Objective To investigate the expression of eotaxin-1, eotaxin-2 and eotaxin-3 in ARPE-19 human RPE cells after exposure to light. Methods Cultured human RPE cells (5th~10th generations) were divided into lightinduced group and control group. Cells light-induced group were exposed to the blue light at the intensity of (600plusmn;100) Lux for 12 h to establish the light damaged model. Eotaxin-1, eotaxin-2 and eotaxin-3 mRNA and protein were determined by real time polymerase chain reaction and Western blot at 0, 3, 6, 12, 24 hours after light-induced. Results In light-induced groups, mRNA levels of eotaxin-1 and eotaxin-2 were increased at 0 h (t1=6.05.t2=12.561) and 3 h (t1=2.95.t2=3.67) significantly(P<0.05), but the mRNA level of eotaxin-3 had not changed (t3=1.57 and 1.00 respectively,P>0.05) at that time. At 6 h (t1=4.73,t2=18.64,t3=28.48), 12 h (t1=3.11,t2=20.62,t3=18.50), 24 h (t1=8.25,t2=38.27,t3=18.60), mRNA levels of eotaxin-1, 2, 3 were increased significantly (P<0.05). Except for the eotaxin-3 protein had not changed at 3 h (t3=1.28,P>0.05), protein expression of eotaxin-1, 2, 3 were increased significantly (P<0.05) at 0 h (t1=4.85,t2=5.45,t3=6..21), 3 h (t1=5.64,t2=4.55), 6 h (t1=31.60,t2=6.63,t3=7.15), 12 h (t1=14.09,t2=18.22,t3=15.76), 24 h (t1=6.96,t2=10.47,t3=12.85). Conclusion Eotaxin-1, eotaxin-2 and eotaxin-3 expression were increased after Light-damage, corresponding to the time after light exposure. Eotaxin-3 was the most prominent isoform.
Objective To investigate the effect of blue light on mRNA expression of L-type calcium channel subtypes of human retinal pigment epithelial (RPE) cells in vitro. Methods The fourth-generation of human RPE cells were randomly divided into four groups including control group (no light group), light group, light + nifedipine group, and light + (-) BayK8644 group. The cells were exposed to blue light (2000plusmn;500) lux for 6 hours, and then cultured for another 24 hours. Reverse transcription polymerase chain reaction real time (RT-PCR) and fluorescence quantitative PCR technologies were used to analyze mRNA expression of L-type calcium channel subunit of cardiac subtype ( 1C or CaV1.2), neuroendocrine subtype ( 1D or CaV1.3) and retinal subtypes ( 1F or CaV1.4) in each group. Results The length of PCR product of 1C, 1D, 1F subunit and actin was 68, 157, 125 and 186 base pairs respectively. (1) 1C mRNA expression in light, light + nifedipine and light + (-) BayK8644 group was higher than that in control group, the difference was statistically significant (P<0.05). 1C mRNA expression in light +nifedipine group and light + (-) BayK8644 group was higher than in light group (P<0.05). 1C mRNA expression in light + (-) BayK8644 group was higher than that in light + nifedipine group (P<0.05). (2) Comparing with control group, 1D mRNA expression was higher in light, light +nifedipine and light + (-) BayK8644 group, the difference was statistically significant (P<0.05). Light + (-) BayK8644 group was higher than light group and light + nifedipine group (P<0.05), light group and the light + nifedipine group was not statistically significant (P>0.05). (3) 1F mRNA expression in light, light + nifedipine and light + (-) BayK8644 group was higher than those in control group, there was statistically significant (P<0.05), light +nifedipine group and light + (-) BayK8644 group was higher than light group (P<0.05), light + nifedipine group and the light + (-) BayK8644 group was not statistically significant (P>0.05). Conclusions The human RPE cells mRNA expression of L-type calcium channel 1C, 1D and 1F subunit was increased after exposing to blue light. Application of the 1times;10-5 mmol/L (-) BayK8644 can increase mRNA expression of 1C, 1D and 1F subunit.
Objective To observe the expression of vascular endothelial growth factor A (VEGFA) and its receptors sFlt-1, kinase insert domain receptor (KDR) in lightinjured human retinal pigment epithelial (RPE) cells. Methods Cultured human RPE cells (8th - 12th generations) were divided into normal control group and light damage group. The cells of two groups were exposed to the 18 W cold white light (2200±300) Lux for 12 hours to induce light damage responses, but the cells of normal control group were packed by tinfoil with doubledeck high pressure disinfection. The VEGF-A, sFlt-1 and KDR mRNA and protein expressions were detected by reverse transcriptionpolymerase chain reaction (RT-PCR) and Western blot at 0, 6, 12, 24 hours after light damage. Results The VEGF-A mRNA and protein expressions in light damage group were significantly increased at 6 hours, and reached its peak at 12 hours after light damage which obviously higher than that in normal group (t=2.74, 2.93; P<0.05), and then went down gradually. The sFlt-1 mRNA and protein expressions in light damage group reached its peak at 12 hours after light damage which obviously higher than that in normal group (t=4.32, P<0.01), but obviously lower than that in normal group at 24 hours after light damage (t=2.41, P<0.05). The KDR mRNA and protein expressions in light damage group were obviously higher than that in normal group at 24 hours after light damage (t=2.89, P<0.05),but there was no changes at 6, 12 hours after light damage (t=1.84, P>0.05). Conclusions At 6, 12 hours after light damage, the expressions of VEGF-A and sFlt-1 increases significantly and KDR expression is stable in lightinjured RPE cells. At 24 hours after light damage, the expression of VEGF-A and sFlt-1 decreases, but KDR expression increases in light-injured RPE cells.
Objective To assess the effects of 670nm LED (lightemitting diode) to protect the photoreceptor from the lightinduced damage in a rat model. Methods 32 SD rats were randomly assigned to one of eight groups: untreated control group, the LEDtreated control group, three groups of lightinduced damage,and three groups of lightinduced damage treated with LED. Lightinduced damage result from exposing to constant light for 3 hours of different illuminations of 900,1800 and 2700 lx, respectively. The LED treatment (50 mW) was delivered for 30 minutes at 3 hours before the light damage and 0,24 and 48 hours after the light damage. Retinal function and morphology were measured by electroretinogram (ERG) and histopathology assay. Results The illumination of 900 lx for 3 hours did not damage the rat retina. The illumination of 1800 lx for 3 hours resulted in thinner ONL and no OS and IS. The ratio of damaged area/total retinal area was 048plusmn;012, the damaged thickness of ONL/normal ONL (L5 ) was 039plusmn;007,and the amplitude of ERG b wave was (431plusmn;120) mu;V. With the LED treatment the ratio of damaged area decreased (M6=017plusmn;0.12, P5/6=0.002), and the ratio of the damaged thickness of ONL also decreased (L6=0.22plusmn;0.09, P5/6lt;0.01), and the amplitude of ERG b wave increased to (1011plusmn;83) mu;V(P5/6lt;0.001). The illumination of 2700 lx for 3 hours caused severed damage to the rat retina and the LED could not protect them significantly. Conclusions 670 nm LED treatment has an evident protective effect on retinal cells against light-induced damage, which may be a simple and effective therapy to prevent or to delay agerelated macular degeneration.
Objective To explore the protective mechanism and effect of coenzyme Q10 on the retinal photic injury in experimental rats. Methods Thirty Sprague-Dawley rats were divided randomly into 3 groups: normal control group, positive control group, and coenzyme Q10 group. The experimental model of photic injury in rats was established by being exposed to intense green fluorescent light with an illuminance level of (2000plusmn;120) Lux for 24 hours. The physiological saline and coenzyme Q10 were given through tail intravenous injection at 24 hours and 30 min before light exposure in positive control group and coenzyme Q10 group, respectively. Ophthalmectomy was performed 1 day after the illumination. Changes of retinal histopathology and ultrastructure were observed by light and electron microscope. The apoptosis rate of retinal cells was detected by flow cytometry. Results The result of histopathological examination showed that in coenzyme Q10 group, the outer segments arranged trimly with only few cell apoptosis; the inner and outer segments slightly swelled, and compared with the positive group, the histopathological changes alleviated obviously. The result of flow cytometry revealed that the apoptosis rate of retinal cells was (1.65plusmn;1.48)% in normal control group, (25.83plusmn;2.92)% in positive control group, and (12.43plusmn;2.25)% in coenzyme Q10 group, respectively. The apoptosis rate of retinal cells was higher in positive control group than that in the normal control group (t=18.28, Plt;0.01), and lower in coenzyme Q10 group than that in the positive control group (t=9.07, Plt;0.01). Conclusion Coenzyme Q10 plays an important role in preventing the photic injury of retina and optic cell apoptosis. (Chin J Ocul Fundus Dis, 2007, 23: 122-125)
Objective:To observe the protective effect of ginkgo bilo ba extrac t (EGb 761), a free radical scavenger, on the photoreceptor cells after lighti nduced retinal damage. Methods:Seventytwo female SpragueDa wley (SD) rats we re randomly divided into 4 groups: normal control group, lightinduced retinal da m age model group, model+physiological saline group, and model+EGb 761 group, with 18 rats in each group. All of the rats except the ones in the control group were exposed to white light at (2740plusmn;120) lx for 6 hours after the dark adap tation for 24 hours to set up the lightinduced retinal damage model. Rats in m o del + physiological saline group and model+EGb 761 group were intraperitoneall y injected daily with physiological saline and 0.35% EGb 761 (100 mg/kg), respec tively 7 days before and 14 days after the light exposure. Apoptosis of photorec eptor cells was detected 4 days after light exposure; 7 and 14 days after light exposure, histopathological examination was performed and the layer number of ou ter nuclear layers (ONL) on the superior and inferior retina was counted. Results:Four days after light exposure, the apoptosis of photorecep tor cells was fou nd on ONL in model, model+ physiological saline and model+EGb 761 group, and w as obviously less in model + EGb 761 group than in model and model+physiologic al saline group. Seven days after light exposure, the layers of ONL on the super ior retina were 3 to 4 in model and model+physiological saline group, and 7 to 8 in model+EGb 761 group; the mean of the layer number of ONL in model+EGb 761 group (6.92plusmn;0.82) was less than that in normal control group (8.40plusmn;0.95) (t=-1.416, P<0.05), but significantly more than that in model (5.96 plusmn;1.36 ) and model+physiological saline group (5.90plusmn;1.40)(t=1.024, 1.084; P<0.05). Fourteen days after light exposure, the layers of ONL on the superior retina were 0 to 1 in model and model+physiological saline group, and 3 to 4 i n model+EGb 761 group. The mean of the layer number of ONL in model+EGb 761 group (5.5 2plusmn;1.06) was significantly more than that in model (3.44plusmn;2.15) and model + physiological saline group (3.37plusmn;1.91) (t=2.082, 2.146, P<0.05). Conclusion:EGb 761 can partially inhibit the apoptosis of pho toreceptor cells, thus exert protective effect on photoreceptor cells.
Objective To observe the expression of proteins in light-injured retinal pigment epithelial (RPE) cells. Methods ARPE19 cells were exposed to the cool white light at the intensity of (2200plusmn;300) Lx for 6 hours to set up the light injured model. Cellular soluble proteins was extracted and analyzed by means of twodimensional electrophoresis to find out the changes of protein map of lightinjured RPE cells. Results Cellular soluble proteins had (390plusmn;10) spots on the map, in which 11 spots had obvious difference between the light injured group and the normal control group. In the lightinjured cells, the expressio of 8 proteins increased, 1 decreased, and 2 disappeared. Conclusion Twodimensional electrophoresis can find out the difference of expression of proteins in lightinjured and normal RPE cells.
Objective To assess the protective effect of recombinant human erythropoietin (EPO) on human retinal pigment epithelial (RPE) cells injured by light. Methods Cultured human RPE cells were exposed to light for 12 hours, and the culture was stopped 24 hours later. The 3(4,5dimethylthiazole2y1)2,5diphenyl tetrazolium bromide (MTT) cell viability assay and annexin V flunorescein isothiocyanate/propidium iodium labeling and flow cytometry were used to assess the effects of EPO with different concentration on the cellular viability and apoptosis of human RPE cells. The protective effect and mechanism of EPO on RPE cells injured by light was detected by adding AG490. Results EPO, especially with the concentration of 40 IU/ml, obviously increased the cellular viability of RPE cells and apparently decrease the cellular apoptosis induced by light injury. After adding AG490, the effects of EPO on cellular viability and apoptosis were inhibited. Conclusion It is suggested that EPO can protect the human RPE cells from lightinduced injures, and its protective mechanism works after the combination of EPO and its receptor.
Objective To observe the effect of blue light on apoptosis of cultured human retinal pigment epithelial (RPE) cells in vitro. Methods Human RPE cells were exposed to blue light, and the cells were divided into 3 groups: group A, with various intensity of illumination; group B: with same intensity but different time of illumination; group C: with same intensity and time of illumination but different finish time of the culture. The apoptosis of RPE cells was observed by TdT-dUTP terminal nick-end labeling (TUNEL) and annexin V-fluoresein isothiocyanate (FITC)/propidium iodide (PI) flow cytometry, and transmission electron microscopy. Results The positive cells stained by TUNEL shrinked and turned round, whose nuclei concentrated and congregated like the crescent or hat. Cracked nuclei and membrane bleb were found. Swollen mitochondrial, disappeared inner limiting membrane of mitochondria, and dilation of the rough endoplasmic reticulum with metabolite were observed by transmission electronmicroscopy. In group A, mild damage of RPE cells was found when the threshold value of the intensity of illumination was less than(500±100)lx, and the apoptosis and necrosis of RPE cells aggravated as the intensity of illumination increased; in group B, as the time of illumination extended, the number of apoptotic RPE cells didn′t increase while the necrosis increased; in group C, 6 and 12 hours after illumination, apoptosis of cells was the main injury, while apoptosis with necrosis was found and necrotic cells increased as the time of illumination was prolonged. Conclusions Illumination with blue light may cause damages of human RPE cells in vitro, with the modalities of apoptosis, apoptotic necrosis and necrosis. The extent of injury is dependent on intensity and duration of the illumination. (Chin J Ocul Fundus Dis, 2005, 21: 384-387)
Objective To investigate the degenerative changes in the inner rat retina after photic injury.Methods After 24 hour-dark adaptation, sixty Lewis rats were exposed in a ventilated green plexiglass chamber that transmitted continuous green light between 480-520 nm with an intensity of 900~1 000 lx. After 24 hour exposure, the rats stayed in darkness and were sacrificed after 1 day, 3,7 or 14 days. The neurons in the inner retina were marked by immunohisto chemical technique and observed by light and electronic microscope.Results The apoptotic photoreceptor cells were noted after photic injury. The degeneration and decreasing number of rod bipolar cells were found after 3 days; the edema of horizontal cells occurred after 1 day but ameliorated gradually; decreasing number of amacrine cells was found after 1 day; sustained edema of ganglion cells and prolifeeration of the Müller cells were found after photic injury. Pyknotic and edematous neruronal degenerations of inner retina were found in ultrastructural study.Conclusion The neurons in the inner retina as well as Müller cells are involved in the degeneration after photic injury. Different neurons manifest different patterns of degeneration.(Chin J Ocul Fundus Dis,2003,19:201-268)