We previously demonstrated that E. coli maltose binding protein (MBP) has a remarkable ability to enhance the solubility and promote the proper folding of its fusion partners. For this reason, and because MBP fusion proteins routinely accumulate to very high levels in E. coli, we have made MBP the cornerstone of our approach for high-throughput protein expression and purification. However, MBP fusion proteins do not always bind efficiently to amylose resin, and even when they do the fusion proteins are rarely pure after amylose affinity chromatography. Therefore, to compensate for the relatively poor performance of MBP as an affinity tag, we attempted to incorporate supplementary tags within the general framework of an MBP fusion protein. We identified several locations within the framework of an MBP fusion protein where accessory tags could be added without compromising the ability of MBP to promote the solubility of its fusion partners. We then designed and successfully tested a generic protocol for protein production in E. coli that utilizes a dual His6-MBP affinity tag. The MBP moiety improves the yield and enhances the solubility of the passenger protein while the His-tag facilitates its purification. We are currently working on applying this method in other hosts for heterologous protein expression.Because most affinity tags have the potential to interfere with structural studies, reliable ways to remove them are absolutely necessary. Accordingly, we have invested a substantial effort in trying to exploit the highly specific tobacco etch virus (TEV) protease for this purpose. To improve the solubility of TEV protease in E. coli, we designed an expression vector that produces the enzyme in the form of an MBP fusion protein that cleaves itself in vivo to generate an N-terminally His-tagged TEV protease catalytic domain that is free of MBP. A dramatic increase in the yield of TEV protease was realized by using a tRNA accessory plasmid to compensate for the presence of arginine codons that are rarely used in E. coli. We also devised a simple method for intracellular processing of fusion proteins by TEV protease, which is used to determine whether or not a passenger protein is likely to be properly folded when it is fused to MBP. We have shown that many different amino acid side chains can be accommodated in the P1? site of a TEV protease recognition site with little or no impact on the efficiency of processing. Consequently, in many cases it is possible to use TEV protease to produce recombinant proteins with no non-native residues attached to their N-termini. Wild-type TEV protease cleaves itself at a specific site to generate a truncated polypeptide with greatly reduced enzymatic activity. We managed to overcome the autolysis problem by constructing a mutant enzyme (S219V) that is nearly impervious to autoinactivation and almost twice as catalytically active as the wild-type enzyme. We have distributed S219V TEV protease expression vectors to hundreds of research laboratories around the world. We have also determined crystal structures of TEV protease complexed with a peptide substrate and an inhibitor, which revealed the structural basis of its stringent sequence specificity. We are currently focusing on the characterization of other highly specific proteases, such as that encoded by the tobacco vein mottling virus (TVMV), which may prove to be useful alternatives to TEV protease.

Agency
National Institute of Health (NIH)
Institute
Division of Basic Sciences - NCI (NCI)
Type
Intramural Research (Z01)
Project #
1Z01BC010341-07
Application #
7338481
Study Section
Mammalian Cell Lines Committee (MCL)
Project Start
Project End
Budget Start
Budget End
Support Year
7
Fiscal Year
2006
Total Cost
Indirect Cost
Name
Basic Sciences
Department
Type
DUNS #
City
State
Country
United States
Zip Code
Zhang, Di; Tozser, Jozsef; Waugh, David S (2009) Molecular cloning, overproduction, purification and biochemical characterization of the p39 nsp2 protease domains encoded by three alphaviruses. Protein Expr Purif 64:89-97
Tropea, Joseph E; Cherry, Scott; Waugh, David S (2009) Expression and purification of soluble His(6)-tagged TEV protease. Methods Mol Biol 498:297-307
Austin, Brian P; Nallamsetty, Sreedevi; Waugh, David S (2009) Hexahistidine-tagged maltose-binding protein as a fusion partner for the production of soluble recombinant proteins in Escherichia coli. Methods Mol Biol 498:157-72
Gan, Jianhua; Shaw, Gary; Tropea, Joseph E et al. (2008) A stepwise model for double-stranded RNA processing by ribonuclease III. Mol Microbiol 67:143-54
Nallamsetty, Sreedevi; Waugh, David S (2007) Mutations that alter the equilibrium between open and closed conformations of Escherichia coli maltose-binding protein impede its ability to enhance the solubility of passenger proteins. Biochem Biophys Res Commun 364:639-44
Tropea, Joseph E; Cherry, Scott; Nallamsetty, Sreedevi et al. (2007) A generic method for the production of recombinant proteins in Escherichia coli using a dual hexahistidine-maltose-binding protein affinity tag. Methods Mol Biol 363:1-19
Nallamsetty, Sreedevi; Waugh, David S (2007) A generic protocol for the expression and purification of recombinant proteins in Escherichia coli using a combinatorial His6-maltose binding protein fusion tag. Nat Protoc 2:383-91
Nallamsetty, Sreedevi; Waugh, David S (2006) Solubility-enhancing proteins MBP and NusA play a passive role in the folding of their fusion partners. Protein Expr Purif 45:175-82
Tozser, Jozsef; Tropea, Joseph E; Cherry, Scott et al. (2005) Comparison of the substrate specificity of two potyvirus proteases. FEBS J 272:514-23
Nallamsetty, Sreedevi; Austin, Brian P; Penrose, Kerri J et al. (2005) Gateway vectors for the production of combinatorially-tagged His6-MBP fusion proteins in the cytoplasm and periplasm of Escherichia coli. Protein Sci 14:2964-71

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