trivial patterns can be evolved, including patterns in which the relative ordering of genes by abundance changes over time. We find that some patterns are easier to evolve than others, and different genomes that express comparable expression patterns may differ in their genetic architecture. Our work opens up a novel avenue to genome engineering via fine-tuning the balance of gene expression and gene degradation rates.

[1]  J. Bull,et al.  Evolutionarily Stable Attenuation by Genome Rearrangement in a Virus , 2013, G3: Genes, Genomes, Genetics.

[2]  Vincent J. Denef,et al.  A genomic catalog of Earth’s microbiomes , 2020, Nature Biotechnology.

[3]  T. Lu,et al.  Phage-Based Applications in Synthetic Biology. , 2018, Annual review of virology.

[4]  T. Lu,et al.  Genetically Engineered Phages: a Review of Advances over the Last Decade , 2016, Microbiology and Molecular Reviews.

[5]  Ashley I. Teufel,et al.  Accelerated simulation of evolutionary trajectories in origin–fixation models , 2016, bioRxiv.

[6]  D. Endy,et al.  A fully decompressed synthetic bacteriophage øX174 genome assembled and archived in yeast. , 2012, Virology.

[7]  Eric Klavins,et al.  Automated design of thousands of nonrepetitive parts for engineering stable genetic systems , 2020, Nature Biotechnology.

[8]  J. Bähler,et al.  Tuning gene expression to changing environments: from rapid responses to evolutionary adaptation , 2008, Nature Reviews Genetics.

[9]  Benjamin R. Jack,et al.  Reduced Protein Expression in a Virus Attenuated by Codon Deoptimization , 2017, G3: Genes, Genomes, Genetics.

[10]  P. Jaschke,et al.  A high-resolution map of bacteriophage ϕX174 transcription. , 2020, Virology.

[11]  Christopher A. Voigt,et al.  Refactoring the nitrogen fixation gene cluster from Klebsiella oxytoca , 2012, Proceedings of the National Academy of Sciences.

[12]  R. Aebersold,et al.  On the Dependency of Cellular Protein Levels on mRNA Abundance , 2016, Cell.

[13]  Benjamin R. Jack,et al.  Transcript degradation and codon usage regulate gene expression in a lytic phage† , 2019, bioRxiv.

[14]  Timothy K Lu,et al.  Engineered bacteriophage targeting gene networks as adjuvants for antibiotic therapy , 2009, Proceedings of the National Academy of Sciences.

[15]  J. Bull,et al.  Gene order constrains adaptation in bacteriophage T7. , 2005, Virology.

[16]  I. Wang,et al.  Lysis Timing and Bacteriophage Fitness , 2006, Genetics.

[17]  D. Endy,et al.  Computation, prediction, and experimental tests of fitness for bacteriophage T7 mutants with permuted genomes. , 2000, Proceedings of the National Academy of Sciences of the United States of America.

[18]  R. Schooley,et al.  Engineered bacteriophages for treatment of a patient with a disseminated drug resistant Mycobacterium abscessus , 2019, Nature Medicine.

[19]  Yizhi Cai,et al.  Design of a synthetic yeast genome , 2017, Science.

[20]  U. Alon,et al.  Central dogma rates and the trade-off between precision and economy in gene expression , 2019, Nature Communications.

[21]  Christopher A. Voigt,et al.  Principles of genetic circuit design , 2014, Nature Methods.

[22]  U. Alon,et al.  Optimality and evolutionary tuning of the expression level of a protein , 2005, Nature.

[23]  Craig R. Miller,et al.  ΦX174 Attenuation by Whole-Genome Codon Deoptimization , 2020, bioRxiv.

[24]  T. Erb,et al.  A synthetic pathway for the fixation of carbon dioxide in vitro , 2016, Science.

[25]  Claus O Wilke,et al.  Pinetree: a step-wise gene expression simulator with codon-specific translation rates , 2019, Bioinform..

[26]  Christopher A. Voigt,et al.  Genetic circuit design automation , 2016, Science.

[27]  Drew Endy,et al.  TABASCO: A single molecule, base-pair resolved gene expression simulator , 2007, BMC Bioinformatics.

[28]  Tanja Kortemme,et al.  Cost-Benefit Tradeoffs in Engineered lac Operons , 2012, Science.

[29]  Drew Endy,et al.  Refactored M13 bacteriophage as a platform for tumor cell imaging and drug delivery. , 2012, ACS synthetic biology.

[30]  D. Endy,et al.  Definitive demonstration by synthesis of genome annotation completeness , 2018, Proceedings of the National Academy of Sciences.

[31]  J. Bull,et al.  Viral attenuation by engineered protein fragmentation , 2018, Virus evolution.

[32]  D. Endy,et al.  Intracellular kinetics of a growing virus: a genetically structured simulation for bacteriophage T7. , 1997, Biotechnology and bioengineering.

[33]  Georgios A. Pavlopoulos,et al.  Uncovering Earth’s virome , 2016, Nature.

[34]  Rob Lavigne,et al.  Exploring the synthetic biology potential of bacteriophages for engineering non-model bacteria , 2020, Nature Communications.

[35]  Benjamin R. Jack,et al.  Combinatorial Approaches to Viral Attenuation , 2018, mSystems.

[36]  W. Mcallister,et al.  Regulation of transcription of the late genes of bacteriophage T7. , 1978, Proceedings of the National Academy of Sciences of the United States of America.

[37]  George M. Church,et al.  Design, synthesis, and testing toward a 57-codon genome , 2016, Science.

[38]  Drew Endy,et al.  Precise and reliable gene expression via standard transcription and translation initiation elements , 2013, Nature Methods.

[39]  Vivek K. Mutalik,et al.  Composability of regulatory sequences controlling transcription and translation in Escherichia coli , 2013, Proceedings of the National Academy of Sciences.

[40]  Gene-Wei Li,et al.  Evolutionary Convergence of Pathway-Specific Enzyme Expression Stoichiometry , 2018, Cell.

[41]  Christopher J Petzold,et al.  Programming mRNA decay to modulate synthetic circuit resource allocation , 2016, Nature Communications.

[42]  Christopher A. Voigt,et al.  Genetic circuit characterization by inferring RNA polymerase movement and ribosome usage , 2020, Nature Communications.

[43]  M. Elowitz,et al.  A synthetic oscillatory network of transcriptional regulators , 2000, Nature.

[44]  M. Linial,et al.  Gene overlapping and size constraints in the viral world , 2016, Biology Direct.

[45]  Yan Zhang,et al.  Programmable RNA Cleavage and Recognition by a Natural CRISPR-Cas9 System from Neisseria meningitidis. , 2018, Molecular cell.

[46]  Stefan Schuster,et al.  Dynamic optimization identifies optimal programmes for pathway regulation in prokaryotes , 2013, Nature Communications.

[47]  Zaida Luthey-Schulten,et al.  Essential metabolism for a minimal cell , 2019, eLife.

[48]  J. Collins,et al.  Construction of a genetic toggle switch in Escherichia coli , 2000, Nature.

[49]  D. Endy,et al.  Refactoring bacteriophage T7 , 2005, Molecular systems biology.

[50]  Tanja Woyke,et al.  Viral dark matter and virus–host interactions resolved from publicly available microbial genomes , 2015, eLife.

[51]  M. Molloy,et al.  Genome modularization reveals overlapped gene topology is necessary for efficient viral reproduction , 2020, bioRxiv.

[52]  Amnon Amir,et al.  Noise in timing and precision of gene activities in a genetic cascade , 2007 .

[53]  M. Selbach,et al.  mRNAs, proteins and the emerging principles of gene expression control , 2020, Nature Reviews Genetics.

[54]  I. Wang,et al.  Bacteriophage Adsorption Rate and Optimal Lysis Time , 2008, Genetics.

[55]  D. G. Gibson,et al.  Design and synthesis of a minimal bacterial genome , 2016, Science.

[56]  W. Mcallister,et al.  Roles of the Early Genes of Bacteriophage T7 in Shutoff of Host Macromolecular Synthesis , 1977, Journal of virology.