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Aspartyl-tRNA synthetases were the model proteins in pilot crystallogenesis experiments. They are homodimeric enzymes of Mr~125 kDa that possess as substrates a transfer RNA, ATP and aspartate. They have been isolated from different sources and were crystallized either as free proteins or in association with their ligands. This review discusses their crystallisability with emphasis to crystal quality and structure determination. Crystallization in low diffusivity gelled media or in microgravity environments is highlighted. It has contributed to prepare high-resolution diffracting crystals with better internal order as reflected by their mosaicity. With AspRS from Thermus thermophilus, the better crystalline quality of the space-grown crystals within APCF is correlated with higher quality of the derived electron density maps. Usefulness for structural biology of targeted methods aimed to improve the intrinsic physical quality of protein crystals is highlighted.

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To understand how surface residues in a protein structure influence crystal growth, packing arrangement and crystal quality, crystal surfaces were modified and crystallizability of seven different mutants investigated. The model was aspartyl-tRNA synthetase-1 from Thermus thermophilus, a homodimer (Mr 122,000) with a subunit of 580 amino acids. Engineering concerned modification of amino acids involved in packing contacts in the orthorhombic lattice (P212121) of the synthetase. Comparison of the crystallization behaviour of the mutants indicates a correlation between disruption/addition of packing interactions and crystallizability of the mutants: disruption or modification of lattice contacts prevents crystallization or leads to crystals of poor quality. In contrast, addition of potential contacts leads to well-shaped crystals of same space group and cell parameters than wild-type crystals.

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