Your search keyword '"Best, L G"' showing total 9 results

1. Arsenic causes distinct gene expression changes in macrophages polarized in vitro with either interferon-γ or interleukin-4.

Author

Makhani, Kiran, Chiavatti, Chris, Silva, Luis Fernando Negro, Lemaire, Maryse, Bolt, Alicia M, Jay, Nicolas De, Giles, Braeden, Zengin, Ayse Nazli, Kleinman, Claudia L, and Mann, Koren K

Subjects

GENE expression, ARSENIC, MACROPHAGES, BONE marrow, INTERLEUKIN-4, ATHEROSCLEROTIC plaque, APOLIPOPROTEIN E

Abstract

Arsenic exposure is correlated with atherosclerosis in epidemiological studies and in animal models. We have previously shown that arsenic exposure enhanced the atherosclerotic plaque size, increased the plaque lipid content, and decreased the plaque smooth muscle cell and collagen contents in the apolipoprotein E knockout (apoE−/−) mice. However, the percentage of plaque-resident macrophages, the primary drivers of atherosclerosis remained unchanged. Therefore, we hypothesized that although arsenic does not change the quantity of macrophages, it alters the macrophage transcriptome towards a proatherogenic state. To test this hypothesis, we used bone marrow-derived macrophages, polarized them to either interferon-γ (IFN-ɣ) stimulated, proinflammatory or interleukin-4 (IL-4) stimulated, alternatively activated macrophages in the presence or absence of 0.67 µM (50 ppb) arsenic and performed RNA sequencing. Arsenic exposure altered the gene expression of the macrophages in a subtype-specific manner. Most differentially expressed genes (88%) were altered specifically in either IFN-ɣ- or IL-4-stimulated macrophages, whereas in the remaining 12% of genes that changed in both cell types, did so in opposite directions. In IL-4-stimulated macrophages, arsenic significantly downregulated the genes involved in cholesterol biosynthesis and the chemokines CCL17/CCL22, whereas in IFN-ɣ-stimulated macrophages, the genes associated with the liver X receptor (LXR) pathway were downregulated by arsenic. Using a bone marrow transplant experiment, we validated that the deletion of LXRα from the hematopoietic compartment rescued arsenic-enhanced atherosclerosis in the apoE−/− mouse model. Together, these data suggest that arsenic modulates subtype-specific transcriptomic changes in macrophages and further emphasize the need to define macrophage heterogeneity in atherosclerotic plaques in order to evaluate the proatherogenic role of arsenic. [ABSTRACT FROM AUTHOR]

Published

2023

2. Arsenic May Act as a Pro-Metastatic Carcinogen Through Promoting Tumor Cell-Induced Platelet Aggregation.

Author

Kim, Keunyoung, Heo, Yoon-Kyung, Chun, Soyoung, Kim, Chang-Hwan, Bian, Yiying, Bae, Ok-Nam, Lee, Moo-Yeol, Lim, Kyung-Min, and Chung, Jin-Ho

Subjects

CARCINOGENS, BLOOD platelets, CARCINOGENESIS, CANCER cells, THROMBIN

Abstract

Arsenic-associated carcinogenesis and related mortality are a major public health concern worldwide; however, the underlying mechanism of action remains unclear. Here, we demonstrated that arsenic promotes tumor metastasis by stimulating tumor cell-platelet aggregation (TCPA), which can ultimately increase cancer-related mortality. In freshly isolated human platelets in vitro, arsenic potentiated TCPA prompted by diverse cancer cell lines, which was attributable to increased platelet reactivity to TCPA with respect to thrombin generation and P-selectin, GPIIb/IIIa expression. Consistently, the co-existence of platelets and arsenic significantly enhanced tumor cell adhesion, extravasation and invasion along with increased metastasis-related markers like metallo-matrix proteinase-2 and -9 in vitro, which was attenuated by platelet activation blockers. Importantly, the exposure to arsenic-contaminated drinking water (2 ppm, 3 weeks) in mice in vivo significantly increased the metastasis of intravenously injected melanoma cells into lung. Furthermore, the exposure to arsenic-contaminated drinking water significantly reduced the survival of melanoma cell-injected mice, which was attenuated by the pretreatment of platelet-activation blockers; aspirin and eptifibatide. All these results provide an important clue to understand the mechanism underlying arsenic-associated cancer mortality and its prevention. [ABSTRACT FROM AUTHOR]

Published

2019

3. Using the Apolipoprotein E Knock-Out Mouse Model to Define Atherosclerotic Plaque Changes Induced by Low Dose Arsenic.

Author

Makhani, Kiran, Chiavatti, Christopher, Plourde, Dany, Silva, Luis Fernando Negro, Lemaire, Maryse, Lemarié, Catherine A, Lehoux, Stephanie, and Mann, Koren K

Subjects

APOLIPOPROTEIN E, KNOCK-out reactions, ATHEROSCLEROTIC plaque, ARSENIC poisoning, HOMEOSTASIS

Abstract

Arsenic exposure increases the risk of atherosclerosis, the gradual occlusion of the large arteries with fibro-fatty plaque. While epidemiologic data provide convincing evidence this is true at higher exposures, it is unclear whether this may occur at low arsenic exposures, near the maximum contaminant level of 10 ppb. We have previously shown that 200 ppb arsenite in the drinking water increased the atherosclerosis in apolipoprotein E knock-out (apoE−/−) mice after 13 weeks, but the effects of lower concentrations were unknown. Therefore, here, we analyzed the effects of oral exposure to arsenite from 10 to 200 ppb after 13 weeks. Importantly, we found that even at the lowest concentration of arsenite, there was a significant increase in atherosclerotic plaque size. In our previous studies, we found that arsenite exposure resulted in decreased smooth muscle cells (SMCs) and collagen within the plaque. This change is indicative of a less stable phenotype that could increase the risk of rupture and subsequently, myocardial infarct or stroke in humans. In addition, we observed that lipid increased within the plaque without concomitant increase in macrophage content, suggesting that the macrophages were retaining more lipid intracellularly. We also assessed these plaque components in apoE−/− mice exposed to 10–200 ppb arsenite. Interestingly, we observed that macrophage lipid accumulation occurred at lower concentrations than the decreased SMC/collagen content. Together these data suggest that in the apoE−/− model, low arsenite concentrations are pro-atherogenic and that macrophage lipid homeostasis is more sensitive to arsenite-induced perturbation than the SMCs. [ABSTRACT FROM AUTHOR]

Published

2018

4. Cellular and Molecular Effects of Prolonged Low-Level Sodium Arsenite Exposure on Human Hepatic HepaRG Cells.

Author

Dreval, Kostiantyn, Tryndyak, Volodymyr, Kindrat, Iryna, Twaddle, Nathan C, Orisakwe, Orish Ebere, Mudalige, Thilak K, Beland, Frederick A, Doerge, Daniel R, and Pogribny, Igor P

Subjects

SODIUM arsenite, LIVER cancer, DOWNREGULATION, CELL proliferation, CARCINOGENESIS

Abstract

Inorganic arsenic is a human carcinogen associated with several types of cancers, including liver cancer. Inorganic arsenic has been postulated to target stemcells, causing their oncogenic transformation. This is proposed to be one of the key events in arsenic-associated carcinogenesis; however, the underlying mechanisms for this process remain largely unknown. To address this question, human hepatic HepaRG cells, at progenitor and differentiated states, were continuously treated with a noncytotoxic concentration of 1 μM sodiumarsenite (NaAsO2). The HepaRG cells demonstrated active intracellular arsenite metabolism that shared important characteristic with primary human hepatocytes. Treatment of proliferating progenitor-like HepaRG cells with NaAsO2 inhibited their differentiation intomature hepatocyte-like cells, up-regulated genes involved in cell growth, proliferation, and survival, and down-regulated genes involved in cell death. In contrast, treatment of differentiated hepatocyte-like HepaRG cells with NaAsO2 resulted in enhanced cell death of mature hepatocyte-like cells, overexpression of cell death-related genes, and down-regulation of genes in the cell proliferation pathway, while biliary-like cells remained largely unaffected. Mechanistically, the cytotoxic effect of arsenic onmature hepatocyte-like HepaRG cellsmay be attributed to arsenic-induced dysregulation of cellular ironmetabolism. The inhibitory effect of NaAsO2 on the differentiation of progenitor cells, the resistance of biliary-like cells to cell death, and the enhanced cell death of functional hepatocyte-like cells resulted in stem-cell activation. These effects favored the proliferation of liver progenitor cells that can serve as a source of initiation and driving force of arsenic-mediated liver carcinogenesis. [ABSTRACT FROM AUTHOR]

Published

2018

5. Association Between Variants in Arsenic (+3 Oxidation State) Methyltranserase (AS3MT) and Urinary Metabolites of Inorganic Arsenic: Role of Exposure Level.

Author

Xiaofan Xu, Drobná, Zuzana, Voruganti, V. Saroja, Barron, Keri, González-Horta, Carmen, Sánchez-Ramírez, Blanca, Ballinas-Casarrubias, Lourdes, Cerón, Roberto Hernández, Morales, Damián Viniegra, Terrazas, Francisco A. Baeza, Ishida, María C., Gutiérrez-Torres, Daniela S., Saunders, R. Jesse, Crandell, Jamie, Fry, Rebecca C., Loomis, Dana, García-Vargas, Gonzalo G., Del Razo, Luz M., Stýblo, Miroslav, and Mendez, Michelle A.

Subjects

ARSENIC metabolism, GENOTYPES, GENETIC polymorphisms, METABOLITES, DNA methylation, URINALYSIS

Abstract

Variants in AS3MT, the gene encoding arsenic (+3 oxidation state) methyltranserase, have been shown to influence patterns of inorganic arsenic (iAs) metabolism. Several studies have suggested that capacity to metabolize iAs may vary depending on levels of iAs exposure. However, it is not known whether the influence of variants in AS3MT on iAs metabolism also vary by level of exposure. We investigated, in a population of Mexican adults exposed to drinking water As, whether associations between 7 candidate variants in AS3MT and urinary iAs metabolites were consistent with prior studies, and whether these associations varied depending on the level of exposure. Overall, associations between urinary iAs metabolites and AS3MT variants were consistent with the literature. Referent genotypes, defined as the genotype previously associated with a higher percentage of urinary dimethylated As (DMAs%), were associated with significant increases in the DMAs% and ratio of DMAs to monomethylated As (MAs), and significant reductions in MAs% and iAs%. For 3 variants, associations between genotypes and iAs metabolism were significantly stronger among subjects exposed to water As >50 versus ≤50 ppb (water As X genotype interaction P < .05). In contrast, for 1 variant (rs17881215), associations were significantly stronger at exposures ≤50 ppb. Results suggest that iAs exposure may influence the extent to which several AS3MT variants affect iAs metabolism. The variants most strongly associated with iAs metabolism--and perhaps with susceptibility to iAs-associated disease--may vary in settings with exposure level. [ABSTRACT FROM AUTHOR]

Published

2016

6. Linkage Analysis of Urine Arsenic Species Patterns in the Strong Heart Family Study.

Author

Gribble, Matthew O., Voruganti, Venkata Saroja, Cole, Shelley A., Haack, Karin, Balakrishnan, Poojitha, Laston, Sandra L., Tellez-Plaza, Maria, Francesconi, Kevin A., Goessler, Walter, Umans, Jason G., Thomas, Duncan C., Gilliland, Frank, North, Kari E., Franceschini, Nora, and Navas-Acien, Ana

Subjects

ARSENIC poisoning, ARSENIC metabolism, DISEASE risk factors, MICROSATELLITE repeats, GENOMES, GENETIC polymorphisms, HERITABILITY

Abstract

Arsenic toxicokinetics are important for disease risks in exposed populations, but genetic determinants are not fully understood. We examined urine arsenic species patterns measured by HPLC-ICPMS among 2189 Strong Heart Study participants 18 years of age and older with data on ~400 genome-wide microsatellite markers spaced ~10 cM and arsenic speciation (683 participants from Arizona, 684 from Oklahoma, and 822 from North and South Dakota). We logittransformed % arsenic species (% inorganic arsenic, %MMA, and %DMA) and also conducted principal component analyses of the logit % arsenic species. We used inverse-normalized residuals from multivariable-adjusted polygenic heritability analysis for multipoint variance components linkage analysis. We also examined the contribution of polymorphisms in the arsenic metabolism gene AS3MT via conditional linkage analysis. We localized a quantitative trait locus (QTL) on chromosome 10 (LOD 4.12 for %MMA, 4.65 for %DMA, and 4.84 for the first principal component of logit % arsenic species). This peak was partially but not fully explained by measured AS3MT variants. We also localized a QTL for the second principal component of logit % arsenic species on chromosome 5 (LOD 4.21) that was not evident from considering % arsenic species individually. Some other loci were suggestive or significant for 1 geographical area but not overall across all areas, indicating possible locus heterogeneity. This genome-wide linkage scan suggests genetic determinants of arsenic toxicokinetics to be identified by future fine-mapping, and illustrates the utility of principal component analysis as a novel approach that considers % arsenic species jointly. [ABSTRACT FROM AUTHOR]

Published

2015

7. Genetic Deletion of LXRα Prevents Arsenic-Enhanced Atherosclerosis, But Not Arsenic-Altered Plaque Composition.

Author

Lemaire, Maryse, Lemarié, Catherine A., Flores Molina, Manuel, Guilbert, Cynthia, Lehoux, Stéphanie, and Mann, Koren K.

Subjects

DELETION mutation, ATHEROSCLEROSIS, PHYSIOLOGICAL effects of arsenic, ATHEROSCLEROTIC plaque, TOXIN receptors, LABORATORY mice, DISEASE incidence

Abstract

Arsenic exposure has been linked to an increased incidence of atherosclerosis. Previously, we have shown in vitro and in vivo that arsenic inhibits transcriptional activation of the liver X receptors (LXRs), key regulators of lipid homeostasis. Therefore, we evaluated the role of LXRα in arsenic-induced atherosclerosis using the apoE−/− mouse model. Indeed, deletion of LXRα protected apoE−/− mice against the proatherogenic effects of arsenic. We have previously shown that arsenic changes the plaque composition in apoE−/− mice. Arsenic decreased collagen content in the apoE−/− model, and we have observed the same diminution in LXRα−/−apoE−/− mice. However, the collagen-producing smooth muscle cells (SMCs) were decreased in apoE−/−, but increased in LXRα−/−apoE−/−. Although transcriptional activation of collagen remained the same in SMC from both genotypes, arsenic-exposed LXRα−/−apoE−/− plaques had increased matrix metalloproteinase activity compared with both control LXRα−/−apoE−/− and apoE−/−, which could be responsible for both the decrease in plaque collagen and the SMC invasion. In addition, arsenic increased plaque lipid accumulation in both genotypes. However, macrophages, the cells known to retain lipid within the plaque, were unchanged in arsenic-exposed apoE−/− mice, but decreased in LXRα−/−apoE−/−. We confirmed in vitro that these cells retained more lipid following arsenic exposure and are more sensitive to apoptosis than apoE−/−. Mice lacking LXRα are resistant to arsenic-enhanced atherosclerosis, but arsenic-exposed LXRα−/−apoE−/− mice still present a different plaque composition pattern than the arsenic-exposed apoE−/− mice. [ABSTRACT FROM AUTHOR]

Published

2014

8. SLC19A1, SLC46A1 and SLCO1B1 Polymorphisms as Predictors of Methotrexate-Related Toxicity in Portuguese Rheumatoid Arthritis Patients.

Author

Lima, Aurea, Bernardes, Miguel, Azevedo, Rita, Monteiro, Joaquim, Sousa, Hugo, Medeiros, Rui, and Seabra, Vítor

Subjects

SINGLE nucleotide polymorphisms, METHOTREXATE, RHEUMATOID arthritis, DRUG toxicity, PHARMACOKINETICS, PATIENTS

Abstract

Methotrexate (MTX) is used for rheumatoid arthritis (RA) treatment showing a wide toxicity profile. This study aimed to evaluate the influence of single nucleotide polymorphisms (SNPs) in genes encoding for MTX transporters with the occurrence of MTX-related toxicity (overall and gastrointestinal). A total of 233 Portuguese RA patients were genotyped for 23 SNPs. Haplotype analyses were performed and a toxicogenetic risk index (TRI) was created for SNPs that revealed to be statistically significant. Regarding MTX overall toxicity, an increased risk was associated to SLC19A1 rs7499 G carriers (p = 0.017), SLC46A1 rs2239907 GG (p = 0.030) and, SLCO1B1 rs4149056 T carriers (p = 0.040) and TT (p = 0.019). TRI revealed that patients with Index 3 were 18-fold more likely to present an adverse drug reaction when compared to those with Index 1 (p = 0.001). For MTX gastrointestinal toxicity, results demonstrated an increased risk associated with SLC19A1 rs7499 G carriers (p = 0.012) and GG (p = 0.045), SLC19A1 rs1051266 G carriers (p = 0.034), SLC19A1 rs2838956 A carriers (p = 0.049) and, SLCO1B1 rs4149056 T carriers (p = 0.042) and TT (p = 0.025). Haplotype analyses showed association between GGAG haplotype for SLC19A1 rs7499, rs1051266, rs2838956 and rs3788200 with MTX gastrointestinal toxicity (p = 0.029). TRI revealed that patients with Index 4 were 9-fold more likely to present a gastrointestinal disorder when compared to those with Index 1 (p = 0.020). This study demonstrated that SLC19A1, SLC46A1 and SLCO1B1 genotypes may help to identify patients with increased risk of MTX-related overall toxicity and that SLC19A1 and SLCO1B1 genotypes, and SLC19A1 haplotypes may help to identify patients with increased risk of MTX-related gastrointestinal toxicity. [ABSTRACT FROM AUTHOR]

Published

2014

9. SLCO1B1 Variants and Urine Arsenic Metabolites in the Strong Heart Family Study.

Author

Gribble, Matthew O., Voruganti, Venkata Saroja, Cropp, Cheryl D., Francesconi, Kevin A., Goessler, Walter, Umans, Jason G., Silbergeld, Ellen K., Laston, Sandra L., Haack, Karin, Kao, Wen Hong Linda, Fallin, Margaret Daniele, MacCluer, Jean W., Cole, Shelley A., and Navas-Acien, Ana

Subjects

ARSENIC metabolism, CARDIOVASCULAR diseases risk factors, CANCER risk factors, ORGANIC anion transporters, URINALYSIS, SINGLE nucleotide polymorphisms, HUMAN genetic variation

Abstract

Arsenic species patterns in urine are associated with risk for cancer and cardiovascular diseases. The organic anion transporter coded by the gene SLCO1B1 may transport arsenic species, but its association with arsenic metabolites in human urine has not yet been studied. The objective of this study is to evaluate associations of urine arsenic metabolites with variants in the candidate gene SLCO1B1 in adults from the Strong Heart Family Study. We estimated associations between % arsenic species biomarker traits and 5 single-nucleotide polymorphisms (SNPs) in the SLCO1B1 gene in 157 participants, assuming additive genetics. Linear regression models for each SNP accounted for kinships and were adjusted for sex, body mass index, and study center. The minor allele of rs1564370 was associated with lower %MMA (p = .0003) and higher %DMA (p = .0002), accounting for 8% of the variance for %MMA and 9% for %DMA. The rs1564370 minor allele homozygote frequency was 17% and the heterozygote frequency was 43%. The minor allele of rs2291075 was associated with lower %MMA (p = .0006) and higher %DMA (p = .0014), accounting for 7% of the variance for %MMA and 5% for %DMA. The frequency of rs2291075 minor allele homozygotes was 1% and of heterozygotes was 15%. Common variants in SLCO1B1 were associated with differences in arsenic metabolites in a preliminary candidate gene study. Replication of this finding in other populations and analyses with respect to disease outcomes are needed to determine whether this novel candidate gene is important for arsenic-associated disease risks. [ABSTRACT FROM PUBLISHER]

Published

2013