Expression of active caspase 3 in the rat lens after in vivo exposure to subthreshold dose of UVR-B.

PURPOSES: The aim of this study is to investigate the time evolution of active caspase 3 within first 120 h in the rat lens after in vivo exposure to subthreshold dose of UVR-B. METHODS: Twenty three six-week-old female albino Sprague-Dawley rats were exposed to subthreshold dose (1 kJ/m2) of UVR-B unilaterally and sacrificed at 24, 41, 70 and 120 h after exposure. Lenses were enucleated and active caspase 3 was detected by Western Blot. The time evolution of active caspase 3 was then plotted as a function of relative mean difference in active caspase 3 between exposed and nonexposed lenses. RESULTS: There is expression of active caspase 3 in both exposed and nonexposed lenses but there is no difference in relative mean difference in active caspase 3 between exposed and nonexposed lenses in all four postexposure groups. CONCLUSIONS: Exposure to subthreshold dose of UVR-B does not induce apoptosis in the rat lens in vivo within first 120 h though there is a non-significant increase of active caspase 3 at 120 h. Increase in sample size might reduce the variation level in expression of active caspase 3 in the rat lenses.

Estimation of the Variance Components in TP53 mRNA Expression in the Rat Lens after in vivo Exposure to Ultraviolet Radiation B.

Introduction: The aim of this study was to investigate the variance components in TP53 mRNA expression after in vivo exposure to double threshold dose of ultraviolet radiation B (UVR-B). Methods: Twelve six-week-old female albino Sprague-Dawley rats were exposed to double threshold dose (8 kJ/m2) of UVR-B unilaterally and sacrificed at 1, 3, 8, and 24 h after exposure. Lenses were enucleated, and TP53 mRNA expression was detected by qRT-PCR. Variance components for groups, animals, and measurements were estimated with analysis of variance. Results: The variance for groups is 0.15 rel.2. The variance for animals is 0.29 rel.2. The variance for measurements is 0.32 rel.2. Conclusion: The variance for animals is in the same order as the variance for measurements. The reduction of the variance for measurements is needed in order to obtain the acceptable level of detection of the difference in TP53 mRNA expression and the reduction in sample size.

Exposure to subthreshold dose of UVR-B induces apoptosis in the lens epithelial cells and does not in the lens cortical fibre cells.

PURPOSE: The aim of this study was to investigate in which part of the lens in vivo exposure to subthreshold dose of UVR-B radiation induces apoptosis. METHODS: Twenty 6-week-old female albino Sprague-Dawley rats were exposed to subthreshold dose (1 kJ/m2 ) of UVR-B unilaterally and killed at 120 hr after exposure. Lenses were enucleated and dissected on three regions: the lens epithelium, the cortex and the nucleus. The lens nucleus then was removed. Apoptosis markers p53 and caspase 3 were used to study apoptosis in the lens regions. qRT-PCR and Western blot were utilized to analyse the lenses. RESULTS: TP53 and CASP3 mRNA expressions are increased in exposed lenses, both in the lens epithelium and in the cortex regions, in relation to non-exposed lenses. Expression of p53 protein is increased in exposed lens epithelium in relation to non-exposed lens epithelium. Caspase 3 protein is expressed in exposed lens epithelial cells, while it is not expressed in non-exposed lens epithelial cells. p53 and caspase 3 proteins are not expressed in either exposed nor non-exposed lens fibre cells. CONCLUSION: Exposure to UVR-B increases mRNA transcription of apoptosis marker p53 in vivo in both regions of the lens and of apoptosis marker caspase 3 in the lens cortex. Exposure to UVR-B increases p53 and caspase 3 proteins expression just in the lens epithelium. In vivo exposure to subthreshold dose of UVR-B induces apoptosis in the lens epithelial cells and does not in the lens fibre cells.

Cataract after repeated daily in vivo exposure to ultraviolet radiation.

Epidemiological data indicate a correlation between lifelong exposure to ultraviolet radiation and cortical cataract. However, there is no quantitative experimental data on the effect of daily repeated in vivo exposures of the eye to UVR. Therefore, this experiment was designed to verify whether the dose additivity for UVR exposures holds through periods of time up to 30 d. Eighty rats were conditioned to a rat restrainer 5 d prior to exposure. All animals were divided into four exposure period groups of 1, 3, 10, and 30 d of exposure to UVR. Each exposure period group of 20 animals was randomly divided into five cumulated UVR dose subgroups. Eighteen-wk-old non-anesthetized albino Sprague-Dawley rats were exposed daily to UVR-300 nm for 15 min. One week after the last exposure, animals were sacrificed. The lenses were extracted for macroscopic imaging of dark-field anatomy, and degree of cataract was quantified by measurement of the intensity of forward lens light scattering. Maximum tolerable dose (MTD(2.3:16)), a statistically defined standard for sensitivity for the threshold for UVR cataract, was estimated for each exposure period. Exposed lenses developed cataract with varying appearance on the anterior surface. Single low doses of UVR accumulated to cause cataract during periods up to 30 d. MTD(2.3:16) for 1, 3, 10, and 30 d of repeated exposures was estimated to 4.70, 4.74, 4.80, and 6.00 kJ m(-2), respectively. In conclusion, the lens sensitivity to UVR-B for 18-wk-old Sprague-Dawley rats decreases with the increasing number of days being exposed.

Characterization of molecular mechanisms of in vivo UVR induced cataract.

Cataract is the leading cause of blindness in the world (1). The World Health Organization defines cataract as a clouding of the lens of the eye which impedes the transfer of light. Cataract is a multi-factorial disease associated with diabetes, smoking, ultraviolet radiation (UVR), alcohol, ionizing radiation, steroids and hypertension. There is strong experimental (2-4) and epidemiological evidence (5,6) that UVR causes cataract. We developed an animal model for UVR B induced cataract in both anesthetized (7) and non-anesthetized animals (8). The only cure for cataract is surgery but this treatment is not accessible to all. It has been estimated that a delay of onset of cataract for 10 years could reduce the need for cataract surgery by 50% (9). To delay the incidence of cataract, it is needed to understand the mechanisms of cataract formation and find effective prevention strategies. Among the mechanisms for cataract development, apoptosis plays a crucial role in initiation of cataract in humans and animals (10). Our focus has recently been apoptosis in the lens as the mechanism for cataract development (8,11,12). It is anticipated that a better understanding of the effect of UVR on the apoptosis pathway will provide possibilities for discovery of new pharmaceuticals to prevent cataract. In this article, we describe how cataract can be experimentally induced by in vivo exposure to UVR-B. Further RT-PCR and immunohistochemistry are presented as tools to study molecular mechanisms of UVR-B induced cataract.

Kinetics of GADD45α, TP53 and CASP3 gene expression in the rat lens in vivo in response to exposure to double threshold dose of UV-B radiation.

The purpose of the present study was to investigate the evolution of expression of mRNA message for the genes for the genome stress sensor GADD45α, the apoptosis initiator TP53 and the apoptosis executor CASP3 in the rat lens in vivo in response to exposure to UVR around 300 nm. Forty six week old female albino Sprague-Dawley rats were unilaterally exposed to double threshold dose for cataract induction, 8 kJ/m(2) (8.9 W/m(2) for 15 min), of UVR (λ(max) = 300 nm). The animals were sacrificed at 1, 5, 24 and 120 h following exposure to UVR-B. For each of the GADD45α, TP53 and CASP3 genes, respectively, mRNA expression in the lenses was measured by quantitative RT-PCR. It was found that expression of mRNA for GADD45α transiently increases between 5 and 24 h after exposure. TP53 is slightly downregulated in exposed lenses at 1 and 5 h after exposure and thereafter the mRNA expression increases with a constant rate of 9.4\ 10(-3) rel. units/h to a 1.8 fold increase at 120 h after exposure. Expression of mRNA for CASP3 is downregulated at 1, 5 and 24 h after in vivo exposure and then increases with a constant rate of 4.7 10(-3) rel. units/h, upto a 1.3 fold upregulation at 120 h. Double threshold dose of UVR, for short delay onset of cataract, in vivo causes a transient upregulation of the stress sensor GADD45α, a concurrent downregulation of TP53 and CASP3, followed by a constant upregulation of TP53 that precedes a constant upregulation of CASP3.

Protective effect of the thioltransferase gene on in vivo UVR-300 nm-induced cataract.

PURPOSE: To determine the protection factor (PF) for glutaredoxin-1 (Grx1) with regard to UVR-induced cataract by comparison of in vivo ultraviolet radiation (UVR) lens toxicity between double knockout Grx1⁻/⁻ and Grx1⁺/⁺ mice. METHODS: Twenty Grx1⁺/⁺ mice and 20 Grx1⁻/⁻ mice were unilaterally exposed in vivo to UVR for 15 minutes. Groups of four animals each received 0.0, 2.1, 2.9, 3.6, and 4.1 kJ/m(2) UVR-300 nm. At 48 hours after UVR exposure, light-scattering in the exposed and contralateral nonexposed lenses was measured quantitatively. Macroscopic lens changes were documented with dark-field illumination photography. RESULTS: UVR-300 nm induced subcapsular and cortical cataract in Grx1⁻/⁻ and Grx1⁺/⁺ mice. In both Grx1⁻/⁻ and Grx1⁺/⁺, the light-scattering intensified with increased in vivo exposure doses of UVR-300 nm. The intensity of forward light-scattering was higher in the lenses of Grx1⁻/⁻ mice than in the lenses of Grx1⁺/⁺ mice. The threshold dose for in vivo UVR-300 nm-induced cataract, expressed as MTD(2.3:16), was 3.8 in the Grx1⁺/⁺ group and 3.0 in the Grx1⁻/⁻ group, resulting in a PF of 1.3. CONCLUSIONS: The PF is an objective relative measure of protective properties. The Grx1 gene is associated with an in vivo PF of 1.3. This result signifies that the presence of the gene allows a 1.3 times longer in vivo exposure to UVR, at equivalent irradiance, than the absence of the gene before early-onset, UVR-induced cataract occurs. This finding indicates the important role of the Grx1 gene in the oxidation defense system of the lens.

Dose-response relationship for α-tocopherol prevention of ultraviolet radiation induced cataract in rat.

The purpose of this study is to establish the dose response relationship for α-tocopherol protection of ultraviolet radiation (UVR) induced cataract in the rat. Four groups of 20 six-week-old albino Sprague Dawley rats received 5, 25, 50, and 100 IU/day α-tocopherol, whilst another group of 20 rats without any α-tocopherol feeding was the control group. After 4 weeks of feeding, each rat was unilaterally exposed to 8 kJ/m(2) UVR-300 nm for 15 min. At 1 week after exposure, the rats were sacrificed and lens light scattering was measured quantitatively. Lens total reduced (GSH) and oxidized (GSSG) glutathione; glutathione reductase (GR) and peroxidase (GPx) were determined spectrophotometrically. The UVR-exposed lenses in the α-tocopherol fed groups developed superficial cataract, whereas lenses in the control group developed cortical and equatorial opacities. Light scattering in lenses from the α-tocopherol-supplemented rats was lower than in lenses from the control group. The difference of light scattering between the exposed and contralateral non-exposed lens decreased with increasing doses of α-tocopherol to an asymptote level. UVR-exposure caused a significant depletion of lens GSH in rats without or at low α-tocopherol supplementation. The depletion of GSH became less with higher α-tocopherol supplementation. There was no detectable difference in lens GSSG, GR or GPx at any level of α-tocopherol supplementation. Orally administered α-tocopherol dose dependently protects against UVR-induced cataract. The protection is associated with an α-tocopherol dose-dependent GSH depletion secondary to UVR exposure. UVR-induced light scattering only occurs if the GSH depletion exceeds a threshold.

A new universal rat restrainer for ophthalmic research.

PURPOSE: Immobilization of rats is required in many psychological and physiological experiments. The aim of the current paper was to invent a universal device allowing for adaptation of rats of a wide age range and to maximize convenience for in vivo exposure to optical radiation under not-anaesthetized conditions. METHODS: Eighty-three 6-week-old and three 18-week-old Sprague-Dawley albino female rats were progressively familiarized daily with the restraining device 5 days prior to exposure to acquire a conditioned response and to reduce stress. After initial habituation, 10 min preceding the ultraviolet radiation (UVR) exposure, the animal was fixed in the rat restrainer. Each unanaesthetized animal was unilaterally exposed to a single dose of 8 kJ/m² UVR-300 nm for 15 min. Three of the 6-week-old and three of the 18-week-old rats were in vivo exposed to UVR once for 10 consecutive days. RESULTS: All rats acclimatized well to immobilization in the restrainer. Young rats adapted quicker than older rats. The device prevented head movement and body rotation, which allowed for uncomplicated single as well as repeated in vivo exposures to UVR. CONCLUSIONS: The restrainer effectively immobilizes unanaesthetized rats in the age range 6-18 weeks old, making it useful in future projects involving chronic repeated in vivo exposure of the eye to UVR.

Evolution of damage in the lens after in vivo close to threshold exposure to UV-B radiation: cytomorphological study of apoptosis.

The purpose of the present study was to investigate cataractogenesis and recovery of lens damage after in vivo close to threshold ultraviolet (UV)-B radiation around 300 nm. Eighty six-week-old albino Sprague-Dawley rats were familiarized to a rat restrainer five days prior to exposure. Groups of non-anesthetized rats were exposed unilaterally to 8 kJ/m(2) UVR-300 nm. The animals were sacrificed at 1, 7, 48 and 336h following exposure. The lenses were extracted for imaging of dark-field lens macro anatomy and measurement of intensity of forward lens light scattering to quantify lens opacities. Three exposed lenses and one non-exposed lens from each time interval were examined with light and transmission electron microscopy (TEM). Macro anatomy and lens light scattering revealed that all contralateral non-exposed lenses were clear. The degree of lens opacity (difference in lens light scattering between exposed and non-exposed lenses) increased during the 336h, reaching a plateau towards the end of the observation period. Light microscopy and TEM demonstrated that apoptotic features appeared in the epithelium already 1h after UVR exposure, and small vacuoles were seen in the outer cortex. Epithelial damage occurs during the first 48h after exposure and is followed by regenerative repair at 336h post-exposure. Apoptotic epithelial cells were phagocytized by adjacent epithelial cells. Cortical fiber cells exhibited increasing damage throughout the observation period without any clear repair after 336h. In conclusion, acute UVR-induced cataract is partly a reversible. Lens epithelium is a primary target for UVR exposure. Damage to cortical fiber cells remained irreversible.

Evolution of light scattering and redox balance in the rat lens after in vivo exposure to close-to-threshold dose ultraviolet radiation.

PURPOSE: To investigate the evolution of cataract development and glutathione redox balance in the rat lens after in vivo close-to-threshold dose exposure to ultraviolet radiation (UVR) around 300 nm. METHODS: Three groups of 10 Sprague-Dawley rats were unilaterally exposed to 8 kJ/m² UVR-300 nm for 15 min, and a fourth group of 10 rats was kept without UVR exposure as nonexposed control animals. The exposed animals were killed at 1, 3 and 7 days after exposure. Both lenses from all animals were extracted and photographed and the intensity of forward light scattering was measured quantitatively. Thereafter, the lenses were homogenized. The concentration of reduced glutathione (GSH) and oxidized glutathione (GSSG), and the activity of glutathione reductase (GR) and glutathione peroxidase (GPx), respectively, were determined spectrophotometrically. The mean paired differences between exposed and nonexposed lenses were used as primary data in the statistical analyses. RESULTS: All exposed lenses developed cataract. Lens light scattering increased throughout the 7 days after UVR exposure. GSH concentration and GPx rate transiently increased at 1 day after exposure and then decreased throughout follow-up, with GSH concentration having a negative balance at the end. GSSG concentration and GR activity did not change after UVR exposure. CONCLUSION: In vivo close-to-threshold UVR exposure induces a gradual increase in rat lens opacification/cataract development and time dependently alters the redox balance in the lens.