Restriction of S-adenosylmethionine conformational freedom by knotted protein binding sites

S-adenosylmethionine (SAM) is one of the most important enzyme substrates. It is vital for the function of various proteins, including large group of methyltransferases (MTs). Intriguingly, some bacterial and eukaryotic MTs, while catalysing the same reaction, possess significantly different topologies, with the former being a knotted one. Here, we conducted a comprehensive analysis of SAM conformational space and factors that affect its vastness. We investigated SAM in two forms: free in water (via NMR studies and explicit solvent simulations) and bound to proteins (based on all data available in the PDB). We identified structural descriptors – angles which show the major differences in SAM conformation between unknotted and knotted methyltransferases. Moreover, we report that this is caused mainly by a characteristic for knotted MTs tight binding site formed by the knot and the presence of adenine-binding loop. Additionally, we elucidate conformational restrictions imposed on SAM molecules by other protein groups in comparison to conformational space in water. Author summary The topology of a folded polypeptide chain has great impact on the resulting protein function and its interaction with ligands. Interestingly, topological constraints appear to affect binding of one of the most ubiquitous substrates in the cell, S-adenosylmethionine (SAM), to its target proteins. Here, we demonstrate how binding sites of specific proteins restrict SAM conformational freedom in comparison to its unbound state, with a special interest in proteins with non-trivial topology, including an exciting group of knotted methyltransferases. Using a vast array of computational methods combined with NMR experiments, we identify key structural features of knotted methyltransferases that impose unorthodox SAM conformations. We compare them with the characteristics of standard, unknotted SAM binding proteins. These results are significant for understanding differences between analogous, yet topologically different enzymes, as well as for future rational drug design.

[1]  Craig P Butts,et al.  Improved NOE fitting for flexible molecules based on molecular mechanics data - a case study with S-adenosylmethionine. , 2018, Physical chemistry chemical physics : PCCP.

[2]  S. Grzesiek,et al.  NMRPipe: A multidimensional spectral processing system based on UNIX pipes , 1995, Journal of biomolecular NMR.

[3]  Hye-Jin Yoon,et al.  Crystal structure of tRNA(m1G37)methyltransferase: insights into tRNA recognition , 2003, The EMBO journal.

[4]  Ping-Chiang Lyu,et al.  Untying a Protein Knot by Circular Permutation. , 2019, Journal of molecular biology.

[5]  Zhaoxi Sun,et al.  Protonation-dependent base flipping in the catalytic triad of a small RNA , 2017 .

[6]  Jennifer L. Martin,et al.  SAM (dependent) I AM: the S-adenosylmethionine-dependent methyltransferase fold. , 2002, Current opinion in structural biology.

[7]  Shigeyuki Yokoyama,et al.  Methyl transfer by substrate signaling from a knotted protein fold , 2016, Nature Structural &Molecular Biology.

[8]  Anders Liljas,et al.  Crystal structure of catechol O-methyltransferase , 1994, Nature.

[9]  Leo Stroosnijder,et al.  To tie or not to tie ridges for water conservation in Rift Valley drylands of Ethiopia , 2012 .

[10]  Hiroyuki Hori,et al.  Transfer RNA methyltransferases with a SpoU-TrmD (SPOUT) fold and their modified nucleosides in tRNA , 2017, Biomolecules.

[11]  Donald G Truhlar,et al.  An Ancient Fingerprint Indicates the Common Ancestry of Rossmann-Fold Enzymes Utilizing Different Ribose-Based Cofactors , 2016, PLoS biology.

[12]  Pei Zhou,et al.  Crystal structure of the nosiheptide-resistance methyltransferase of Streptomyces actuosus. , 2010, Biochemistry.

[13]  Victor Guallar,et al.  Archives of Biochemistry and Biophysics , 1951, Nature.

[14]  Berk Hess,et al.  GROMACS: High performance molecular simulations through multi-level parallelism from laptops to supercomputers , 2015 .

[15]  N. Grishin,et al.  PROMALS3D: a tool for multiple protein sequence and structure alignments , 2008, Nucleic acids research.

[16]  C. L. Ventola The antibiotic resistance crisis: part 1: causes and threats. , 2015, P & T : a peer-reviewed journal for formulary management.

[17]  R L Walter,et al.  Crystal structure of protein isoaspartyl methyltransferase: a catalyst for protein repair. , 2000, Structure.

[18]  Piotr Sliz,et al.  Structure and Function of an Essential Component of the Outer Membrane Protein Assembly Machine , 2007, Science.

[19]  Antonio Suma,et al.  How to fold intricately: using theory and experiments to unravel the properties of knotted proteins. , 2016, Current opinion in structural biology.

[20]  G. Cantoni Biological methylation: selected aspects. , 1975, Annual review of biochemistry.

[21]  T. Henkin,et al.  A tertiary structural element in S box leader RNAs is required for S‐adenosylmethionine‐directed transcription termination , 2005, Molecular microbiology.

[22]  Lukasz Goldschmidt,et al.  Structure and folding of a designed knotted protein , 2010, Proceedings of the National Academy of Sciences.

[23]  Eric J. Rawdon,et al.  KnotProt 2.0: a database of proteins with knots and other entangled structures , 2018, Nucleic Acids Res..

[24]  Kap Lim,et al.  Structure of the YibK methyltransferase from Haemophilus influenzae (HI0766): A cofactor bound at a site formed by a knot , 2003, Proteins.

[25]  James R. Williamson,et al.  Chemical Probe for Glycosidic Conformation in Telomeric DNAs , 1994 .

[26]  Mark L. Stolowitz,et al.  S-adenosyl-L-methionine and S-adenosyl-L-homocysteine, an NMR study , 1981 .

[27]  Janusz M. Bujnicki,et al.  Structural and evolutionary bioinformatics of the SPOUT superfamily of methyltransferases , 2007, BMC Bioinformatics.

[28]  Piotr Sułkowski,et al.  Dodging the crisis of folding proteins with knots , 2009, Proceedings of the National Academy of Sciences.

[29]  Esteban Vöhringer-Martinez,et al.  A consistent S-Adenosylmethionine force field improved by dynamic Hirshfeld-I atomic charges for biomolecular simulation , 2015, Journal of Computer-Aided Molecular Design.

[30]  T. N. Bhat,et al.  The Protein Data Bank , 2000, Nucleic Acids Res..

[31]  Matthew A. Cooper,et al.  Polishing the tarnished silver bullet: the quest for new antibiotics , 2017, Essays in biochemistry.

[32]  V. Hornak,et al.  Comparison of multiple Amber force fields and development of improved protein backbone parameters , 2006, Proteins.

[33]  Pawel Dabrowski-Tumanski,et al.  To Tie or Not to Tie? That Is the Question , 2017, Polymers.

[34]  Graeme L. Conn,et al.  Structure of the Thiostrepton Resistance Methyltransferase·S-Adenosyl-l-methionine Complex and Its Interaction with Ribosomal RNA* , 2009, The Journal of Biological Chemistry.

[35]  Anders Poulsen,et al.  Targeting the Bacterial Epitranscriptome for Antibiotic Development: Discovery of Novel tRNA-(N1G37) Methyltransferase (TrmD) Inhibitors. , 2019, ACS infectious diseases.

[36]  Skorn Mongkolsuk,et al.  Methylation at position 32 of tRNA catalyzed by TrmJ alters oxidative stress response in Pseudomonas aeruginosa , 2016, Nucleic acids research.

[37]  Gevorg Grigoryan,et al.  Rapid search for tertiary fragments reveals protein sequence–structure relationships , 2015, Protein science : a publication of the Protein Society.

[38]  Peter Virnau,et al.  Intricate Knots in Proteins: Function and Evolution , 2006, PLoS Comput. Biol..

[39]  Martin A Walsh,et al.  Crystal structure of MboIIA methyltransferase. , 2003, Nucleic acids research.

[40]  Per-Ola Norrby,et al.  S-adenosylmethionine conformations in solution and in protein complexes: conformational influences of the sulfonium group. , 2002, Biochemistry.

[41]  Ning Gao,et al.  Selective inhibitors of bacterial t-RNA-(N(1)G37) methyltransferase (TrmD) that demonstrate novel ordering of the lid domain. , 2013, Journal of medicinal chemistry.

[42]  R. Blumenthal,et al.  Many paths to methyltransfer: a chronicle of convergence. , 2003, Trends in biochemical sciences.

[43]  Eric J. Rawdon,et al.  Conservation of complex knotting and slipknotting patterns in proteins , 2012, Proceedings of the National Academy of Sciences.

[44]  J. Broderick,et al.  Glycyl radical activating enzymes: structure, mechanism, and substrate interactions. , 2014, Archives of biochemistry and biophysics.

[45]  Chi-Huey Wong,et al.  S-adenosylmethionine: Stability and stabilization☆ , 1987 .