Quality control of inclusion bodies in Escherichia coli

BackgroundBacterial inclusion bodies (IBs) are key intermediates for protein production. Their quality affects the refolding yield and further purification. Recent functional and structural studies have revealed that IBs are not dead-end aggregates but undergo dynamic changes, including aggregation, refunctionalization of the protein and proteolysis. Both, aggregation of the folding intermediates and turnover of IBs are influenced by the cellular situation and a number of well-studied chaperones and proteases are included. IBs mostly contain only minor impurities and are relatively homogenous.ResultsIBs of α-glucosidase of Saccharomyces cerevisiae after overproduction in Escherichia coli contain a large amount of (at least 12 different) major product fragments, as revealed by two-dimensional polyacrylamide gel electrophoresis (2D PAGE). Matrix-Assisted-Laser-Desorption/Ionization-Time-Of-Flight Mass-Spectrometry (MALDI-ToF MS) identification showed that these fragments contain either the N- or the C-terminus of the protein, therefore indicate that these IBs are at least partially created by proteolytic action. Expression of α-glucosidase in single knockout mutants for the major proteases ClpP, Lon, OmpT and FtsH which are known to be involved in the heat shock like response to production of recombinant proteins or to the degradation of IB proteins, clpP, lon, ompT, and ftsH did not influence the fragment pattern or the composition of the IBs. The quality of the IBs was also not influenced by the sampling time, cultivation medium (complex and mineral salt medium), production strategy (shake flask, fed-batch fermentation process), production strength (T5-lac or T7 promoter), strain background (K-12 or BL21), or addition of different protease inhibitors during IB preparation.Conclusionsα-glucosidase is fragmented before aggregation, but neither by proteolytic action on the IBs by the common major proteases, nor during downstream IB preparation. Different fragments co-aggregate in the process of IB formation together with the full-length product. Other intracellular proteases than ClpP or Lon must be responsible for fragmentation. Reaggregation of protease-stable α-glucosidase fragments during in situ disintegration of the existing IBs does not seem to occur.

[1]  J. Corchero,et al.  The position of the heterologous domain can influence the solubility and proteolysis of beta-galactosidase fusion proteins in E. coli. , 1996, Journal of biotechnology.

[2]  C. Chou,et al.  Roles of DegP in Prevention of Protein Misfolding in the Periplasm upon Overexpression of Penicillin Acylase in Escherichia coli , 2003, Journal of bacteriology.

[3]  S. Ventura,et al.  Protein activity in bacterial inclusion bodies correlates with predicted aggregation rates. , 2006, Journal of biotechnology.

[4]  J. Bernhardt,et al.  Specific and general stress proteins in Bacillus subtilis--a two-deimensional protein electrophoresis study. , 1997, Microbiology.

[5]  U. Brinkmann,et al.  High-level expression of recombinant genes in Escherichia coli is dependent on the availability of the dnaY gene product. , 1989, Gene.

[6]  G. Georgiou,et al.  Isolating inclusion bodies from bacteria. , 1999, Methods in enzymology.

[7]  R. Riek,et al.  Solid-state NMR spectroscopy reveals that E. coli inclusion bodies of HET-s(218-289) are amyloids. , 2009, Angewandte Chemie.

[8]  M. Hecker,et al.  The Clp Proteases of Bacillus subtilisAre Directly Involved in Degradation of Misfolded Proteins , 2000, Journal of bacteriology.

[9]  S. Gottesman,et al.  Proteases and their targets in Escherichia coli. , 1996, Annual review of genetics.

[10]  James E. Bailey,et al.  Protein compositional analysis of inclusion bodies produced in recombinant Escherichia coli , 1992, Applied Microbiology and Biotechnology.

[11]  A. Villaverde,et al.  Amyloid-like properties of bacterial inclusion bodies. , 2005, Journal of molecular biology.

[12]  G. Georgiou,et al.  In vivo degradation of secreted fusion proteins by the Escherichia coli outer membrane protease OmpT , 1990, Journal of bacteriology.

[13]  P Neubauer,et al.  Monitoring of genes that respond to overproduction of an insoluble recombinant protein in Escherichia coli glucose-limited fed-batch fermentations. , 2000, Biotechnology and bioengineering.

[14]  G. Georgiou,et al.  Construction and characterization of Escherichia coli strains deficient in multiple secreted proteases: protease III degrades high-molecular-weight substrates in vivo , 1991, Journal of bacteriology.

[15]  H. Hara,et al.  A novel glycan polymerase that synthesizes uncross‐linked peptidoglycan in Escherichia coli , 1984, FEBS letters.

[16]  E. Laskowska,et al.  Degradation by proteases Lon, Clp and HtrA, of Escherichia coli proteins aggregated in vivo by heat shock; HtrA protease action in vivo and in vitro , 1996, Molecular microbiology.

[17]  C. Tu,et al.  Pentobarbital-induced Changes in Drosophila Glutathione S-Transferase D21 mRNA Stability (*) , 1995, The Journal of Biological Chemistry.

[18]  U. Rinas,et al.  Secretion-dependent proteolysis of heterologous protein by recombinant Escherichia coli is connected to an increased activity of the energy-generating dissimilatory pathway. , 1999, Biotechnology and bioengineering.

[19]  Lei Wang Towards revealing the structure of bacterial inclusion bodies , 2009, Prion.

[20]  J. Corchero,et al.  Proteolytic digestion of bacterial inclusion body proteins during dynamic transition between soluble and insoluble forms. , 1999, Biochimica et biophysica acta.

[21]  P. Neubauer,et al.  The small heat-shock proteins IbpA and IbpB reduce the stress load of recombinant Escherichia coli and delay degradation of inclusion bodies , 2005, Microbial cell factories.

[22]  J. Bailey,et al.  Characterization of inclusion bodies in recombinant Escherichia coli producing high levels of porcine somatotropin. , 1993, Journal of biotechnology.

[23]  A. Goldberg,et al.  Production of abnormal proteins in E. coli stimulates transcription of ion and other heat shock genes , 1985, Cell.

[24]  P. Babbitt,et al.  A Novel Activity of OmpT. , 1995, The Journal of Biological Chemistry.

[25]  John C Joly,et al.  High‐level accumulation of a recombinant antibody fragment in the periplasm of Escherichia coli requires a triple‐mutant (degP prc spr) host strain , 2004, Biotechnology and bioengineering.

[26]  Salvador Ventura,et al.  Sequence determinants of protein aggregation: tools to increase protein solubility , 2005, Microbial cell factories.

[27]  M Kandilogiannaki,et al.  Expression of a recombinant human anti-MUC1 scFv fragment in protease-deficient Escherichia coli mutants. , 2001, International journal of molecular medicine.

[28]  A. Goldberg,et al.  Effects of protease inhibitors on protein breakdown in Escherichia coli. , 1972, The Journal of biological chemistry.

[29]  Bernd Bukau,et al.  Thermotolerance Requires Refolding of Aggregated Proteins by Substrate Translocation through the Central Pore of ClpB , 2004, Cell.

[30]  U. Rinas,et al.  Kinetics of Heat‐Shock Response and Inclusion Body Formation During Temperature‐Induced Production of Basic Fibroblast Growth Factor in High‐Cell‐Density Cultures of Recombinant Escherichiacoli , 2000, Biotechnology progress.

[31]  J. Buchner,et al.  Refolding of inclusion body proteins. , 2004, Methods in molecular medicine.

[32]  A. Villaverde,et al.  Protein aggregation in recombinant bacteria: biological role of inclusion bodies , 2003, Biotechnology Letters.

[33]  A. Goldberg,et al.  Rapid degradation of an abnormal protein in Escherichia coli involves the chaperones GroEL and GroES. , 1994, The Journal of biological chemistry.

[34]  J. Gierse,et al.  Two novel heat shock genes encoding proteins produced in response to heterologous protein expression in Escherichia coli , 1992, Journal of bacteriology.

[35]  Antonio Villaverde,et al.  Role of molecular chaperones in inclusion body formation , 2003, FEBS letters.

[36]  J. Corchero,et al.  Tolerance of Escherichia coli β‐galactosidase C‐terminus to different‐sized fusions , 1999 .

[37]  Uwe Völker,et al.  A comprehensive proteome map of growing Bacillus subtilis cells , 2004, Proteomics.

[38]  Jeffrey H. Miller,et al.  A short course in bacterial genetics , 1992 .

[39]  S. Morimura,et al.  Structure and function of the ftsH gene in Escherichia coli. , 1991, Research in microbiology.

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

[41]  E. Laskowska,et al.  Escherichia coli small heat shock proteins IbpA/B enhance activity of enzymes sequestered in inclusion bodies. , 2004, Acta biochimica Polonica.

[42]  R. Moritz,et al.  C-terminal Extension of Truncated Recombinant Proteins in Escherichia coli with a 10Sa RNA Decapeptide(*) , 1995, The Journal of Biological Chemistry.

[43]  P. Neubauer,et al.  Growth Rate Related Concentration Changes of the Starvation Response Regulators σS and ppGpp in Glucose‐Limited Fed‐Batch and Continuous Cultures of Escherichia coli , 1999, Biotechnology progress.

[44]  A. Wawrzynów,et al.  IbpA and IbpB, the new heat-shock proteins, bind to endogenous Escherichia coli proteins aggregated intracellularly by heat shock. , 1996, Biochimie.

[45]  Antonio Villaverde,et al.  Localization of Chaperones DnaK and GroEL in Bacterial Inclusion Bodies , 2005, Journal of bacteriology.

[46]  T. Schweder,et al.  Regulation of Escherichia coli starvation sigma factor (sigma s) by ClpXP protease , 1996, Journal of bacteriology.

[47]  M. Sarvas,et al.  The class 1 outer membrane protein of Neisseria meningitidis produced in Bacillus subtilis can give rise to protective immunity , 1992, Molecular microbiology.

[48]  J. Corchero,et al.  Limited in vivo proteolysis of aggregated proteins. , 1997, Biochemical and biophysical research communications.

[49]  U. Rinas Synthesis Rates of Cellular Proteins Involved in Translation and Protein Folding Are Strongly Altered in Response to Overproduction of Basic Fibroblast Growth Factor by Recombinant Escherichia coli , 1996, Biotechnology progress.

[50]  P. Buckel,et al.  Control of formation of active soluble or inactive insoluble baker's yeast α-glucosidase PI in Escherichia coli by induction and growth conditions , 1989, Molecular and General Genetics MGG.

[51]  P. Valax,et al.  Molecular Characterization of β‐Lactamase Inclusion Bodies Produced in Escherichia coli. 1. Composition , 1993, Biotechnology progress.

[52]  T. Meinnel,et al.  Enzymatic properties of Escherichia coli peptide deformylase , 1995, Journal of bacteriology.

[53]  Hirotada Mori,et al.  Heat shock regulation in the ftsH null mutant of Escherichia coli: dissection of stability and activity control mechanisms of σ32in vivo , 1998, Molecular microbiology.

[54]  M. Hecker,et al.  Stress proteins and cross-protection by heat shock and salt stress in Bacillus subtilis. , 1992, Journal of general microbiology.

[55]  J. Bailey,et al.  Overexpression of bacterial hemoglobin causes incorporation of pre-beta-lactamase into cytoplasmic inclusion bodies , 1993, Applied and environmental microbiology.

[56]  S. Gottesman,et al.  Genetics of proteolysis in Escherichia coli*. , 1989, Annual review of genetics.

[57]  Jimena Weibezahn,et al.  Novel insights into the mechanism of chaperone-assisted protein disaggregation , 2005, Biological chemistry.

[58]  A. Villaverde,et al.  Construction and deconstruction of bacterial inclusion bodies. , 2002, Journal of biotechnology.

[59]  A. Villaverde,et al.  Bacterial inclusion bodies are cytotoxic in vivo in absence of functional chaperones DnaK or GroEL. , 2005, Journal of biotechnology.