Catalase enrichment using recombinant adenovirus protects alphaTN4-1 cells from H(2)O(2).

Since oxidative stress has been implicated in the development of numerous diseases including cataract, this laboratory has created and investigated the stress response of murine immortal lens epithelial cell lines (alphaTN4-1) conditioned to withstand lethal peroxide concentrations. Two of a group of antioxidative defense (AOD) enzymes found in such cells to have markedly enhanced activity are catalase (CAT) and GSH S-transferase alpha2 (GST). In order to determine if enrichment of one or both of these AODs is sufficient to protect alphaTN4-1 cells from lethal H(2)O(2) levels, these cells were infected with adenovirus vectors capable of expressing these AODs at a high level. With this system, gene enrichment and increased enzyme activity were observed with both CAT and GST vectors. The percentage of cells infected ranged from about 50 to 90% depending on the multiplicity of infection (MOI). CAT but not GST protected the cells from H(2)O(2) stress. The CAT activity was increased from 15- to 150-fold and even at the lower levels protected the cells from H(2)O(2) concentrations as high as 200 microM or more (H(2)O(2) levels which rapidly kill non-enriched cells). Even when only about 50% of the cell population is infected as judged by GFP infection, the entire population appeared to be protected based on cell viability. The CAT enrichment appears to protect other intracellular defense systems such as GSH from being depleted in contrast to non-enriched cell populations where GSH is rapidly exhausted. The overall results suggest that enriching the cellular CAT gene level with an appropriate recombinant viral vector may be sufficient to protect in vivo systems from peroxide stress.

Peroxide resistance in human and mouse lens epithelial cell lines is related to long-term changes in cell biology and architecture.

It is well established that the response of the cell to environmental stress is a major basis for cell modification. Such modification is believed to adapt the cell to better survive its environment. Oxidative stress, a major and ubiquitous stressing factor, was selected for investigating the cellular response to stress. Most studies investigating such cellular response have employed examination of the cell either during or shortly after exposure to stress. We have employed a different approach arguing that the short-term response to stress obscures the biological changes that allow the cell to continue to thrive in its new environment. Reflecting this concept, murine and human cell lines capable of surviving regular exposure to toxic levels of H(2)O(2) or TBOOH have been developed. It was found that certain fundamental long-term changes in cell biology had occurred. The peroxide-resistant cells are diploid rather than aneuploid, show fundamental changes in the cytoskeletal cellular structure, suggesting less rigid more flexible cells, express a new lower molecular mass of p53, a key stress protein responder involved in adaptation, and finally have an immunochemical modification in alphaA-crystallin, a small heat-shock protein. Previously, it was found that there is a dramatic increase in catalase and gluthathione S-transferase activity and a remarkable limited change in expression in other antioxidative genes in these cells. The impact of these changes is discussed. It is apparent that evolutionary cell modifications can occur in response to relatively rapid changes in environment over periods ranging from days to months rather than the thousands of years considered in most evolutionary modifications.

Comparison of characteristics of peroxide-conditioned immortal human lens-epithelial cell lines with their murine counterparts.

Previously, this laboratory has reported the characteristics of murine immortal lens-epithelial cells (alphaTN4-1) conditioned to survive either H2O2 or tertiary butyl hydroperoxide (TBOOH) stress. This communication now describes similar observations upon human HLE-B3 cells. It was found that the human cells are more sensitive to peroxides than their murine counterpart. Similar to the murine cells, conditioning to TBOOH endows the HLE-B3 cells with resistance to H2O2 but unlike the murine cells, conditioning to H2O2 gives the human cells resistance to TBOOH. Furthermore, while withdrawal of TBOOH stress from TBOOH-conditioned alphaTN4-1 cells causes a loss of resistance to this peroxide but not H2O2, with human cells resistance to both peroxides is retained. Examination of the antioxidative defense (AOD) enzyme activities show an extraordinary increase in catalase activity and significant augmentation of most other enzymes assayed in all conditioned human cell lines. In contrast, it was previously found that only catalase and glutathione-S-transferase have considerable increases in activity in the murine lines. However, in most cases, the AOD enzyme activity in murine-control cells is about 2-fold higher than in human control cells. The gene expression of human TBOOH-conditioned (Thum) and control (Chum) lines were also examined utilizing microarray analysis. Surprisingly, no significant change in gene expression was found for any of the prominent AOD enzymes. Such results differ from the response of murine cells where many AOD enzymes have increased expression. These observations suggest while the same AOD enzymes may be utilized in both murine and human lens-epithelial cells, the levels at which they are maintained and the manner in which they are recruited in response to stress may differ.

Mice lacking catalase develop normally but show differential sensitivity to oxidant tissue injury.

Catalase plays a major role in cellular antioxidant defense by decomposing hydrogen peroxide, thereby preventing the generation of hydroxyl radical by the Fenton reaction. The degree of catalase deficiency in acatalasemic and hypocatalasemic mice varies from tissue to tissue. They therefore may not be suitable for studying the function of this enzyme in certain models of oxidant-mediated tissue injury. We sought to generate a new line of catalase null mice by the gene targeting technique. The mouse catalase (Cat or Cas1) gene was disrupted by replacing parts of intron 4 and exon 5 with a neomycin resistance cassette. Homozygous Cat knockout mice, which are completely deficient in catalase expression, develop normally and show no gross abnormalities. Slices of liver and lung and lenses from the knockout mice exhibited a retarded rate in decomposing extracellular hydrogen peroxide compared with those of wild-type mice. However, mice deficient in catalase were not more vulnerable to hyperoxia-induced lung injury; nor did their lenses show any increased susceptibility to oxidative stress generated by photochemical reaction, suggesting that the antioxidant function of catalase in these two models of oxidant injury is negligible. Further studies showed that cortical injury from physical impact caused a significant decrease in NAD-linked electron transfer activities and energy coupling capacities in brain mitochondria of Cat knockout mice but not wild-type mice. The observed decrease in efficiency of mitochondrial respiration may be a direct result of an increase in mitochondrion-associated calcium, which is secondary to the increased oxidative stress. These studies suggest that the role of catalase in antioxidant defense is dependent on the type of tissue and the model of oxidant-mediated tissue injury.

The effect of stress withdrawal on gene expression and certain biochemical and cell biological properties of peroxide-conditioned cell lines.

Maturity onset cataract is a disease that afflicts >25% of the U.S. population over 65. Oxidative stress is believed to be a major factor in the development of this disease and peroxides are suspected to be prominent stressing agents. To elucidate mechanisms involved in the protection of cells against oxidative stress, immortal murine lens epithelial cells (alphaTN4-1) have been conditioned to survive lethal concentrations of either tertiary butyl hydroperoxide, TBOOH (a lipid peroxide prototype) (T cells), or H2O2 (H cells). It was found that T cells survived exposure to H2O2 but H cells were killed by TBOOH. In this communication, biological characteristics of the T cells are reported. It is shown that the T cell's ability to survive TBOOH is lost if the cells are grown in the absence of this peroxide (denoted as T- cells). By comparing the differential gene expression of 12,422 genes and ESTs from T and T- and the unconditioned control cells, 16 genes were found that may account for the loss of resistance to TBOOH. They include 5 glutathione-S-transferases, superoxide dismutase 1, zeta crystallin, a NADPH quinone reductase, as well as genes involved in detoxifying aldehydes, controlling iron metabolism, and degrading toxic lipoproteins.

Oxygen tension in the rabbit lens and vitreous before and after vitrectomy.

Oxygen is believed to be one of the potential causative agents for the development of nuclear cataract following vitrectomy. The aim of this study was to determine the partial pressure of oxygen (pO2) in different compartments of the rabbit eye, and to describe the changes following vitrectomy. Twenty-six rabbits (3.5-5.3 kg) were anesthetized and oxygen tension was probed using a fiber-optic oxygen sensor system (optode). A micromanipulator was employed to ascertain the exact position of the probe within the eye. Measurements were taken pre- and post-vitrectomy at several defined positions within the vitreous, the lens and the anterior chamber. Follow-up measurements were performed 2 and 8 weeks after vitrectomy. The contralateral eye served as a control. Measurements in the normal rabbit eye showed that oxygen tension in the globe is asymmetrical with the lowest pO2 in the nucleus of the lens (10.4 mmHg+/-3.0). The region of the lens near the posterior capsule has an oxygen tension close to the values of the vitreous directly behind the posterior capsule (12.4 mmHg+/-3.1). The highest pO2 within the posterior compartment of the eye was measured close to the retinal surface (40-l60 mmHg) depending on neighboring large vessels. The tension drops off rapidly to 20 mmHg some 0.5 mm from the retina. From that position to the posterior surface of the lens there is a shallow gradient of decreasing pO2. Immediately following vitrectomy the pO2 in the BSS replacement varied from ca. 90-140 mmHg, and decreased over approximately 30 min. to levels that were 2-3 times that of normal vitreous. Two weeks after vitrectomy the pO2 values in the lens were 2-3 times as high as in the control eye (p < 0.05). In addition there is no longer a gradient in the vitreous cavity, except close to the retina. Eight weeks after vitrectomy, pO2 levels in the lens were decreased but still remained higher than in the normal eye (13.83 mmHg+/-0.02). The pO2 gradient in the vitreous was not detectable anymore. Overall the results provide evidence that oxygen levels in the lens increase significantly after vitrectomy in rabbits. If this occurs in humans it may contribute to cataract formation following surgery.

Characteristics of tertiary butyl hydroperoxide and hydrogen peroxide conditioned cells withdrawn from peroxide stress.

This laboratory has recently reported the preparation of immortal lens epithelial cell lines conditioned to survive in concentrations of peroxide sufficient to cause cataract with in vitro lens culture conditions. The cell conditioning process takes many months during which time the peroxide concentration is gradually increased. It was found that while the acquired resistance to H2O2 was permanent, if tertiary butyl hydroperoxide (TBOOH) was used the resistance was lost within 6-8 weeks of the withdrawal of the peroxide. We now report that resistance is lost within a few days but can be regained within 48 hr. Furthermore, cells resistant to H2O2 while vulnerable to TBOOH could also be rapidly conditioned to tolerate TBOOH in a manner similar to the reconditioning of cells that had lost their TBOOH resistance. The results suggest that a history of exposure to certain oxidative stresses produces a change in cell biology which allows the cell to rapidly respond to the same or other stresses and survive.

Cluster analysis of genes with significant change in expression in cells conditioned to survive TBOOH.

Immortal murine lens epithelial cells, alphaTN4-1 have been conditioned to survive H2O2, H cells, or TBOOH, T cells, at concentrations that will cause cataract in vitro. Since H cells are killed by TBOOH but T cells survive H2O2, it is of interest to examine the gene expression of these cell lines. We now report the results of cluster analysis of genes whose expression is significantly changed by TBOOH. The analysis has revealed a small group of antioxidative defense genes that contribute to the survival of T and H cells when exposed to oxidative stress.

Matrix metalloproteinases are down-regulated in rat lenses exposed to oxidative stress.

Matrix metalloproteinases are important biological effectors of tissue remodelling. Increased MMP expression occurs during injury, inflammation, cellular transformation, and oxidative stress. Oxidative stress in the lens, a causal factor in cataractogenesis, has been shown to induce MMP secretion. The objective of this study was to assess the expression of MMPs and their regulators in an oxidative stress model of cataract, where epithelial cell death and cortical fibre cell swelling occurs in rat lenses after exposure to riboflavin, oxygen, and light. Two time points (4 and 7 hr of exposure) were chosen in order to compare transparent lenses with partially opaque lenses. MMP activity, protein, and mRNA levels were measured. The results show that MMP-2, MMP-9, MT1-MMP, and MT3-MMP are down-regulated by oxidative stress and that the down-regulation is most likely due to reduced gene transcription. In contrast, genes for catalase, glutathione peroxidase, and GAPDH are essentially unaffected, while beta-actin mRNA and protein levels are markedly increased at both time points. The down-regulation of MMPs occurs in lenses still seemingly transparent after 4 hr of exposure, indicating that reduced MMP activity is a relatively early response to the oxidative stress. Moreover, in our model system, MMP inhibition, not induction, is associated with cataractogenesis.

DeltaFosB expression and cataract.

DeltaFosB is a truncated form of a FosB transcription factor, which is created by alternative splicing. Previous work has shown that transgenic mice expressing DeltaFosB both in the retina and in the lens developed a posterior subcapsular cataract resulting from the misalignment of the fibres in the suture region. In the previous study, it was not clear whether DeltaFosB expression was required in both tissues to produce the cataract. Therefore, DeltaFosB expression targeted to either the lens or the retina was undertaken in order to clarify the contribution of each tissue to cataract development. For lens expression, the R2betaB1DeltaFosB construct was synthesized (R2, an enhancer; betaB1, a chicken betaB1 crystallin gene promoter fragment). For the retina, RhoDeltaFosB was prepared. As a promoter, the bovine rhodopsin upstream region was used. DeltaFosB expression in heterozygote animals was monitored by Western blotting. Cataract development in heterozygotes of R2betaB1DeltaFosB transgenics and in both heterozygotes and homozygotes of RhoDeltaFosB transgenics was followed by slitlamp examination. The transgenic mice prepared with RhoDeltaFosB expressed DeltaFosB only in the retina and showed no sign of lens opacity. One line of the R2betaB1DeltaFosB transgenic was found to have expression only in the lens and developed posterior subcapsular cataract. We concluded that retinal expression of DeltaFosB is not sufficient to cause cataract while expression exclusively in the lens produces posterior subcapsular cataract.

Peroxide toxicity in conditioned lens epithelial cells--evaluation of multi-defense systems.

Immortal murine lens epithelial cells which were conditioned to survive peroxide stress were found to have a remarkable increase in catalase activity as well as lesser changes in a number of other antioxidative defense systems [Invest. Ophthalmol. Vis. Sci. 43 (2002) 3251]. Furthermore, the gene expression of hundreds of other genes was altered. In order to determine the relative importance of catalase, other enzyme systems which maintain the reducing environment of the cell and the involvement of Fenton chemistry, an analysis of the effect of inhibiting catalase, disruption of the cells' reducing environment by inhibition of GSSG reductase (GR) and chelation of metal ion was investigated. It was found that inhibition of catalase caused peroxide resistant cells to die within 48-72 hr when exposed to normally tolerated concentrations of peroxide. If 1,10-phenanthroline (OP), an effective metal ion chelator was present, the cells were not affected by catalase inhibition and survived peroxide stress. Peroxide vulnerable unconditioned control cells were similarly protected by the chelator. The results demonstrate that H2O2 itself has minimal toxicity and that it is the products resulting from interaction with metal ion that produces lethal toxicity. In stark contrast, however, metal chelation did not protect the cells when GR was inhibited by BCNU. Examination of non-protein thiol (NP-SH), which is primarily GSH, indicated that rapid and extensive oxidation occurred almost immediately after exposure to peroxide under all conditions. However, NP-SH returns to the normal range in the conditioned cells even though later cell death is observed in some cases, suggesting fatal damage during the period when the cell is exposed to an oxidizing environment. Examination of DNA damage by alkaline elution indicated that H2O2 caused little observed strand breakage in peroxide resistant cells even if catalase is inhibited, suggesting that such cells have developed other systems to protect DNA and that H2O2 induced death is probably not related to DNA single strand breaks. In contrast, unconditioned cells (C cells) show extensive H2O2 induced DNA damage which is prevented by OP. Thus, depending on the conditions, DNA damage may contribute to cell death. The overall results indicate that the conditioned cell lines are not simply dependent on catalase activity but have developed a complex defense which includes GSH dependent systems and possibly more effective regulation of metal ion concentrations to resist oxidative stress.

The effect of H2O2 and tertiary butyl hydroperoxide upon a murine immortal lens epithelial cell line, alphaTN4-1.

The effect of comparable concentrations of H(2)O(2) and tertiary butyl hydroperoxide (TBHP) upon an immortal murine lens epithelial cell line was examined as part of an ongoing effort to delineate differences in the mechanism by which these peroxides cause cell death. Both compounds result in cell death of normal, unconditioned cells within 24hr. It was found that with similar conditions, TBHP conditioned alphaTN4-1 cells survive H(2)O(2) stress while H(2)O(2) conditioned cells are killed by TBHP. To better understand how these peroxides act, their effect upon unconditioned cells has been investigated. Both peroxides cause a rapid loss of GSH and disruption of pump activity as illustrated by (14)C-choline transport and (86)Rb uptake. While H(2)O(2) exposure resulted in extensive DNA damage, TBHP had a minimal effect. DNA damage caused by H(2)O(2) was shown to activate polyADP-ribosyl polymerase (PARP), leading to depletion of NAD and ATP. H(2)O(2) induced cell death could be delayed by addition of 3-aminobenzamide (3AB), an inhibitor of PARP. ATP levels in cells subjected to H(2)O(2) were also maintained by the presence of 3AB. H(2)O(2) stress also disrupted glycolysis and mitochondrial activity but these parameters were not affected by TBHP. TBHP induced cell death, under the relatively mild conditions used in this work, appears to be caused by membrane disruption and loss of a reducing environment.

Differential amplification of gene expression in lens cell lines conditioned to survive peroxide stress.

PURPOSE: The response of lens systems to oxidative stress is confusing. Antioxidative defense systems are not mobilized as expected, and unanticipated defenses appear important. Therefore, mouse lens cell lines conditioned to survive different peroxide stresses have been analyzed to determine their global changes in gene expression. METHODS: The immortal mouse lens epithelial cell line alphaTN4-1 was conditioned to survive 125 microM H2O2 (H cells) or a combination of both 100 microM tertiary butyl hydroperoxide (TBHP) and 125 microM H2O2 (HT cells), by a methodology previously described. The total RNA was isolated from the different cell lines and analyzed with oligonucleotide mouse expression microarrays. Four microarrays were used for each cell line. Microarray results were confirmed by real-time RT-PCR. RESULTS: A new cell line resistant to both 125 microM H2O2 and 100 micro M TBHP was developed, because cells resistant to H2O2 were killed by TBHP. Analysis of classic antioxidative enzyme activities showed little change between cells that survive H2O2 (H) and those that survive H2O2 and TBHP (HT). Therefore, the global change in gene expression in these cell lines was determined with gene expression microarrays. The fluorescent signal changes of the genes within the three cell lines, H, HT, and control (C), were analyzed by statistical methods including Tukey analysis. It was found that from the 12,422 gene fragments and expressed sequence tags (ESTs) analyzed--based on a one-way ANOVA with a stringent cutoff of one false positive per 1000 genes and correcting for microarray background and noise--approximately 950 (7.6%) genes had a significant change in expression in comparing the C, H, and HT groups. A small group of antioxidative defense genes were found in this population, including catalase, members of the glutathione (GSH)-S-transferase family, NAD(P)H menadione oxidoreductase 1, and the ferritin light chain. The remaining genes are involved in a broad spectrum of other biological systems. In the HT versus H comparison, only a few genes were found that had increased expression in the HT line compared with expression in the H line, including GSH-S-transferase alpha 3 and hephaestin. Many genes that are frequently considered antioxidative defense genes, including most of the GSH peroxidases, unexpectedly showed little change. CONCLUSIONS: An unusual and generally unexpected small group of antioxidative defense genes appear to have increased expression in response to H2O2 stress. Cell lines resistant to H2O2 do not appear to survive challenge with another type of peroxide, TBHP, a lipid peroxide prototype. However, acquisition of TBHP resistance by H cells was found to be accompanied by significantly amplified expression of only a few additional antioxidative defense genes. Many of the amplified genes do not appear to be involved with antioxidative systems, reflecting the complexity of the cells' response to oxidative stress.