Structural and dynamic evolution of the amphipathic N-terminus diversifies enzyme thermostability in the glycoside hydrolase family 12.

Understanding the molecular mechanism underlying protein thermostability is central to the process of efficiently engineering thermostable cellulases, which can provide potential advantages in accelerating the conversion of biomass into clean biofuels. Here, we explored the general factors that diversify enzyme thermostability in the glycoside hydrolase family 12 (GH12) using comparative molecular dynamics (MD) simulations coupled to a bioinformatics approach. The results indicated that protein stability is not equally distributed over the whole structure: the N-terminus is the most thermal-sensitive region of the enzymes with a β-sandwich architecture and it tends to lose its secondary structure during the course of protein unfolding. Furthermore, we found that the total interaction energy within the N-terminus is appreciably correlated with enzyme thermostability. Interestingly, the internal interactions within the N-terminus are organized in a special amphipathic pattern in which a hydrophobic packing cluster and a hydrogen bonding cluster lie at the two ends of the N-terminus. Finally, bioinformatics analysis demonstrated that the amphipathic pattern is highly conserved in GH12 and besides that, the evolution of the amino acids in the N-terminal region is an inherent mechanism underlying the diversity of enzyme thermostability. Taken together, our results demonstrate that the N-terminus is generally the structure that determines enzyme thermostability in GH12, and thereby it is also an ideal engineering target. The dynameomics study of a protein family can give a general view of protein functions, which will offer a wide range of applications in future protein engineering.

[1]  Lushan Wang,et al.  Substrate-binding specificity of chitinase and chitosanase as revealed by active-site architecture analysis. , 2015, Carbohydrate research.

[2]  Jay H. Lee,et al.  Protein engineering of cellulases. , 2014, Current opinion in biotechnology.

[3]  S. M. Kristensen,et al.  Enhanced stability of a protein with increasing temperature. , 2011, Journal of the American Chemical Society.

[4]  F. Arnold,et al.  Engineered thermostable fungal cellulases exhibit efficient synergistic cellulose hydrolysis at elevated temperatures , 2014, Biotechnology and Bioengineering.

[5]  M. Himmel,et al.  Computational Investigation of the pH Dependence of Loop Flexibility and Catalytic Function in Glycoside Hydrolases* , 2013, The Journal of Biological Chemistry.

[6]  Balvinder Singh,et al.  Replacement of the active surface of a thermophile protein by that of a homologous mesophile protein through structure-guided 'protein surface grafting'. , 2008, Biochimica et biophysica acta.

[7]  G M Crippen,et al.  Size‐independent comparison of protein three‐dimensional structures , 1995, Proteins.

[8]  R. Levy,et al.  Corrections to the quasiharmonic approximation for evaluating molecular entropies , 1986 .

[9]  E. Bayer,et al.  A combined cell-consortium approach for lignocellulose degradation by specialized Lactobacillus plantarum cells , 2014, Biotechnology for Biofuels.

[10]  J. Ståhlberg,et al.  Structural and biochemical studies of GH family 12 cellulases: improved thermal stability, and ligand complexes. , 2005, Progress in biophysics and molecular biology.

[11]  Mousumi Hazra,et al.  Comparative molecular dynamics simulation studies for determining factors contributing to the thermostability of chemotaxis protein “CheY” , 2014, Journal of biomolecular structure & dynamics.

[12]  P. Kollman,et al.  A Second Generation Force Field for the Simulation of Proteins, Nucleic Acids, and Organic Molecules , 1995 .

[13]  J. Joo,et al.  Development of thermostable Candida antarctica lipase B through novel in silico design of disulfide bridge , 2012, Biotechnology and bioengineering.

[14]  Peter M. Kasson,et al.  GROMACS 4.5: a high-throughput and highly parallel open source molecular simulation toolkit , 2013, Bioinform..

[15]  Pedro M. Coutinho,et al.  The carbohydrate-active enzymes database (CAZy) in 2013 , 2013, Nucleic Acids Res..

[16]  Shuai Wang,et al.  Ligand-binding specificity and promiscuity of the main lignocellulolytic enzyme families as revealed by active-site architecture analysis , 2016, Scientific Reports.

[17]  Valerie Daggett,et al.  Dynameomics: a consensus view of the protein unfolding/folding transition state ensemble across a diverse set of protein folds. , 2009, Biophysical journal.

[18]  F. Tjerneld,et al.  Enzymatic properties of the low molecular mass endoglucanases Cel12A (EG III) and Cel45A (EG V) of Trichoderma reesei. , 2002, Journal of biotechnology.

[19]  Temperature-induced unfolding pathway of a type III antifreeze protein: insight from molecular dynamics simulation. , 2008, Journal of molecular graphics & modelling.

[20]  Claire Dumon,et al.  Engineering Hyperthermostability into a GH11 Xylanase Is Mediated by Subtle Changes to Protein Structure* , 2008, Journal of Biological Chemistry.

[21]  G. Crooks,et al.  WebLogo: a sequence logo generator. , 2004, Genome research.

[22]  Joseph A. Bank,et al.  Supporting Online Material Materials and Methods Figs. S1 to S10 Table S1 References Movies S1 to S3 Atomic-level Characterization of the Structural Dynamics of Proteins , 2022 .

[23]  Yanhe Ma,et al.  Enhanced activity of Thermotoga maritima cellulase 12A by mutating a unique surface loop , 2012, Applied Microbiology and Biotechnology.

[24]  Guohui Li,et al.  UNDERSTANDING THE MOLECULAR MECHANISM OF BINDING MODES OF AURORA A INHIBITORS BY LONG TIME SCALE GPU DYNAMICS , 2013 .

[25]  G. Huisman,et al.  Engineering the third wave of biocatalysis , 2012, Nature.

[26]  Kapil Kumar,et al.  Insights into the unfolding pathway and identification of thermally sensitive regions of phytase from Aspergillus niger by molecular dynamics simulations , 2015, Journal of Molecular Modeling.

[27]  F. Sun,et al.  Five mutations in N-terminus confer thermostability on mesophilic xylanase. , 2010, Biochemical and biophysical research communications.

[28]  P. Bharatam,et al.  Pharmacoinformatics analysis to identify inhibitors of Mtb-ASADH , 2016, Journal of biomolecular structure & dynamics.

[29]  A. Szilágyi,et al.  Structural differences between mesophilic, moderately thermophilic and extremely thermophilic protein subunits: results of a comprehensive survey. , 2000, Structure.

[30]  Jill E. Gready,et al.  Optimization of parameters for molecular dynamics simulation using smooth particle‐mesh Ewald in GROMACS 4.5 , 2011, J. Comput. Chem..

[31]  D. Bevan,et al.  Study and design of stability in GH5 cellulases , 2012, Biotechnology and bioengineering.

[32]  Indira Wu,et al.  Engineered thermostable fungal Cel6A and Cel7A cellobiohydrolases hydrolyze cellulose efficiently at elevated temperatures , 2013, Biotechnology and bioengineering.

[33]  P. Biswas,et al.  Shape dependence of the radial distribution function of hydration water around proteins , 2014, Journal of physics. Condensed matter : an Institute of Physics journal.

[34]  G. Schreiber,et al.  Assessing computational methods for predicting protein stability upon mutation: good on average but not in the details. , 2009, Protein engineering, design & selection : PEDS.

[35]  A. G. Day,et al.  Comparison of family 12 glycoside hydrolases and recruited substitutions important for thermal stability , 2003, Protein science : a publication of the Protein Society.

[36]  J. Rouvinen,et al.  Molecular dynamics studies on the thermostability of family 11 xylanases. , 2007, Protein engineering, design & selection : PEDS.

[37]  Lennart Nilsson,et al.  Rigidity versus flexibility: the dilemma of understanding protein thermal stability , 2015, The FEBS journal.

[38]  Kaare Teilum,et al.  Protein stability, flexibility and function. , 2011, Biochimica et biophysica acta.

[39]  J. Frère,et al.  An additional aromatic interaction improves the thermostability and thermophilicity of a mesophilic family 11 xylanase: Structural basis and molecular study , 2008, Protein science : a publication of the Protein Society.

[40]  M. Nei,et al.  MEGA5: molecular evolutionary genetics analysis using maximum likelihood, evolutionary distance, and maximum parsimony methods. , 2011, Molecular biology and evolution.

[41]  George I Makhatadze,et al.  Contribution of surface salt bridges to protein stability: guidelines for protein engineering. , 2003, Journal of molecular biology.

[42]  B. Yao,et al.  Improved thermal performance of Thermomyces lanuginosus GH11 xylanase by engineering of an N-terminal disulfide bridge. , 2012, Bioresource technology.

[43]  J. Zielkiewicz Structural properties of water: comparison of the SPC, SPCE, TIP4P, and TIP5P models of water. , 2005, The Journal of chemical physics.

[44]  Tim J Kamerzell,et al.  The complex inter-relationships between protein flexibility and stability. , 2008, Journal of pharmaceutical sciences.

[45]  Wilfred F. van Gunsteren,et al.  Lattice‐sum methods for calculating electrostatic interactions in molecular simulations , 1995 .

[46]  Narayanaswamy Srinivasan,et al.  Nucleic Acids Research Advance Access published June 21, 2007 PIC: Protein Interactions Calculator , 2007 .

[47]  D. Raleigh,et al.  The cold denatured state is compact but expands at low temperatures: hydrodynamic properties of the cold denatured state of the C-terminal domain of L9. , 2007, Journal of molecular biology.

[48]  Guanjun Chen,et al.  Subsite-specific contributions of different aromatic residues in the active site architecture of glycoside hydrolase family 12 , 2015, Scientific Reports.

[49]  Rodrigo Lopez,et al.  Clustal W and Clustal X version 2.0 , 2007, Bioinform..

[50]  Milton T. W. Hearn,et al.  Physicochemical Basis of Amino Acid Hydrophobicity Scales: Evaluation of Four New Scales of Amino Acid Hydrophobicity Coefficients Derived from RP-HPLC of Peptides , 1995 .

[51]  Yu Zhang,et al.  Improving Trichoderma reesei Cel7B Thermostability by Targeting the Weak Spots , 2014, J. Chem. Inf. Model..

[52]  A. Suurnäkki,et al.  Enzymatic hydrolysis of lignocellulosic polysaccharides in the presence of ionic liquids , 2015 .

[53]  M. Parrinello,et al.  Polymorphic transitions in single crystals: A new molecular dynamics method , 1981 .

[54]  Jian Chen,et al.  Improving the Thermostability and Catalytic Efficiency of Bacillus deramificans Pullulanase by Site-Directed Mutagenesis , 2013, Applied and Environmental Microbiology.

[55]  Lushan Wang,et al.  Investigating the Impact of Asp181 Point Mutations on Interactions between PTP1B and Phosphotyrosine Substrate , 2014, Scientific Reports.

[56]  M. Parrinello,et al.  Canonical sampling through velocity rescaling. , 2007, The Journal of chemical physics.

[57]  T. Straatsma,et al.  Separation‐shifted scaling, a new scaling method for Lennard‐Jones interactions in thermodynamic integration , 1994 .

[58]  S. Bejar,et al.  Improvement of Trichoderma reesei xylanase II thermal stability by serine to threonine surface mutations. , 2015, International journal of biological macromolecules.

[59]  M. Levitt,et al.  Protein unfolding pathways explored through molecular dynamics simulations. , 1993, Journal of molecular biology.

[60]  Neelanjana Sengupta,et al.  Signatures of protein thermal denaturation and local hydrophobicity in domain specific hydration behavior: a comparative molecular dynamics study. , 2016, Molecular bioSystems.

[61]  Chris Sander,et al.  The double cubic lattice method: Efficient approaches to numerical integration of surface area and volume and to dot surface contouring of molecular assemblies , 1995, J. Comput. Chem..

[62]  Joseph A. Rollin,et al.  Increasing cellulose accessibility is more important than removing lignin: A comparison of cellulose solvent‐based lignocellulose fractionation and soaking in aqueous ammonia , 2011, Biotechnology and bioengineering.

[63]  L Wang,et al.  The early stage of folding of villin headpiece subdomain observed in a 200-nanosecond fully solvated molecular dynamics simulation. , 1998, Proceedings of the National Academy of Sciences of the United States of America.

[64]  Berk Hess,et al.  LINCS: A linear constraint solver for molecular simulations , 1997 .

[65]  Neelanjana Sengupta,et al.  The non-uniform early structural response of globular proteins to cold denaturing conditions: a case study with Yfh1. , 2014, The Journal of chemical physics.

[66]  P. Kollman,et al.  Settle: An analytical version of the SHAKE and RATTLE algorithm for rigid water models , 1992 .