Conserved quantitative stability/flexibility relationships (QSFR) in an orthologous RNase H pair

Many reports qualitatively describe conserved stability and flexibility profiles across protein families, but biophysical modeling schemes have not been available to robustly quantify both. Here we investigate an orthologous RNase H pair by using a minimal distance constraint model (DCM). The DCM is an all atom microscopic model [Jacobs and Dallakyan, Biophys J 2005;88(2):903–915] that accurately reproduces heat capacity measurements [Livesay et al., FEBS Lett 2004;576(3):468–476], and is unique in its ability to harmoniously calculate thermodynamic stability and flexibility in practical computing times. Consequently, quantified stability/flexibility relationships (QSFR) can be determined using the DCM. For the first time, a comparative QSFR analysis is performed, serving as a paradigm study to illustrate the utility of a QSFR analysis for elucidating evolutionarily conserved stability and flexibility profiles. Despite global conservation of QSFR profiles, distinct enthalpy‐entropy compensation mechanisms are identified between the RNase H pair. In both cases, local flexibility metrics parallel H/D exchange experiments by correctly identifying the folding core and several flexible regions. Remarkably, at appropriately shifted temperatures (e.g., melting temperature), these differences lead to a global conservation in Landau free energy landscapes, which directly relate thermodynamic stability to global flexibility. Using ensemble‐based sampling within free energy basins, rigidly, and flexibly correlated regions are quantified through cooperativity correlation plots. Five conserved flexible regions are identified within the structures of the orthologous pair. Evolutionary conservation of these flexibly correlated regions is strongly suggestive of their catalytic importance. Conclusions made herein are demonstrated to be robust with respect to the DCM parameterization. Proteins 2006. © 2005 Wiley‐Liss, Inc.

[1]  H. Nakamura,et al.  Crystal structure of ribonuclease H from Thermus thermophilus HB8 refined at 2.8 A resolution. , 1993, Journal of molecular biology.

[2]  M. Oobatake,et al.  Stabilization of Escherichia coli ribonuclease HI by strategic replacement of amino acid residues with those from the thermophilic counterpart. , 1992, The Journal of biological chemistry.

[3]  Srebrenka Robic,et al.  Role of residual structure in the unfolded state of a thermophilic protein , 2003, Proceedings of the National Academy of Sciences of the United States of America.

[4]  S. Marqusee,et al.  Comparison of the folding processes of T. thermophilus and E. coli ribonucleases H. , 2002, Journal of molecular biology.

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

[6]  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.

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

[8]  C. Hall,et al.  Phase diagrams describing fibrillization by polyalanine peptides. , 2004, Biophysical journal.

[9]  D. Matthews,et al.  Crystal structure of the ribonuclease H domain of HIV-1 reverse transcriptase. , 1991, Science.

[10]  R. Nussinov,et al.  How do thermophilic proteins deal with heat? , 2001, Cellular and Molecular Life Sciences CMLS.

[11]  S. Subramaniam,et al.  Explicit solvent models in protein pKa calculations. , 1996, Biophysical journal.

[12]  D C Rees,et al.  Some thermodynamic implications for the thermostability of proteins , 2001, Protein science : a publication of the Protein Society.

[13]  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.

[14]  L. R. Scott,et al.  Electrostatics and diffusion of molecules in solution: simulations with the University of Houston Brownian dynamics program , 1995 .

[15]  J. Lee,et al.  Binding sites in Escherichia coli dihydrofolate reductase communicate by modulating the conformational ensemble. , 2000, Proceedings of the National Academy of Sciences of the United States of America.

[16]  M. Gilson Multiple‐site titration and molecular modeling: Two rapid methods for computing energies and forces for ionizable groups in proteins , 1993, Proteins.

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

[18]  Huan-Xiang Zhou,et al.  A Gaussian-chain model for treating residual charge–charge interactions in the unfolded state of proteins , 2002, Proceedings of the National Academy of Sciences of the United States of America.

[19]  H. Nakamura,et al.  How does RNase H recognize a DNA.RNA hybrid? , 1991, Proceedings of the National Academy of Sciences of the United States of America.

[20]  Feng Dong,et al.  Electrostatic contributions to the stability of a thermophilic cold shock protein. , 2003, Biophysical journal.

[21]  M Ikehara,et al.  Importance of the positive charge cluster in Escherichia coli ribonuclease HI for the effective binding of the substrate. , 1991, The Journal of biological chemistry.

[22]  J. Skolnick,et al.  Reduced models of proteins and their applications , 2004 .

[23]  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.

[24]  R. Sterner,et al.  Thermophilic Adaptation of Proteins , 2001, Critical reviews in biochemistry and molecular biology.

[25]  R. Raines,et al.  Adjacent cysteine residues as a redox switch. , 2001, Protein engineering.

[26]  D. Shortle,et al.  Characterization of long-range structure in the denatured state of staphylococcal nuclease. II. Distance restraints from paramagnetic relaxation and calculation of an ensemble of structures. , 1997, Journal of molecular biology.

[27]  W. L. Jorgensen,et al.  The OPLS [optimized potentials for liquid simulations] potential functions for proteins, energy minimizations for crystals of cyclic peptides and crambin. , 1988, Journal of the American Chemical Society.

[28]  Themis Lazaridis,et al.  Thermodynamics of protein folding: a microscopic view. , 2002, Biophysical chemistry.

[29]  M. Gilson,et al.  Prediction of pH-dependent properties of proteins. , 1994, Journal of molecular biology.

[30]  D. Perl,et al.  Electrostatic stabilization of a thermophilic cold shock protein. , 2001, Journal of molecular biology.

[31]  G. Böhm,et al.  The stability of proteins in extreme environments. , 1998, Current opinion in structural biology.

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

[33]  M. Gilson,et al.  The determinants of pKas in proteins. , 1996, Biochemistry.

[34]  K Morikawa,et al.  Cooperative stabilization of Escherichia coli ribonuclease HI by insertion of Gly-80b and Gly-77-->Ala substitution. , 1994, Biochemistry.

[35]  K Morikawa,et al.  Structural details of ribonuclease H from Escherichia coli as refined to an atomic resolution. , 1992, Journal of molecular biology.

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

[37]  K. Sharp,et al.  Heat capacity in proteins. , 2005, Annual review of physical chemistry.

[38]  A. Elcock Realistic modeling of the denatured states of proteins allows accurate calculations of the pH dependence of protein stability. , 1999, Journal of molecular biology.

[39]  Srebrenka Robic,et al.  Energetic evidence for formation of a pH-dependent hydrophobic cluster in the denatured state of Thermus thermophilus ribonuclease H. , 2003, Journal of molecular biology.

[40]  S. Marqusee,et al.  Structural distribution of stability in a thermophilic enzyme. , 1999, Proceedings of the National Academy of Sciences of the United States of America.

[41]  S. Redner,et al.  Introduction To Percolation Theory , 2018 .

[42]  D. Covell,et al.  Correlation between native-state hydrogen exchange and cooperative residue fluctuations from a simple model. , 1998, Biochemistry.

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

[44]  S. Marqusee,et al.  Importance of the C-terminal helix to the stability and enzymatic activity of Escherichia coli ribonuclease H. , 1997, Biochemistry.

[45]  Charles L Brooks,et al.  The effects of ionic strength on protein stability: the cold shock protein family. , 2002, Journal of molecular biology.

[46]  S. Marqusee,et al.  A thermodynamic comparison of mesophilic and thermophilic ribonucleases H. , 1999, Biochemistry.

[47]  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.

[48]  M. Karplus,et al.  CHARMM: A program for macromolecular energy, minimization, and dynamics calculations , 1983 .

[49]  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.

[50]  D. Livesay,et al.  Conferring thermostability to mesophilic proteins through optimized electrostatic surfaces. , 2003, Biophysical journal.

[51]  P. A. Fields,et al.  Review: Protein function at thermal extremes: balancing stability and flexibility. , 2001, Comparative biochemistry and physiology. Part A, Molecular & integrative physiology.

[52]  M. DePristo,et al.  Simultaneous determination of protein structure and dynamics , 2005, Nature.

[53]  S. Kanaya,et al.  Identification of the amino acid residues involved in an active site of Escherichia coli ribonuclease H by site-directed mutagenesis. , 1990, The Journal of biological chemistry.