Elucidation of the Active Form and Reaction Mechanism in Human Asparaginase Type III Using Multiscale Simulations.

l-asparaginases catalyze the asparagine hydrolysis to aspartate. These enzymes play an important role in the treatment of acute lymphoblastic leukemia because these cells are unable to produce their own asparagine. Due to the immunogenic response and various side effects of enzymes of bacterial origin, many attempts have been made to replace these enzymes with mammalian enzymes such as human asparaginase type III (hASNaseIII). This study investigates the reaction mechanism of hASNaseIII through molecular dynamics simulations, quantum mechanics/molecular mechanics methods, and free energy calculations. Our simulations reveal that the dimeric form of the enzyme plays a vital role in stabilizing the substrate in the active site, despite the active site residues coming from a single protomer. Protomer-protomer interactions are essential to keep the enzyme in an active conformation. Our study of the reaction mechanism indicates that the self-cleavage process that generates an N-terminal residue (Thr168) is required to activate the enzyme. This residue acts as the nucleophile, attacking the electrophilic carbon of the substrate after a proton transfer from its hydroxyl group to the N-terminal amino group. The reaction mechanism proceeds with the formation of an acyl-enzyme complex and its hydrolysis, which turns out to be the rate-determining step. Our proposal of the enzymatic mechanism sheds light on the role of different active site residues and rationalizes the studies on mutations. The insights provided here about hASNaseIII activity could contribute to the comprehension of the disparities among different ASNases and might even guide the design of new variants with improved properties for acute lymphoblastic leukemia treatment.

[1]  Gonzalo A. Jaña,et al.  Elucidation of the Reaction Mechanism of Cavia porcellus l-Asparaginase: A QM/MM Study , 2022, J. Chem. Inf. Model..

[2]  M. Burke,et al.  Hypersensitivity reactions to asparaginase therapy in acute lymphoblastic leukemia: immunology and clinical consequences. , 2022, Future oncology.

[3]  Oriol Vinyals,et al.  Highly accurate protein structure prediction with AlphaFold , 2021, Nature.

[4]  A. Pessoa,et al.  Structural and functional diversity of asparaginases: Overview and recommendations for a revised nomenclature , 2021, Biotechnology and applied biochemistry.

[5]  J. Weinstein,et al.  The mechanism of catalysis by L-asparaginase. , 2020, Biochemistry.

[6]  Junmei Wang,et al.  Fast, Accurate, and Reliable Protocols for Routine Calculations of Protein–Ligand Binding Affinities in Drug Design Projects Using AMBER GPU-TI with ff14SB/GAFF , 2020, ACS omega.

[7]  M. Bianchi,et al.  Asparagine Synthetase in Cancer: Beyond Acute Lymphoblastic Leukemia , 2020, Frontiers in Oncology.

[8]  L. Antolini,et al.  Acute myeloid leukaemia niche regulates response to L‐asparaginase , 2019, British journal of haematology.

[9]  R. Khavari-Nejad,et al.  Novel mutant of Escherichia coli asparaginase II to reduction of the glutaminase activity in treatment of acute lymphocytic leukemia by molecular dynamics simulations and QM-MM studies. , 2018, Medical hypotheses.

[10]  I. Tuñón,et al.  Adaptive Finite Temperature String Method in Collective Variables. , 2017, The journal of physical chemistry. A.

[11]  M. Konrad,et al.  Fluorescence-Activated Cell Sorting of Human l-asparaginase Mutant Libraries for Detecting Enzyme Variants with Enhanced Activity. , 2016, ACS chemical biology.

[12]  R. S. Babu,et al.  Exploration of the binding modes of l-asparaginase complexed with its amino acid substrates by molecular docking, dynamics and simulation , 2016, 3 Biotech.

[13]  C. Simmerling,et al.  ff14SB: Improving the Accuracy of Protein Side Chain and Backbone Parameters from ff99SB. , 2015, Journal of chemical theory and computation.

[14]  Anselm H. C. Horn,et al.  A consistent force field parameter set for zwitterionic amino acid residues , 2014, Journal of Molecular Modeling.

[15]  A. Lavie,et al.  Elucidation of the specific function of the conserved threonine triad responsible for human L-asparaginase autocleavage and substrate hydrolysis. , 2014, Journal of molecular biology.

[16]  A. Lavie,et al.  Structural and Kinetic Characterization of Guinea Pig l-Asparaginase Type III , 2014, Biochemistry.

[17]  W. Tissing,et al.  A prospective study on drug monitoring of PEGasparaginase and Erwinia asparaginase and asparaginase antibodies in pediatric acute lymphoblastic leukemia. , 2013, Blood.

[18]  P. Fernandes,et al.  Unraveling the enigmatic mechanism of L-asparaginase II with QM/QM calculations. , 2013, Journal of the American Chemical Society.

[19]  M. Konrad,et al.  Free glycine accelerates the autoproteolytic activation of human asparaginase. , 2013, Chemistry & biology.

[20]  Andreas W. Götz,et al.  SPFP: Speed without compromise - A mixed precision model for GPU accelerated molecular dynamics simulations , 2013, Comput. Phys. Commun..

[21]  M. Konrad,et al.  Structures of apo and product-bound human L-asparaginase: insights into the mechanism of autoproteolysis and substrate hydrolysis. , 2012, Biochemistry.

[22]  Duncan Poole,et al.  Routine Microsecond Molecular Dynamics Simulations with AMBER on GPUs. 1. Generalized Born , 2012, Journal of chemical theory and computation.

[23]  A. Cavalli,et al.  A Catalytic Mechanism for Cysteine N-Terminal Nucleophile Hydrolases, as Revealed by Free Energy Simulations , 2012, PloS one.

[24]  Roland L. Dunbrack,et al.  A smoothed backbone-dependent rotamer library for proteins derived from adaptive kernel density estimates and regressions. , 2011, Structure.

[25]  Michael Gaus,et al.  DFTB3: Extension of the self-consistent-charge density-functional tight-binding method (SCC-DFTB). , 2011, Journal of chemical theory and computation.

[26]  Marc N. Offman,et al.  Rational engineering of L-asparaginase reveals importance of dual activity for cancer cell toxicity. , 2011, Blood.

[27]  Jan H. Jensen,et al.  PROPKA3: Consistent Treatment of Internal and Surface Residues in Empirical pKa Predictions. , 2011, Journal of chemical theory and computation.

[28]  S. Grimme,et al.  A consistent and accurate ab initio parametrization of density functional dispersion correction (DFT-D) for the 94 elements H-Pu. , 2010, The Journal of chemical physics.

[29]  I. Ivanov,et al.  Do N‐terminal nucleophile hydrolases indeed have a single amino acid catalytic center? , 2009, The FEBS journal.

[30]  P. Kollman,et al.  Automatic atom type and bond type perception in molecular mechanical calculations. , 2006, Journal of molecular graphics & modelling.

[31]  J. Rouvinen,et al.  Ab Initio Quantum Mechanical Model Calculations on the Catalytic Mechanism of Aspartylglucosaminidase (AGA): A Serine Protease‐Like Mechanism with an N‐terminal Threonine and Substrate‐Assisted Catalysis , 1996 .

[32]  L. Peltonen,et al.  Functional analyses of active site residues of human lysosomal aspartylglucosaminidase: implications for catalytic mechanism and autocatalytic activation. , 1996, The EMBO journal.

[33]  A. Murzin,et al.  A protein catalytic framework with an N-terminal nucleophile is capable of self-activation , 1995, Nature.

[34]  T. Darden,et al.  A smooth particle mesh Ewald method , 1995 .

[35]  P. Kollman,et al.  A well-behaved electrostatic potential-based method using charge restraints for deriving atomic char , 1993 .

[36]  T. Darden,et al.  Particle mesh Ewald: An N⋅log(N) method for Ewald sums in large systems , 1993 .

[37]  A. Becke Density-functional thermochemistry. III. The role of exact exchange , 1993 .

[38]  R. Swendsen,et al.  THE weighted histogram analysis method for free‐energy calculations on biomolecules. I. The method , 1992 .

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

[40]  W. L. Jorgensen,et al.  Comparison of simple potential functions for simulating liquid water , 1983 .

[41]  G. Torrie,et al.  Nonphysical sampling distributions in Monte Carlo free-energy estimation: Umbrella sampling , 1977 .

[42]  H. Kay,et al.  L-Asparaginase in Treatment of Acute Leukaemia and Lymphosarcoma , 1970, British medical journal.

[43]  M. Jaskólski,et al.  Structural aspects of L-asparaginases, their friends and relations. , 2006, Acta biochimica Polonica.

[44]  J. Rouvinen,et al.  Structural comparison of Ntn‐hydrolases , 2000, Protein science : a publication of the Protein Society.