Chemistry Central Journal | |
The multiple roles of histidine in protein interactions | |
Si-Ming Liao4  Qi-Shi Du1  Jian-Zong Meng3  Zong-Wen Pang3  Ri-Bo Huang2  | |
[1] Gordon Life Science Institute, San Diego, California, 92130, USA | |
[2] State Key Laboratory of Non-food Biomass Energy and Enzyme Technology, National Engineering Research Center for Non-food Biorefinery, Guangxi Academy of Sciences, 98 Daling Road, Nanning, Guangxi, 530007, China | |
[3] State Key Laboratory for Conservation and Utilization of Subtropical Agro-bioresources, Life Science and Biotechnology College, Guangxi University, Nanning, Guangxi, 530004, China | |
[4] Guangxi Mangrove Research Center, Beihai, Guangxi, 536000, China | |
关键词: Protein structure; Protein interaction; Protonation; Histidine; Amino acids; | |
Others : 787948 DOI : 10.1186/1752-153X-7-44 |
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received in 2012-09-24, accepted in 2012-11-27, 发布年份 2013 | |
【 摘 要 】
Background
Among the 20 natural amino acids histidine is the most active and versatile member that plays the multiple roles in protein interactions, often the key residue in enzyme catalytic reactions. A theoretical and comprehensive study on the structural features and interaction properties of histidine is certainly helpful.
Results
Four interaction types of histidine are quantitatively calculated, including: (1) Cation-π interactions, in which the histidine acts as the aromatic π-motif in neutral form (His), or plays the cation role in protonated form (His+); (2) π-π stacking interactions between histidine and other aromatic amino acids; (3) Hydrogen-π interactions between histidine and other aromatic amino acids; (4) Coordinate interactions between histidine and metallic cations. The energies of π-π stacking interactions and hydrogen-π interactions are calculated using CCSD/6-31+G(d,p). The energies of cation-π interactions and coordinate interactions are calculated using B3LYP/6-31+G(d,p) method and adjusted by empirical method for dispersion energy.
Conclusions
The coordinate interactions between histidine and metallic cations are the strongest one acting in broad range, followed by the cation-π, hydrogen-π, and π-π stacking interactions. When the histidine is in neutral form, the cation-π interactions are attractive; when it is protonated (His+), the interactions turn to repulsive. The two protonation forms (and pKa values) of histidine are reversibly switched by the attractive and repulsive cation-π interactions. In proteins the π-π stacking interaction between neutral histidine and aromatic amino acids (Phe, Tyr, Trp) are in the range from -3.0 to -4.0 kcal/mol, significantly larger than the van der Waals energies.
【 授权许可】
2013 Liao et al; licensee Chemistry Central Ltd.
【 预 览 】
Files | Size | Format | View |
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20140702222804298.pdf | 871KB | download | |
Figure 5. | 105KB | Image | download |
Figure 4. | 48KB | Image | download |
Figure 3. | 75KB | Image | download |
Figure 2. | 162KB | Image | download |
Figure 1. | 111KB | Image | download |
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【 参考文献 】
- [1]Martínez A: Evidence for a functionally important histidine residue in human tyrosine hydroxylase. Amino Acids 1995, 9:285-292.
- [2]Uchida K: Histidine and lysine as targets of oxidative modification. Amino Acids 2003, 25:249-257.
- [3]Remko M, Fitz D, Rode BM: Effect of metal ions (Li+, Na+, K+, Mg2+, Ca2+, Ni2+, Cu2+ and Zn2+) and water coordination on the structure and properties of l-histidine and zwitterionic l-histidine. Amino Acids 2010, 39:1309-1319.
- [4]Li F, Fitz D, Fraser DG, Rode BM: Catalytic effects of histidine enantiomers and glycine on the formation of dileucine and dimethionine in the salt-induced peptide formation reaction. Amino Acids 2010, 38:287-294.
- [5]Agnieszka M, Janina KW, Katarzyna KK: Five-membered heterocycles. Part III. Aromaticity of 1,3-imidazole in 5+n hetero-bicyclic molecules. J Mol Struc 2003, 655:397-403.
- [6]Doğan A, Özel AD, Kılıç E: The protonation equilibria of selected glycine dipeptides in ethanol–water mixture: solvent composition effect. Amino Acids 2009, 36:373-379.
- [7]Priyakumar UD, Punnagai M, Krishna Mohan GP, Sastry GN: A computational study of cation-π interactions in polycyclic systems: exploring the dependence on the curvature and electronic factors. Tetrahedron 2004, 60:3037-3043.
- [8]Reddy AS, Sastry GN: Cation [M = H+, Li+, Na+, K+, Ca2+, Mg2+, NH4+, and NMe4+] interactions with the aromatic motifs of naturally occurring amino acids: A theoretical study. J Phys Chem A 2005, 109:8893-8903.
- [9]Engerer LK, Hanusa TP: Geometric Effects in Olefinic Cation−π Interactions with Alkali Metals: A Computational Study. J Org Chem 2011, 76:42-49.
- [10]Hunter CA, Lawson KR, Perkins J, Urch CJ: Aromatic interactions. J Chem Soc Perkin Trans 2001, 2:651-669.
- [11]Crowley PB, Golovin A: Cation–π interactions in protein–protein interfaces. Proteins 2005, 59:231-239.
- [12]Vijay D, Sastry GN: Exploring the size dependence of cyclic and acyclic π-systems on cation-π binding. Phys Chem Chem Phys 2008, 10:582-590.
- [13]Matsumura H, Yamamoto T, Leow TC, Mori T, Salleh AB, Basri M, Inoue T, Kai Y, Zaliha RN, Rahman RA: Novel cation-π interaction revealed by crystal structure of thermoalkalophilic lipase. Proteins 2008, 70:592-598.
- [14]Reddy AS, Zipse H, Sastry GN: Cation-π Interactions of Bare and Coordinatively Saturated Metal Ions: Contrasting Structural and Energetic Characteristics. J Phys Chem B 2007, 111:11546-11553.
- [15]Schottel BL, Chifotides HT, Dunbar KR: Anion-π interactions. Chem Soc Rev 2008, 37:68-83.
- [16]Burley SK, Petsko GA: Amino-aromatic interactions in proteins. FEBS Lett 1986, 203:139-143.
- [17]Stefan G: Do special noncovalent π-π stacking interactions really exist? Angew Chem Int Ed 2008, 47:3430-3434.
- [18]Mignon P, Loverix S, Steyaert J, Geerlings P: Influence of the π–π interaction on the hydrogen bonding capacity of stacked DNA/RNA bases. Nucl Acids Res 2005, 33:1779-1789.
- [19]Petitjean A, Khoury RG, Kyritsakas N, Lehn JM: Dynamic devices, shape switching and substrate binding in ion-controlled nanomechanical molecular tweezers. J Am Chem Soc 2004, 126:6637-6647.
- [20]Sygula A, Fronczek FR, Sygula R, Rabideau PW, Olmstead MM: A Double Concave Hydrocarbon Buckycatcher. J Am Chem Soc 2007, 129:3842-3843.
- [21]Janiak C: A critical account on π-π stacking in metal complexes with aromatic nitrogen-containing ligands. J Chem Soc Dalton Trans 2000, 3885-3896.
- [22]Meyer EA, Castellano RK, Diederich F: Interactions with aromatic rings in chemical and biological recognition. Angew Chem Int Ed 2003, 42:1210-1250.
- [23]Hughes RM, Waters ML: Effects of lysine acylation in a β-hairpin peptide: comparison of an amide-π and a cation-π interaction. J Am Chem Soc 2006, 128:13586-13591.
- [24]Kang SO, Hossain MA, Bowman-James K: Influence of dimensionality and charge on anion binding in amide-based macrocyclic receptors. Coord Chem Rev 2000, 250:3038-3052.
- [25]Miessler GL, Tarr DA: Inorganic Chemistry. 3rd edition. Upper Saddle River, NJ: Pearson Prentice Hall; 2003.
- [26]Smith MB, March J: March's Advanced Organic Chemistry: Reactions, Mechanisms, and Structure. 6th edition. New York: Wiley-Interscience; 2007.
- [27]Jackson WG, Josephine AM, Silvia C: Alfred Werner's inorganic counterparts of racemic and mesomeric tartaric acid: A milestone revisited. Inorg Chem 2004, 43:6249-6254.
- [28]Sirois SW, Proynov EI, Truchon JF, Tsoukas CM, Salahub DR: A density functional study of the hydrogen-bond network within the HIV-1 protease catalytic site cleft. J Comput Chem 2003, 24:1110-1119.
- [29]Du QS, Li DP, Liu PJ, Huang RB: Molecular potential energies in dodecahedron cell of methane hydrate and dispersion correction for DFT. J Mol Graph Model 2008, 27:140-146.
- [30]Henry M: Thermodynamics of hydrogen bond patterns in supramolecular assemblies of water molecules. Chem Phys Chem 2002, 3:607-616.
- [31]Henry M: Nonempirical quantification of molecular interactions in supramolecular assemblies. Chem Phys Chem 2002, 3:561-569.
- [32]Andrews LJ, Keefer RM: Molecular complexes in organic chemistry. San Francisco: Holden-Day; 1964.
- [33]Mezey PG: Macromolecular density matrices and electron densities with adjustable nuclear geometries. J Math Chem 1995, 18:141-168.
- [34]Mezey PG: Quantum similarity measures and Löwdin's transform for approximate density matrices and macromolecular forces. Int J Quantum Chem 1997, 63:39-48.
- [35]Sayyed FB, Suresh CH: Accurate prediction of cation−π interaction energy using substituent effects. J Phys Chem A 2012, 116:5723-5732.
- [36]Mohan N, Vijayalalakshmi KP, Koga N, Suresh CH: Comparison of aromatic NH…π, OH…π, and CH…π interactions of alanine using MP2, CCSD, and DFT methods. J Comput Chem 2010, 31:2874-2882.
- [37]Gresh N, Kafafi SA, Truchon JF, Salahub DR: Intramolecular interaction energies in model alanine and glycine tetrapeptides. Evaluation of anisotropy, polarization, and correlation effects. A parallel ab initio HF/MP2, DFT, and polarizable molecular mechanics study. J Compt Chem 2004, 25:823-834.
- [38]Jurecka P, Cerný J, Hobza P, Salahub DR: Density functional theory augmented with an empirical dispersion term. Interaction energies and geometries of 80 noncovalent complexes compared with ab initio quantum mechanics calculations. J Comput Chem 2007, 28:555-569.
- [39]Van Mourik T, Gdanitz RJ: A critical note on density functional theory studies on rare-gas dimers. J Chem Phys 2002, 116:9620-9623.
- [40]Morgado C, Vincent MA, Hillier IH, Shan X: Can the DFT-D method describe the full range of noncovalent interactions found in large biomolecules? Phys Chem Chem Phys 2007, 9:448-451.
- [41]Von Lilienfeld OA, Tavernelli I, Rothlisberger U, Sebastiani D: Optimization of effective atom centered potentials for London dispersion forces in density functional theory. Phys Rev Lett 2004, 93:153004-153007.
- [42]Du Q-S, Liu P-J, Deng J: Empirical correction to molecular interaction energies in density functional theory (DFT) for methane hydrate simulation. J Chem Theory Comput 2007, 3:1665-1672.
- [43]Purvis GD, Bartlett RJ: A full coupled-cluster singles and doubles model: The inclusion of disconnected triples. J Chem Phys 1982, 76:1910-1919.
- [44]Lee TJ, Rice JE: An efficient closed-shell singles and doubles coupled-cluster method. Chem Phys Lett 1988, 23:406-415.
- [45]Scuseria GE, Schaefer HF III: Is coupled cluster singles and doubles (CCSD) more computationally intensive than quadratic configuration interaction (QCISD)? J Chem Phys 1989, 90:3700-3703.
- [46]Scuseria GE, Janssen CL, Schaefer HF III: An efficient reformulation of the closed-shell coupled cluster single and double excitation (CCSD) equations. J Chem Phys 1988, 89:7382-7388.
- [47]Grimme S: Semiempirical hybrid density functional with perturbative second-order correlation. J Chem Phys 2006, 124:034108.
- [48]Zimmerli U, Parrinello M, Koumoutsakos P: Dispersion corrections to density functionals for water aromatic interactions. J Chem Phys 2004, 120:2693-2699.
- [49]Grimme S: Accurate description of van der Waals complexes by density functional theory including empirical corrections. J Comput Chem 2004, 25:1463-1473.
- [50]Miertus S, Scrocco E, Tomasi J: Electrostatic interaction of a solute with a continuum. A direct utilization of ab initio molecular potentials for the prevision of solvent effects. Chem Phys 1981, 55:117-129.
- [51]Amovilli C, Barone V, Cammi R, Cances E, Cossi M, Mennucci B, Pomelli CS, Tomasi J: Recent advances in the description of solvent effects with the polarizable continuum model. Adv Quant Chem 1998, 32:227-262.
- [52]Cossi M, Barone V: Analytical second derivatives of the free energy in solution by polarizable continuum models. J Chem Phys 1998, 109:6246-6254.
- [53]Foresman JB, Keith TA, Wiberg KB, Snoonian J, Frisch MJ: Solvent effects. 5. influence of cavity shape, truncation of electrostatics, and electron correlation on ab initio reaction field calculations. J Phys Chem 1996, 100:16098-16104.
- [54]Frisch MJ, Trucks GW, Schlegel HB, Scuseria GE, Robb MA, Cheeseman JR, Scalmani G, Barone V, Mennucci B, Petersson GA, Nakatsuji H, Caricato M, Li X, Hratchian HP, Izmaylov AF, Bloino J, Zheng G, Sonnenberg JL, Hada M, Ehara M, Toyota K, Fukuda R, Hasegawa J, Ishida M, Nakajima T, Honda Y, Kitao O, Nakai H, Vreven T, Montgomery JA: Gaussian 09, Revision B,01. Wallingford CT: Gaussian Inc; 2010.
- [55]Zielkiewicz J: Structural properties of water: Comparison of the SPC, SPCE, TIP4P, and TIP5P models of water. J Chem Phys 2005, 123:104501.
- [56]Markovitch O, Agmon N: Structure and energetics of the hydronium hydration shells. J Phys Chem A 2007, 111:2253-2256.
- [57]Du QS, Long SY, Meng JZ, Huang RB: Empirical formulation and parameterization of cation-π interactions for protein modeling. J Compt Chem 2012, 33:153-162.
- [58]Du QS, Liao SM, Meng JZ, Huang RB: Energies and Physicochemical Properties of Cation-π Interactions in Biology Structures. J Mol Graph Model 2012, 34:38-45.
- [59]Olsson MHM, Søndergaard CR, Rostkowski M, Jensen JH: PROPKA3: consistent treatment of internal and surface residues in empirical pKa predictions. J Chem Theory Comput 2011, 7:525-537.
- [60]Huang RB, Du QS, Wang CH, Liao SM, Chou KC: A fast and accurate method for predicting pKa of residues in proteins. Protein Eeng Des Sel 2010, 23:35-42.
- [61]Ottiger P, Pfaffen C, Leist R, Leutwyler S, Bachorz RA, Klopper W: Strong N−H···π Hydrogen Bonding in Amide−Benzene Interactions. J Phys Chem B 2009, 113:2937-2943.
- [62]Steiner T, Koellner G: Hydrogen bonds with pi-acceptors in proteins: frequencies and role in stabilizing local 3D structures. J Mol Biol 2001, 305:535-557.
- [63]Trakhanov S, Quiocho FA: Influence of divalent cations in protein crystallization. Protein Sci 1995, 4:1914-1919.
- [64]Fischer M, Pleiss J: The Lipase Engineering Database: a navigation and analysis tool for protein families. Nucleic Acids Res 2003, 31:319-321.
- [65]Bas DC, Rogers DM, Jensen JH: Very fast prediction and rationalization of pKa values for protein-ligand complexes. Proteins 2008, 73:765-783.
- [66]Li H, Robertson AD, Jensen JH: Very fast empirical prediction and rationalization of protein pKa values. Proteins 2005, 6:704-721.
- [67]Badger MR, Price GD: The role of carbonic anhydrase in photosynthesis. Annu Rev Plant Physio Plant Mol Bio 1994, 45:369-392.
- [68]Lindskog S: Structure and mechanism of carbonic anhydrase. Pharmacol Ther 1997, 74:1-20.
- [69]Biot C, Buisine E, Rooman M: Free-energy calculations of protein-ligand cation-π and amino-π interactions: From vacuum to protein-like environments. J Am Chem Soc 2003, 125:13988-13994.
- [70]Crowley PB, Golovin A: Cation-π interactions in protein–protein interfaces. Proteins 2005, 59:231-239.