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Direct imaging of carbohydrate stereochemistry (2410.20897v1)

Published 28 Oct 2024 in cond-mat.mtrl-sci and physics.bio-ph

Abstract: Carbohydrates, essential biological building blocks, exhibit functional mechanisms tied to their intricate stereochemistry. Subtle stereochemical differences, such as those between the anomers maltose and cellobiose, lead to distinct properties due to their differing glycosidic bonds; the former is digestible by humans, while the latter is not. This underscores the importance of precise structural determination of individual carbohydrate molecules for deeper functional insights. However, their structural complexity and conformational flexibility, combined with the high spatial resolution needed, have hindered direct imaging of carbohydrate stereochemistry. Here, we employ non-contact atomic force microscopy integrated with a data-efficient, multi-fidelity structure search approach accelerated by machine learning integration to determine the precise 3D atomic coordinates of two carbohydrate anomers. We observe that glycosidic bond stereochemistry regulates on-surface chiral selection in carbohydrate self-assemblies. The reconstructed models, validated against experimental data, provide reliable atomic-scale structural evidence, uncovering the origin of on-surface chirality from carbohydrate anomerism. Our study confirms that nc-AFM is a reliable technique for real-space discrimination of carbohydrate stereochemistry at the single-molecule level, providing a pathway for bottom-up investigations into the structure-property relationships of carbohydrates in biological research and materials science.

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References (57)
  1. A magnetic assembly approach to chiral superstructures. Science, 380(6652):1384–1390, 2023.
  2. Chirality conferral enables the observation of hyper-raman optical activity. Nature Photonics, 18(9):982–989, 2024.
  3. Transmission of chirality through space and across length scales. Nature Nanotechnology, 12(5):410–419, May 2017.
  4. Bottom-Up Approach to Understand Chirality Transfer across Scales in Cellulose Assemblies. Journal of the American Chemical Society, 144(27):12469–12475, July 2022.
  5. Eric Grelet and Maxime M. C. Tortora. Elucidating chirality transfer in liquid crystals of viruses. Nature Materials, 23(9):1276–1282, 2024.
  6. Synthesis and Predetermined Supramolecular Chirality of Carbohydrate‐Functionalized Perylene Bisimide Derivatives. Chemistry – An Asian Journal, 10(5):1204–1214, May 2015.
  7. Sensing the anomeric effect in a solvent-free environment. Nature, 469(7328):76–79, JAN 6 2011.
  8. Enhanced reactivity of twisted amides inside a molecular cage. Nature Chemistry, 12(6):574–578, June 2020. Publisher: Nature Publishing Group.
  9. Towards glycan foldamers and programmable assemblies. Nature Reviews Materials, 9(3):190–201, February 2024.
  10. Carbohydrates in Supramolecular Chemistry. Chemical Reviews, 116(4):1693–1752, February 2016.
  11. Identification of carbohydrate anomers using ion mobility–mass spectrometry. Nature, 526(7572):241–244, October 2015.
  12. Glycan Analysis by Ion Mobility–Mass Spectrometry. Angewandte Chemie International Edition, 56(29):8342–8349, July 2017.
  13. Unravelling the structural complexity of glycolipids with cryogenic infrared spectroscopy. Nature Communications, 12(1):1201, February 2021.
  14. Yu Ogawa and Jean-Luc Putaux. Recent Advances in Electron Microscopy of Carbohydrate Nanoparticles. Frontiers in Chemistry, 10, February 2022. Publisher: Frontiers.
  15. Martina Delbianco and Yu Ogawa. Visualizing the structural diversity of glycoconjugates. Nature Chemical Biology, 20(1):11–12, January 2024.
  16. Imaging single glycans. Nature, 582(7812):375–378, June 2020.
  17. Direct observation of glycans bonded to proteins and lipids at the single-molecule level. Science, 382(6667):219–223, October 2023.
  18. Visualizing Chiral Interactions in Carbohydrates Adsorbed on Au(111) by High‐Resolution STM Imaging. Angewandte Chemie International Edition, 62(39):e202305733, September 2023.
  19. The Chemical Structure of a Molecule Resolved by Atomic Force Microscopy. Science, 325(5944):1110–1114, August 2009.
  20. Scanning probe microscopy. Nature Reviews Methods Primers, 1(1):36, May 2021.
  21. Automated structure discovery in atomic force microscopy. 6(9):eaay6913, 2020. Publisher: American Association for the Advancement of Science Section: Research Article.
  22. Structure Discovery in Atomic Force Microscopy Imaging of Ice. ACS Nano, 18(7):5546–5555, February 2024. Publisher: American Chemical Society.
  23. Stefan Goedecker. Minima hopping: An efficient search method for the global minimum of the potential energy surface of complex molecular systems. The Journal of Chemical Physics, 120(21):9911–9917, May 2004.
  24. E(3)-equivariant graph neural networks for data-efficient and accurate interatomic potentials. Nature Communications, 13(1):2453, May 2022. Number: 1 Publisher: Nature Publishing Group.
  25. Bayesian inference of atomistic structure in functional materials. npj Computational Materials, 5(1):1–7, March 2019. Number: 1 Publisher: Nature Publishing Group.
  26. A general intermolecular force field based on tight-binding quantum chemical calculations. The Journal of Chemical Physics, 147(16):161708, July 2017.
  27. Sensing the anomeric effect in a solvent-free environment. 469(7328):76–79.
  28. Direct Spectroscopic Evidence for an n→π𝜋\piitalic_π* Interaction. Angewandte Chemie International Edition, 55(27):7801–7805, 2016.
  29. Insight into chemoselectivity of nitroarene hydrogenation: A DFT-D3 study of nitroarene adsorption on metal surfaces under the realistic reaction conditions. Applied Surface Science, 392:456–471, January 2017.
  30. Insights into the interaction of nitrobenzene and the Ag(111) surface: A DFT study. Surface Science, 750:122578, December 2024.
  31. Ab initio molecular simulations with numeric atom-centered orbitals. Computer Physics Communications, 180(11):2175–2196, 11 2009.
  32. Gaussian 16 Revision C.02, 2016. Gaussian Inc. Wallingford CT.
  33. Accurate molecular van der Waals interactions from ground-state electron density and free-atom reference data. Physical Review Letters, 102(7):073005, 2 2009.
  34. Density-functional theory with screened van der waals interactions for the modeling of hybrid inorganic-organic systems. Physical Review Letters, 108:146103, Apr 2012.
  35. Ken-ichi Tanaka. Surface Nano-Structuring by Adsorption and Chemical Reactions. Materials, 3(9):4518–4549, September 2010. Number: 9 Publisher: Molecular Diversity Preservation International.
  36. NBO Version 3.1.
  37. A. D. Becke. Density-functional exchange-energy approximation with correct asymptotic behavior. Physical Review A, 38:3098–3100, Sep 1988.
  38. Development of the colle-salvetti correlation-energy formula into a functional of the electron density. Physical Review B, 37:785–789, Jan 1988.
  39. Automated exploration of the low-energy chemical space with fast quantum chemical methods. Physical Chemistry Chemical Physics, 22(14):7169–7192, April 2020. Publisher: The Royal Society of Chemistry.
  40. CREST—A program for the exploration of low-energy molecular chemical space. The Journal of Chemical Physics, 160(11):114110, March 2024.
  41. The design space of e(3)-equivariant atom-centered interatomic potentials, 2022.
  42. The atomic simulation environment—a Python library for working with atoms. Journal of Physics: Condensed Matter, 29(27):273002, June 2017. Publisher: IOP Publishing.
  43. e3nn/e3nn: 2021-05-04, May 2021.
  44. Andrew A. Peterson. Global Optimization of Adsorbate–Surface Structures While Preserving Molecular Identity. Topics in Catalysis, 57(1):40–53, February 2014.
  45. Mechanism of high-resolution STM/AFM imaging with functionalized tips. Physical Review B, 90(8):085421, August 2014. Publisher: American Physical Society.
  46. Principles and simulations of high-resolution STM imaging with a flexible tip apex. Physical Review B, 95(4):045407, January 2017. Publisher: American Physical Society.
  47. J. Tersoff and D. R. Hamann. Theory of the scanning tunneling microscope. Physical Review B, 31:805–813, Jan 1985.
  48. WSXM: A software for scanning probe microscopy and a tool for nanotechnology. Review of Scientific Instruments, 78(1):013705, 01 2007.
  49. What is NBO analysis and how is it useful? International Reviews in Physical Chemistry, 35(3):399–440, July 2016. Publisher: Taylor & Francis _eprint: https://doi.org/10.1080/0144235X.2016.1192262.
  50. Nanostructuring of Au(111) during the Adsorption of an Aromatic Isocyanide from Solution. Langmuir, 33(1):91–99, January 2017. Publisher: American Chemical Society.
  51. Leaching of borosilicate glasses. I. Experiments. Journal of Non-Crystalline Solids, 343(1):3–12, September 2004.
  52. Dimers of formic acid: Structures, stability, and double proton transfer. The Journal of Chemical Physics, 147(4):044312, July 2017.
  53. Formic Acid Dimerization: Evidence for Species Diversity from First Principles Simulations. The Journal of Physical Chemistry A, 113(22):6266–6274, June 2009. Publisher: American Chemical Society.
  54. Telomere Structure and Stability: Covalency in Hydrogen Bonds, Not Resonance Assistance, Causes Cooperativity in Guanine Quartets. Chemistry – A European Journal, 17(45):12612–12622, 2011. _eprint: https://onlinelibrary.wiley.com/doi/pdf/10.1002/chem.201102234.
  55. Origin of cooperativity in hydrogen bonding. Physical Chemistry Chemical Physics, 19(23):15256–15263, June 2017. Publisher: The Royal Society of Chemistry.
  56. Quantitative Measurement of Cooperativity in H-Bonded Networks. Journal of the American Chemical Society, 144(42):19499–19507, October 2022. Publisher: American Chemical Society.
  57. Mapping the electrostatic force field of single molecules from high-resolution scanning probe images. Nature Communications, 7(1):11560, May 2016. Publisher: Nature Publishing Group.

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