Browsing by Subject "Health Sciences, Toxicology"
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Item Open Access Characterization of Fxr Alpha in Medaka and Its Involvement in Hepatobiliary Injury(2009) Howarth, Deanna LynneThe liver is a primary target for toxicants and/or their metabolites. Selected fish species now serve as model organisms for laboratory investigations of toxic responses in the liver. One such model is the Japanese medaka (Oryzias latipes), a small freshwater teleost with a robust history of usage in liver and biliary toxicity studies. The structural components of the medaka hepatobiliary system have been well-described by recent studies in two- and three-dimensional contexts, but efforts to characterize the molecular mechanisms underlying critical medaka liver functions during normalcy remain sparse. This dearth of information makes it difficult to definitively characterize toxic responses in this model organism. A crucial transcription factor underlying proper hepatobiliary function in both mammalian and non-mammalian species is the farnesoid X receptor alpha (FXRα), a member of the nuclear receptor superfamily that plays a key role in bile acid homeostasis. This dissertation describes the function of medaka fxrα during both normalcy and toxicity.
To achieve this overall objective, in vitro techniques were first employed to study the function of medaka fxrα. Two isoforms of fxrα that differ in the AF1 domain, Fxrα1 and Fxrα2, were isolated from liver cDNA and are the result of alternative splicing of one gene locus. Fxrα2 responded significantly to C24 bile acids and the synthetic FXRα agonist GW4064. On the other hand, Fxrα1, despite having an identical ligand-binding domain to that of Fxrα2, showed no response to any agonists tested by transient transactivation assays. Furthermore, Fxrα2 interacted with nuclear receptor coactivators PGC-1α and SRC-1 in mammalian two-hybrid assays while Fxrα1 did not. These findings point to a significant importance of the AF1 domain to overall receptor structure and function.
Following in vitro functional characterization, in vivo experiments using medaka larvae were performed to determine fxrα's function during normalcy. Quantitative, real-time PCR data demonstrated that Fxrα1 is highly expressed in adult liver, while Fxrα2 is expressed predominantly in gut. Fxrα1's expression was higher than Fxrα2 in embryos and larvae at all developmental timepoints tested. In vivo exposures of medaka hatchlings to GW4064 at various doses significantly altered expression of defined FXRα targets, including: bile salt export protein (BSEP), small heterodimer partner (SHP), and cytochrome P450 7A1 (CYP7A1). Surprisingly, numerous sublethal hepatic alterations to hepatocytes and bile preductular epithelial cells (BPDECs) were observed following exposure to GW4064; alterations included: lipid accumulation, glycogen depletion, mitochondrial swelling and rupture of mitochondrial membranes, disruption of endoplasmic reticulum, and apoptosis. Significant lipid accumulation, as revealed by oil red O whole mount staining of larvae, was also noted at lower doses of GW4064. These findings were the first observations of sublethal hepatotoxicity of GW4064; to date, no studies in the mammalian literature reported alterations following its administration.
Because of studies in the mammalian literature that demonstrated alleviation of cholestatic injury induced via the classic hepatotoxicant α-naphthylisothiocyanate (ANIT) by GW4064, it was originally hypothesized that a similar finding would be observed in medaka coexposed to these compounds. However, because of GW4064's ability to induce sublethal hepatic alterations in medaka, it was anticipated that its coadministration with ANIT would result in enhanced toxicity rather than alleviation as described in rodent models. However, despite the sublethal alterations induced by 1 uM GW4064, alleviation of toxicity following exposure to 15 uM ANIT was observed. Surprisingly, reduction of GW4064's toxicity was also observed in larvae exposed to both compounds. These investigations of fxrα function are an important and essential component in furthering our understanding of hepatobiliary toxicity in small aquarium fish models of human liver disease. These collective findings have created molecular underpinnings necessary for understanding medaka hepatobiliary function during normalcy and toxicity.
Item Open Access Mitochondria as a Target of Benzo[a]pyrene Toxicity in a PAH-adapted and Naive Population of the Atlantic Killifish (Fundulus Heteroclitus)(2009) Jung, DawoonPolycyclic aromatic hydrocarbons (PAHs) are important contaminants that are found in increasing amounts in aquatic ecosystems. One of the sites that that is contaminated by extremely high levels of PAHs is the Atlantic Wood Industries Superfund Site on the Elizabeth River, VA. The Atlantic killifish (Fundulus heteroclitus) from this site exhibit increased levels of antioxidants, increased sensitivity to hypoxia, and increased expression of enzymes involved in glycolytic metabolism, suggesting that exposure to PAHs in the environment may induce changes in mitochondrial function and energy metabolism. Normal mitochondrial activity is crucial to an organism's survival. Therefore, gaining a better understanding of how mitochondria are affected by environmental contaminants such as PAHs is a pressing research objective. As a first step in understanding changes in cellular bioenergetics of aquatic organisms in response to PAHs, this research focused on the effect of benzo[a]pyrene (BaP), a representative PAH, on mitochondria the killifish model and on comparison of the mitochondria of the PAH-adapted killifish from the Elizabeth River Superfund Site to reference site fish. In order to assess the extent of mitochondrial DNA damage in the killifish, a PCR-based assay (LA-QPCR) for nuclear and mitochondrial DNA (nDNA, mtDNA) damage was adapted to this model and validated in with UV exposure and BaP exposure studies, as well as with ex situ study examining DNA damage in killifish inhabiting the Elizabeth River Superfund site. With the newly adapted LA-QPCR, mtDNA and nDNA damage in the killifish from the Elizabeth River Superfund site and from a reference site (King's Creek, VA) that were treated with BaP were examined. Similar increases in mitochondrial and nuclear DNA damage were observed in King's Creek fish treated with BaP. Killifish from the Elizabeth River showed high levels of basal nDNA and mtDNA damage compared to fish from the reference site, but the level of damage induced due to BaP treatment was much lower in Elizabeth River killifish. Laboratory-reared offspring from both populations showed increased BaP-induced damage in mtDNA, relative to nDNA. Similar to the adult experiment, the Elizabeth River larvae had higher levels of basal DNA damage than those from the reference site, but were less impacted by BaP exposure. Results suggest that BaP exposure can have important energetic consequences and that multi-generational exposure in the wild may lead to adaptation that dampens DNA damage arising from BaP exposure. Since the toxic effects of many PAHs are the result of bioactivation by cytochrome P4501A (CYP1A), the existence of enzymes that can potentially metabolize PAHs in mitochondria was verified. Using Western blot, protein similar in size to microsomal CYP1A was identified with monoclonal antibody against scup CYP1A in the mitochondrial fraction from adult male killifish livers. The size of the protein in the mitochondria was the similar to that of microsomal CYP1A. Fish dosed with BaP had increased EROD activity in the liver mitochondrial fraction compared to controls. In killifish larvae dosed with BaP and benzo[k]fluoranthene (BkF), CYP1A protein levels as well as enzyme activity were elevated. However, fish from the Elizabeth River Superfund site showed recalcitrant mitochondrial CYP1A protein levels and enzyme activity in a similar manner to microsomal CYP1A. Finally, the hypothesis that energy metabolism of BaP-treated fish may be different from the control group and that killifish from the Elizabeth River Superfund site may also have altered energy metabolism compared to reference site fish was tested. Respiration of killifish embryos treated with BaP from both populations was measured. Compared to the King's Creek control fish, all other treatment groups showed decrease in oxygen consumption, indicating lower respiration rate. However, when activities of key enzymes involved in glycolysis (PK) and anaerobic metabolism (LDH) in adult killifish liver and muscle were measured, no differences in the enzyme activities were observed in BaP-treated group compared to the control group. Moreover, metabolomic analysis on BaP treated King's Creek and Elizabeth River killifish showed no difference in the profile in all four treatment groups. The findings in this thesis contribute to the understanding of how BaP, a common environmental pollutant in the aquatic ecosystem, targets the mitochondria in fish model. Nevertheless, deeper examination of how BaP may impact mitochondrial function in killifish and potentially influence adaptation of killifish at a highly contaminated site is necessary. Further studies will elucidate whether such impacts can potentially affect the energy budget and organism level fitness in populations in the wild.
Item Open Access Molecular Mechanisms Underlying Adaptation to PAHs in Fundulus heteroclitus(2010) Clark, BryanChronic exposure to toxicant mixtures is a serious threat to environmental and human health. It is especially important to understand the effects of these exposures for contaminants, such as polycyclic aromatic hydrocarbons (PAHs), which are toxic, ubiquitous, and increasingly prevalent. Furthermore, estuarine systems are of particular concern, as they are highly impacted by a wide variety of pollutants; fish there are often exposed to some of the highest levels of contaminants of any vertebrate populations, along with other stressors such as fluctuations in water level, dissolved oxygen, and temperature. A population of Fundulus heteroclitus (the Atlantic killifish or mummichog, hereafter referred to as killifish) inhabits a Superfund site heavily contaminated with a mixture of PAHs from former creosote operations; they have developed resistance to the acute toxicity and teratogenic effects caused by the mixture of PAHs in sediment from the site. The primary goal of this dissertation was to better understand the mechanism(s) by which Elizabeth River killifish resist the developmental toxicity of a complex mixture of PAHs and to investigate the tradeoffs associated with this resistance. Because the aryl hydrocarbon receptor (AHR) pathway plays an important role in mediating the effects of PAHs, one major hypothesis of my work was that suppression of the AHR response plays an important role in the resistance of Elizabeth River killifish. For this reason, investigation of the activation of the AHR pathway, as measured by CYP induction, is a unifying thread throughout the work. Another major hypothesis of this work is that adaptation to PAHs has secondary consequences for Elizabeth River killifish, such as altering their response to other xenobiotics. To investigate these hypotheses, a series of experiments were carried out in PAH-adapted killifish from the Elizabeth River and in reference fish. The morpholino gene knockdown technique was modified for use in killifish; we demonstrated that CYP1A knockdown exacerbates PAH-driven cardiac teratogenesis and AHR2 (but not AHR1) knockdown rescues PAH-driven cardiac teratogenesis. Using acute toxicity tests of larval killifish, we showed that Elizabeth River killifish are less sensitive than reference larvae to chlorpyrifos, permethrin, and carbaryl. These results demonstrated that the adaptation was able to protect from multiple xenobiotics, not just PAHs. Using the in ovo ethoxyresorufin-o-deethylase (EROD) assay and a subjective cardiac deformity screen, we showed that the adaptation was spread throughout the killifish subpopulations of the Elizabeth River estuary. However, the adaptive response varied greatly among the subpopulations, which showed that AHR pathway suppression was not required for some level of protection from PAH toxicity. Finally, using the quantitative real-time PCR, the EROD assay, and cardiac deformity screening, we demonstrated that the adaptation was heritable for two generations of fish reared in clean laboratory conditions. The findings in this dissertation will help to reveal how mixtures of PAHs exert their toxic action in un-adapted organisms. Furthermore, these studies will hopefully demonstrate how chronic exposure to PAH mixtures can affect organisms at the population and even evolutionary level. Perhaps most importantly, they will help us to better predict the consequences and tradeoffs for organisms and populations persisting in PAH-contaminated environments.