The effect of pressure on the crystal structure of hexagonal L-cystine

Stephen A. Moggach, David R. Allan, Simon Parsons, Lindsay Sawyer, John E. Warren

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    The crystal structure of hexagonal L-cystine has been determined at room temperature at pressures between 0.4 and 3.7 GPa; unit-cell dimensions were measured up to 6.4 GPa. The structure of this phase consists of molecules in their zwitterionic form, and crystallizes in the hexagonal space group P6 122. The structure consists of hydrogen-bonded layers which are strongly reminiscent of those seen in a-glycine, and consist of R 44(16) hydrogen-bonded ring motifs. These layers are connected on one side by the disulflde bridges within the cystine molecules, and on the other by NH⋯O hydrogen bonds to other glycine-like layers. The most compressible unit-cell dimension, and the direction of greatest strain in the structure, is along the c-axis, and application of pressure pushes the layers closer together. The compression occurs approximately equally in the regions of the interlayer hydrogen bonds and the disulflde bridges; in the latter, changes in the C-S-S-C torsion angles allow the cystine molecules to act like springs. The effects of pressure can be interpreted in terms of closing-up of voids in the structure, and this leads to (i) a lessening of the N-C-C-O and C-S-S-C torsional angles, (ii) shortening of the N-H⋯O hydrogen bonds by 0.10-0.60 Å and (iii) a further shortening of an already short S⋯S contact from 3.444 (4) Å to 3.264 (4) Å. © 2005 International Union of Crystallography Printed in Great Britain - all rights reserved.
    Original languageEnglish
    Pages (from-to)598-607
    Number of pages9
    JournalJournal of Synchrotron Radiation
    Issue number5
    Publication statusPublished - Sept 2005


    • Amino acid
    • High-pressure single-crystal diffraction
    • Hydrogen bonding


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