Indoleamine 2,3-dioxygenase overexpression causes kynurenine-modification of proteins, fiber cell apoptosis and cataract formation in the mouse lens.

Indoleamine 2,3-dioxygenase (IDO) is the first enzyme in the kynurenine pathway. The kynurenines formed in this pathway chemically modify proteins and cause apoptosis in cells. Evidence suggests that kynurenines and their protein modifications are involved in cataract formation, but this has yet to be directly demonstrated. We generated transgenic (Tg) mouse lines that overexpress human IDO in the lens. Homozygous Tg (homTg) lenses had higher IDO immunoreactivity, approximately 4.5 times greater IDO mRNA, and approximately 8 times higher IDO activity compared to lenses from hemizygous Tg (hemTg) animals. The kynurenine content was threefold higher in homTg than in hemTg but was not detected in wild-type (Wt) lenses. Kynurenine modifications were approximately 2.6 times greater in homTg than in hemTg or Wt. HomTg lenses had vacuoles in the epithelium and cortical fiber cells. Kynurenine modifications coincided with apoptosis in the secondary fiber cells of homTg lenses. Caspase-3 and caspase-9 activities were markedly higher in homTg than in hemTg and Wt. The glutathione content was approximately 36% lower in homTg compared to hemTg and Wt lenses. HomTg animals also developed bilateral cataracts within 3 months of birth. Together these data demonstrate that IDO-mediated production of kynurenines results in defects in fiber cell differentiation and their apoptosis and suggest that IDO activity is kept low in the lens to prevent deleterious effects by kynurenines.

Upregulation of glyoxalase I fails to normalize methylglyoxal levels: a possible mechanism for biochemical changes in diabetic mouse lenses.

Glyoxalase I is the first enzyme in a two-enzyme glyoxalase system that metabolizes physiological methylglyoxal (MGO). MGO reacts with proteins to form irreversible adducts that may lead to crosslinking and aggregation of lens proteins in diabetes. This study examined the effect of hyperglycemia on glyoxalase I activity and its mRNA content in mouse lens epithelial cells (mLE cells) and in diabetic mouse lenses and investigated the relationship between GSH and MGO in organ cultured lenses. mLE cells cultured with 25 mM D-glucose (high glucose) showed an upregulation of glyoxalase I activity and a higher content of glyoxalase I mRNA when compared with either cells cultured with 5 mM glucose (control) or with 20 mM L-glucose + 5 mM D-glucose. MGO concentration was significantly elevated in cells cultured with high D-glucose, but not in L-glucose. GSH levels were lower in cells incubated with high glucose compared to control cells. Glyoxalase I activity and mRNA levels were elevated in diabetic lenses compared to non-diabetic control mouse lenses. MGO levels in diabetic lenses were higher than in control lenses. Incubation of lenses with buthionine sulfoximine (BSO) resulted in a dramatic decline in GSH but the MGO levels were similar to lenses incubated without BSO. Our data suggest that in mouse lenses MGO accumulation may occur independent of GSH concentration and in diabetes there is an upregulation of glyoxalase I, but this upregulation is inadequate to normalize MGO levels, which could lead to MGO retention and chemical modification of proteins.

3-hydroxykynurenine-mediated modification of human lens proteins: structure determination of a major modification using a monoclonal antibody.

Tryptophan can be oxidized in the eye lens by both enzymatic and non-enzymatic mechanisms. Oxidation products, such as kynurenines, react with proteins to form yellow-brown pigments and cause covalent cross-linking. We generated a monoclonal antibody against 3-hydroxykynurenine (3OHKYN)-modified keyhole limpet hemocyanin and characterized it using 3OHKYN-modified amino acids and proteins. This monoclonal antibody reacted with 3OHKYN-modified N(alpha)-acetyl lysine, N(alpha)-acetyl histidine, N(alpha)-acetyl arginine, and N(alpha)-acetyl cysteine. Among the several tryptophan oxidation products tested, 3OHKYN produced the highest concentration of antigen when reacted with human lens proteins. A major antigen from the reaction of 3OHKYN and N(alpha)-acetyl lysine was purified by reversed phase high pressure liquid chromatography, which was characterized by spectroscopy and identified as 2-amino-3-hydroxyl-alpha-((5S)-5-acetamino-5-carboxypentyl amino)-gamma-oxo-benzene butanoic acid. Enzyme-digested cataractous lens proteins displayed 3OHKYN-derived modifications. Immunohistochemistry revealed 3OHKYN modifications in proteins associated with the lens fiber cell plasma membrane. The low molecular products (<10,000 Da) isolated from normal lenses after reaction with glucosidase followed by incubation with proteins generated 3OHKYN-derived products. Human lens epithelial cells incubated with 3OHKYN showed intense immunoreactivity. We also investigated the effect of glycation on tryptophan oxidation and kynurenine-mediated modification of lens proteins. The results showed that glycation products failed to oxidize tryptophan or generate kynurenine modifications in proteins. Our studies indicate that 3OHKYN modifies lens proteins independent of glycation to form products that may contribute to protein aggregation and browning during cataract formation.