Regulation of thioltransferase expression in human lens epithelial cells.

PURPOSE: To study how the expression of thioltransferase (TTase), a critical thiol repair and dethiolating enzyme, is regulated in human lens epithelial cells under oxidative stress. Also to examine whether depleting the primary cellular antioxidant glutathione (GSH) in these cells has any influence on TTase expression under the same conditions. METHODS: Human lens epithelial cells (B3) were grown to confluence (1.6 million) and gradually weaned from serum in the medium before exposing to 0.1 mM H2O2 for 2 hours. Cells were removed at the time intervals of 0, 5, 10, 15, 30, 60, and 120 minutes for protein measurements of GSH and TTase activity and for reverse transcription-polymerase chain reaction (RT-PCR) or Northern hybridization analysis to quantify TTase mRNA. The effect of GSH depletion on TTase mRNA expression was examined by treating the cells with buthionine S,R-sulfoximine (BSO); 1-chloro, 2,4-dinitrobenzene (CDNB); or 1,3-bis (2-chloroethyl)-1-nitrosourea (BCNU). Lens epithelial cells, depleted of cellular GSH by treatment with BCNU, were subjected to oxidative stress to examine the effect on TTase activity and mRNA level. RESULTS: A transient increase was detected in TTase mRNA after 5 minutes of H2O2 treatment. The upregulation reached a maximum of 80% above the normal level by 10 minutes and gradually decreased as the oxidant was detoxified by the cells. Manipulation of cellular GSH level by treatment with BSO, CDNB, and BCNU resulted in a minimum change in TTase expression. It is noteworthy that when cells depleted of GSH were subjected to oxidative stress, TTase expression was also found to be strongly upregulated. CONCLUSIONS: These observations suggest that the upregulation of TTase expression in the lens epithelial cells could be an adaptive response of the cells to combat oxidative stress to restore the vital functions of the lens proteins and enzymes. Such regulation is independent of cellular GSH concentration.

Human lens thioltransferase: cloning, purification, and function.

PURPOSE: To clone the human lens thioltransferase (TTase) gene and to purify, characterize and study the possible function of the recombinant human lens thioltransferase (RHLT). METHODS: The human lens TTase gene was cloned by using RT-PCR and verified by sequence and RNase protection assay. TTase overexpressed in Escherichia coli was isolated and purified to homogeneity by column chromatography and identified by Western blot analysis. The activity was assayed with a synthetic substrate hydroxyethyl disulfide. Its function in dethiolating and reactivating other key metabolic enzymes was studied by using pure glutathione S:-transferase (GST) and glutathione peroxidase (GPx) from commercial source and also with the cell extract of rabbit lens epithelial cells preexposed to H2O2. RESULTS: The cloned human lens TTase gene showed identical sequence to the TTase gene from other human tissues. The RNase protection assay displayed a single transcript from the total RNA of human lens epithelial cells. The purified RHLT had a molecular weight of 11.8 kDa and reacted positively with anti-pig liver TTase. It displayed similar structural, functional, and kinetic characteristics to those of TTases from other sources. It was shown that RHLT effectively regenerated the activities of GST and GPx, after each was inactivated by S-thiolation with cystine in vitro. Furthermore, RHLT was able to restore the activity of the oxidatively inactivated glyceraldehyde-3-phosphate dehydrogenase (G-3PD) in H2O2-exposed rabbit lens epithelial cells. CONCLUSIONS: The human lens TTase gene has been cloned for the first time. Its gene product showed the characteristics which support our speculation that TTase may play a major role in maintaining the homeostasis of lens protein thiols thus protecting against oxidative stress.

Does glutathione-S-transferase dethiolate lens protein-thiol mixed disulfides?-A comparative study with thioltransferase.

Protein S-thiolation is a process in which under oxidative stress, vulnerable sulfhydryl groups of proteins are conjugated to non-protein thiols such as glutathione (GSH) or cysteine resulting in the formation of protein-thiol mixed disulfides, protein-S-S-glutathione (PSSG) and protein-S-S-cysteine (PSSC). This process spontaneously disrupts the redox homeostasis of the cells, which in turn leads to functional disturbances in the respective tissue. In the ocular lens, such modification of proteins may trigger a cascade of events starting with the alteration of protein conformation, protein/enzyme deactivation, protein-S-S-protein aggregation and eventually lens opacification or cataract. Generally, the first line of defense system in the cells protects the lens proteins against such damage. Recent studies in our laboratory have shown that in addition to this defense system, lens cells also possess a well developed system to repair the oxidative damage to the lens proteins. We have identified this repair system as thioltransferase (TTase) and have proved that TTase by its dethiolase activity reverses the protein S-thiolation process which returns the oxidatively damaged lens proteins/enzymes to their original reduced state and restores their physiological functions. We investigated if this repair mechanism was mediated by enzymes other than TTase. We studied glutathione S-transferase (GST) and report here for the first time the cloning, high level expression, and purification of human lens mu and pi isoforms of GST. A comparative study of recombinant human lens TTase and GST (mu and pi) on their dethiolating abilities using lens crystallin-thiol mixed disulfides showed that the lens TTase is 60-70% more efficient in the dethiolation/repair process than GST. When TTase and GST were tested in conjunction for the dethiolation of thiol mixed disulfides, there was no significant enhancement of dethiolase activity. These findings suggest that TTase by itself is an efficient enzyme in the dethiolation/repair process and hence can be considered a crucial system to counteract oxidative stress in the lens.

Cloning, high level-expression and characterization of human lens thioltransferase.

Polymerase chain reaction (PCR) primers, directed against the nucleotide sequence of pig liver thioltransferase (PLTT) were used to amplify human lens thioltransferase (HLTT) from a pool of human lens cDNA. The 520 bp PCR fragment obtained was cloned unidirectionally into pCR 3.1-Uni vector and sequenced. The cDNA sequence of the lens thioltransferase had 98% and 87% homology to pig liver and human placental thioltransferases (TTase) respectively. Nhe1 and EcoR1 fragment of the recombinant PCR 3.1-Uni vector was subcloned in pET 23a Expression vector. High level expression of HLTT was accomplished in Escherichia coli and the expressed protein was characterized by immunoblot analysis with anti PLTT and N-terminal amino acid sequence analysis. The recombinant enzyme efficiently dethiolated protein thiol mixed disulfides conjugated to both cystine (PSSC) and glutathione (PSSG) and had a significant dehydroascorbate reductase activity. Human lens thioltransferase thus displayed structural and functional characteristics identical to pig liver and human placental thioltransferases.

Thioltransferase is present in the lens epithelial cells as a highly oxidative stress-resistant enzyme.

The redox homeostasis is controlled by several enzyme systems. Sulfhydryl groups in lens proteins are very sensitive to oxidative stress and can easily conjugate with nonprotein thiols (S-thiolation) to form protein-thiol mixed disulfides. We have observed an elevation of protein S-S-glutathione (PSSG) and protein-S-S-cysteine (PSSC) in cataractous lenses from humans and from animal models subjected to oxidative stress. We also observed that these protein-thiol mixed disulfides could be spontaneously dissociated and lowered to basal levels if the lens which was pre-exposed to H2O2 was subsequently cultured in H2O2-free medium. This suggests that the lens has a system to repair oxidative damage through dethiolation thereby restoring its redox homeostasis. In other tissues, an enzyme, thioltransferase (TTase), has been shown to be responsible for thiol/disulfide regulation. We recently demonstrated the presence of this enzyme in the lens and in cultured lens epithelial cells. Here, we investigated the response of TTase to H2O2 stress and its possible repair function in cultured lens epithelial cells. Rabbit lens epithelial cell line N/N 1003A was raised to confluence, trypsinized and plated at 0.8 million cells per 60 mm culture dish. The cells were incubated overnight in Eagle's minimum essential medium (MEM) with 1% rabbit serum and then in serum-free MEM for 30 min before a bolus of 0.5 mm H2O2 was added. At intervals of 5, 15, 30 min and up to 3 hr, the cells were harvested and used for enzyme assays for TTase, glutathione reductase (GR), glutathione peroxidase (GPx) and glyceraldehyde-3-phosphate dehydrogenase (G-3PD). Free GSH, total SH and PSSG and PSSC were also determined. Hydrogen peroxide in the medium was measured at each time point. Cells incubated without H2O2 were used as controls. The results showed that the H2O2 concentration was reduced to 50% within 30 min and was undetectable at 2 hr. Cellular GSH dropped to 40% within 5 min and stayed at this level before it began to increase at 90 min and completely recovered by 2 hr. The total SH groups were similar to free GSH. PSSG and PSSC increased 6.5 and 2 times respectively before 30 min and then decreased when GSH started to recover. G-3PD was most sensitive to H2O2 and lost 95% activity within 5 min. The activity was regained quickly when H2O2 diminished in the medium. A similar but less severe pattern was observed in both GPx (60% loss at 60 min) and GR (30% loss at 90 min). In contrast, TTase activity remained constant during the entire 3 hr. Only when a higher dose of H2O2 (0.8-1.0 mM) was used, did TTase activity show a brief loss (<30% at 60 min) and a swift recovery. Cells exposed to H2O2 exhibited a normal morphology with no evidence of DNA fragmentation. The lens epithelial cells showed a remarkable ability to repair the early damages induced by H2O2. The unusual oxidative stress-resistant property displayed by TTase, coupled with its known function suggest that it plays an important role in the repair of oxidative damage.

Distribution of thioltransferase (glutaredoxin) in ocular tissues.

PURPOSE: A new redox regulating enzyme, thioltransferase (TTase), has been found in the lens. The authors investigated whether TTase is also present in other ocular tissues. METHODS: Fresh enucleated bovine eyes were obtained from a local abattoir 4 hours after death. The eyes were processed immediately to remove corneal epithelial cells, conjunctiva, corneal endothelial cells, iris, ciliary body, lens epithelial cells, vitreous body, and retina. Other than conjunctiva and vitreous body, which were collected from a single eye, all other tissues were pooled from three bovine eyes. Each sample was homogenized in 0.1 M phosphate buffer, pH 7.4, and centrifuged at 10,000 g for 20 minutes, and the supernatant was assayed for TTase activity. Total RNA from each tissue sample was extracted and used for slot blot hybridization using cDNA from pig liver TTase with beta-actin as control. RESULTS: Among all the ocular tissues tested, iris showed the highest TTase activity (35 mU/mg protein) followed by conjunctiva, corneal epithelial cells, and corneal endothelial cells. Ciliary body, lens epithelial cells, and retina had moderate activity. No activity could be detected in vitreous body. The presence of this enzyme transcript in these ocular tissues was further confirmed by the positive slot blot hybridization with the pig liver TTase cDNA. Here again, iris showed the highest TTase mRNA expression, followed by ciliary body, lens epithelial cells, corneal endothelial cells, conjunctiva, retina, and corneal epithelial cells. The whole lens showed the lowest TTase mRNA expression, and no TTase mRNA was found in the vitreous body. CONCLUSIONS: TTase was found in most ocular tissues and was concentrated in the anterior segment of the eye. Highest activity was found in the iris, conjunctiva, corneal epithelial, and endothelial cells. TTase was absent in the vitreous body.

Relationship of protein-glutathione mixed disulfide and thioltransferase in H2O2-induced cataract in cultured pig lens.

It has been previously shown in H2O2-induced cataract model in the rat lens that protein-GSH (PSSG) formation precedes protein-protein disulfide (PSSP) conjugation and lens opacity. This elevated PSSG spontaneously reduces to a normal level when H2O2 is removed. To verify if thioltransferase (TTase), an enzyme that is known in other tissues to dethiolate PSSG, takes part in this recovery process, we examined the relationship of PSSG and TTase in this cataract model. To ensure enough tissue would be available for various biochemical studies, H2O2 induced cataract in pig lens was established and validated with the rat lens model. The study was divided into two parts. One part was to examine the effect of H2O2 concentration, ranging from 0.1 mM-10 mM, during 24 hr. Another part was to study the H2O2 (1.5 mM) induced cataract progression and recovery, parallel to the long-term study in rat lenses reported previously. These lenses were compared for transparency, wet weight, GSH, PSSG levels and the activity of two redox regulating enzymes, glutathione reductase (GR) and TTase. For the most part, pig lens responded to oxidation parallel to the rat lens except that a higher concentration of H2O2 was needed to achieve the same results. Damage induced by H2O3 was concentration dependent. In general TTase activity and GSH level were depleted with a concomitant increase in PSSG. The D50 (50% damage) for GSH in pig lens was 1.5 mM H2O2 (0.5 mM for rat lens) which was chosen for further studies in cataract progression and recovery. At 1.5 mM H2O2, pig lens showed superficial opacity within 24 hr and deeper cortical opacity in 48 hr. The pre-exposed lens became less cloudy when H2O3 was removed from the medium. Incubation of the lens in 1.5 mM H2O2 for one day also induced 50% GSH depletion and four fold PSSG elevations. This accumulated PSSG was dethiolated spontaneously in the absence of H2O2, similar to the findings in the rat lens and human lens models. In contrast protein-cysteine (PSSC) showed little change and did not respond to the recovery condition. TTase lost 50% activity in these lenses during 24-hr H2O3 exposure but regained most of it under recovery. The study on rat lens showed similar results as before, therefore only data on the relationship of TTase activity to PSSG level during cataract development and recovery is reported here. It was found that in the H2O2 (0.5 mM)-exposed rat lenses, the TTase activity was depleted but PSSG accumulation was accelerated within 8 hr. Both recovered quickly (within 8 hr) as soon as the oxidant was removed. Therefore, protein thiolation and dethiolation processes in the cultured rat or pig lenses display a mirror image with the activity pattern of TTase. Based on the close relationship between lens TTase and PSSG indicated above, it is speculated that TTase may regulate PSSG and maintain it at a low concentration in situ. This repair process may contribute to the improved transparency during recovery. Further studies are planned to substantiate this hypothesis.

Evidence for the presence of thioltransferase in the lens.

Thioltransferase (TTase) activity was identified and partially purified from the ocular tissue for the first time. The enzyme activity depended on the presence of reduced glutathione (GSH), glutathione reductase (GR) and NADPH to reduce the disulfide bond in a synthetic substrate, hydroxyl ethyl disulfide (HEDS). Maximum activity was obtained in a pH 7.4 phosphate buffer at 30 degrees C. This enzyme distinguishes from other reducing enzymes such as thioredoxin that do not require GSH and GR for their catalytic activity. It also differs from the 52 kDa enzyme, protein disulfide isomerase by its smaller molecular size and its stability against heat treatment. TTase activity was higher in the epithelial layer but distributed evenly in the rest of the lens also, TTase showed similar activity in the lenses obtained from rats, pigs, bovine, guinea pigs, chick embryos and humans. The molecular weight of this enzyme was estimated to be 11.5 kDa on a SDS-PAGE system. Western blot analysis showed the protein reacted positively to the antibody raised by the purified pig liver TTase. Similarly the antibody raised by the partially purified lens enzyme reacted positively with the purified pig lever TTase. The presence of TTase in the lens was confirmed further with the slot blot analysis where it demonstrated a 32P-labeled cDNA from pig liver TTase hybridizing with the RNA in the pig lens or rabbit lens epithelium cells. Based on the above information it was concluded that the lens TTase is comparable to TTase from other tissues in its functional and structural properties. It is hypothesized that the lens TTase has a significant physiological role in sulfhydryl homeostasis in the lens by protecting the SH groups of the proteins from S-thiolation. It is speculated that, lens TTase may be primary antioxidant in the lens along with GSH and GR by protecting the vulnerable lens proteins against oxidative damage.