Entasis through hook-and-loop fastening in a glycoligand with cumulative weak forces stabilizing Cu(I).

The idea of a possible control of metal ion properties by constraining the coordination sphere geometry was introduced by Vallee and Williams with the concept of entasis, which is frequently postulated to be at stake in metallobiomolecules. However, the interactions controlling the geometry at metal centers remain often elusive. In this study, the coordination properties toward copper ions—Cu(II) or Cu(I)—of a geometrically constrained glycoligand centered on a sugar scaffold were compared with those of an analogous ligand built on an unconstrained alkyl chain. The sugar-centered ligand was shown to be more preorganized for Cu(II) coordination than its open-chain analogue, with an unusual additional stabilization of the Cu(I) redox state. This preference for Cu(I) was suggested to arise from geometric constraints favoring an optimized folding of the glycoligand minimizing steric repulsions. In other words, the Cu(I) d(10) species is stabilized by valence shell electron pair repulsion (VSEPR). This idea was rationalized by a theoretical noncovalent interactions (NCI) analysis. The cumulative effects of weak forces were shown to create an efficient buckle as in a hook-and-loop fastener, and fine structural features within the glycoligand reduce repulsive interactions for the Cu(I) state. This study emphasizes that monosaccharide platforms are appropriate ligand backbones for a delicate geometric control at the metal center, with a network of weak interactions within the ligand. This structuration availing in glycoligands makes them attractive for metallic entasis.

[1]  S. Mehrman,et al.  A Review on the Use of Sodium Triacetoxyborohydride in the Reductive Amination of Ketones and Aldehydes , 2006 .

[2]  T. Prangé,et al.  Efficient synthesis of calix[6]tmpa: a new calix[6]azacryptand with unique conformational and host-guest properties. , 2006, Chemistry.

[3]  R. D. Shannon Revised effective ionic radii and systematic studies of interatomic distances in halides and chalcogenides , 1976 .

[4]  A. Martell,et al.  Determination and Use of Stability Constants , 1992 .

[5]  L. Berlouis,et al.  Modelling the impact of geometric parameters on the redox potential of blue copper proteins. , 2006, Journal of inorganic biochemistry.

[6]  D. Rorabacher,et al.  Electron transfer by copper centers. , 2004, Chemical reviews.

[7]  Parr,et al.  Development of the Colle-Salvetti correlation-energy formula into a functional of the electron density. , 1988, Physical review. B, Condensed matter.

[8]  P. Comba Strains and stresses in coordination compounds , 1999 .

[9]  M. Desmadril,et al.  Sugars to control ligand shape in metal complexes: conformationally constrained glycoligands with a predetermination of stereochemistry and a structural control. , 2010, Inorganic chemistry.

[10]  H. Schugar,et al.  Nearly tetrahedral 1:2 complexes of copper(I), copper(II), nickel(II), cobalt(II), and zinc(II) with 2,2'-bis(2-imidazolyl)biphenyl , 1987 .

[11]  R. Hancock,et al.  Factors affecting stabilities of chelate, macrocyclic and macrobicyclic complexes in solution , 1994 .

[12]  J. Contreras-Garcı́a,et al.  Unraveling non-covalent interactions within flexible biomolecules: from electron density topology to gas phase spectroscopy. , 2014, Physical chemistry chemical physics : PCCP.

[13]  L. Pedersen,et al.  Understanding selectivity of hard and soft metal cations within biological systems using the subvalence concept. I. Application to blood coagulation: direct cation-protein electronic effects vs. indirect interactions through water networks. , 2010, Journal of chemical theory and computation.

[14]  Nolan E. Dean,et al.  Metal ion recognition in aqueous solution by highly preorganized non-macrocyclic ligands☆ , 2007 .

[15]  Weitao Yang,et al.  Coupling quantum interpretative techniques: another look at chemical mechanisms in organic reactions. , 2012, Journal of chemical theory and computation.

[16]  U. Schubert,et al.  Prospects of metal complexes peripherally substituted with sugars in biomedicinal applications. , 2009, Chemistry.

[17]  G. Bernardinelli,et al.  2,2'-Bis(6-(2,2'-bipyridyl))biphenyl (TET), a sterically constricted tetradentate ligand: structures and properties of it's complexes with copper(I) and copper(II) , 1988 .

[18]  Jean‐Didier Maréchal,et al.  Metal Complexation of a D‐Ribose‐Based Ligand Decoded by Experimental and Theoretical Studies , 2012 .

[19]  C. Policar,et al.  Superoxide dismutase-like activity of cobalt(II) complexes based on a sugar platform. , 2005, Chemical communications.

[20]  D. Baigl,et al.  An intrinsically fluorescent glycoligand for direct imaging of ligand trafficking in artificial and living cell systems , 2013 .

[21]  T. Hor,et al.  Redox tuning of two biological copper centers through non-covalent interactions: same trend but different magnitude. , 2012, Chemical communications.

[22]  M. Aumont-Nicaise,et al.  Apo-neocarzinostatin: a protein carrier for Cu(II) glycocomplexes and Cu(II) into U937 and HT29 cell lines. , 2014, Journal of inorganic biochemistry.

[23]  T. E. Gough,et al.  Jahn-Teller distortions in octahedral copper(II) complexes , 1969 .

[24]  J. Pople,et al.  Self‐Consistent Molecular‐Orbital Methods. I. Use of Gaussian Expansions of Slater‐Type Atomic Orbitals , 1969 .

[25]  F. D. Leeuw,et al.  The relationship between proton-proton NMR coupling constants and substituent electronegativities—I : An empirical generalization of the karplus equation , 1980 .

[26]  C. Policar,et al.  Glycosiderophores: synthesis of tris-hydroxamate siderophores based on a galactose or glycero central scaffold, Fe(III) complexation studies. , 2012, Journal of inorganic biochemistry.

[27]  M. Desmadril,et al.  Glycoligands and Co(II) glycocomplexes. Investigation of the variation of the sugar-scaffold on the structure and chirality measured by circular dichroism. , 2007, Dalton transactions.

[28]  I. Bertini Biological Inorganic Chemistry: Structure and Reactivity , 2017 .

[29]  Yi Lu,et al.  Rationally tuning the reduction potential of a single cupredoxin beyond the natural range , 2009, Nature.

[30]  A. Barra,et al.  Glycoligands tuning the magnetic anisotropy of Ni(II) complexes. , 2007, Chemistry.

[31]  A. Deydier,et al.  Influence of Coordination Geometry upon Copper(II/I) Redox Potentials. Physical Parameters for Twelve Copper Tripodal Ligand Complexes , 1999 .

[32]  Peter Comba,et al.  Fit and misfit between ligands and metal ions , 2003 .

[33]  Peter Comba,et al.  Coordination compounds in the entatic state , 2000 .

[34]  C. Claver,et al.  Carbohydrate derivative ligands in asymmetric catalysis , 2004 .

[35]  R. Hancock,et al.  The Chelate, Cryptate and Macrocyclic Effects , 1988 .

[36]  R J Williams,et al.  Metalloenzymes: the entatic nature of their active sites. , 1968, Proceedings of the National Academy of Sciences of the United States of America.

[37]  R J Williams,et al.  Energised (entatic) states of groups and of secondary structures in proteins and metalloproteins. , 1995, European journal of biochemistry.

[38]  H. Schugar,et al.  Synthesis, characterization, and metal coordinating ability of multifunctional carbohydrate-containing compounds for Alzheimer's therapy. , 2007, Journal of the American Chemical Society.

[39]  Julia Contreras-García,et al.  Revealing noncovalent interactions. , 2010, Journal of the American Chemical Society.

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

[41]  J. Mahy,et al.  Series of Mn Complexes Based on N‐Centered Ligands and Superoxide – Reactivity in an Anhydrous Medium and SOD‐Like Activity in an Aqueous Medium Correlated to MnII/MnIII Redox Potentials , 2005 .

[42]  Dongwhan Lee,et al.  How bulky is a bulky ligand: energetic consequences of steric constraint in ligand-directed cluster assembly and disassembly. , 2005, Journal of the American Chemical Society.

[43]  C. Policar,et al.  Intrinsically fluorescent glycoligands to study metal selectivity. , 2011, Inorganic chemistry.

[44]  T. Hubin Synthesis and coordination chemistry of topologically constrained azamacrocycles , 2003 .

[45]  Arthur E. Martell,et al.  Ligand design for selective complexation of metal ions in aqueous solution , 1989 .

[46]  Z. Damaj,et al.  Synthesis, characterization and dioxygen reactivity of copper(I) complexes with glycoligands. , 2008, Dalton transactions.

[47]  J. Harrington,et al.  Iron chelation equilibria, redox, and siderophore activity of a saccharide platform ferrichrome analogue. , 2007, Inorganic chemistry.

[48]  Jäger,et al.  New Building Blocks for the Design of Oligonuclear Copper Complexes Based on Amino Carbohydrates. , 2000, Angewandte Chemie.

[49]  Jean-Philip Piquemal,et al.  NCIPLOT: a program for plotting non-covalent interaction regions. , 2011, Journal of chemical theory and computation.

[50]  A. W. Addison,et al.  Synthesis, structure, and spectroscopic properties of copper(II) compounds containing nitrogen–sulphur donor ligands; the crystal and molecular structure of aqua[1,7-bis(N-methylbenzimidazol-2′-yl)-2,6-dithiaheptane]copper(II) perchlorate , 1984 .