Chaperone function of mutant versions of alpha A- and alpha B-crystallin prepared to pinpoint chaperone binding sites.

A major stress protein, alpha-crystallin, functions as a chaperone. Site-directed mutagenesis has been used to identify regions of the protein necessary for chaperone function. In this work we have taken some of the previously described mutants produced and assessed their chaperone function by both a traditional heat-induced aggregation method at elevated temperature and using enzyme methods at 37 degrees C. In general the different assays gave parallel results indicating that the same property is being measured. Discrepancies were explicable by the heat lability of some mutants. Most mutants had full chaperone function showing the robust nature of alpha-crystallin. A mutant corresponding to a minor component of rodent alpha A-crystallin, alpha Ains-crystallin, had decreased chaperone function. Decreased chaperone function was also found for human Ser139--> Arg, Thr144-->Arg, Ser59-->Ala mutants of alpha B-crystallin and double mutants Ser45-->Ala/Ser59-->Ala, Lys103--> Leu/His104-->Ile, and Glu110-->His/His111-->Glu. A mutant Phe27-->Arg that was the subject of previous controversy was shown to be fully active at physiological temperatures.

Alpha-crystallin as a molecular chaperone.

The role of alpha-crystallin as a molecular chaperone may explain how the lens stays transparent for so long. Alpha-crystallin prevents the aggregation of other lens crystallins and proteins that have become unfolded by "trapping" the protein in a high molecular weight complex. It also protects enzyme activities. The substrate protein may interact while in a molten globule state. Alpha-crystallin predominantly binds to proteins very early in the denaturation pathways. The amphiphilic nature of alpha-crystallin, a polar C-terminal-region and a hydrophobic N-terminal-region are all essential for chaperone function. The flexible C-terminal extension maintains solubility and can bind to opposing charged residues of unfolding proteins. Hydrophobic regions in the N-terminal region then hold the unfolded protein. Specific areas important for chaperone binding and function have been identified throughout the N-terminal-region, connecting peptide and C-terminal extension. After a substantial amount of chemical data and models, cryo-EM images of alpha-crystallin have confirmed a variable 3D surface with a hollow interior. Alpha-crystallin taken from the lens nucleus shows an age-dependent decrease in chaperone function. High molecular weight aggregates and alpha-crystallin found within the nucleus from clear and cataract lenses have reduced chaperone function. Post-translational modifications, known to occur during ageing, such as glycation, carbamylation, oxidation, phosphorylation and truncation cause a decrease in chaperone function. Alpha-crystallin is expressed outside the lens. AlphaB-crystallin can be induced by heat shock in many tissues where it is translocated from cytoplasm to nucleus. Increased expression of alphaB-crystallin has been seen in many pathological states. Conformational disorders, including cataract may have a common aetiology and potentially a common therapy.

The effects of ageing on the chaperone-like function of rabbit alpha-crystallin, comparing three methods of assay.

The lens has a high protein content necessary for focusing light on to the retina. Alpha-Crystallin accounts for approximately 40% of the protein and has been shown to act in a chaperone-like manner. Here we show the effects of ageing on the chaperone-like properties of alpha-crystallin from rabbit lens. Three assays were used to determine chaperone ability. Non-enzymatic glycosylation inactivation of malate dehydrogenase is protected by alpha-crystallin. Thermal aggregation of beta-low crystallin and malate dehydrogenase are both prevented by alpha-crystallin. Three ages of rabbit lens were used. Alpha-Crystallin from the soluble fraction of the cortex and nucleus were investigated as well as alpha-high and alpha-low fractions resolved by size-exclusion chromatography. All three methods complemented each other. There was no age-dependent loss in chaperone-like behaviour for both alpha fractions in the cortex. There was an early decrease with age of the nuclear alpha-low fraction. Nuclear alpha-high shows no age-related decrease but its chaperoning ability is greatly compromised. Post-translational modifications which occur during ageing may be responsible for the effect of alpha-crystallin chaperone-like ability in the lens nucleus.

Effect of aging on the chaperone-like function of human alpha-crystallin assessed by three methods.

alpha-Crystallin can function as a molecular chaperone by preventing unwanted interactions. This paper presents the effects of aging and cataract on the chaperone-like properties of alpha-crystallin from soluble fractions from the cortex and nucleus of human lenses by using three assays: enzyme inactivation and two turbidity experiments. The three methods complemented each other. There was no decrease with age of chaperone-like function of cortical alpha-low and alpha-high crystallin. Nuclear alpha-low crystallin showed a decrease, whereas alpha-high crystallin showed no age-related change but its protective effect was diminished. Results from the nucleus of 40-year-old cataractous lenses seemed similar to those for clear lenses of equivalent age, whereas 80-year-old cataractous lenses showed decreased chaperone-like behaviour.