Elucidating quantitative stability/flexibility relationships within thioredoxin and its fragments using a distance constraint model.

Numerous quantitative stability/flexibility relationships, within Escherichia coli thioredoxin (Trx) and its fragments are determined using a minimal distance constraint model (DCM). A one-dimensional free energy landscape as a function of global flexibility reveals Trx to fold in a low-barrier two-state process, with a voluminous transition state. Near the folding transition temperature, the native free energy basin is markedly skewed to allow partial unfolded forms. Under native conditions the skewed shape is lost, and the protein forms a compact structure with some flexibility. Predictions on ten Trx fragments are generally consistent with experimental observations that they are disordered, and that complementary fragments reconstitute. A hierarchical unfolding pathway is uncovered using an exhaustive computational procedure of breaking interfacial cross-linking hydrogen bonds that span over a series of fragment dissociations. The unfolding pathway leads to a stable core structure (residues 22-90), predicted to act as a kinetic trap. Direct connection between degree of rigidity within molecular structure and non-additivity of free energy is demonstrated using a thermodynamic cycle involving fragments and their hierarchical unfolding pathway. Additionally, the model provides insight about molecular cooperativity within Trx in its native state, and about intermediate states populating the folding/unfolding pathways. Native state cooperativity correlation plots highlight several flexibly correlated regions, giving insight into the catalytic mechanism that facilitates access to the active site disulfide bond. Residual native cooperativity correlations are present in the core substructure, suggesting that Trx can function when it is partly unfolded. This natively disordered kinetic trap, interpreted as a molten globule, has a wide temperature range of metastability, and it is identified as the "slow intermediate state" observed in kinetic experiments. These computational results are found to be in overall agreement with a large array of experimental data.

[1]  DSC studies of a family of natively disordered fragments from Escherichia coli thioredoxin: surface burial in intrinsic coils. , 2003, Biochemistry.

[2]  A. Rader,et al.  Identifying protein folding cores from the evolution of flexible regions during unfolding. , 2002, Journal of molecular graphics & modelling.

[3]  Shankar Subramaniam,et al.  Protein local structure prediction from sequence , 2003, Proteins.

[4]  F M Richards,et al.  Replacement of proline-76 with alanine eliminates the slowest kinetic phase in thioredoxin folding. , 1987, Biochemistry.

[5]  Ronald L. Rivest,et al.  Introduction to Algorithms , 1990 .

[6]  G. G. Wood,et al.  Understanding the α‐helix to coil transition in polypeptides using network rigidity: Predicting heat and cold denaturation in mixed solvent conditions , 2004, Biopolymers.

[7]  K A Dill,et al.  Additivity Principles in Biochemistry* , 1997, The Journal of Biological Chemistry.

[8]  Donald J Jacobs,et al.  Elucidating protein thermodynamics from the three-dimensional structure of the native state using network rigidity. , 2005, Biophysical journal.

[9]  G. G. Wood,et al.  A flexible approach for understanding protein stability , 2004, FEBS letters.

[10]  V. Muñoz,et al.  A simple model for calculating the kinetics of protein folding from three-dimensional structures. , 1999, Proceedings of the National Academy of Sciences of the United States of America.

[11]  D. Jacobs,et al.  Protein flexibility predictions using graph theory , 2001, Proteins.

[12]  Ariel Fernández,et al.  Protein folding: could hydrophobic collapse be coupled with hydrogen‐bond formation? , 2003, FEBS letters.

[13]  M. L. Tasayco,et al.  NMR study of the reconstitution of the β‐sheet of thioredoxin by fragment complementation , 1995 .

[14]  H. Hinz,et al.  Group additivity schemes for the calculation of the partial molar heat capacities and volumes of unfolded proteins in aqueous solution. , 2002, Biophysical chemistry.

[15]  K A Dill,et al.  Native protein fluctuations: the conformational-motion temperature and the inverse correlation of protein flexibility with protein stability. , 1998, Journal of biomolecular structure & dynamics.

[16]  V Muñoz,et al.  What can we learn about protein folding from Ising-like models? , 2001, Current opinion in structural biology.

[17]  W F van Gunsteren,et al.  Decomposition of the free energy of a system in terms of specific interactions. Implications for theoretical and experimental studies. , 1994, Journal of molecular biology.

[18]  Dennis R Livesay,et al.  Conserved quantitative stability/flexibility relationships (QSFR) in an orthologous RNase H pair , 2005, Proteins.

[19]  H. Yamawaki,et al.  Thioredoxin: a multifunctional antioxidant enzyme in kidney, heart and vessels , 2005, Current opinion in nephrology and hypertension.

[20]  M. L. Tasayco,et al.  Reduced Spectral Density Mapping of a Partially Folded Fragment of E. coli Thioredoxin , 2004, Journal of biomolecular structure & dynamics.

[21]  V. Hilser,et al.  Structure-based calculation of the equilibrium folding pathway of proteins. Correlation with hydrogen exchange protection factors. , 1996, Journal of molecular biology.

[22]  Ruth Nussinov,et al.  Hierarchical protein folding pathways: A computational study of protein fragments , 2003, Proteins.

[23]  Recognition between disordered states: kinetics of the self-assembly of thioredoxin fragments. , 1997, Biochemistry.

[24]  S. L. Mayo,et al.  Automated design of the surface positions of protein helices , 1997, Protein science : a publication of the Protein Society.

[25]  and David M. LeMaster,et al.  Dynamical Mapping of E. coli Thioredoxin via 13C NMR Relaxation Analysis , 1996 .

[26]  Shankar Subramaniam,et al.  Protein fragment clustering and canonical local shapes , 2003, Proteins.

[27]  M. L. Tasayco,et al.  Interaction between two discontiguous chain segments from the beta-sheet of Escherichia coli thioredoxin suggests an initiation site for folding. , 2000, Biochemistry.

[28]  J. Udgaonkar,et al.  GroEL channels the folding of thioredoxin along one kinetic route. , 2001, Journal of molecular biology.

[29]  M. L. Tasayco,et al.  Proline isomerization-independent accumulation of an early intermediate and heterogeneity of the folding pathways of a mixed alpha/beta protein, Escherichia coli thioredoxin. , 1998, Biochemistry.

[30]  M. L. Tasayco,et al.  Magic angle spinning solid-state NMR spectroscopy for structural studies of protein interfaces. resonance assignments of differentially enriched Escherichia coli thioredoxin reassembled by fragment complementation. , 2004, Journal of the American Chemical Society.

[31]  Leslie A Kuhn,et al.  Protein unfolding: Rigidity lost , 2002, Proceedings of the National Academy of Sciences of the United States of America.

[32]  Leslie A. Kuhn,et al.  Flexible and Rigid Regions in Proteins , 2002 .

[33]  J. Udgaonkar,et al.  Folding subdomains of thioredoxin characterized by native‐state hydrogen exchange , 2003, Protein science : a publication of the Protein Society.

[34]  A. Fersht,et al.  Exploring the folding funnel of a polypeptide chain by biophysical studies on protein fragments. , 1999, Journal of molecular biology.

[35]  A. Ghoshal Minithioredoxin: a folded and functional peptide fragment of thioredoxin. , 1999, Biochemical and biophysical research communications.

[36]  H. Dyson,et al.  Comparison of the hydrogen-exchange behavior of reduced and oxidized Escherichia coli thioredoxin. , 1995, Biochemistry.

[37]  J. Onuchic,et al.  Theory of Protein Folding This Review Comes from a Themed Issue on Folding and Binding Edited Basic Concepts Perfect Funnel Landscapes and Common Features of Folding Mechanisms , 2022 .

[38]  M. L. Tasayco,et al.  NMR analysis of cleaved Escherichia coli thioredoxin (1–73/74–108) and its P76A variant: Cis/trans peptide isomerization , 2008, Protein science : a publication of the Protein Society.

[39]  M. Thorpe,et al.  Rigidity theory and applications , 2002 .

[40]  Gonzalo de Prat-Gay,et al.  Association of complementary fragments and the elucidation of protein folding pathways , 1996 .

[41]  P. Picotti,et al.  Probing protein structure by limited proteolysis. , 2004, Acta biochimica Polonica.

[42]  A. Gronenborn,et al.  The solution structure of human thioredoxin complexed with its target from Ref-1 reveals peptide chain reversal. , 1996, Structure.

[43]  G. G. Wood,et al.  Network rigidity at finite temperature: relationships between thermodynamic stability, the nonadditivity of entropy, and cooperativity in molecular systems. , 2003, Physical review. E, Statistical, nonlinear, and soft matter physics.