Protective potential of glutathione peroxidase‐1 gene against cocaine‐induced acute hepatotoxic consequences in mice

Nhu, Huynh; Jung, Tae Woo; Kim, Dae-Joong; Sharma, Garima; Sharma, Naveen; Shin, Eun‐Joo; Jang, Choon‐Gon; Nah, Seung-Yeol; Lee, Sung Hoon; Chung, Yoon Hee; Lei, Xin Gen; Jeong, Ji Hoon; Kim, Hyoung‐Chun

doi:10.1002/jat.3666

Cited by 8 publications

(5 citation statements)

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“…There were significant increases in SOD activity, ROS, protein carbonylation and lipid peroxidation, cleaved caspase-3 expression and intramitochondrial calcium, accompanied by a significant decrease in GPx. Examples of histological changes include hemorrhage, congestion, periventricular necrosis and hydropic degeneration [124]. Notably, enhanced expression of GPx protected the animals from having such severe outcomes, as did the depletion of p53 [125].…”

Section: Livermentioning

confidence: 98%

Cocaine: An Updated Overview on Chemistry, Detection, Biokinetics, and Pharmacotoxicological Aspects including Abuse Pattern

Bravo

Faria

Brito-da-Costa

et al. 2022

Toxins

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Cocaine is one of the most consumed stimulants throughout the world, as official sources report. It is a naturally occurring sympathomimetic tropane alkaloid derived from the leaves of Erythroxylon coca, which has been used by South American locals for millennia. Cocaine can usually be found in two forms, cocaine hydrochloride, a white powder, or ‘crack’ cocaine, the free base. While the first is commonly administered by insufflation (‘snorting’) or intravenously, the second is adapted for inhalation (smoking). Cocaine can exert local anaesthetic action by inhibiting voltage-gated sodium channels, thus halting electrical impulse propagation; cocaine also impacts neurotransmission by hindering monoamine reuptake, particularly dopamine, from the synaptic cleft. The excess of available dopamine for postsynaptic activation mediates the pleasurable effects reported by users and contributes to the addictive potential and toxic effects of the drug. Cocaine is metabolised (mostly hepatically) into two main metabolites, ecgonine methyl ester and benzoylecgonine. Other metabolites include, for example, norcocaine and cocaethylene, both displaying pharmacological action, and the last one constituting a biomarker for co-consumption of cocaine with alcohol. This review provides a brief overview of cocaine’s prevalence and patterns of use, its physical-chemical properties and methods for analysis, pharmacokinetics, pharmacodynamics, and multi-level toxicity.

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Section: Livermentioning

confidence: 98%

Cocaine: An Updated Overview on Chemistry, Detection, Biokinetics, and Pharmacotoxicological Aspects including Abuse Pattern

Bravo

Faria

Brito-da-Costa

et al. 2022

Toxins

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show abstract

“…Although the detailed cell death signaling mechanisms are unknown, one recent report showed that cocaine toxicity was attenuated in p53-knockout (p53-KO) mice, suggesting the involvement of the p53-mediated apoptosis pathway [ 295 ]. A recent study showed that cocaine caused mitochondrial dysfunction and acute liver injury in WT mice, and hepatotoxicity was prominently observed in Gpx-1 -KO mice but protected in Gpx1-overexpressing transgenic mice [ 66 ]. Based on the importance of PTMs in mitochondrial dysfunction and hepatocyte cell death in DILI, ALD, and MASLD models, the contributing roles of various PTMs in cocaine-mediated mitochondrial dysfunction and hepatotoxicity are expected, although this needs to be verified by future research.…”

Section: The Causal Roles Of Oxidative Stress Ptms Mitochondrial Dysf...mentioning

confidence: 99%

“…The proteins involved in promoting various PTMs exist in several subcellular organelles, including the cytoplasm [ 39 ], ER [ 40 , 41 ], mitochondria [ 42 ], and nucleus [ 43 ]; PTMs may also be observed in the proteomes of the liver [ 37 , 44 – 47 ], gut [ 7 ], and other peripheral tissues [ 29 ]. PTMs found in liver diseases include protein acetylation [ 37 , 42 , 48 ], nitration [ 10 , 26 , 37 , 49 – 53 ], S -nitrosylation [ 49 , 54 , 55 ], oxidation [ 37 ], phosphorylation [ 26 , 56 , 57 ], succinylation [ 58 ], ADP-ribosylation [ 44 ], ubiquitination [ 37 , 59 ], SUMOylation [ 60 – 65 ], carbonylation [ 66 – 68 ], S -palmitoylation [ 45 – 47 , 69 ], glycosylation [ 7 , 37 , 70 , 71 ], protein adducts of aldehyde (i.e., acetaldehydes) [ 9 , 72 ], lipid peroxidation products (LPOs), and advanced glycation end products (AGEs) [ 6 , 66 , 74 – 79 ]. Several studies detail that specific PTMs correlate with exposures to excessive alcohol [ 80 , 81 ], CCl 4 [ 7 , 56 ], acetaminophen (APAP) [ 53 , 82 ], 3,4-methylenedioxymethamphetamine (MDMA, Ecstasy) [ 39 ], or fructose [ 51 ].…”

Section: Introductionmentioning

confidence: 99%

“…Several studies detail that specific PTMs correlate with exposures to excessive alcohol [ 80 , 81 ], CCl 4 [ 7 , 56 ], acetaminophen (APAP) [ 53 , 82 ], 3,4-methylenedioxymethamphetamine (MDMA, Ecstasy) [ 39 ], or fructose [ 51 ]. In these cases, PTMs accumulate in cells and contribute significantly to fat accumulation [ 54 ], hepatocyte apoptosis, inflammation, fibrosis [ 51 ], and cirrhosis [ 37 ], by altering signaling pathways affiliated with liver disease progression [ 43 , 66 , 67 ] and by targeting proteins for ubiquitin-mediated proteolysis [ 59 ]. Overall, PTMs are one of the various ROS-mediated changes that occur on cellular and translational levels [ 29 ] to, directly and indirectly, contribute to alcohol-mediated hepatic injuries [ 12 , 83 , 84 ].…”

Section: Introductionmentioning

confidence: 99%

“…Typically, in the second line of defense, mitochondria trigger mitophagy to restore redox homeostasis and retain the function of other mitochondria and organelles for cellular activities [ 101 ]. However, these natural lines of defense in mitochondria can be altered after excessive consumption of or exposure to alcohol (ethanol) [ 85 , 94 ], drugs [ 66 , 102 , 103 ], viruses [ 104 ], and some nutrients, including fructose [ 105 ]. Specifically, these exposures can alter mitochondrial redox homeostasis and oxidatively damage DNA [ 106 , 107 ], RNA [ 106 ], lipids, and proteins, through PTMs [ 8 , 26 , 48 , 70 , 108 , 109 ], causing inactivation of their functions and signaling pathways, leading to mitochondrial dysfunction [ 26 , 53 , 68 , 83 ], death of hepatocytes, and liver damage [ 17 , 110 ] or age-related conditions [ 91 , 111 – 113 ].…”

Section: Introductionmentioning

confidence: 99%

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Contributing roles of mitochondrial dysfunction and hepatocyte apoptosis in liver diseases through oxidative stress, post-translational modifications, inflammation, and intestinal barrier dysfunction

LeFort,

Rungratanawanich,

Song

2024

Cell. Mol. Life Sci.

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This review provides an update on recent findings from basic, translational, and clinical studies on the molecular mechanisms of mitochondrial dysfunction and apoptosis of hepatocytes in multiple liver diseases, including but not limited to alcohol-associated liver disease (ALD), metabolic dysfunction-associated steatotic liver disease (MASLD), and drug-induced liver injury (DILI). While the ethanol-inducible cytochrome P450-2E1 (CYP2E1) is mainly responsible for oxidizing binge alcohol via the microsomal ethanol oxidizing system, it is also responsible for metabolizing many xenobiotics, including pollutants, chemicals, drugs, and specific diets abundant in n-6 fatty acids, into toxic metabolites in many organs, including the liver, causing pathological insults through organelles such as mitochondria and endoplasmic reticula. Oxidative imbalances (oxidative stress) in mitochondria promote the covalent modifications of lipids, proteins, and nucleic acids through enzymatic and non-enzymatic mechanisms. Excessive changes stimulate various post-translational modifications (PTMs) of mitochondrial proteins, transcription factors, and histones. Increased PTMs of mitochondrial proteins inactivate many enzymes involved in the reduction of oxidative species, fatty acid metabolism, and mitophagy pathways, leading to mitochondrial dysfunction, energy depletion, and apoptosis. Unique from other organelles, mitochondria control many signaling cascades involved in bioenergetics (fat metabolism), inflammation, and apoptosis/necrosis of hepatocytes. When mitochondrial homeostasis is shifted, these pathways become altered or shut down, likely contributing to the death of hepatocytes with activation of inflammation and hepatic stellate cells, causing liver fibrosis and cirrhosis. This review will encapsulate how mitochondrial dysfunction contributes to hepatocyte apoptosis in several types of liver diseases in order to provide recommendations for targeted therapeutics.

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Glutathione peroxidase-1 knockout potentiates behavioral sensitization induced by cocaine in mice via σ-1 receptor-mediated ERK signaling: A comparison with the case of glutathione peroxidase-1 overexpressing transgenic mice

Nhu

Pham

Chung

et al. 2020

Brain Research Bulletin

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Protective potential of glutathione peroxidase‐1 gene against cocaine‐induced acute hepatotoxic consequences in mice

Cited by 8 publications

References 89 publications

Cocaine: An Updated Overview on Chemistry, Detection, Biokinetics, and Pharmacotoxicological Aspects including Abuse Pattern

Cocaine: An Updated Overview on Chemistry, Detection, Biokinetics, and Pharmacotoxicological Aspects including Abuse Pattern

Contributing roles of mitochondrial dysfunction and hepatocyte apoptosis in liver diseases through oxidative stress, post-translational modifications, inflammation, and intestinal barrier dysfunction

Glutathione peroxidase-1 knockout potentiates behavioral sensitization induced by cocaine in mice via σ-1 receptor-mediated ERK signaling: A comparison with the case of glutathione peroxidase-1 overexpressing transgenic mice

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