Individual ionization constants of all the carboxyl groups in ribonuclease HI from Escherichia coli determined by NMR.

All of the individual carboxyl groups (the side-chain carboxyl groups of Asp and Glu, and the C-terminal alpha-carboxyl group) in Escherichia coli ribonuclease HI, which is an enzyme that cleaves the RNA strand of a RNA/DNA hybrid, were pH-titrated, and their ionization constants (pKa) were determined from an analysis of the pH-dependent chemical shifts of the carboxyl carbon resonances obtained from 1H-13C heteronuclear two-dimensional NMR. The pKa values in the enzyme varied widely among individual residues, for example, in the unusual pKa values for two important catalytic residues, Asp10 (pKa 6.1) and Asp70 (pKa 2.6). Moreover, remarkable two-step titrations were observed for these carboxylates. The binding of Mg2+ ion to the enzyme, which is the cofactor necessary for catalytic activity, caused no significant change in the pKa values of the carboxyl groups, except for that of Asp10. The variations of the pKas that were dependent on the microenvironment in the protein were theoretically reproduced to compare with the experimental results by a numerical calculation, using a continuum electrostatic model. Most of the significant pKa decreases were brought about through strong electrostatic interactions with the neighboring basic amino acids, Arg or Lys. The pKa shifts and the two-step titrations of Asp10 and -70, which are close to each other, were interpreted to be due to the neighboring effect of two functional groups, as observed in the interacting titratable groups of a dicarboxyl compound or in the active site carboxylates of lysozyme and aspartic protease. The role of Asp10 in the catalytic action is either to be the proton donor to the RNA moiety or the binding partner of the Mg2+ ion cofactor. Asp70, on the other hand, is considered to be the proton acceptor from a water molecule.

[1]  M. Oobatake,et al.  pH-dependent thermostabilization of Escherichia coli ribonuclease HI by histidine to alanine substitutions. , 1993, Journal of biotechnology.

[2]  A. Wada,et al.  A theoretical study of the dielectric constant of protein. , 1988, Protein engineering.

[3]  M. Yoshida,et al.  Complete assignments of magnetic resonances of ribonuclease H from Escherichia coli by double- and triple-resonance 2D and 3D NMR spectroscopies. , 1993, Biochemistry.

[4]  M. Karplus,et al.  pKa's of ionizable groups in proteins: atomic detail from a continuum electrostatic model. , 1990, Biochemistry.

[5]  A. D. Clark,et al.  Structure of HIV-1 reverse transcriptase/DNA complex at 7 Å resolution showing active site locations , 1992, Nature.

[6]  S. Kanaya,et al.  Role of histidine 124 in the catalytic function of ribonuclease HI from Escherichia coli. , 1993, The Journal of biological chemistry.

[7]  H. Nakamura,et al.  Stabilization of Escherichia coli ribonuclease H by introduction of an artificial disulfide bond. , 1991, The Journal of biological chemistry.

[8]  P E Wright,et al.  Electrostatic calculations of side-chain pK(a) values in myoglobin and comparison with NMR data for histidines. , 1993, Biochemistry.

[9]  K. Morikawa,et al.  Crystal structure of Escherichia coli RNase HI in complex with Mg2+ at 2.8 Å resolution: Proof for a single Mg2+‐binding site , 1993, Proteins.

[10]  K. Sharp,et al.  On the calculation of pKas in proteins , 1993, Proteins.

[11]  H. Nakamura,et al.  Assignments of backbone 1H, 13C, and 15N resonances and secondary structure of ribonuclease H from Escherichia coli by heteronuclear three-dimensional NMR spectroscopy. , 1991, Biochemistry.

[12]  R. Ma,et al.  Ionization behavior of the cleft carboxyls in lysozyme-substrate complexes. , 1972 .

[13]  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.

[14]  K. Morikawa,et al.  Effect of mutagenesis at each of five histidine residues on enzymatic activity and stability of ribonuclease H from Escherichia coli. , 1991, European journal of biochemistry.

[15]  J. Warwicker,et al.  Calculation of the electric potential in the active site cleft due to alpha-helix dipoles. , 1982, Journal of molecular biology.

[16]  C. Tanford,et al.  Interpretation of protein titration curves. Application to lysozyme. , 1972, Biochemistry.

[17]  S. Kanaya,et al.  DNA sequence of the gene coding for Escherichia coli ribonuclease H. , 1983, The Journal of biological chemistry.

[18]  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.

[19]  R. Jou,et al.  Ribonuclease H activation by inert transition-metal complexes. Mechanistic probes for metallocofactors : insights on the metallobiochemistry of divalent magnesium ion , 1991 .

[20]  D. Kohda,et al.  Characterization of pH titration shifts for all the nonlabile proton resonances a protein by two-dimensional NMR: the case of mouse epidermal growth factor. , 1991, Biochemistry.

[21]  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.

[22]  S. Kanaya,et al.  1H NMR studies of deuterated ribonuclease HI selectively labeled with protonated amino acids , 1992, Journal of biomolecular NMR.

[23]  Y. Satow,et al.  Structure of ribonuclease H phased at 2 A resolution by MAD analysis of the selenomethionyl protein. , 1990, Science.

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

[25]  T. Steitz,et al.  Crystal structure at 3.5 A resolution of HIV-1 reverse transcriptase complexed with an inhibitor. , 1992, Science.

[26]  J. Hartsuck,et al.  pH dependence of kinetic parameters of pepsin, rhizopuspepsin, and their active-site hydrogen bond mutants. , 1992, The Journal of biological chemistry.

[27]  J. Hurwitz,et al.  Isolation and characterization of an endonuclease from Escherichia coli specific for ribonucleic acid in ribonucleic acid-deoxyribonucleic acid hybrid structures. , 1973, The Journal of biological chemistry.

[28]  Haruki Nakamura,et al.  Electrostatic forces in two lysozymes: Calculations and measurements of histidine pKa values , 1992, Biopolymers.

[29]  M Oobatake,et al.  Intermolecular interactions between protein and other molecules including hydration effects. , 1988, Journal of biochemistry.

[30]  M. Karplus,et al.  Multiple-site titration curves of proteins: an analysis of exact and approximate methods for their calculation , 1991 .

[31]  U. Wintersberger Ribonucleases H of retroviral and cellular origin. , 1990, Pharmacology & therapeutics.

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

[33]  K. Morikawa,et al.  Three-dimensional structure of ribonuclease H from E. coli , 1990, Nature.

[34]  Haruki Nakamura,et al.  Numerical Calculations of Electrostatic Potentials of Protein-Solvent Systems by the Self Consistent Boundary Method , 1987 .

[35]  H. Nakamura,et al.  Combination of heteronuclear 1H-15N and 1H-13C three-dimensional nuclear magnetic resonance experiments for amide-directed sequential assignment in larger proteins. , 1990, Journal of biochemistry.

[36]  H. Nakamura,et al.  Binding of metal ions toE. coli RNase HI observed by1H−15N heteronuclear 2D NMR , 1991, Journal of biomolecular NMR.

[37]  K Wüthrich,et al.  High-field 13C nuclear magnetic resonance studies at 90.5 MHz of the basic pancreatic trypsin inhibitor. , 1978, Biochemistry.

[38]  M. A. McClure,et al.  Origins and Evolutionary Relationships of Retroviruses , 1989, The Quarterly Review of Biology.

[39]  A. Schechter,et al.  Mathematical models for interacting groups in nuclear magnetic resonance titration curves. , 1972, Biochemistry.

[40]  K. Nagayama,et al.  A novel NMR microcell with symmetric geometry , 1988 .

[41]  M. James,et al.  Penicillopepsin from Penicillium janthinellum crystal structure at 2.8 Å and sequence homology with porcine pepsin , 1977, Nature.

[42]  C. Perrin,et al.  Symmetries of hydrogen bonds in monoanions of dicarboxylic acids , 1992 .

[43]  Haruki Nakamura,et al.  High-frequency dielectric relaxation of water bound to hydrophilic silica gels , 1989 .

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

[45]  H. Berendsen,et al.  The α-helix dipole and the properties of proteins , 1978, Nature.

[46]  Haruki Nakamura,et al.  Numerical Calculations of Reaction Fields of Protein-Solvent Systems , 1988 .

[47]  M. Raftery,et al.  Ionization behavior of the catalytic carboxyls of lysozyme. Effects of ionic strength. , 1972, Biochemistry.

[48]  D. Bashford,et al.  Electrostatic calculations of the pKa values of ionizable groups in bacteriorhodopsin , 1992 .

[49]  K. Morikawa,et al.  Overproduction and preliminary crystallographic study of ribonuclease H from Escherichia coli. , 1989, The Journal of biological chemistry.