Spectroscopic studies on the riboflavin-sensitized conformational changes of calf lens alpha-crystallin

Structural and functional alteration of human αA-crystallin after exposure to full spectrum solar radiation and preventive role of lens antioxidants

The chronically exposure of eye lenses to ultra violet and visible light of the solar radiation is an important risk factor for development of the senile cataract diseases. Various photosensitizer molecules including riboflavin (RF) play a significant role in photo-oxidative damages of lens proteins underlying development of opacity in the lenticular tissues. In the current study, RF-mediated photo-oxidation of human αA-crystallin (αA-Cry) was assessed using SDS-PAGE analysis, dynamic light scattering and other spectroscopic assessments. The RF-photosensitized reactions led to non-disulfide covalent cross-linking, oligomerization and significant structural changes in αA-Cry. The photo-damaging of αA-Cry under solar radiation was also accompanied by the reduction in both Trp and Tyr fluorescence intensities which followed by the formation of new photosensitizer chromophores. The solvent exposed hydrophobic patches, secondary structures and chaperone-like activity of αA-Cry were significantly altered after exposure to the solar radiation in the presence of RF. Although glutathione and ascorbate were capable to partially protect the photo-induced structural damages of human αA-Cry, they also disrupted its chaperone function when co-exposed with this protein to the solar radiation. Also, the most promising data were obtained with cysteine which its availability in the lenticular tissues is a rate limiting factor for the biosynthesis of glutathione. Overall our results suggest that glutathione and ascorbate, as the major anti-oxidant compounds within lenticular tissues, demonstrate controversial effect on structure and chaperone-like activity of human αA-Cry. Elucidation of this effect may demand further experiments.

Photosensitized structural modifications of the lens protein alpha-crystallin: do all modifications impair chaperone-like activity?

Among chaperone-like functioning proteins, the lens alpha-crystallins are of particular interest because they are not renewed, and even minor alterations can hurt their function of maintaining the proper refractive index and avoiding cataract formation in the lens. Several reports have suggested the occurrence of remarkable structural modifications in lens proteins in the presence of endogenous and exogenous sensitizers upon exposure to light. In particular, it has been shown in vitro that hypericin, the active ingredient of Hypericum, can bind to and, in the presence of light, cause the photopolymerization of alpha-crystallin. On the basis of these results it has also been suggested that a subsequent significant impairment of the protein function can occur. Using absorption and emission spectroscopic techniques, as well as circular dichroism, we have studied the structural modifications of alpha-crystallin resulting from its interaction with hypericin after irradiation with visible light. To investigate the chaperone-like function of alpha-crystallin, the heat-induced aggregation kinetics of another lens protein, betaLow-crystallin, was monitored by measuring the apparent absorption due to scattering at 360 nm as a function of time, and no apparent damage to its functional role was observed. Spectroscopic results, on the contrary, show a prominent reduction in both tryptophan and hypericin fluorescence emission intensity after light irradiation, suggesting an alteration in the tryptophan microenvironment and a high degree of packing of the chromophore due to photoinduced modification of the molecular framework. Control experiments on alpha-crystallin structurally modified by light in the presence of hypericin indicated that the protein still retains its ability to chaperone both lens crystallins and insulin.

UV-B-induced secondary conformational changes in lens alpha-crystallin

The changes in turbidity and protein secondary structure of alpha-crystallin after a 72 h UV-B (302 nm) irradiation in aqueous solution have been determined by UV spectrophotometry and Fourier transform infrared (FT-IR) microspectroscopy with reflection mode. The relative transmission of alpha-crystallin aqueous solution gradually decreases with the exposure time, indicating that the transparent alpha-crystallin aqueous solution becomes opaque with prolonged UV-B irradiation. The turbidity induced by UV-B shows first-order kinetics due to the photo-induced aggregation. The modification of the secondary structure of the alpha-crystallin molecule in aqueous solution caused by this aggregation might enhance the alpha-helix and beta-turn structures from 8.14 to 14.92% and from 24.46 to 35.54%, respectively; reduce the beta-sheet structure from 60.20% to 43.77%; and leave the random coil structure almost unaltered. The secondary conformation of alpha-crystallin changes gradually but evidently with its increase of turbidity during UV-B exposure.

Concentration dependence of transmission losses in UV-laser irradiated bovine alpha-, beta H-, beta L- and gamma-crystallin solutions

Experiments with calf lens protein fractions in aqueous buffer solutions at room temperature showed that beta H-, beta L- and gamma-crystallin fractions became opaque following ultraviolet exposure at 308 nm, while the alpha-crystallin fraction remained transparent. Transmission loss, due to UV-irradiation, for all of the crystallin samples was studied in the concentration range of 0.1 mg/mL to 1.0 mg/mL, and for alpha- and gamma-crystallin, in the range up to 5 mg/mL. With increased concentrations of beta H-, beta L- and gamma-crystallin, the rate of opacification increased. However, with alpha-crystallin, the loss of transmission was negligible for all of the concentrations and irradiation times studied. Opacification of the crystallins was accompanied by formation of higher molecular weight insoluble proteins as detected by SDS-PAGE.

Photooxidation of specific residues in alpha-crystallin polypeptides

Singlet oxygen is a biologically important, photochemically generated species that preferentially oxidizes His, Trp, and Met residues of protein molecules. Calf alpha-crystallin was photooxidized with use of meso-tetra(p-sulfonatophenyl)porphyrin (TPPS) and uroporphyrin (UP) as singlet oxygen generators. The effects of photooxidation were monitored by analyzing the changes in alpha-crystallin peptide maps obtained by reversed-phase HPLC using a photodiode array absorbance detector. The reaction led to the loss of six specific peptides, five of which contained photooxidizable residues. Peptides containing His-97 and His-154 from the A chain and Met-68 from the B chain are preferentially photooxidized, suggesting that those residues have access to singlet oxygen. Trp residues in the N-terminal region are converted to NFK, whereas Trp-60 in the B chain is not photooxidized strongly suggesting that the former are close to the surface of alpha-crystallin while the latter Trp residue is buried. Only one peptide that is lost from the peptide maps does not contain a photooxidizable group; however, this peptide does contain an apparently undigested Lys residue. It is suggested that it forms a cross-link with a photooxidized His residue.

Mechanisms of photochemically produced turbidity in lens protein solutions

Calf alpha- and gamma-crystallin were photolyzed in 1-2 mg ml-1 aqueous solutions, using both laser and conventional UV radiation in the 297-320 nm wavelength region. Gamma-crystallin solutions became highly turbid upon UV irradiation, while alpha-crystallin developed no turbidity when irradiated under identical conditions. The photolyzed solutions were analyzed by SDS-PAGE. These gels revealed loss of normal 20 kDa polypeptide, and formation of higher molecular weight peptides, in both alpha- and gamma-crystallin, presumably as a result of photocross-linking reactions and/or protein insolubilization. Thus, although both crystallins underwent photocross-linking, significant turbidity production only occurred in gamma-crystallin. Some possible explanations for these differences are proposed, with one possibility being that most photocross-links in alpha-crystallin occur between subunits of the 1000-kDa oligomer, while in gamma-crystallin the cross-links occur between 20-kDa monomer units. Hence, cross-linking in alpha-crystallin does not affect the average size of particles in solution (or the turbidity), while cross-linking in gamma-crystallin results in a significant increase in average particle size with concomitant increase in turbidity. Another possible explanation is that UV-irradiated gamma-crystallin becomes insoluble (due to charge changes resulting in non-covalent aggregation) while alpha-crystallin does not. Other differences in the photochemical behavior of alpha- vs. gamma-crystallin were noted--gamma-crystallin photolysis rate was about 50% greater than alpha-crystallin. Alpha-crystallin photolysis yielded strong NFK-like fluorescence, while gamma-crystallin did not. One similarity was that photolyzed alpha- and gamma-crystallin lost amino acids His and Trp at about the same rate.(ABSTRACT TRUNCATED AT 250 WORDS)

The anaerobic photolysis of lens alpha-crystallin: evidence for triplet state mediated photodamage

Anaerobic solutions of lens alpha-crystallin were subjected to near-UV (greater than 295 nm) irradiation, and the photoproducts were analyzed by fluorescence and room-temperature phosphorescence spectroscopy. The principal photoproduct was excited maximally at 340 nm, fluoresced maximally at 430 nm, and phosphoresced with an emission maximum at 510 nm. The phosphorescence intensity decay of this species was well fit by a sum of two exponentials with lifetimes of 9.2 ms (78%) and 61 ms (22%); this report is the first demonstration of a long-lived triplet state associated with a protein photolysis product. As reported previously, 3trp* is also long-lived in deoxygenated alpha-crystallin solution at room-temperature (Berger and Vanderkooi, 1989, Biochemistry 28, 5501-5508), hence both tryptophan and photoproduct triplet states are good candidates to mediate photodamage. Photolysis experiments in the presence of agents known to alter the tryptophan triplet yield provide evidence for the importance of triplet-state-mediated photodamage of lens crystallins in anaerobic solution. In 30 mM acrylamide where 3trp*, but not 1trp*, is efficiently quenched, anaerobic solutions exhibited marked resistance to protein photodamage, whereas the photoprotection in aerobic solution was minimal. In D2O, where photoionization is suppressed but triplet states are longer-lived, photodamage was accelerated in anaerobic solution but reduced in aerobic solutions. Finally, the anaerobic photodestruction rate was increased in 500 mM Cs+ solution where the triplet yield is increased by a heavy atom effect.

The conformational status of a protein influences the aerobic photolysis of its tryptophan residues: melittin, beta-lactoglobulin and the crystallins

We have studied the aerobic photolysis of the tryptophan residues of the proteins melittin and beta-lactoglobulin when the proteins are in ordered conformations and when they are in randomly coiled states. The results suggest that the conformational status of the protein is a factor that influences the photolysis of the constituent tryptophan residues. This point appears to be of relevance to the photo-oxidation of the tryptophan residues of the eye lens proteins crystallins.

Conformational changes of beta H-crystallin in riboflavin-sensitized photooxidation

The effect of riboflavin-sensitized photooxidation on calf lens beta H-crystallin has been investigated by using fluorescence and circular dichroism techniques. beta H-Crystallin showed a pronounced change in its tertiary structure (conformation) as manifested in the near-u.v. circular dichroism spectra and fluorescence yield of tryptophan residues. The rate of tryptophan photolysis was significantly diminished under anaerobic conditions, but was not affected appreciably when D2O was used in the reaction mixture instead of H2O. Ferricyanide and ferricytochrome c added to the solution prior to irradiation inhibited the rate of photolysis of tryptophan, suggesting the involvement of O2- anion in the photoreactions. Quantitative assays of O2- and H2O2 in the irradiated protein solution strongly suggest that the Type I photosensitization pathway is involved in the RF-sensitized photooxidation of beta H-crystallin. The effect of photolysis on the cysteine residues of the protein was also studied. The sulfhydryl specific fluorophore N-iodoacetyl-N'-(5-sulfonaphthyl) ethylenediamine (1,5-IAEDANS) was used to study the change in the microenvironment of the cysteine (sulfhydryl) residues of the protein by photolysis. The results indicate that there is a quantitative loss of IAEDANS labeling sites due to photooxidation as well as structural changes of the protein. Fluorescence lifetime measurements indicate that the probe is bound in two environments--the major one (95%) is exposed and the minor one (5%) hydrophobic. A decrease in the lifetimes of the bound label occurs after photooxidation. However, the relative proportion of the hydrophobic IAEDANS-labeling sites increases in the photooxidized beta H-crystallin, probably due to the formation of supra-aggregated protein by photolysis.