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Crystal 102 m 2 m 2 mm 7 Crystal lattices 14 Bravais lattices.

Published byHelena Copeland Modified over 9 years ago

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Presentation on theme: "Crystal 102 m 2 m 2 mm 7 Crystal lattices 14 Bravais lattices."— Presentation transcript:

1

2 Crystal 102 m 2 m 2 mm

3 7 Crystal lattices

4 14 Bravais lattices

5 Symmetry – Space groups 2D symmetry3D symmetry Screw axis Proteins are chiral – no mirror symmetry Combination of Bravais lattices and symmetry operations leads to 230 possible space groups (not all for proteins).

6 Example of space group information from International Crystallographic Tables

7 Protein Big molecule Temperature sensitive Hundreds-thousands of rotating bonds Weak interactions mostly involved High solvent content (30-70 %) Fragile crystals Inorganic salt (ev. organics) Small molecule Thermostable None/few rotating bonds Strong (coulombic) interactions frequent Low/none solvent content Hard crystals

8 Phase diagram

9 Protein crystallization techniques Protein crystallization by vapour diffusion: (a) microbatch, (b) sitting drop and (c,d) hanging drop. In d and e, a sandwich is made of the mesophase (red) by placing a small glass coverslip (hatched) (d) below or (e) above the bolus. From Nature Protocols Protein crystallization by counter diffusion in capillaries. Protein crystallization by dialysis.

10 Various techniques = various path in the phase diagram

11 Automatization vs. manual work  High-throughput  Low volumes (20-150 nl)  Reproducibility  Individual design  Immediate visual control  Complex sample handling

12 Further reading http://journals.iucr.org/ Naomi E. Chayen: Protein Crystallization Strategies for Structural Genomics, 2007 Terese M. Bergfors: Protein Crystallization, 2009 Alexander McPherson: Introduction to Macromolecular Crystallography, 2011 etc.

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