Chi-square analysis of the reduction of ATP levels in L-02 hepatocytes by hexavalent chromium

Yuan, Yang; Peng, Li; Gong-Hua, Hu; Lu, Dai; Xia-Li, Zhong; Yu, Zhou; Cai-Gao, Zhong

doi:10.1590/S0100-879X2012007500040

Abstract

This study explored the reduction of adenosine triphosphate (ATP) levels in L-02 hepatocytes by hexavalent chromium (Cr(VI)) using chi-square analysis. Cells were treated with 2, 4, 8, 16, or 32 μM Cr(VI) for 12, 24, or 36 h. Methyl thiazolyl tetrazolium (MTT) experiments and measurements of intracellular ATP levels were performed by spectrophotometry or bioluminescence assays following Cr(VI) treatment. The chi-square test was used to determine the difference between cell survival rate and ATP levels. For the chi-square analysis, the results of the MTT or ATP experiments were transformed into a relative ratio with respect to the control (%). The relative ATP levels increased at 12 h, decreased at 24 h, and increased slightly again at 36 h following 4, 8, 16, 32 μM Cr(VI) treatment, corresponding to a "V-shaped" curve. Furthermore, the results of the chi-square analysis demonstrated a significant difference of the ATP level in the 32-μM Cr(VI) group (P < 0.05). The results suggest that the chi-square test can be applied to analyze the interference effects of Cr(VI) on ATP levels in L-02 hepatocytes. The decreased ATP levels at 24 h indicated disruption of mitochondrial energy metabolism and the slight increase of ATP levels at 36 h indicated partial recovery of mitochondrial function or activated glycolysis in L-02 hepatocytes.

Hexavalent chromium; ATP level; Interference effect; Chi-square test

Abstract

Introduction

Material and Methods

Results

Discussion

Acknowledgments

Braz J Med Biol Res, June 2012, Volume 45(6) 482-487

Chi-square analysis of the reduction of ATP levels in L-02 hepatocytes by hexavalent chromium

Yang Yuan^1,2, Li Peng¹, Hu Gong-Hua¹, Dai Lu¹, Zhong Xia-Li¹, Zhou Yu¹and Correspondence and Footnotes Zhong Cai-Gao¹

¹School of Public Health, Central South University, Changsha Hunan, China

²Department of Clinical Laboratory, Huaihua Medical College, Huaihua Hunan, China

References

Correspondence and Footnotes ^{Correspondence and Footnotes} Correspondence and Footnotes

This study explored the reduction of adenosine triphosphate (ATP) levels in L-02 hepatocytes by hexavalent chromium (Cr(VI)) using chi-square analysis. Cells were treated with 2, 4, 8, 16, or 32 μM Cr(VI) for 12, 24, or 36 h. Methyl thiazolyl tetrazolium (MTT) experiments and measurements of intracellular ATP levels were performed by spectrophotometry or bioluminescence assays following Cr(VI) treatment. The chi-square test was used to determine the difference between cell survival rate and ATP levels. For the chi-square analysis, the results of the MTT or ATP experiments were transformed into a relative ratio with respect to the control (%). The relative ATP levels increased at 12 h, decreased at 24 h, and increased slightly again at 36 h following 4, 8, 16, 32 μM Cr(VI) treatment, corresponding to a "V-shaped" curve. Furthermore, the results of the chi-square analysis demonstrated a significant difference of the ATP level in the 32-μM Cr(VI) group (P < 0.05). The results suggest that the chi-square test can be applied to analyze the interference effects of Cr(VI) on ATP levels in L-02 hepatocytes. The decreased ATP levels at 24 h indicated disruption of mitochondrial energy metabolism and the slight increase of ATP levels at 36 h indicated partial recovery of mitochondrial function or activated glycolysis in L-02 hepatocytes.

Key words: Hexavalent chromium; ATP level; Interference effect; Chi-square test

Hexavalent chromium, Cr(VI), is a well-documented human carcinogen and is widely found in human living environments as the result of industrial production or discharge (1). Recently, Cr(VI) pollution has been found in crops due to the uptake of Cr(VI) from the soil and in rivers in some regions of China (2,3). The toxicity caused by oral Cr(VI) ingestion is thought to be due to toxicity to the liver, which is the main organ of biological metabolism, and liver damage (or hepatotoxicity) from Cr(VI) exposure has been confirmed in animal experiments and in cultured L-02 hepatocytes, which showed hepatocyte ultrastructure disruption, mitochondrial damage and apoptosis (4-6).

Mitochondria are the main site of ATP synthesis, which is produced by the tricarboxylic acid cycle (TCA) and oxidative phosphorylation (OXPHOS) in the inner mitochondrial membrane (7). At present, the detailed interference effect of Cr(VI) on the cellular ATP levels is not known. Generally, Cr(VI) can induce apoptosis and lead to a decrease in cell survival or cell number, and differences in cell number result in the different cellular ATP levels. And in this case manual adjustment of cell number is commonly applied to balance differences in cell number in each group. Small sample t-tests or one-way ANOVA were applied to compare the differences between the Cr(VI) treatment groups and control. However, in our view, adjusting the cell number is not the only way to analyze the toxic effects of Cr(VI) in vitro. The chi-square statistical test (χ²) can also be used to analyze the physiological or toxicological effects of Cr(VI) in vitro.

The χ² test is a commonly used statistical method and consists of the Pearson chi-square, linear-by-linear chi-square, McNemar and Mantel-Haenszel tests, among others. Currently, χ²analysis is widely applied to compare the difference of a relative ratio existing between two or more groups. It is frequently used in the fields of clinical and experimental epidemiology to explore etiological factors, to assess risk, and to predict trends of disease development. However, the χ²test is rarely applied in the field of in vitro cytotoxicity. For this reason, after cultured L-02 hepatocytes were exposed to 0, 2, 4, 8, 16, and 32 μM Cr(VI) for 12, 24, or 36 h, a χ² test was applied to analyze the interference effect by comparing the difference between cell survival rate and intracellular ATP levels to establish a novel method of analyzing the cytotoxicity induced by toxic chemicals in vitro.

Material

Potassium dichromate [K₂Cr₂O₇, abbreviated as Cr(VI)] was purchased from Sigma (USA). Roswell Park Memorial Institute (RPMI-1640) culture medium was purchased from Solarbio (USA), and newborn calf serum was purchased from Shi Ji Qing (China). A methyl thiazolyl tetrazolium (MTT) cell death kit was purchased from Amresco (USA). The ATP assay kit-S0026 was purchased from Beyotime (China). The human embryonic liver cell line L-02 (L-02 hepatocytes) was obtained from the Shang Hai Center of Cell Culture of Chinese Academy of Sciences. A 0.1 M Cr(VI) stock solution was prepared by adding 29.418 g K₂Cr₂O₇to 1000 mL ddH₂O. The stock was then diluted in culture medium to 2, 4, 8, 16, 32 µM.

L-02 hepatocyte culture and Cr(VI) exposure

L-02 hepatocytes were cultured on a six-well plate with RPMI-1640 medium containing 15% newborn calf serum at 37°C in a 5% CO₂atmosphere. The culture medium was changed every 1-2 days. When the cell density reached 60% confluence, the cells were exposed to Cr(VI) for different periods of time (12, 24, or 36 h) at 37°C. Untreated cultures were used as a control group. Cell survival was analyzed by the MTT method according to manufacturer instructions.

MTT reduction assay

The MTT assay was performed according to manufacturer instructions. The growing cells were collected by 0.25% Trypsin digestion, centrifugation, and supernatant removal. Two milliliters of RPMI-1640 culture medium containing 15% newborn calf serum was added to resuspend the cells as a single cell suspension. The cell suspension was then inoculated in a 96-well culture plate at a density of 1.0 x 10⁴ cells/well. The following day, the cells were grown in medium containing 0, 2, 4, 8, 16, or 32 µM Cr(VI) for 12, 24, or 36 h at 37°C. Following Cr(VI) treatment, MTT was added at a volume of 10 μL/well and cultured for 4 h at 37°C, then 100 μL formazan lysate was added, and the cells were cultured for 6 h at 37°C. Finally, the 96-well culture plate was removed from the incubator and continually shaken for 5 min on a micro-oscillator to completely dissolve the formazan. Immediately, cell vitality was analyzed by measuring absorbance at 492 nm with a multifunction microplate reader (Thermo Varioskan Flash 3001, USA).

ATP bioluminescence assay

L-02 hepatocytes were seeded at a density of 2.5 x 10⁵ cells/well on three six-well plates. When the cells reached 60% confluence, they were exposed to Cr(VI) for 12, 24, or 36 h. Following Cr(VI) treatment, intracellular ATP levels were determined using a bioluminescent ATP assay kit. The cells were disrupted in 200 μL lysis buffer by mechanical disruption, and centrifuged at 12,000 g to collect the cell supernatant. Meanwhile, an aliquot (100 μL) of an ATP detection working solution was added to each well of a black 96-well culture plate and incubated for 3 min at room temperature. Then, four replicates of 40-μL samples of the cell lysate from each group were added to the wells. After allowing the reaction to take place for a few seconds, the luminescence value was measured. In addition, the 96-well plates also contained serial dilutions of an ATP standard solution to generate a standard curve, and the ATP levels in L-02 hepatocytes were calculated by comparison with the ATP standard curve.

Data analysis

Data were analyzed statistically with Microsoft Office Excel 2003 and SPSS 13.5. The results of the ATP and MTT assays are reported as means ± SD. The statistical significance of differences between means was determined by an F-test (ANOVA analysis) followed by least significant difference (LSD) post hoc tests. The survival rate of the cultured cells (from the MTT assay) and the relative ATP levels are reported as percent (%) change from control. Statistical significance was determined by Pearson chi-square or linear χ²tests. For the purpose of χ²analysis, the compared groups were divided by the same number to achieve a gain of less than 100%. A P < 0.05 values (two-sided test) was accepted as statistically significant.

Cell viability

Following treatment with 2, 4, 8, 16, and 32 µM Cr(VI), L-02 hepatocyte viability decreased progressively over 12, 24, or 36 h (P < 0.05). The survival rates ranged from 88.20 to 100% after treatment with low concentrations of Cr(VI) (2, 4, and 8 µM), and the high Cr(VI) concentrations (16 and 32 µM) led to lower cell survival rates (64.22 to 83.58%). Further details from this experiment are shown in Table 1.

ATP level in L-02 hepatocytes

Following 12 h of Cr(VI) treatment, the ATP levels of L-02 hepatocytes were increased. However, after 24 h of treatment, intracellular ATP levels decreased significantly with Cr(VI) exposure, except for a slight increase in the 2- µM Cr(VI) group. Following 36 h of Cr(VI) treatment, the low ATP levels showed a slight up-regulation, while the ATP levels in the 16 and 32 µM Cr(VI) groups remained lower than control. The graphic change of relative ATP levels was described as a "V-shaped" curve (Table 2, Figure 1).

χ² analyses comparing cell survival rate and relative ATP levels

Following 12 h of Cr(VI) treatment, the χ²test showed a significant difference in ATP levels in the 8, 16, and 32 µM groups (P < 0.05). Following 24 h of Cr(VI) treatment, the χ²test showed a significant difference in ATP levels in the 4, 8, 16, and 32 µM groups (P < 0.05). Following 36 h of Cr(VI) treatment, the χ²test showed a significant difference in ATP levels in the 8 and 32 µM Cr(VI) groups (P < 0.05) (Table 3).

Figure 1.
Relative ATP levels in L-02 hepatocytes following hexavalent chromium (Cr(VI)) treatment.

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Table 1.
Effect of Cr(VI) on the viability of L-02 hepatocytes.

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Table 2.
ATP levels in L-02 hepatocytes following hexavalent chromium (Cr(VI)) treatment.

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Table 3.
χ² analysis of ATP level and cell viability of L-02 hepatocytes after treatment with hexavalent chromium (Cr(VI)) for 12, 24, and 36 h.

Cr(VI) is a common environmental pollutant that is widely used in electroplating, metal refining, printing, dyeing, tanning, and other industrial and agricultural processes, and its carcinogenicity has been documented by the International Research Agency of Cancer (IRAC) (1). In China, epidemiological studies suggested that occupational Cr(VI) exposure led to chronic damage of liver, lung, nasal mucosa, skin and other organs, and an increased risk of cancer incidence (8-10). Furthermore, the study of Cr(VI) cytotoxicity revealed that Cr(VI) could readily cross the cell membrane through nonspecific anion channels, resulting in excessive generation of reactive oxygen species. Consequently, induced oxidative stress, genetic damage, mitochondrial dysfunction, activation of apoptosis-related caspases, and mitochondrial-mediated apoptosis were observed (11-13), while chromium-induced genotoxicity and apoptosis were closely associated with Cr(VI) carcinogenesis (14).

Mitochondria are the main site of ATP synthesis, which is produced mainly through the TCA cycle and OXPHOS, named as mitochondrial aerobic respiration (7). Under normal physiological conditions, mitochondrial aerobic respiration is the main way of energy provision, while glycolysis in the cytoplasm is negligible due to the low effectiveness of ATP production (7). Interestingly, the glycolysis metabolism is activated as a compensatory means of energy production existing in many cancer cells (15-17). At present, it is unclear whether toxic chemicals cause also the activation of glycolysis in the process of toxicity. In an adverse environment of exposure to toxic chemicals, several studies have shown that the disorder of energy metabolism induced by toxic chemicals was closely associated with mitochondrial dysfunction. For example, acute ethanol exposure led to suppression of mitochondrial ATP generation and fatty acid oxidation and decreased respiration and accessibility of mitochondrial adenylate kinase in permeabilized hepatocytes (18,19). Exposure to 5 and 10 µM Pb reduced decreased cellular ATP levels in the neuronal cell lines PC-12 and SH-SY5Y, which correlated with voltage-dependent anion channel (VDAC) transcription and expression (20). VDAC is an important protein located on the outer mitochondrial membrane, which controls mitochondrial life and death (21). At present, the effect of Cr(VI) hepatotoxicity on cellular ATP levels remains ambiguous; therefore, it is important to elucidate the interference effect of Cr(VI) on ATP levels in L-02 hepatocytes.

Different doses of Cr(VI) can lead to differences in cell survival rates and cell number from control and consequently alter intracellular ATP levels. Therefore, it was interesting to scientifically evaluate the interference effect of Cr(VI) on ATP level in cells. For the first time, a chi-square test was used to analyze experimental data on the toxicity of Cr(VI), which is a novel method of analysis of the toxicological effects induced by Cr(VI). Chi-square testing was applied to compare differences between cell survival rates and ATP levels. If there were significant differences between the variables, this would indicate that the change in intracellular ATP levels is not related to changes in cellular survival rates, which could indicate that Cr(VI) interferes with ATP synthesis in L-02 hepatocytes.

The experimental results showed that Cr(VI) led to a gradual decrease of cell survival rate in L-02 hepatocytes at 12, 24, or 36 h of exposure, and the 32 µM Cr(VI) treatment was able to significantly decrease the cell survival rate. Meanwhile, the relative ATP level showed a pattern of Cr(VI) interference with ATP levels described as an increase at 12 h, a decrease at 24 h, and a new slight increase at 36 h, looking like a "V-shaped" curve. Furthermore, the results of the Pearson χ² test showed that doses of 8, 16, and 32 µM Cr(VI) induced a significant increase of ATP levels at 12 h, while 4, 8, 16, and 32 µM Cr(VI) doses induced a significant decrease of ATP at 24 h. However, after Cr(VI) treatment for 36 h, the ATP levels increassed slightly again, but the ATP levels in the 16 and 32 µM Cr(VI) groups were still lower than control. In our view, the increase of ATP level at 12 h indicated activation of mitochondrial aerobic respiration, the decreased ATP levels at 24 h indicated disruption of mitochondrial energy metabolism and, interestingly, the slight increase of ATP levels at 36 h indicated partial recovery of mitochondrial function or activated glycolysis in L-02 hepatocytes.

In summary, the χ² test enabled us to distinguish the confounding effects of decreased cell survival rate from changes in intracellular ATP content. This study is the first to demonstrate that exposure to 32 µM Cr(VI) leads to a significant increase in cellular ATP at 12 h, a decrease at 24 h, and a slight increase again at 36 h. furthermore, in future studies, the χ²statistical test could also be considered as a reference for exploring cytotoxicity or pharmacological mechanisms of other chemicals. It would be interesting to further explore the molecular mechanism of mitochondrial energy metabolism- or glycolysis-related genes by the χ²method during Cr(VI) toxicity.

Research supported by the Natural Science Foundation of China (#30972511) and the Science Innovation Project from the Educational Committee of Hunan Province (#CX2010B098).

Address for correspondence: Zhong Cai-Gao, School of Public Health, Central South University, Changsha Hunan, 410078 China. E-mail: zcg54@xysm.net

Received May 21, 2011. Accepted March 9, 2012. Available online March 23, 2012. Published June 4, 2012.

The Brazilian Journal of Medical and Biological Research is partially financed by

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¹
International Agency for Researchon Cancer. [Chromium, nickel and welding. IARC Monographs on the evaluation of the carcinogenic risks to humans]. IARC 1990; 51: 49-256.
2. Wang Wei, Liu Dong-hua, Jiang Wu-sheng, Hou Wen-qiang. [Effects of plant growth in the soil polluted by chromium]. Agro-Environ Protection 2002; 21: 257-259.
3. Zhang Dong, Zhu Li-xia, Yin Guo-xun. [Investigation on hexavalent chromium pollution of karst groundwater in Jiaozuo, China]. Earth Environ 2009; 37: 237-242.
4. Xiao-Ling Zhou, Han Ying-Shi, Ceng Qing-Shan, Wang Xiang-Pu. [Study of mouse liver tissue cytochemistry and morphology induced by acute chromium trioxide exposure]. J Toxicol 1990; 4: 92-94.
5. Zeng Ming, Wang Xiang-Pu, An Fei-Yun, Gao Ze-Xuan, Wang An. [An experimental study on the toxic liver and renal damage induced by chromium]. China Public Health 1999; 15: 869-870.
6. Xiao JW, Zhong CG, Li B. [Study of L-02 hepatocyte apoptosis induced by hexavalent chromium associated with mitochondria function damage]. Wei Sheng Yan Jiu 2006; 35: 416-418.
7. Voet D, Voet JG, Pratt CW. Fundamentals of biochemistry 2nd edn. Hoboken: John Wiley and Sons, Inc.; 2006.
8. Cai Shi-xiong, Huang Mei-yuan, Luo Yu-mei, Fu Zhen-ying, Chui Yu-zhen, Chen Fu-ming. [Survey of malignant tumor incidence in chromate salt production workers]. Chinese J Industr Hygiene Occupational Dis 1986; 4: 210-213.
9. Liao Yongling, Zhou Xu, He Chunlan, Tang Yaoyuan, Zou Lunling, Chen ZhiLian, et al. [Survey on occupational diseases of skin and nasopharynx of 233 workers exposed to chromium]. Occup Health 2001; 17: 2-4.
10. Li Deng-jiu, Qian Sheng-feng, Li Liang, Guo Ping, Wang Xiao-fang. [Health survey of chromate salt production workers]. China Occup Safety Health Manag System Certification 2001; 21: 37-39.
11. Kasprzak KS. Oxidative DNA and protein damage in metal-induced toxicity and carcinogenesis. Free Radic Biol Med 2002; 32: 958-967.
12. Valko M, Rhodes CJ, Moncol J, Izakovic M, Mazur M. Free radicals, metals and antioxidants in oxidative stress-induced cancer. Chem Biol Interact 2006; 160: 1-40.
13. Son YO, Hitron JA, Wang X, Chang Q, Pan J, Zhang Z, et al. Cr(VI) induces mitochondrial-mediated and caspase-dependent apoptosis through reactive oxygen species-mediated p53 activation in JB6 Cl41 cells. Toxicol Appl Pharmacol 2010; 245: 226-235.
14. Singh J, Carlisle DL, Pritchard DE, Patierno SR. Chromium-induced genotoxicity and apoptosis: relationship to chromium carcinogenesis (review). Oncol Rep 1998; 5: 1307-1318.
15. Gatenby RA, Gillies RJ. Why do cancers have high aerobic glycolysis? Nat Rev Cancer 2004; 4: 891-899.
16. Elstrom RL, Bauer DE, Buzzai M, Karnauskas R, Harris MH, Plas DR, et al. Akt stimulates aerobic glycolysis in cancer cells. Cancer Res 2004; 64: 3892-3899.
17. Shi DY, Xie FZ, Zhai C, Stern JS, Liu Y, Liu SL. The role of cellular oxidative stress in regulating glycolysis energy metabolism in hepatoma cells. Mol Cancer 2009; 8: 32.
18. Hoek JB, Cahill A, Pastorino JG. Alcohol and mitochondria: a dysfunctional relationship. Gastroenterology 2002; 122: 2049-2063.
19. Holmuhamedov E, Lemasters JJ. Ethanol exposure decreases mitochondrial outer membrane permeability in cultured rat hepatocytes. Arch Biochem Biophys 2009; 481: 226-233.
20. Prins JM, Park S, Lurie DI. Decreased expression of the voltage-dependent anion channel in differentiated PC-12 and SH-SY5Y cells following low-level Pb exposure. Toxicol Sci 2010; 113: 169-176.
21. Abu-Hamad S, Sivan S, Shoshan-Barmatz V. The expression level of the voltage-dependent anion channel controls life and death of the cell. Proc Natl Acad Sci U S A 2006; 103: 5787-5792.

Correspondence and Footnotes

Publication Dates

Publication in this collection
23 July 2012
Date of issue
June 2012

History

Received
21 May 2011
Accepted
09 Mar 2012

This work is licensed under a Creative Commons Attribution 4.0 International License.

[1] ¹
International Agency for Researchon Cancer. [Chromium, nickel and welding. IARC Monographs on the evaluation of the carcinogenic risks to humans]. IARC 1990; 51: 49-256.

[2] 2. Wang Wei, Liu Dong-hua, Jiang Wu-sheng, Hou Wen-qiang. [Effects of plant growth in the soil polluted by chromium]. Agro-Environ Protection 2002; 21: 257-259.

[3] 3. Zhang Dong, Zhu Li-xia, Yin Guo-xun. [Investigation on hexavalent chromium pollution of karst groundwater in Jiaozuo, China]. Earth Environ 2009; 37: 237-242.

[4] 4. Xiao-Ling Zhou, Han Ying-Shi, Ceng Qing-Shan, Wang Xiang-Pu. [Study of mouse liver tissue cytochemistry and morphology induced by acute chromium trioxide exposure]. J Toxicol 1990; 4: 92-94.

[5] 5. Zeng Ming, Wang Xiang-Pu, An Fei-Yun, Gao Ze-Xuan, Wang An. [An experimental study on the toxic liver and renal damage induced by chromium]. China Public Health 1999; 15: 869-870.

[6] 6. Xiao JW, Zhong CG, Li B. [Study of L-02 hepatocyte apoptosis induced by hexavalent chromium associated with mitochondria function damage]. Wei Sheng Yan Jiu 2006; 35: 416-418.

[7] 7. Voet D, Voet JG, Pratt CW. Fundamentals of biochemistry 2nd edn. Hoboken: John Wiley and Sons, Inc.; 2006.

[8] 8. Cai Shi-xiong, Huang Mei-yuan, Luo Yu-mei, Fu Zhen-ying, Chui Yu-zhen, Chen Fu-ming. [Survey of malignant tumor incidence in chromate salt production workers]. Chinese J Industr Hygiene Occupational Dis 1986; 4: 210-213.

[9] 9. Liao Yongling, Zhou Xu, He Chunlan, Tang Yaoyuan, Zou Lunling, Chen ZhiLian, et al. [Survey on occupational diseases of skin and nasopharynx of 233 workers exposed to chromium]. Occup Health 2001; 17: 2-4.

[10] 10. Li Deng-jiu, Qian Sheng-feng, Li Liang, Guo Ping, Wang Xiao-fang. [Health survey of chromate salt production workers]. China Occup Safety Health Manag System Certification 2001; 21: 37-39.

[11] 11. Kasprzak KS. Oxidative DNA and protein damage in metal-induced toxicity and carcinogenesis. Free Radic Biol Med 2002; 32: 958-967.

[12] 12. Valko M, Rhodes CJ, Moncol J, Izakovic M, Mazur M. Free radicals, metals and antioxidants in oxidative stress-induced cancer. Chem Biol Interact 2006; 160: 1-40.

[13] 13. Son YO, Hitron JA, Wang X, Chang Q, Pan J, Zhang Z, et al. Cr(VI) induces mitochondrial-mediated and caspase-dependent apoptosis through reactive oxygen species-mediated p53 activation in JB6 Cl41 cells. Toxicol Appl Pharmacol 2010; 245: 226-235.

[14] 14. Singh J, Carlisle DL, Pritchard DE, Patierno SR. Chromium-induced genotoxicity and apoptosis: relationship to chromium carcinogenesis (review). Oncol Rep 1998; 5: 1307-1318.

[15] 15. Gatenby RA, Gillies RJ. Why do cancers have high aerobic glycolysis? Nat Rev Cancer 2004; 4: 891-899.

[16] 16. Elstrom RL, Bauer DE, Buzzai M, Karnauskas R, Harris MH, Plas DR, et al. Akt stimulates aerobic glycolysis in cancer cells. Cancer Res 2004; 64: 3892-3899.

[17] 17. Shi DY, Xie FZ, Zhai C, Stern JS, Liu Y, Liu SL. The role of cellular oxidative stress in regulating glycolysis energy metabolism in hepatoma cells. Mol Cancer 2009; 8: 32.

[18] 18. Hoek JB, Cahill A, Pastorino JG. Alcohol and mitochondria: a dysfunctional relationship. Gastroenterology 2002; 122: 2049-2063.

[19] 19. Holmuhamedov E, Lemasters JJ. Ethanol exposure decreases mitochondrial outer membrane permeability in cultured rat hepatocytes. Arch Biochem Biophys 2009; 481: 226-233.

[20] 20. Prins JM, Park S, Lurie DI. Decreased expression of the voltage-dependent anion channel in differentiated PC-12 and SH-SY5Y cells following low-level Pb exposure. Toxicol Sci 2010; 113: 169-176.

[21] 21. Abu-Hamad S, Sivan S, Shoshan-Barmatz V. The expression level of the voltage-dependent anion channel controls life and death of the cell. Proc Natl Acad Sci U S A 2006; 103: 5787-5792.

Brasil

Brasil

Chi-square analysis of the reduction of ATP levels in L-02 hepatocytes by hexavalent chromium

Abstract

Abstract

Introduction

Material and Methods

Results

Discussion

Acknowledgments

Correspondence and Footnotes

Publication Dates

History