The protective role of transglutaminase 2 in ischemic stroke

Filiano, Anthony J.

January 2009

Thesis (Ph.D.)--University of Alabama at Birmingham, 2009. / Title from PDF title page (viewed on Sept. 4, 2009). Includes bibliographical references.

Over-Expression of Aryl Hydrocarbon Receptor (AhR) Enhances Src Kinase Activity to Functionally Induce AR Signaling and Promote Prostate Cancer Progression

Ghotbaddini, Maryam

21 May 2018

The aryl hydrocarbon receptor (AhR) has been reported to interact with multiple signaling pathways during prostate development including the androgen receptor. AhR was overexpressed in LNCaP using PLNCX2 retrovirus vector containing AhR cDNA to determine if ectopic overexpression induces castrate resistant phenotype. The highly overexpressed AhR clone illustrated further increase in transcriptional and promotor activity for AhR and AR compared to the moderately overexpressed AhR clone and control. Western blot analysis showed more AhR, AR, cSrc, and pSrc protein expression in clones. AhR overexpression was found to induce several biological properties such as migration, invasion, proliferation, and promotion of G1 to S phase during the cell cycle. Bicalutamide treatment had no effect on AR transcriptional activity in either clone, proving resistance to anti-androgen therapy. Our results confirm that overexpression of AhR induces constitutive activity and stimulates androgen receptor signaling. This suggests a role for AhR in the development of CRPC.

Prostate cancer

Aryl Hydrocarbon Receptor (AhR)

Androgen Receptor (AR)

Src kinase

CRPC

Biology

Evaluating the function of the Aryl Hydrocarbon Receptor in CNS autoimmunity

Avendaño Guzmán, Erika

17 October 2018

No description available.

610

Multiple Sclerosis

aryl hydrocarbon receptor

dendritic cells

quinoline-3-carboxamide

Biologie (PPN619462639)

The role of the aryl hydrocarbon receptor in megakaryocyte development

Smith, Brenden

03 November 2016

Megakaryocyte specification is the process by which discrete hematopoietic subpopulations undergo lineage commitment towards the myeloid compartment, finally specifying as a megakaryocyte erythroid progenitor (MEP) by way of thrombopoietin (TPO) and erythropoietin (EPO) signaling, before becoming a megakaryocyte lineage restricted progenitor that will progressively increase cellular ploidy and compartmentalize its cytoplasm in preparation for platelet production. With the advent of induced pluripotent stem cells (iPSCs), a cell type that is experimentally manipulated to function as embryonically derived pluripotent cells, there now exists the ability to analyze signal transduction throughout discrete phases of hematopoiesis, megakaryocyte lineage cell fate, and platelet production. Recent studies have implicated the aryl hydrocarbon receptor (AHR) as a transcription factor that plays a critical role in multiple aspects of hematopoiesis. These results inspired the hypothesis that AHR signaling may be functionally relevant in the context of megakaryopoiesis. To test this hypothesis, an iPSC directed differentiation strategy was established in order to create a platform upon which to experimentally manipulate AHR signaling throughout megakaryocyte specification. The results demonstrate: 1) iPSC derived hematopoietic progenitor cells (HPCs) undergo exponential expansion upon AHR agonism; 2) AHR antagonism allows for megakaryocyte lineage bias; 3) Optimization of directed-differentiation allows for the examination of AHR signaling in megakaryocyte lineage-restricted cells; 4) AHR signaling suppresses the expression of MPL, the gene that encodes the thrombopoietin receptor (C-MPL) in iPSC derived megakaryocyte lineage committed cells; 5) AHR activation concomitantly suppresses cell surface expression of C-MPL, which may alter the sensitivity of HPCs to TPO signaling; 6) Multiple gene targets are modulated by AHR activation within megakaryocyte lineage cells, providing evidence of a transcriptional program downstream of AHR signaling that preferentially suppresses megakaryocyte specification; 7) A reporter iPSC line of AHR activity provides evidence of endogenous AHR signaling throughout megakaryocyte specification and shows a sharp decline in AHR activity upon megakaryocyte lineage commitment; 8) In a mouse model of megakaryocyte lineage specific AHR knockout, platelet counts are significantly reduced. These data suggest that the AHR plays a significant role in megakaryocyte specification by modulating the expression of multiple lineage specific gene targets, including MPL, the thrombopoietin receptor. / 2017-05-02T00:00:00Z

Molecular biology

Hematopoiesis

Megakaryocyte

Platelet

Aryl hydrocarbon receptor

Induced pluripotent stem cell

REGULATION OF CIRCADIAN CLOCKS AND METABOLISM BY ARYL HYDROCARBON RECEPTOR

XU, CANXIN

01 December 2014

The aryl hydrocarbon receptor (AhR), a ligand-dependent transcription factor, plays a crucial role in regulation of xenobiotic metabolism. AhR is also involved in dioxin-induced metabolic disorders and alteration of circadian rhythm. Furthermore, circadian clock disruption and metabolic dysfunction are integrally associated with each other. This study was designed to understand the mechanisms by which AhR contributes to regulation of circadian clocks, fat metabolism and glucose homeostasis. In the first aim, I have tested whether AhR interacts with the core clock gene, brain and muscle AhR nuclear translocator like-1(BMAL1), disrupting circadian locomotor output cycle kaput (CLOCK)/BMAL1 complex activity, and leading to the suppression of period1 gene (Per1) expression rhythm. My studies indicate that AhR activation by its agonists 2,3,7,8-tetrachlorodibenzo-p-dioxin (TCDD) and beta-naphoflavone (BNF) disrupts the rhythm and inhibits the expression of Per1 in mouse liver and hepatoma cell lines, respectively. Mechanistically, the disruption of the rhythm and the inhibition of Per1 expression occur secondary to the interaction between AhR and BMAL1, which attenuates transcriptional activity of the core clock complex CLOCK/BMAL1. These results suggest alteration of the circadian clock as a novel signaling event downstream of AhR activation. The integral relationship between the clock and metabolic function further suggest that AhR activation may cause metabolic dysfunction. In the second aim, I have tested whether AhR activation inhibits Per1 gene induction and influences circadian clock resetting through activation of JNK pathway. AhR activation by it agonists TCDD and BNF decreases light-induced phase shifts in the early night and inhibits light-induced Per1 expression in both suprachiasmatic nucleus (SCN) and liver. Inhibition of Per1 induction results from increased phospho-JNK induced by AhR activation. Taken together, activation of AhR disrupts circadian clock resetting which also could cause metabolic dysfunction. In the third aim, I have tested whether AhR deficiency regulates nuclear receptor peroxisome proliferator-activated receptor a; (PPARa) and alters glucose homeostasis. PPARa, a clock-controlled gene (CCG) that acts as a fat metabolism sensor, is important for lipid metabolism and glucose homeostasis. AhR knockout (AhRKO or AhR-/-) mice exhibit enhanced insulin sensitivity and glucose tolerance, accompanied by decreased expression of PPARa, key gluconeogenic genes, glucose-6 phosphatase (G6Pase) and phosphoenolpyruvate carboxykinase (PEPCK) and key fatty acid oxidation enzymes, carnitine palmitoyl transferase1b (CPT1b) and acyl-CoA oxidase (ACO). Conversely, AhR agonists increase PPARa; expression in a BMAL1-dependent manner. In addition, AhRKO mice display altered rhythm for clock genes, clock-controlled genes (CCGs) and physiological blood glucose. These data suggest that AhR may modulate the glucose homeostasis through regulation of CCGs such as PPARa and that PPARa may be an important link between the circadian clock and metabolism. In the fourth aim, I have tested the effects of AhR ablation or attenuation in high-fat diet (HFD)-induced obesity, insulin resistance and hepatic steatosis in mice. Recent studies suggest that PPARα expression is elevated with HFD feeding as an adaptive response to attenuate hepatic steatosis, and PPARa deficiency protects against HFD-induced insulin resistance. AhR-/- as well as AhR heterozygous (AhR+/-) mice are protected from the HFD-induced obesity, insulin resistance, hepatic steatosis and show reduced inflammatory cytokine expression. In addition, AhR-/- and AhR+/- mice display protected insulin signaling, a higher adiponectin and a lower leptin and insulin in serum. Food intake and physical activity are not significantly different among WT, AhR-/- and AhR+/- mice with HFD feeding. Indirect calorimetry has demonstrated that the AhR+/- mice have higher oxygen consumption, CO2 production and heat production. In addition, Real-time PCR data show that uncoupling protein 1(Ucp1) is higher in brown adipose tissue which supports the higher heat production; moreover, the muscle gene profile reveals that the fatty acid beta-oxidation genes and mitochondrial respiratory genes are higher in AHR+/- mice which further support higher energy expenditure in these mice. Collectively, these data suggest that AhR signaling could be a potential target for treatment of obesity and type 2 diabetes, and AhR antagonist may be developed into a drug for these metabolic diseases.

Aryl Hydrocarbon Receptor

Circadian Clock

Glucose Homeostasis

Metabolic Disorders

Obesity

Persistant Organic Pollutants

Energetic Costs of AhR Activation in Rainbow Trout (Oncorhynchus mykiss) Hepatocytes

Nault, Rance

January 2011

Aquatic organisms in response to toxic insults from environmental pollutants activate defence systems including the aryl hydrocarbon receptor (AhR) in an attempt to metabolize and excrete these toxicants and their metabolites. These detoxification mechanisms however may come with certain energetic costs. I hypothesize that the activation of the AhR by β-Naphthoflavone (β-NF), a model AhR agonist, results in increased energetic costs requiring metabolic reorganization in rainbow trout hepatocytes. While the results obtained suggest that there are no significant energetic costs of AhR activation, analysis of enzyme activities suggests possible metabolic reorganization. This study also showed significant changes in cellular processes in hepatocytes over the incubation periods which previously were not reported. Furthermore, for the first time in fish hepatocytes, metabolic flux analysis (MFA) was used to examine intra-cellular metabolism, the applicability of which is discussed.

rainbow trout

hepatocytes

detoxification

aryl hydrocarbon receptor

energetic costs

metabolic flux analysis

Analysis of the aryl hydrocarbon receptor and a truncated form (AHR C[upper case symbol for greek Delta]Δ553) in cancer cells

Chow, Marilynn

01 January 2011

The aryl hydrocarbon receptor (AhR) is a ligand-activated bHLH-PAS protein that binds its partner, the aryl hydrocarbon receptor nuclear translocator (Arnt), in the nucleus to initiate the expression of proteins involved with detoxification. Published work suggests cross-talk between both proteins and cellular pathways involving the transcription factors, HIF -1 , ER, and NFKB, whose activity is typically upregulated in cancer. This thesis focuses on using a truncated form of AhR, AhR CΔ553, which is thought to act as a dominant-negative to sequester Arnt from its other binding partners. To test this hypothesis, we transfected HeLa cells with AhR CΔ553 fused to pEGFP or a vector under a tetracycline-inducible promoter. Stable cell lines expressing pEGFP-AhR CΔ553 have been generated and confirmed to have nuclear localization. We were also interested in confirming endogenous localization patterns of AhR and Arnt to study the role of p23 in the nuclear translocation of AhR. While we were successful in showing AhR translocating to the nucleus in treated MCF-7 cells, we couldn't clearly see nuclear AhR in Hepalclc7 cells, the cell line with knockdown levels of p23. To compare DNA damage generated in Jm·kat and Hepalclc7 cells, we looked for reactive oxygen species (ROS) production and quantified DNA damage after exposure to benzo[a]pyrene (B[a]P) and some of its derivatives. Hepalclc7 cells were prone to a wide variety of DNA damage, but Jurkat cells did not appear to undergo damage specifically through ROS production. Finally, we wanted to confirm apoptosis in HeLa cells after being cocultured with Trichomonas vaginalis. The G3 lab strain was more aggressive than Tl , but Parp, and apoptotic marker, was not observed in HeLa cells, suggesting that experimental conditions need to be further optimized.

Receptors

Aryl Hydrocarbon

Cancer cells Research

Proteins Research

Biology

Life Sciences

Mechanistic Study of p23-Mediated Aryl Hydrocarbon Receptor Expression

Pappas, Beverly

01 January 2018

The aryl hydrocarbon receptor (AHR) is a ligand-activated signaling molecule which is involved in diverse biological functions ranging from cancer metastasis to immune regulation. This receptor forms a cytoplasmic complex with Hsp90, p23, and XAP2. We have previously reported that down-regulation of p23 triggers degradation of the AHR protein, uncovering a potentially dynamic event which controls the cellular AHR levels without ligand treatment. Here we investigate the underlying mechanisms for this p23 effect using wild-type HeLa and the p23 knockdown HeLa cells. Reduction of the Hsp90 and XAP2 contents, however, did not affect the AHR protein levels, implying that this p23 effect on AHR is more than just alteration of the cytoplasmic complex dynamics. Association of p23 with Hsp90 is not important for the modulation of the AHR levels since exogenous expression of p23 mutants with modest Hsp90-binding affinity effectively restored the AHR message and protein levels. The protein folding property of p23 which resides at the terminal 50-amino acid region is not involved for this p23 effect. Results from our interaction study using the affinity purified thioredoxin fusion proteins and GST fusion proteins and isothermal titration calorimetry showed that p23 directly interacts with AHR and the interaction surface lies within AHR amino acid 1–216 and p23 amino acid 1–110. Down-regulation of the p23 protein content promotes the ubiquitination of AHR, indicating that p23 protects AHR from the ubiquitin-meditated protein degradation. However, the increased ubiquitination is not through the small ubiquitin-like modifier (SUMO) signaling pathway. Troubleshooting and optimization were paramount for understanding and evaluating the p23 and AHR interaction. Specifically, the p23 mutant purification, p23: Hsp90 interaction, transient transfection, p23: AHR assay, and ITC study were phases of this research that required extensive time and critical thinking. These topics were further detailed to outline the specific problems encountered and the various steps taken to alleviate or optimize these issues.

AHR

Aryl hydrocarbon receptor

Biological sciences

Health and environmental sciences

p23

pharmacology

pharmaceutical science

Pharmacy and Pharmaceutical Sciences

Dioxin Impact on Cardiac Development, Structure, Function, and Health, and Implications for Disease

de Gannes, Matthew K.

January 2020

No description available.

Toxicology

DNA methylation

TCDD

aryl hydrocarbon receptor

epigenetics

heart failure

heart development

Involvement of Aryl Hydrocarbon Receptor in Adipocyte Differentiation and Circadian Clock Regulation

Khazaal, Ali

01 December 2018

Type 2 diabetes is a metabolic disorder characterized by increased glucose concentrations in the blood due to decreased insulin sensitivity. The worldwide incidence of diabetes has increased remarkably over the last two decades. Obesity, due to increased consumption of calorie dense diets, and sedentary life styles, is commonly cited as a primary cause. However, many epidemiological studies have established a relationship between insulin resistance and exposure to environmental chemicals such as persistent organic pollutants (POPs). The mechanisms by which POPs alter metabolism remain poorly understood, although their lipophilic nature suggests a role in adipose tissue function. The Tischkau lab has established a relationship between Aryl hydrocarbon Receptor (AhR) activation by different types of POPs and increased risk of insulin resistance. This dissertation, therefore, explored the effects of AhR activation by POPs on adipose tissue function. Adipose tissue regulates systemic glucose and lipid metabolism through production of hormones and cytokines that regulate appetite and energy homeostasis. It is well-known that impaired adipose function promotes systemic insulin resistance. The first specific aim examined the hypothesis that activation of AhR suppresses adipogenesis by lowering the rate of pre-adipocyte differentiation. Adipogenesis is a process by which mesenchymal stem cells (MSCs) and pre-adipocytes differentiate into mature adipocytes. Limitations in adipogenesis and accumulation of ectopic lipid have significant roles in decreasing insulin sensitivity. Thus, I hypothesized that POPs contribute to systemic insulin resistance by lowering the rate of MSCs and preadipocyte differentiation; the resulting large, poorly-functioning adipocytes increase serum lipids and promote lipid deposition in other tissues. MSCs derived from mouse bone marrow and pre-adipocytes were treated with different concentrations of AhR agonist, β-Naphthoflavone (BNF), and levels of transcripts associated with adipocyte differentiation were determined by using quantitative PCR. Oil red O staining and lipid content were observed to examine differentiation into mature adipocytes. Genes that promote adipogenesis, including peroxisome proliferator-activated receptor gamma (PPARγ), CCAAT/enhancer-binding protein alpha (CEBPα), fatty acid binding protein 4 (FABP4), and adiponectin were downregulated in MSCs treated with BNF. Moreover, accumulation of triglycerides was decreased after BNF treatment. Recombinant lentivirus vector-mediated AhR knockdown blocked the effects of BNF on adipogenesis. Therefore, activation of AhR by exogenous ligands inhibits adipogenesis leading to impaired fat storage. Limitations in adipogenesis promotes accumulation of the excess lipid in non-fat tissue such as liver, muscle, and heart leading to decrease the insulin sensitivity and disrupt energy homeostasis. The second specific aim examined effects of AhR activation on circadian clock regulation in adipose tissue. A circadian clock essentially regulates systematic energy homeostasis; the central clock in the suprachiasmatic nucleus (SCN) works with the local clocks in peripheral tissues such as liver, muscle, and adipose tissue to regulate whole-body metabolism. The Tischkau lab has previously shown that AhR interacts with the core machinery of the circadian clock. Activation of AhR by environmental toxicants leads to a dampening of the rhythm expression of core clock genes or an alteration in the timing of their peak expression, which subsequently promotes metabolic disorders such as glucose insensitivity and hyperlipidemia. Given the importance of appropriately timed adipose tissue function to regulation of energy homeostasis, this study focused on mechanisms by which AhR may influence clock-controlled mature adipose tissue activity. Lipolysis is a clock-regulated process in adipose tissue that provides the necessary energy during periods of fasting and exercise. Thus, I hypothesized that AhR activation in adipose tissue would impair lipolysis by altering molecular circadian clock function. AhR activation was proposed to dampen adipose rhythms, leading to a decreased lipolysis rate during the absence of food, and subsequently, increased glucose concentrations in the blood. C57BL/6 mice were injected with vehicle or 50 mg/kg body weight of the AhR agonist, BNF, 48 hours after release into constant darkness. Mice were sacrificed, and epididymal adipose tissue was collected every 6 hours over a 24 hour period. Real-Time RT-qPCR was used to measure mRNA expression of genes responsible for lipolysis. To examine effects of AhR activation in vitro; mouse pre-adipocytes, 3T3-L1 cells, were differentiated into mature adipocytes for 12 days. Cells were then starved for 24 hours with DMEM media containing 1% FBS to induce lipolysis in the presence of 100, 200, 300 µM of BNF. RNA was then extracted and mRNA expression for genes responsible for circadian clock and lipolysis were determined by RT-qPCR. Alterations were observed in rhythms of core clock genes in wild type mice injected with BNF compared to wild type mice injected with vehicle. Rhythms of key enzymes controlling lipolysis including hormone sensitive lipase (HSL) and adipose triglycerides lipolysis (ATGL) was changed in wild type mice injected with BNF compared to wild type mice injected with vehicle. These effects were blocked in AhR deficient mice, suggesting that these effects were AhR dependent. Liver glycogen was decreased in mice injected with BNF compared to wild type mice injected with vehicle after 12 hour of food restriction but not in AhR null mice. Activation of AhR led to decreased expression of lipolysis genes in adipose tissue at CT6 (middle of the rest phase) as well as in 3T3-L1 cells. Recombinant lentivirus vector-mediated AhR knockdown blocked the effects of BNF on lipolysis in 3T3-L1 cell line. These data establish a link between environmental toxicants and impaired lipolysis, specifically by altering rhythms of clock genes in adipose tissue. In response to the decreased available energy from impaired lipolysis, the body increases glycogenolysis, thereby degrading more glycogen to provide the necessary energy. This process may lead to increased glucose level in the blood and development of type 2 diabetes. The data from this study suggest that activation of AhR by BNF increases the risk of insulin resistance and type 2 diabetes by impairing adipogenesis. Reduced adipogenesis likely decreases adipocyte capacity to capture triglycerides from the blood. These effects may disturb energy homeostasis and contribute to the development of metabolic syndrome. This study also establishes a link between environmental toxicants and impaired lipolysis, specifically by altering rhythms of clock genes in adipose tissue. In response to the decreased available energy from impaired lipolysis, the body increases glycogenolysis, thereby degrading more glycogen to provide the necessary energy. This process may lead to increased glucose level in the blood and development of type 2 diabetes. All together, these data suggest that environmental pollutants result in adipose tissue dysfunction by reducing adipogenesis and lipolysis. Therefore, activation of AHR by its exogenous ligands may increase the risk of insulin resistance and type 2 diabetes by impairing adipose tissue function. In particular, activation of AHR by exogenous ligands leads to impairment of free fatty acids storage during feeding and release during fasting to disturb energy homeostasis.

Adipogenesis

Adipose Tissue

Aryl hydrocarbon Receptor

Circadian Clock

Lipolysis

Mesenchymal Stem Cells