Eye-Lens proteins structure, superstructure, stability, genetics
- 1 October 1994
- journal article
- research article
- Published by Springer Nature in The Science of Nature
- Vol. 81 (10) , 423-429
- https://doi.org/10.1007/bf01136641
Abstract
The eye lens in vertebrates and invertebrates is an avascular tissue which allows one to focus objects on the retina. The lens grows throughout life, maintaining transparency without significant turnover of its densely packed proteins. Apart from cytoskeletal and taxon-specific components, these proteins belong mainly to the alpha- and beta gamma-crystallin families. The detailed structural analysis of beta gamma-crystallins can explain the anomalous stability by the specific supersecondary structure ("Greek key" topology) of the domains and by strong domain and subunit interactions. The spatial correlation of the molecules at the given high concentrations in the fiber cells gives rise to "short-range order" with minimum light scattering, thus providing optimum transparency of the eye lens.Keywords
This publication has 22 references indexed in Scilit:
- Dimerization of βB2‐crystallin: The role of the linker peptide and the N‐ and C‐terminal extensionsProtein Science, 1994
- Domain interactions and connecting peptides in lens crystallinsJournal of Molecular Biology, 1994
- Lens crystallins: gene recruitment and evolutionary dynamismTrends in Biochemical Sciences, 1993
- Limited proteolysis of γII‐crystallin from calf eye lensEuropean Journal of Biochemistry, 1990
- X-ray analysis of βB2-crystallin and evolution of oligomeric lens proteinsNature, 1990
- The evolution of lenticular proteins: The β- and γ-crystallin super gene familyProgress in Biophysics and Molecular Biology, 1988
- The enzyme lactate dehydrogenase as a structural protein in avian and crocodilian lensesNature, 1987
- Short-range order of crystallin proteins accounts for eye lens transparencyNature, 1983
- Intracellular Degradation and Deamidation of α‐Crystallin SubunitsEuropean Journal of Biochemistry, 1976
- Acquisition of Three-Dimensional Structure of ProteinsAnnual Review of Biochemistry, 1973