J S Zigler

The effects of "oxygen radicals" generated in the medium on lenses in organ culture: inhibition of damage by chelated iron.

Rat lenses in organ culture were exposed to activated species of oxygen generated in the culture medium either by xanthine oxidase and hypoxanthine or by riboflavin and visible light, two systems which have been shown to produce superoxide and H2O2. In each case there was marked damage to carrier-mediated transport systems of the lens. Under standard culture conditions this damage was strongly inhibited by catalase, but not by superoxide dismutase (SOD). By the addition to the medium of chelated iron, hydroxyl radicals were produced in a Fenton reaction with a concomitant decrease in H2O2 levels. With both oxygen radical-generating systems, the addition of chelated iron strongly inhibited lens damage. This inhibitory effect could be reversed by the addition of SOD with the chelated iron. Under such conditions SOD converts superoxide anion to H2O2, thereby preventing reduction of the chelated iron and thus stopping the generation of hydroxyl radicals. Increased lens damage following addition of SOD to the iron-containing systems correlated with higher H2O2 concentrations, and was inhibited by catalase. These findings suggest that, when generated in the fluids surrounding the lens, H2O2 poses a much greater oxidative stress for the lens than do the superoxide or hydroxyl free radicals.

Impaired cytoskeletal organization and membrane integrity in lens fibers of a Rho GTPase functional knockout transgenic mouse.

To investigate the effects of Rho GTPase inactivation on lens fiber cell cytoskeletal and morphological integrity, a transgenic mouse model expressing C3-exoenzyme (a bacterial toxin) in a lens-specific manner was utilized. Cryosections of whole eyes from C3 transgenic mice and littermate controls were stained for F-actin with rhodamine–phalloidin or immunostained for β-catenin, aquaporin-0 or connexin-50, and confocal images were recorded. Lens fiber cell morphology was examined at both light and electron microscopic levels. To investigate the influence of Rho GTPase inactivation on the profiles of gene expression, cDNA libraries generated from transgenic and littermate control mouse lenses were screened by cDNA microarray analysis. In contrast to the wild-type lens, fiber cells of the transgenic lens were grossly swollen and disorganized, with abnormal membrane architecture. Staining of F-actin, β-catenin, aquaporin-0 and connexin-50 was reduced dramatically in the C3 transgenic lens as compared to controls. Western blot analysis and cDNA microarray analysis did not reveal any noticeable decreases in actin, β-catenin and aquaporin-0 protein levels or expression in C3 transgenic lenses, indicating that altered cytoskeletal organization in response to Rho GTPase inactivation might underlie the noted changes in staining for these proteins. Additionally, cDNA microarray analysis of C3 lens revealed altered expression (at least two-fold, compared to littermate controls) of 44 genes. These include genes encoding extracellular matrix and basement membrane proteins, cell survival and apoptotic pathways, and ion and protein transport. These data indicate that disruption of Rho GTPase function in the developing mouse lens results in abnormal cytoskeletal organization, fiber cell interactions, impaired lens fiber cell morphology and altered gene expression of cellular proteins involved in diverse functions. This work reveals that the morphological and cytoskeletal abnormalities triggered upon Rho GTPase inactivation in lens could be one of the important insults associated with cataract formation in C3 transgenic mouse lens.

Enzyme/crystallins and extremely high pyridine nucleotide levels in the eye lens.

Taxon‐specific crystalling are proteins present in high abundance in the lens of phylogenetically restricted groups of animals. Recently it has been found that these proteins are actually enzymes which the lens has apparently adopted to serve as structural proteins. Most of these proteins have been shown to be identical to, or related to, oxidoreductases. In guinea pig lens, which contains zeta‐crystallin, a protein with an NADPH‐dependent oxidoreductase activity, the levels of both NADPH and NADP+ are extremely high and correlate with the concentration of zeta‐crystallin. We report here nucleotide assays on lenses from vertebrates containing other enzyme/crystallins. In each case where the enzyme/crystallin is a pyridine nucleotide‐binding protein the level of that particular nucleotide is extremely high in the lens. The presence of an enzyme/crystallin does not affect the lenticular concentrations of those nucleotides which are not specifically bound. The possibility that nucleotide binding may be a factor in the selection of some enzymes to serve as enzyme/crystallins is considered.—Zigler, J. S., Jr.; Rao, P. V. Enzyme/crystallins and extremely high pyridine nucleotide levels in the eye lens. FASEB J. 5: 223–225; 1991.

Carbonyl-Metabolizing Enzymes and Their Relatives Recruited as Structural Proteins in the Eye Lens

The refractive properties of the eye lens are determined by abundant soluble structural proteins known as crystallins. While some crystallins are common to most vertebrates, others are abundant only in groups of related species. These taxon-specific crystallins all turn out to be enzymes, apparently recruited by modification of gene expression without prior gene duplication. They include eta-crystallin, accounting for up to 25% of protein in elephant shrew lenses and apparently identical to cytoplasmic aldehyde dehydrogenase; rho-crystallin from frog lenses, a member of the same superfamily as aldose and aldehyde reductases; and zeta-crystallin, found in guinea pig and camel lenses, which is structurally related to alcohol dehydrogenase (ADH). Unlike ADH, zeta-crystallin requires NADPH rather than NAD+/NADH as cofactor. Molecular modelling of zeta-crystallin shows that amino-acid changes around the co-factor binding site are responsible for this change in affinity. Purified guinea pig lens zeta-crystallin has a substrate preference for orthoquinones which are reduced by a single electron transfer mechanism. cDNA sequencing of zeta-crystallin suggests that the expression in lens as a crystallin depends on a different gene promoter from that used predominantly in liver. The putative guinea pig zeta-crystallin lens promoter has now been assayed for function in transfection studies. Elements with positive and negative effects on transcription, at least one of which has tissue preferred function, have been defined. When introduced into transgenic mice this promoter exhibits tissue-specific expression in the lens. This is the first identification of a lens-specific, alternative promoter in an enzyme crystallin gene.