J. Samuel Zigler

A STUDY OF THE PHOTODYNAMIC EFFICIENCIES OF SOME EYE LENS CONSTITUENTS

We have studied the photochemical quantum yields of singlet oxygen production (using the RNO bleaching method) and superoxide production (using the EPR‐spin trapping method and the SOD‐inhibitable ferricytochrome c reduction spectral assay) of kynurenine (Ky), N‐formylkynurenine (NFK), 3‐hydroxykynurenine (3HK), kynurenic acid (KUA), and the flavins, riboflavin (RF) and flavin mononucleotide (FMN). Such a study of the photodynamic efficiencies is important since these compounds appear endogenously in the eye. The singlet oxygen quantum yields of the flavins and KUA are high, while Ky and 3HK generate no detectable amounts of singlet oxygen. The superoxide quantum yields of the sensitizers are low compared to their singlet oxygen, and Ky and 3HK produce no detectable amounts of superoxide. The production of the superoxide radical is enhanced in the presence of electron donor molecules such as EDTA and NADH. These results suggest that the production of oxyradicals in the lens may be modulated by the presence of endogenous electron donor molecules such as the coenzymes NADH and NADPH, which are present in significant amounts in some lenses. They also suggest that Ky and 3HK, which are known to be present in aged lenses, might play a protective rather than a deleterious role in the eye.

Immunocytochemical demonstration of retinal S-antigen in the pineal organ of four mammalian species

SummaryBy means of immunocytochemistry retinal S-antigen is selectively demonstrated in retinal photoreceptor cells of the rat and in pinealocytes of the hedgehog, rat, gerbil and cat. Brain areas surrounding the pineal organ are immunonegative. The immunoreactive material is evenly distributed in the perikarya of the cells. Occasionally, inner segments of retinal photoreceptors and processes of pinealocytes are also stained. The outer segments of retinal photoreceptors display a strong immunoreaction. In both pinealocytes and retinal photoreceptors the intensity of the immunoreaction varied considerably among individual cells.The immunocytochemical demonstration of retinal S-antigen in mammalian pinealocytes indicates that these cells still bear characteristics of photoreceptors. This finding is in accord with the concept that mammalian pinealocytes are derived from pineal photoreceptor cells of poikilothermic vertebrates.

PHOTOSENSITIZED OXIDATION IN THE OCULAR LENS: EVIDENCE FOR PHOTOSENSITIZERS ENDOGENOUS TO THE HUMAN LENS

Abstract— Numerous investigators have attempted to associate near UV light exposure with various changes which occur to lens crystallins during aging and cataractogenesis. Recently we have shown in vitro that singlet oxygen mediated oxidation of lens crystallins produces effects very similar to those documented for crystallins from old or cataractous lenses and suggested that near UV photodynamic effects may play a major role in vivo in aging in the human lens. In the present work we demonstrate that certain oxidation products of tryptophan which have been identified in human lens can act as near UV photosensitizers, producing singlet oxygen. The insoluble protein fraction from human cataracts is shown to have the capacity to act as a photosensitizer. An age‐related increase in photosensitizing capacity is also demonstrated in the soluble crystallins from human lens. These findings are discussed with respect to development of pigmented nuclear cataracts.

Evidence that α-crystallin prevents non-specific protein aggregation in the intact eye lens

Abstract The ocular lens is a transparent organ comprised of a highly concentrated and highly ordered matrix of structural proteins, called crystallins, which are probably the longest lived proteins of the body. Lens transparency is dependent upon maintenance of the short range order of the crystallin matrix. This transparency must be maintained for decades in the absence of normal protein synthesis or repair capacity. We present evidence here that α-crystallin, one of the major lens proteins, plays a central role in vivo in stabilizing the other crystallins and preventing uncontrolled aggregation of these progressively modified and aging molecules. α-Crystallin has previously been shown to suppress non-specific aggregation of denaturing proteins in simple binary systems through a chaperone-like activity. Our studies using soluble homogenates of monkey lenses demonstrate a strong resistance to heat induced non-specific aggregation when the complete complement of crystallins is present; in contrast, if α-crystallin is selectively removed prior to heating, the remaining crystallins undergo extensive non-specific aggregation as indicated by light scattering. When α-crystallin is present it complexes with denaturing proteins forming a soluble heavy molecular weight (HMW) fraction but no insolubilization is observed, while when α-crystallin is absent there is heavy insolubilization and no HMW formed. When intact monkey lenses were heated it could be demonstrated that soluble HMW was generated. Similar HMW protein appears in vivo in the human lens as a function of age. These findings suggest that the soluble HMW protein present in the human lens is the product of the chaperone-like function of α-crystallin and that under physiological conditions α-crystallin inhibits the uncontrolled aggregation of damaged proteins, thereby preventing the formation of light scattering centers and opacification of the lens.

Singlet oxygen as a possible factor in human senile nuclear cataract development

The effects of photodynamically generated singlet oxygen on lens crystallins were investigated. This highly reactive oxidant can produce in crystallins in vitro the oxidative modifications characteristic of proteins from aging and cataractous lens. Additionally species capable of producing singlet oxygen in the presence of near UV radiation are shown to be present in human lenses. These findings are discussed with respect to a possible role of singlet oxygen in the etiology of human senile nuclear cataracts.

Effects of lipid peroxidation products on the rat lens in organ culture: A possible mechanism of cataract initiation in retinal degenerative disease

Rat lenses in organ culture which are exposed to bovine rod outer segments (ROS) or to the major fatty acid of ROS, docosahexaenoic acid, are impaired in their ability to accumulate radiolabeled compounds which lenses normally accumulate by active processes. The extent of lens damage correlates well with the extent of lipid peroxidation in the culture medium as assessed by the thiobarbituric acid assay. Addition of vitamin E to the medium inhibits the effect on the lens while addition of Fe-ADP complexes potentiates the effect. Thus, the lens damage appears to be attributable to toxic species generated by peroxidation of the polyunsaturated lipid added to the culture medium. Toxic aldehyde products appear to be major mediators of the lens damage, since semi-carbazide, which avidly reacts with aldehydes, can protect lenses in this system. These findings may have relevance to the cataracts clinically associated with retinal degenerative diseases such as retinitis pigmentosa. The highly membranous photoreceptor cells are extremely rich in polyunsaturated lipid. Degeneration of these cells, which is the primary pathology in such diseases, would likely lead to peroxidation with generation of toxic products within the eye. Such products could potentially produce secondary damage to other ocular structures including the lens.

Structural changes in bovine lens crystallins induced by ascorbate, metal, and oxygen

Ascorbate, Fe3+, or Cu2+ and oxygen induced the oxidation of bovine lens crystallins. The modifications mimicked those that occur in the lens with aging. The modifications included the formation of nondisulfide crosslinks in alpha- and beta H-crystallin and the cleavage of alpha-, beta H-, and the low molecular weight crystallin fractions. In all three fractions, there was a loss of the more basic protein species and an increase in the more acidic species. Nontryptophan fluorescence with emission spectra between 400 and 500 nm was produced in beta H-crystallin. Cu2+ was less effective than Fe3+ in catalyzing the modification of beta H- and gamma-crystallin. Both metal ions were equally effective in catalyzing the modification of alpha-crystallin.

Oxidative modification of lens crystallins by H2O2 and chelated iron

Crystallins are the soluble structural proteins that constitute approximately 90% of the dry mass of the eye lens. The present study attempts to elucidate possible mechanisms whereby the H2O2 present in the eye could contribute to the oxidative modification of lens crystallins. The data indicate that exposure of solutions of crystallins to H2O2 and EDTA-chelated iron leads to covalent crosslinking of polypeptides, loss of intrinsic protein fluorescence, and the generation of a novel fluorophor emitting in the 420 nm range. These changes closely mimic oxidative modifications that occur in lens proteins in vivo. Exposure of the proteins to H2O2 in the absence of chelated iron failed to generate detectable levels of these modifications. These findings are contrasted with earlier studies of lenses in organ culture where H2O2 alone produced marked damage while the further addition of chelated iron protected the lenses from oxidation.

Aging of protein molecules: lens crystallins as a model system

Abstract As a result of the unique development and protein metabolism of the vertebrate lens this organ probably contains the bodys longest-lived proteins. The major structural proteins of the lens, the crystallins, offer unusual advantages for studying a wide variety of age-related structural modifications to proteins.

Clinical Detection of Precataractous Lens Protein Changes Using Dynamic Light Scattering

OBJECTIVE To use dynamic light scattering to clinically assess early precataractous lens protein changes. METHODS We performed a cross-sectional study in 380 eyes of 235 patients aged 7 to 86 years with Age-Related Eye Disease Study clinical nuclear lens opacity grades 0 to 3.8. A dynamic light-scattering device was used to assess alpha-crystallin, a molecular chaperone protein shown to bind other damaged lens proteins, preventing their aggregation. The outcome measure was the alpha-crystallin index, a measure of unbound alpha-crystallin in each lens. The association of the alpha-crystallin index with increasing nuclear opacity and aging was determined. RESULTS There was a significant decrease in the alpha-crystallin index associated with increasing nuclear lens opacity grades (P < .001). There were significant losses of alpha-crystallin even in clinically clear lenses associated with aging (P < .001). The standard error of measurement was 3%. CONCLUSIONS Dynamic light scattering clinically detects alpha-crystallin protein loss even in clinically clear lenses. alpha-Crystallin index measurements may be useful in identifying patients at high risk for cataracts and as an outcome variable in clinical lens studies. CLINICAL RELEVANCE The alpha-crystallin index may be a useful measure of the protective alpha-crystallin molecular chaperone reserve present in a lens, analogous to creatinine clearance in estimating renal function reserve.