tretinoin and 4-hydroxy-2-nonenal

The mechanisms that control the natural rate of lipofuscin accumulation in the retinal pigment epithelial (RPE) cell and its stability over time are not well understood. Similarly, the contributions of retinoids, phospholipids and oxidation to the rate of accumulation of lipofuscin are uncertain. The experiments in this study were conducted to explore the individual contribution of rod outer segments (ROS) components to lipofuscin formation and its accumulation and stability over time. During the period of 14 days incubation of ROS, lipofuscin-like autofluorescence (LLAF) determined at two wavelengths (530 and 585 nm) by fluorescence-activated cell sorting (FACS) was measured from RPE cells. The autofluorescence increased in an exponential manner with a strong linear component between days 1 and 7. The magnitude of the increase was larger in cells incubated with 4-hydroxynonenal (HNE-ROS) compared with cells incubated with either bleached or unbleached ROS, but with a different spectral profile. A small (10-15%) decrease in LLAF was observed after stopping the ROS feeding for 14 days. The phagocytosis rate of HNE-ROS was higher than that of either bleached or unbleached ROS during the first 24 h of supplementation. Among the different ROS components, the increase of LLAF was highest in cells incubated with all-trans-retinal. Surprisingly, incubation with 11-cis-retinal and 9-cis-retinal also resulted in strong LLAF increase, comparable to the increase induced by all-trans-retinal. Supplementation with liposomes containing phosphatidylethanolamine (22: 6-PE) and phosphatidylcholine (18:1-PC) also increased LLAF, while incubation with opsin had little effect. Cells incubated with retinoids demonstrated strong dose-dependence in LLAF increase, and the magnitude of the increase was 2-3 times higher at 585 nm compared to 530 nm, while cells incubated with liposomes showed little dose-dependence and similar increase at both wavelengths. Very little difference in LLAF was noted between cells incubated with either unbleached or bleached ROS under any conditions. In summary, results from this study suggest that supplementation with various ROS components can lead to an increase in LLAF, although the autofluorescence generated by the different classes of components has distinct spectral profiles, where the autofluorescence induced by retinoids results in a spectral profile closest to the one observed from human lipofuscin. Future fluorescence characterization of LL

Topics: Aldehydes; Animals; Cattle; Cell Line; Cells, Cultured; Diterpenes; Flow Cytometry; Humans; Lipofuscin; Liposomes; Microscopy, Confocal; Phagocytosis; Phosphatidylcholines; Phosphatidylethanolamines; Retinal Pigment Epithelium; Retinaldehyde; Retinoids; Rod Cell Outer Segment; Tretinoin

Alzheimer's disease (AD) a progressive neurodegenerative disorder of later life, is characterized by brain deposition of amyloid beta-protein (Abeta) plaques, accumulation of intracellular neurofibrillatory tangles, synaptic loss and neuronal cell death. There is significant evidence that oxidative stress is a critical event in the pathogenesis of AD. In the present study Abeta formation was induced in NT2N neurons, one of the most appropriate cell line models in AD. Our results indicate that oxidative stress resulting from the treatment of H(2)O(2)/FeSO(4) and/or 4-hydroxy-2-noenal (HNE) can be inhibited in the presence of tBHQ, a known inducer of nuclear factor-erythroid 2 related factor 2 (Nrf2) in NT2N neurons and can therefore be used to elucidate the relationship between oxidative stress, Abeta formation and Nrf2. The role of Nrf2 was confirmed using retinoic acid as an inhibitor of Nrf2. It provides the first documentation that tBHQ not only protects the neurons against cell death but also decreases amyloid beta formation. Moreover, the results indicate that oxidative stress fosters Abeta formation in NT2N neurons, creating a vicious neurodegenerative loop.

Topics: Aldehydes; Alzheimer Disease; Amyloid beta-Peptides; Animals; Antineoplastic Agents; Antioxidants; Astrocytes; Caspase 3; Cell Line; Cysteine Proteinase Inhibitors; Enzyme Activation; Ferrous Compounds; Glutathione; Humans; Hydrogen Peroxide; Hydroquinones; Neurons; NF-E2-Related Factor 2; Oxidants; Oxidative Stress; Tretinoin

Clinical use of retinoic acids (RA) is hindered by toxicity possibly related to oxidative stress. Recently, RA at relatively low concentrations was shown to inhibit NRF2 and the expression of its target antioxidative genes. This raises the possibility that RA toxicity may result from cellular inability to cope with resultant oxidative stress. Using in vitro cell and in vivo mouse models, we report that RA, specifically all-trans-RA (atRA) at concentrations implicated in toxicity, can activate NRF2 and induce NRF2 target genes, particularly the subunits of the rate-limiting enzyme of glutathione biosynthesis, glutamate cysteine ligase (GCLM/GCLC). RNA interference-mediated silencing of NRF2, but not of retinoid X receptor-alpha and -beta, reduced basal and atRA-induced GCLM/GCLC gene expression. Moreover, RA increased nuclear accumulation of NRF2, antioxidant response element (ARE) reporter activity, and NRF2 occupancy at AREs. 4-Hydroxynonenal, a lipid peroxidation product, was increased by RA. Inhibition of MEK1/ERK mitogen-activated protein kinases significantly suppressed atRA-induced NRF2 activation and ARE-regulated gene expression, reducing cell resistance against toxic concentrations of RA. NRF2-silenced cells were vulnerable to atRA-induced mitochondrial toxicity and apoptosis. In conclusion, toxic RA activates NRF2, thereby triggering an adaptive response against the resultant oxidative stress. NRF2 enhancement as a therapeutic target of retinoid toxicity awaits further investigation.

Topics: Adenocarcinoma; Aldehydes; Animals; Antineoplastic Agents; Antioxidants; Apoptosis; Breast Neoplasms; Carcinoma, Hepatocellular; Cells, Cultured; Gene Expression Regulation; Glutamate-Cysteine Ligase; Humans; Kidney; Lipid Peroxidation; Liver Neoplasms; Male; MAP Kinase Kinase 1; Mice; Mitochondria; Mitogen-Activated Protein Kinase 1; Mitogen-Activated Protein Kinase 3; NF-E2-Related Factor 2; Response Elements; Retinoid X Receptor alpha; Retinoid X Receptor beta; RNA, Small Interfering; Tretinoin

4-Hydroxynonenal (HNE), a product of lipid peroxidation, inhibits proliferation of several tumor cells. The p53 tumor suppressor protein plays a critical role in cell cycle control, by inducing p21 expression, and in apoptosis, by inducing bax expression. Recently, two other proteins with many p53-like properties, TAp73 (p73) and TAp63 (p63), have been discovered. SK-N-BE human neuroblastoma cells express the three p53 family proteins and can be used for the study of their induction. We investigated HNE action in the control of proliferation, differentiation, and apoptosis in SK-N-BE cells and the HNE effect on the expression of p53, p63, p73, p21, bax, and G1 cyclins. Retinoic acid (RA) was used as a positive control. HNE inhibited cell proliferation without inducing differentiation; it decreased S-phase cells and increased the number of apoptotic cells. RA reduced the proportion of S-phase cells and did not induce apoptosis. HNE increased p53, p73, p63, p21, and bax expression at different time points. HNE reduced cyclin D2 expression and the phosphorylation of pRb protein. Our results demonstrated that HNE inhibits SK-N-BE cell proliferation by increasing the expression of p53 family proteins and p53 target proteins which modulate cell cycle progression and apoptosis.

Topics: Aldehydes; Apoptosis; bcl-2-Associated X Protein; Blotting, Western; Cell Cycle; Cell Cycle Proteins; Cell Differentiation; Cell Line, Tumor; Cell Proliferation; Chromatography, High Pressure Liquid; Cyclin-Dependent Kinase Inhibitor p21; Cysteine Proteinase Inhibitors; DNA-Binding Proteins; Flow Cytometry; Genes, Tumor Suppressor; HL-60 Cells; Humans; Lipid Metabolism; Microscopy, Fluorescence; Neuroblastoma; Nuclear Proteins; Peroxides; Phosphoproteins; Phosphorylation; Proto-Oncogene Proteins c-bcl-2; Retinoblastoma Protein; Reverse Transcriptase Polymerase Chain Reaction; Time Factors; Trans-Activators; Transcription Factors; Tretinoin; Tumor Protein p73; Tumor Suppressor Protein p53; Tumor Suppressor Proteins

Inhibition of conceptal biosynthesis of all-trans-retinoic acid (t-RA) by aldehydes generated from lipid peroxidation was investigated. Oxidative conversion of all-trans-retinal (t-RAL, 18 microM) to t-RA catalyzed by rat conceptal cytosol (RCC) was sensitive to inhibition by trans-2-nonenal (tNE), nonyl aldehyde (NA), 4-hydroxy-2-nonenal (4HNE), and hexanal. With an initial molar ratio of aldehyde/t-RAL of 2:1, tNE, NA, and 4HNE caused 70, 65, and 40% reductions of t-RA synthesis, respectively. Hexanal reduced generation of t-RA by approximately 50% as the ratio of aldehyde/t-RAL was raised to 20:1. tNE significantly increased the Km of the reaction and kinetic analyses indicated a mixed competitive/noncompetitive inhibition. By contrast, analogous reactions catalyzed by adult rat hepatic cytosol (ARHC) were highly resistant to inhibition by the same aldehydes. Significant inhibition (> 40% reduction of t-RA generation) by 4HNE, NA, and tNE were achieved at high molar ratios of aldehyde/t-RAL (> 175:1). Hexanal did not inhibit the reaction significantly even at very high ratios of aldehyde/t-RAL (> 2,000:1). Interestingly, when reduced glutathione (GSH, 10 mM) alone or GSH plus glutathione S-transferase (GST) were added to RCC-catalyzed reactions, additions of tNE or 4HNE showed either no significant inhibition or a partial lack of inhibition. Results suggested that GSH-dependent conjugation with 4HNE proceeded slowly compared to conjugation with tNE. To test the hypothesis that GST-catalyzed GSH conjugation can effectively prevent inhibition of t-RA synthesis by aldehydic products of lipid peroxidation, triethyltin bromide (TEB, a potent inhibitor of GST, 20 microM) was added to ARHC-catalyzed reactions when hexanal or tNE were present in the incubations. Eighty and 60% of hexanal and tNE inhibition, respectively, were observed. This was apparently due to TEB blockage of GST-catalyzed GSH conjugation reactions and thus strongly supported the stated hypothesis.

Topics: Aldehydes; Animals; Embryo, Mammalian; Female; Glutathione; Glutathione Transferase; Kinetics; Lipid Peroxidation; Pregnancy; Rats; Rats, Sprague-Dawley; Tretinoin