Modulating Protein Folding Rates in Vivo and in Vitro by Side-chain Interactions between the Parallel β Strands of Green Fluorescent Protein*

We have identified pairs of residues across the two parallel β strands of green fluorescent protein that facilitate native strand register of the surface-exposed β barrel. After constructing a suitable host environment around two guest residues, minimizing interactions of the guest residues with surrounding side-chains yet maintaining the wild-type protein structure and the chromophore environment, we introduced a library of cross-strand pairings by cassette mutagenesis. Colonies of Escherichia coli transformed with the library differ in intracellular fluorescence. Most of the fluorescent pairs have predominantly charged and polar guest site residues. The magnitude and the rate of fluorescence acquisition in vivo from transformed E. coli cells varies among the mutants despite comparable levels of protein expression. Spectroscopic measurements of purified mutants show that the native protein structure is maintained. Kinetic studies using purified protein with fully matured chromophores demonstrate that the mutants span a 10-fold range in folding rates with undetectable differences in unfolding rates. Thus, green fluorescent protein provides an ideal system for monitoring determinants of in vivo protein folding. Cross-strand pairings affect both protein stability and folding kinetics by favoring the formation of native strand register preferentially to non-native strand alignments.

[1]  B. Reid,et al.  Chromophore formation in green fluorescent protein. , 1997, Biochemistry.

[2]  B. Matthews,et al.  Stabilization of functional proteins by introduction of multiple disulfide bonds. , 1991, Methods in enzymology.

[3]  M. J. Cormier,et al.  Primary structure of the Aequorea victoria green-fluorescent protein. , 1992, Gene.

[4]  E. Hudson,et al.  Development and applications of enhanced green fluorescent protein mutants. , 1998, BioTechniques.

[5]  M. Chalfie,et al.  Green fluorescent protein as a marker for gene expression. , 1994, Science.

[6]  P. S. Kim,et al.  Context is a major determinant of β-sheet propensity , 1994, Nature.

[7]  L. Regan,et al.  Surface point mutations that significantly alter the structure and stability of a protein's denatured state , 1996, Protein science : a publication of the Protein Society.

[8]  M Levitt,et al.  Stabilization of phage T4 lysozyme by engineered disulfide bonds. , 1989, Proceedings of the National Academy of Sciences of the United States of America.

[9]  P. V. von Hippel,et al.  Calculation of protein extinction coefficients from amino acid sequence data. , 1989, Analytical biochemistry.

[10]  P. S. Kim,et al.  Measurement of the β-sheet-forming propensities of amino acids , 1994, Nature.

[11]  R. Tsien,et al.  green fluorescent protein , 2020, Catalysis from A to Z.

[12]  P. Curmi,et al.  The dependence of amino acid pair correlations on structural environment , 1998, Proteins.

[13]  W. M. Westler,et al.  Chemical structure of the hexapeptide chromophore of the Aequorea green-fluorescent protein. , 1993, Biochemistry.

[14]  Mike Carson,et al.  Algorithm for ribbon models of proteins , 1986 .

[15]  Jim Haseloff,et al.  Mutations that suppress the thermosensitivity of green fluorescent protein , 1996, Current Biology.

[16]  L. Regan,et al.  Aromatic rescue of glycine in β sheets , 1998 .

[17]  Keith Dudley Short protocols in molecular biology , 1990 .

[18]  W. Stemmer,et al.  Improved Green Fluorescent Protein by Molecular Evolution Using DNA Shuffling , 1996, Nature Biotechnology.

[19]  A. Xie,et al.  Characterization of the photoconversion of green fluorescent protein with FTIR spectroscopy. , 1998, Biochemistry.

[20]  W. Ward,et al.  Reversible denaturation of Aequorea green-fluorescent protein: physical separation and characterization of the renatured protein. , 1982, Biochemistry.

[21]  W. Ward,et al.  Renaturation of Aequorea green-fluorescent protein , 1981 .

[22]  M. A. Wouters,et al.  An analysis of side chain interactions and pair correlations within antiparallel β‐sheets: The differences between backbone hydrogen‐bonded and non‐hydrogen‐bonded residue pairs , 1995, Proteins.

[23]  J. Berg,et al.  Electrostatic interactions across a beta-sheet. , 1997, Biochemistry.

[24]  L. Regan,et al.  Guidelines for Protein Design: The Energetics of β Sheet Side Chain Interactions , 1995, Science.

[25]  J. Thornton,et al.  Determinants of strand register in antiparallel β‐sheets of proteins , 1998, Protein science : a publication of the Protein Society.

[26]  G. Patterson,et al.  Use of the green fluorescent protein and its mutants in quantitative fluorescence microscopy. , 1997, Biophysical journal.

[27]  B. Matthews,et al.  Enhanced protein thermostability from site-directed mutations that decrease the entropy of unfolding. , 1987, Proceedings of the National Academy of Sciences of the United States of America.

[28]  Alexander Wlodawer,et al.  The structural basis for spectral variations in green fluorescent protein , 1997, Nature Structural Biology.

[29]  D. A. Dougherty,et al.  The Cationminus signpi Interaction. , 1997, Chemical reviews.

[30]  B. Matthews,et al.  Substantial increase of protein stability by multiple disulphide bonds , 1989, Nature.

[31]  R Y Tsien,et al.  Wavelength mutations and posttranslational autoxidation of green fluorescent protein. , 1994, Proceedings of the National Academy of Sciences of the United States of America.

[32]  B. Matthews,et al.  Analysis of the effectiveness of proline substitutions and glycine replacements in increasing the stability of phage T4 lysozyme , 1992, Biopolymers.

[33]  J M Sturtevant,et al.  Sidechain interactions in parallel beta sheets: the energetics of cross-strand pairings. , 1999, Structure.

[34]  M. Oka,et al.  Thermosensitivity of green fluorescent protein fluorescence utilized to reveal novel nuclear-like compartments in a mutant nucleoporin NSP1. , 1995, Journal of biochemistry.

[35]  F. Young Biochemistry , 1955, The Indian Medical Gazette.