Heat-Shock Response Transcriptional Program Enables High-Yield and High-Quality Recombinant Protein Production in Escherichia coli

The biosynthesis of soluble, properly folded recombinant proteins in large quantities from Escherichia coli is desirable for academic research and industrial protein production. The basal E. coli protein homeostasis (proteostasis) network capacity is often insufficient to efficiently fold overexpressed proteins. Herein we demonstrate that a transcriptionally reprogrammed E. coli proteostasis network is generally superior for producing soluble, folded, and functional recombinant proteins. Reprogramming is accomplished by overexpressing a negative feedback deficient heat-shock response transcription factor before and during overexpression of the protein-of-interest. The advantage of transcriptional reprogramming versus simply overexpressing select proteostasis network components (e.g., chaperones and co-chaperones, which has been explored previously) is that a large number of proteostasis network components are upregulated at their evolved stoichiometry, thus maintaining the system capabilities of the proteostasis network that are currently incompletely understood. Transcriptional proteostasis network reprogramming mediated by stress-responsive signaling in the absence of stress should also be useful for protein production in other cells.

• Publication year

  2014

• Venue

  ACS Chemical Biology

• Publication date

  2014-07-22

• Fields of study

  Biology, Medicine, Engineering

• Identifiers
  DOI 10.1021/cb5004477PMID 25051296PMCID 4168666
• External record

  Open on Semantic Scholar

• Source metadata

  Semantic Scholar, PubMed

• No claims are published for this paper.

• No concepts are published for this paper.

• Protein Misfolding

  2019cited by this paper
• Characterizing the Altered Cellular Proteome Induced by the Stress-Independent Activation of Heat Shock Factor 1

  2014cited by this paper
• Exploration of alternate catalytic mechanisms and optimization strategies for retroaldolase design.

  2014cited by this paper
• Co-expression of a heat shock transcription factor to improve conformational quality of recombinant protein in Escherichia coli.

  2014cited by this paper
• Small molecule probes to quantify the functional fraction of a specific protein in a cell with minimal folding equilibrium shifts

  2014cited by this paper
• Stress-independent activation of XBP1s and/or ATF6 reveals three functionally diverse ER proteostasis environments.

  2013cited by this paper
• Molecular chaperone functions in protein folding and proteostasis.

  2013cited by this paper
• Broadly applicable methodology for the rapid and dosable small molecule-mediated regulation of transcription factors in human cells.

  2013cited by this paper
• Activation of Hsp70 reduces neurotoxicity by promoting polyglutamine protein degradation

  2012cited by this paper
• Molecular and chemical chaperones for improving the yields of soluble recombinant proteins.

  2011cited by this paper
• Molecular chaperones in protein folding and proteostasis

  2011cited by this paper
• Molecular and chemical chaperones for improving the yields of soluble recombinant proteins.

  2011cited by this paper
• Small Molecule Proteostasis Regulators for Protein Conformational Diseases

  2011cited by this paper
• pHsh vectors, a novel expression system of Escherichia coli for the large-scale production of recombinant enzymes

  2010cited by this paper
• Production of recombinant proteins in E. coli by the heat inducible expression system based on the phage lambda pL and/or pR promoters

  2010cited by this paper
• Biological and chemical approaches to diseases of proteostasis deficiency.

  2009cited by this paper
• Converging concepts of protein folding in vitro and in vivo

  2009cited by this paper
• Disulfide-linked protein folding pathways.

  2008cited by this paper
• Adapting Proteostasis for Disease Intervention

  2008cited by this paper
• Analysis of σ32 mutants defective in chaperone-mediated feedback control reveals unexpected complexity of the heat shock response

  2007cited by this paper
• Analysis of sigma32 mutants defective in chaperone-mediated feedback control reveals unexpected complexity of the heat shock response.

  2007cited by this paper
• Protocol for preparing proteins with improved solubility by co-expressing with molecular chaperones in Escherichia coli

  2007cited by this paper
• Two families of chaperonin: physiology and mechanism.

  2007cited by this paper
• Protocol for preparing proteins with improved solubility by co-expressing with molecular chaperones in Escherichia coli.

  2007cited by this paper
• High-level Expression of an α-l-arabinofuranosidase from Thermotoga maritima in Escherichia coli for the Production of Xylobiose from Xylan

  2006cited by this paper
• Molecular chaperones and protein quality control.

  2006cited by this paper
• The Global Transcriptional Response of Escherichia coli to Induced σ32 Protein Involves σ32 Regulon Activation Followed by Inactivation and Degradation of σ32 in Vivo*

  2005cited by this paper
• The global transcriptional response of Escherichia coli to induced sigma 32 protein involves sigma 32 regulon activation followed by inactivation and degradation of sigma 32 in vivo.

  2005cited by this paper
• Recombinant protein folding and misfolding in Escherichia coli

  2004cited by this paper
• Bacteria co-transformed with recombinant proteins and chaperones cloned in independent plasmids are suitable for expression tuning.

  2004cited by this paper
• Bacteria co-transformed with recombinant proteins and chaperones cloned in independent plasmids are suitable for expression tuning.

  2004cited by this paper
• A chaperone network controls the heat shock response in E. coli.

  2004cited by this paper
• Improving heterologous protein folding via molecular chaperone and foldase co-expression.

  2003cited by this paper
• Getting Newly Synthesized Proteins Minireview into Shape

  2000cited by this paper
• Identification of in vivo substrates of the chaperonin GroEL

  1999cited by this paper
• Substrate specificity of the DnaK chaperone determined by screening cellulose‐bound peptide libraries

  1997cited by this paper
• Molecular chaperones, folding catalysts, and the recovery of active recombinant proteins fromE. coli

  1997cited by this paper
• Protein Misfolding and Inclusion Body Formation in Recombinant Escherichia coli Cells Overexpressing Heat-shock Proteins (*)

  1996cited by this paper
• The heat shock response of E. coli is regulated by changes in the concentration of sigma 32.

  1987cited by this paper
• The heat shock response of E. coli is regulated by changes in the concentration of σ32

  1987cited by this paper
• The heat-shock response.

  1986cited by this paper
• The heat shock response.

  1985cited by this paper

• Shelf-life extension of turbot using theaflavin-3,3'-digallate: A growth-neutral quorum sensing inhibitor targeting Hafnia alvei.

  2026cites this paper
• Transcription factor condensates, 3D clustering, and gene expression enhancement of the MET regulon

  2024cites this paper
• Transcription Factor Condensates Mediate Clustering of MET Regulon and Enhancement in Gene Expression

  2024cites this paper
• Constitutive Activation of RpoH and the Addition of L-arabinose Influence Antibiotic Sensitivity of PHL628 E. coli

  2024cites this paper
• Synthetic activation of yeast stress response improves secretion of recombinant proteins.

  2023cites this paper
• Takashi Yura: pioneer, visionary scientist, friend

  2023cites this paper
• Folding of heterologous proteins in bacterial cell factories: Cellular mechanisms and engineering strategies.

  2022cites this paper
• N-terminal domain of TDP43 enhances liquid-liquid phase separation of globular proteins.

  2021cites this paper
• Effect of restricted dissolved oxygen on expression of Clostridium difficile toxin A subunit from E. coli

  2020cites this paper
• Heat-responsive and time-resolved transcriptome and metabolome analyses of Escherichia coli uncover thermo-tolerant mechanisms

  2020cites this paper
• The companion of cellulose synthase 1 confers salt tolerance through a Tau-like mechanism in plants

  2019cites this paper
• Over‐Expression of Functionally Active Inclusion Bodies of Enzymes in Recombinant Escherichia coli

  2018cites this paper
• Nuclear, Cytosolic, and Surface-Localized Poly(A)-Binding Proteins of Plasmodium yoelii

  2018cites this paper
• A Molecular Rotor-Based Halo-Tag Ligand Enables a Fluorogenic Proteome Stress Sensor to Detect Protein Misfolding in Mildly Stressed Proteome.

  2018cites this paper
• A molecular mechanism for salt stress-induced microtubule array formation in Arabidopsis

  2018cites this paper
• Translation efficiency is maintained at elevated temperature in E. coli

  2017cites this paper
• Transcriptome analysis of Corynebacterium glutamicum in the process of recombinant protein expression in bioreactors

  2017cites this paper
• Burden-driven feedback control of gene expression

  2017cites this paper
• Bacterial proteostasis balances energy and chaperone utilization efficiently

  2017cites this paper
• Hydroxycinnamic acids and curcumin production in engineered Escherichia coli using heat shock promoters

  2017cites this paper
• Potential Applications of the Escherichia coli Heat Shock Response in Synthetic Biology.

  2017cites this paper
• Translation efficiency is maintained at elevated temperature in Escherichia coli

  2017cites this paper
• Exploring the Impact of the E. coli Proteostasis Network on the Folding Fate of Proteins with Different Intrinsic Biophysical Properties

  2016influential citation
• Fluorescence Turn-On Folding Sensor To Monitor Proteome Stress in Live Cells

  2015cites this paper
• Individual and collective contributions of chaperoning and degradation to protein homeostasis in E. coli.

  2015cites this paper