Altered phase diagram due to a single point mutation in human γD-crystallin

The P23T mutant of human γD-crystallin (HGD) is associated with cataract. We have previously investigated the solution properties of this mutant, as well as those of the closely related P23V and P23S mutants, and shown that although mutations at site 23 of HGD do not produce a significant structural...

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Bibliographic Details
Published in:Proceedings of the National Academy of Sciences - PNAS 2007-10, Vol.104 (43), p.16856-16861
Main Authors: McManus, Jennifer J, Lomakin, Aleksey, Ogun, Olutayo, Pande, Ajay, Basan, Markus, Pande, Jayanti, Benedek, George B
Format: Article
Language:English
Subjects:
Aggregation
Biological Sciences
Crystals
Diffusion coefficient
Genetic mutation
Monomers
Mutant proteins
Phase diagrams
Physical Sciences
Solid phases
Solubility
Temperature dependence
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Summary:The P23T mutant of human γD-crystallin (HGD) is associated with cataract. We have previously investigated the solution properties of this mutant, as well as those of the closely related P23V and P23S mutants, and shown that although mutations at site 23 of HGD do not produce a significant structural change in the protein, they nevertheless profoundly alter the solubility of the protein. Remarkably, the solubility of the mutants decreases with increasing temperature, in sharp contrast to the behavior of the native protein. This inverted solubility corresponds to a strong increase in the binding energy with temperature. Here we have investigated the liquid-liquid coexistence curve and the diffusivity of the P23V mutant and find that these solution properties are unaffected by the mutation. This means that the chemical potentials in the solution phase are essentially unaltered. The apparent discrepancy between the interaction energies in the solution phase, as compared with the solid phase, is explicable in terms of highly anisotropic interprotein interactions, which are averaged out in the solution phase but are fully engaged in the solid phase.
ISSN:0027-8424
1091-6490
DOI:10.1073/pnas.0707412104