Targeting Transcriptional and Translational Hindrances in a Modular T7RNAP Expression System in Engineered Pseudomonas putida.

The T7 RNA polymerase is considered one of the most popular tools for heterologous gene expression in the gold standard biotechnological host Escherichia coli. However, the exploitation of this tool in other prospective hosts, such as the biotechnologically relevant bacterium Pseudomonas putida, is still very scarce. The majority of the existing T7-based systems in P. putida show low expression strengths and possess only weak controllability. A fundamental understanding of these systems is necessary in order to design robust and predictable biotechnological processes. To fill this gap, we established and characterized a modular T7 RNA polymerase-based system for heterologous protein production in P. putida, using the enhanced Green Fluorescent Protein (eGFP) as an easy-to-quantify reporter protein. We have effectively targeted the limitations associated with the initial genetic setup of the system, such as slow growth and low protein production rates. By replacing the T7 phage-inherent TΦ terminator downstream of the heterologous gene with the synthetic tZ terminator, growth and protein production rates improved drastically, and the T7 RNA polymerase system reached a productivity level comparable to that of an intrinsic RNA polymerase-based system. Furthermore, we were able to show that the system was saturated with T7 RNA polymerase by applying a T7 RNA polymerase ribosome binding site library to tune heterologous protein production. This saturation indicates an essential role for the ribosome binding sites of the T7 RNA polymerase since, in an oversaturated system, cellular resources are lost to the synthesis of unnecessary T7 RNA polymerase. Eventually, we combined the experimental data into a model that can predict the eGFP production rate with respect to the relative strength of the ribosome binding sites upstream of the T7 gene.

[1]  Jun Sun,et al.  Construction of T7-Like Expression System in Pseudomonas putida KT2440 to Enhance the Heterologous Expression Level , 2021, Frontiers in Chemistry.

[2]  V. M. D. Martins dos Santos,et al.  A navigation guide of synthetic biology tools for Pseudomonas putida. , 2021, Biotechnology advances.

[3]  J. Keasling,et al.  A synthetic RNA-mediated evolution system in yeast , 2021, bioRxiv.

[4]  E. A. Moreb,et al.  Escherichia coli Cas1/2 Endonuclease Complex Modifies Self-Targeting CRISPR/Cascade Spacers Reducing Silencing Guide Stability. , 2020, ACS synthetic biology.

[5]  Christoph Wittmann,et al.  Industrial biotechnology of Pseudomonas putida: advances and prospects , 2020, Applied Microbiology and Biotechnology.

[6]  L. Regestein,et al.  Rational design of flavonoid production routes using combinatorial and precursor-directed biosynthesis. , 2020, ACS synthetic biology.

[7]  Jennifer N. Hennigan,et al.  Improved, two-stage protein expression and purification via autoinduction of both autolysis and auto DNA/RNA hydrolysis conferred by phage lysozyme and DNA/RNA endonuclease. , 2020, Biotechnology and bioengineering.

[8]  D. Daley,et al.  Improved designs for pET expression plasmids increase protein production yield in Escherichia coli , 2020, Communications Biology.

[9]  U. Rinas,et al.  Recombinant protein production associated growth inhibition results mainly from transcription and not from translation , 2020, Microbial Cell Factories.

[10]  James Alastair McLaughlin,et al.  SEVA 3.0: an update of the Standard European Vector Architecture for enabling portability of genetic constructs among diverse bacterial hosts , 2019, Nucleic Acids Res..

[11]  Xiao Liang,et al.  Integrating T7 RNA Polymerase and Its Cognate Transcriptional Units for a Host-Independent and Stable Expression System in Single Plasmid. , 2018, ACS synthetic biology.

[12]  A. Nielsen,et al.  Broad-Host-Range ProUSER Vectors Enable Fast Characterization of Inducible Promoters and Optimization of p-Coumaric Acid Production in Pseudomonas putida KT2440. , 2016, ACS synthetic biology.

[13]  N. Wierckx,et al.  Tn7-Based Device for Calibrated Heterologous Gene Expression in Pseudomonas putida. , 2015, ACS synthetic biology.

[14]  G. Stan,et al.  Quantifying cellular capacity identifies gene expression designs with reduced burden , 2015, Nature Methods.

[15]  Gerald Striedner,et al.  Preventing T7 RNA polymerase read-through transcription-A synthetic termination signal capable of improving bioprocess stability. , 2015, ACS synthetic biology.

[16]  R. Takors,et al.  Genome reduction boosts heterologous gene expression in Pseudomonas putida , 2015, Microbial Cell Factories.

[17]  V. de Lorenzo,et al.  Pseudomonas 2.0: genetic upgrading of P. putida KT2440 as an enhanced host for heterologous gene expression , 2014, Microbial Cell Factories.

[18]  Germán L. Rosano,et al.  Recombinant protein expression in Escherichia coli: advances and challenges , 2014, Front. Microbiol..

[19]  Ivan B. N. Clark,et al.  Unmixing of fluorescence spectra to resolve quantitative time-series measurements of gene expression in plate readers , 2014, BMC Biotechnology.

[20]  Ron Milo,et al.  Quantifying translational coupling in E. coli synthetic operons using RBS modulation and fluorescent reporters. , 2013, ACS synthetic biology.

[21]  Jae-Seong Yang,et al.  Predictive design of mRNA translation initiation region to control prokaryotic translation efficiency. , 2013, Metabolic engineering.

[22]  Stephan Thies,et al.  Novel broad host range shuttle vectors for expression in Escherichia coli, Bacillus subtilis and Pseudomonas putida. , 2012, Journal of biotechnology.

[23]  T. Drepper,et al.  A T7 RNA polymerase-based toolkit for the concerted expression of clustered genes. , 2012, Journal of biotechnology.

[24]  A. C. Forster,et al.  Multigene expression in vivo: Supremacy of large versus small terminators for T7 RNA polymerase , 2012, Biotechnology and bioengineering.

[25]  M. Silby,et al.  Pseudomonas genomes: diverse and adaptable. , 2011, FEMS microbiology reviews.

[26]  A. C. Forster,et al.  Engineering multigene expression in vitro and in vivo with small terminators for T7 RNA polymerase , 2009, Biotechnology and bioengineering.

[27]  A Kremling,et al.  Comment on mathematical models which describe transcription and calculate the relationship between mRNA and protein expression ratio. , 2007, Biotechnology and bioengineering.

[28]  Silvia Kuhlmann,et al.  Metabolic engineering of Pseudomonas putida for methylmalonyl-CoA biosynthesis to enable complex heterologous secondary metabolite formation. , 2006, Chemistry & biology.

[29]  Leemor Joshua-Tor,et al.  Strategies for protein coexpression in Escherichia coli , 2006, Nature Methods.

[30]  T. Elston,et al.  Stochasticity in gene expression: from theories to phenotypes , 2005, Nature Reviews Genetics.

[31]  O. White,et al.  Complete genome sequence and comparative analysis of the metabolically versatile Pseudomonas putida KT2440. , 2002, Environmental microbiology.

[32]  V. de Lorenzo,et al.  A T7 RNA polymerase-based system for the construction of Pseudomonas strains with phenotypes dependent on TOL-meta pathway effectors. , 1993, Gene.

[33]  F. Studier,et al.  Controlling basal expression in an inducible T7 expression system by blocking the target T7 promoter with lac repressor. , 1991, Journal of molecular biology.

[34]  R. Miller,et al.  One-step preparation of competent Escherichia coli: transformation and storage of bacterial cells in the same solution. , 1989, Proceedings of the National Academy of Sciences of the United States of America.

[35]  F. Studier,et al.  Use of bacteriophage T7 RNA polymerase to direct selective high-level expression of cloned genes. , 1986, Journal of molecular biology.

[36]  C. Richardson,et al.  A bacteriophage T7 RNA polymerase/promoter system for controlled exclusive expression of specific genes. , 1985, Proceedings of the National Academy of Sciences of the United States of America.

[37]  F. Studier,et al.  Complete nucleotide sequence of bacteriophage T7 DNA and the locations of T7 genetic elements. , 1983, Journal of molecular biology.