Your search keyword '"Gomez-Quiroz, Luis E."' showing total 8 results

1. Loss of c-Met signaling sensitizes hepatocytes to lipotoxicity and induces cholestatic liver damage by aggravating oxidative stress.

Author

Gomez-Quiroz LE, Seo D, Lee YH, Kitade M, Gaiser T, Gillen M, Lee SB, Gutierrez-Ruiz MC, Conner EA, Factor VM, Thorgeirsson SS, and Marquardt JU

Subjects

Animals, Cell Survival drug effects, Cell Survival genetics, Cholesterol, Dietary toxicity, Glutathione metabolism, Lipid Metabolism drug effects, Lipid Peroxidation, Liver Function Tests, Mice, Mice, Knockout, Signal Transduction, Cholestasis, Intrahepatic chemically induced, Cholestasis, Intrahepatic metabolism, Hepatocytes drug effects, Lipids toxicity, Oxidative Stress drug effects, Proto-Oncogene Proteins c-met genetics, Proto-Oncogene Proteins c-met metabolism

Abstract

Recent studies confirmed a critical importance of c-Met signaling for liver regeneration by modulating redox balance. Here we used liver-specific conditional knockout mice (MetKO) and a nutritional model of hepatic steatosis to address the role of c-Met in cholesterol-mediated liver toxicity. Liver injury was assessed by histopathology and plasma enzymes levels. Global transcriptomic changes were examined by gene expression microarray, and key molecules involved in liver damage and lipid homeostasis were evaluated by Western blotting. Loss of c-Met signaling amplified the extent of liver injury in MetKO mice fed with high-cholesterol diet for 30days as evidenced by upregulation of liver enzymes and increased synthesis of total bile acids, aggravated inflammatory response and enhanced intrahepatic lipid deposition. Global transcriptomic changes confirmed the enrichment of networks involved in steatosis and cholestasis. In addition, signaling pathways related to glutathione and lipid metabolism, oxidative stress and mitochondria dysfunction were significantly affected by the loss of c-Met function. Mechanistically, exacerbation of oxidative stress in MetKO livers was corroborated by increased lipid and protein oxidation. Western blot analysis further revealed suppression of Erk, NF-kB and Nrf2 survival pathways and downstream target genes (e.g. cyclin D1, SOD1, gamma-GCS), as well as up-regulation of proapoptotic signaling (e.g. p53, caspase 3). Consistent with the observed steatotic and cholestatic phenotype, nuclear receptors RAR, RXR showed increased activation while expression levels of CAR, FXR and PPAR-alpha were decreased in MetKO. Collectively, our data provide evidence for the critical involvement of c-Met signaling in cholesterol and bile acids toxicity., (Copyright © 2016. Published by Elsevier Ireland Ltd.)

Published

2016

2. A noncanonical NF-κB pathway through the p50 subunit regulates Bcl-2 overexpression during an oxidative-conditioning hormesis response.

Author

Luna-López A, González-Puertos VY, Romero-Ontiveros J, Ventura-Gallegos JL, Zentella A, Gomez-Quiroz LE, and Königsberg M

Subjects

Animals, Cell Line, Cell Survival drug effects, Gene Expression Regulation drug effects, Hormesis, Humans, Mice, NF-kappa B genetics, NF-kappa B p50 Subunit genetics, Proto-Oncogene Proteins c-bcl-2, Signal Transduction drug effects, Hydrogen Peroxide pharmacology, NF-kappa B metabolism, NF-kappa B p50 Subunit metabolism, Oxidative Stress drug effects

Abstract

Cells can respond to damage and stress by activating various repair and survival pathways. One of these responses can be induced by preconditioning the cells with sublethal stress to provoke a prosurvival response that will prevent damage and death, and which is known as hormesis. Bcl-2, an antiapoptotic protein recognized by its antioxidant and prosurvival functions, has been documented to play an important role during oxidative-conditioning hormesis. Using an oxidative-hormetic model, which was previously established in the L929 cell line by subjecting the cells to a mild oxidative stress of 50 μM H₂O₂ for 9 h, we identified two different transductional mechanisms that participate in the regulation of Bcl-2 expression during the hormetic response. These mechanisms converge in activating the nuclear transcription factor NF-κB. Interestingly, the noncanonical p50 subunit of the NF-κB family is apparently the subunit that participates during the oxidative-hormetic response., (Copyright © 2013 Elsevier Inc. All rights reserved.)

Published

2013

3. Cell proliferation arrest and redox state status as part of different stages during senescence establishment in mouse fibroblasts

Author

Triana-Martínez, Francisco, López-Diazguerrero, Norma E., Maciel-Barón, Luis A., Morales-Rosales, Sandra L., Galván-Arzate, Sonia, Fernandez-Perrino, Francisco J., Zentella, Alejandro, Pérez, Viviana I., Gomez-Quiroz, Luis E., and Königsberg, Mina

Published

2014

4. Mechanism of cholangiocellular damage and repair during cholestasis.

Author

Salas-Silva, Soraya, Simoni-Nieves, Arturo, Chávez-Rodríguez, Lisette, Gutiérrez-Ruiz, María Concepción, Bucio, Leticia, and Gomez Quiroz, Luis E.

Subjects

CHOLESTASIS, BILIARY tract, CHOLANGITIS, BILE ducts

Abstract

The mechanism of damage of the biliary epithelium remains partially unexplored. However, recently many works have offered new evidence regarding the cholangiocytes' damage process, which is the main target in a broad spectrum of pathologies ranging from acute cholestasis, cholangiopathies to cholangiocarcinoma. This is encouraging since some works addressed this epithelium's relevance in health and disease until a few years ago. The biliary tree in the liver, comprised of cholangiocytes, is a pipeline for bile flow and regulates key hepatic processes such as proliferation, regeneration, immune response, and signaling. This review aimed to compile the most recent advances on the mechanisms of cholangiocellular damage during cholestasis, which, although it is present in many cholangiopathies, is not necessarily a common or conserved process in all of them, having a relevant role cAMP and PKA during obstructive cholestasis, as well as Ca2+-dependent PKC in functional cholestasis. Cholangiocellular damage could vary according to the type of cholestasis, the aggressor, or the bile ducts' location where it develops and what kind of damage can favor cholangiocellular carcinoma development. [ABSTRACT FROM AUTHOR]

Published

2021

5. Cholesterol burden in the liver induces mitochondrial dynamic changes and resistance to apoptosis.

Author

Domínguez‐Pérez, Mayra, Simoni‐Nieves, Arturo, Rosales, Patricia, Nuño‐Lámbarri, Natalia, Rosas‐Lemus, Mónica, Souza, Verónica, Miranda, Roxana U., Bucio, Leticia, Uribe Carvajal, Salvador, Marquardt, Jens U., Seo, Daekwan, Gomez‐Quiroz, Luis E., and Gutiérrez‐Ruiz, María Concepción

Subjects

CHOLESTEROL, APOPTOSIS, FATTY liver, HEPATIC fibrosis, HYPERCHOLESTEREMIA, CARCINOGENESIS

Abstract

Non‐alcoholic fatty liver disease (NAFLD) encompasses a broad spectrum of histopathological changes ranging from non‐inflammatory intracellular fat deposition to non‐alcoholic steatohepatitis (NASH), which may progress into hepatic fibrosis, cirrhosis, or hepatocellular carcinoma. Recent data suggest that impaired hepatic cholesterol homeostasis and its accumulation are relevant to the pathogenesis of NAFLD/NASH. Despite a vital physiological function of cholesterol, mitochondrial dysfunction is an important consequence of dietary‐induced hypercholesterolemia and was, subsequently, linked to many pathophysiological conditions. The aim in the current study was to evaluate the morphological and molecular changes of cholesterol overload in mouse liver and particularly, in mitochondria, induced by a high‐cholesterol (HC) diet for one month. Histopathological studies revealed microvesicular hepatic steatosis and significantly elevated levels of liver cholesterol and triglycerides leading to impaired liver synthesis. Further, high levels of oxidative stress could be determined in liver tissue as well as primary hepatocyte culture. Transcriptomic changes induced by the HC diet involved disruption in key pathways related to cell death and oxidative stress as well as upregulation of genes related to glutathione homeostasis. Impaired liver function could be associated with a decrease in mitochondrial membrane potential and ATP content and significant alterations in mitochondrial dynamics. We demonstrate that cholesterol overload in the liver leads to mitochondrial changes which may render damaged hepatocytes proliferative and resistant to cell death whereby perpetuating liver damage. A high cholesterol diet indices liver damage by impairing mitochondrial function Cholesterol cellular overload induces oxidative stress and apoptosis resistance. [ABSTRACT FROM AUTHOR]

Published

2019

6. Ginkgo biloba induces different gene expression signatures and oncogenic pathways in malignant and non-malignant cells of the liver.

Author

Czauderna, Carolin, Palestino-Dominguez, Mayrel, Castven, Darko, Becker, Diana, Zanon-Rodriguez, Luis, Hajduk, Jovana, Mahn, Friederike L., Herr, Monika, Strand, Dennis, Strand, Susanne, Heilmann-Heimbach, Stefanie, Gomez-Quiroz, Luis E., Wörns, Marcus A., Galle, Peter R., and Marquardt, Jens U.

Subjects

GENE expression, GINKGO, ONCOGENIC proteins, APOPTOSIS, OXIDATIVE stress

Abstract

Ginkgo biloba (EGb761) is a widely used botanical drug. Several reports indicate that EGb761 confers preventive as well as anti-tumorigenic properties in a variety of tumors, including hepatocellular carcinoma (HCC). We here evaluate functional effects and molecular alterations induced by EGb761 in hepatoma cells and non-malignant hepatocytes. Hepatoma cell lines, primary human HCC cells and immortalized human hepatocytes (IH) were exposed to various concentrations (0–1000 μg/ml) of EGb761. Apoptosis and proliferation were evaluated after 72h of EGb761 exposure. Response to oxidative stress, tumorigenic properties and molecular changes were further investigated. While anti-oxidant effects were detected in all cell lines, EGb761 promoted anti-proliferative and pro-apoptotic effects mainly in hepatoma cells. Consistently, EGb761 treatment caused a significant reduction in colony and sphere forming ability in hepatoma cells and no mentionable changes in IH. Transcriptomic changes involved oxidative stress response as well as key oncogenic pathways resembling Nrf2- and mTOR signaling pathway. Taken together, EGb761 induces differential effects in non-transformed and cancer cells. While treatment confers protective effects in non-malignant cells, EGb761 significantly impairs tumorigenic properties in cancer cells by affecting key oncogenic pathways. Results provide the rational for clinical testing of EGb761 in preventive and therapeutic strategies in human liver diseases. [ABSTRACT FROM AUTHOR]

Published

2018

7. The mechanism of the cadmium-induced toxicity and cellular response in the liver.

Author

Souza-Arroyo, Verónica, Fabián, Jessica J., Bucio-Ortiz, Leticia, Miranda-Labra, Roxana U., Gomez-Quiroz, Luis E., and Gutiérrez-Ruiz, María Concepción

Subjects

*CADMIUM, *LIVER, *HUMAN body, *POISONS, *OXIDATIVE stress, *HEPATOCELLULAR carcinoma, *LIVER cells

Abstract

Cadmium is a toxic element to which man can be exposed at work or in the environment. Cd's most salient toxicological property is its exceptionally long half-life in the human body. Once absorbed, Cd accumulates in the human body, particularly in the liver. The cellular actions of Cd are extensively documented, but the molecular mechanisms underlying these actions are still not resolved. The liver manages the cadmium to eliminate it by a diverse mechanism of action. Still, many cellular and physiological responses are executed in the task, leading to worse liver damage, ranging from steatosis, steatohepatitis, and eventually hepatocellular carcinoma. The progression of cadmium-induced liver damage is complex, and it is well-known the cellular response that depends on the time in which the metal is present, ranging from oxidative stress, apoptosis, adipogenesis, and failures in autophagy. In the present work, we aim to present a review of the current knowledge of cadmium toxicity and the cellular response in the liver. [ABSTRACT FROM AUTHOR]

Published

2022

8. Hepatocyte growth factor reverses cholemic nephropathy associated with α-naphthylisothiocyanate-induced cholestasis in mice.

Author

Salas-Silva, Soraya, López-Ramirez, Jocelyn, Barrera-Chimal, Jonatan, Lazzarini-Lechuga, Roberto, Simoni-Nieves, Arturo, Souza, Verónica, Miranda-Labra, Roxana U., Masso, Felipe, Roma, Marcelo G., Gutiérrez-Ruiz, María Concepción, Bucio-Ortiz, Leticia, and Gomez-Quiroz, Luis E.

Subjects

*HEPATOCYTE growth factor, *CHOLESTASIS, *KIDNEY diseases, *BILE salts, *ENTEROHEPATIC circulation, *KIDNEY physiology

Abstract

Hepatocyte growth factor (HGF) has been proved to protect the liver against α-naphthylisothiocyanate (ANIT)-induced cholestasis by acting as an antioxidant agent and redirecting toxic biliary solutes towards blood for urinary excretion. However, this may represent an additional potential risk for kidney integrity, which is already compromised by the cholestatic process itself (cholemic nephropathy). Therefore, in the present work, we studied the renal damage caused by ANIT-induced cholestasis and whether it is aggravated or, on the contrary, counteracted by HGF; if the latter holds, the involvement of its antioxidant properties will be ascertained. ANIT-induced cholestatic deleterious renal effects were corroborated by the presence of urine bile salts, impairment of renal function, and the alterations of renal damage markers, such as HSP72, creatinine clearance, and albuminuria. HGF fully reverted all these, and the cast formation in the tubules was significantly decreased. These findings were associated with the control of renal oxidative stress. In summary, despite HGF enhancing the overload of potentially harmful biliary constituents that the kidney should remove from the bloodstream as an alternative depuration organ in cholestasis, it simultaneously protects the kidney from this damage by counteracting the prooxidant effects resulting from this harmful exposure. [Display omitted] • ANIT induces cholestasis and cholemic nephropathy. • ANIT increases oxidative stress in the kidneys. • HGF protects the kidneys from ANIT toxicity. • HGF induces an antioxidant effect. [ABSTRACT FROM AUTHOR]

Published

2022