An Assessment of Pyridoxine as a Biological Response Modifier During Colon Carcinogenesis

Kular, Aneta

04 October 2007

The main objective of this proposal was to investigate the effect of vitamin B6 on colon carcinogenesis in vivo. Two in vivo studies were conducted to determine the role of vitamin B6 as a biological modifier of colon carcinogenesis. It is hypothesized that vitamin B6 may serve as an antioxidant in vivo and will modulate colon carcinogenesis. In the first study, a 2X3 factorial experimental design was used to determine if three different levels of vitamin B6, classified as low, normal and high in conjunction with two different levels of protein intake, classified as normal or high, will affect post-initiation stages of colon carcinogenesis, in Sprague-Dawley rats. Male Sprague-Dawley male were injected with azoxymethane for two weeks (15mg/kg/week) and then one week later they were allocated to different dietary treatment groups. After eight weeks, the effects of dietary treatment on hematological status, oxidative stress markers and antioxidant enzymes, as well as enumeration of preneoplastic lesions, aberrant crypt foci (ACF), were evaluated. The lowest level of vitamin B6 intake with a high protein diet reduced the growth and development of ACF. Vitamin B6 had no significant effect on the oxidative stress markers. The level of protein was an important variable in modulating the levels of 3-nitrotyrosine and 8-OH-DG which were lower in high protein groups than normal protein counterparts. The objective of the second study was to investigate if a supraphysiological (5 fold higher than normal level) dosage of vitamin B6 could have an antioxidant effect in a metabolically compromised state like obesity and thereby lower the risk of colon cancer. Female Zucker obese (Zk-OB) rats received normal (Zk-OBN, 7 mg/kg) or high (Zk-OBH, 35 mg/kg) vitamin B6 (Pyridoxine-HCl) diets two weeks prior to, during and six weeks following injection with colon carcinogen AOM. The effects of supplemental vitamin B6 on hematological status, oxidative stress markers and antioxidant enzymes, as well as enumeration of ACF were carried out. High intake of vitamin B6 significantly lowered liver weights and plasma cholesterol compared to the normal intake (p≤0.05). Zk-OBH rats had significantly reduced number of ACF compared to Zk-OBN (p≤0.05). Hepatic GSH increased in the ZK-OBH group with a concomitant decrease in GPx activity. The findings demonstrate that in Zucker Obese rats, a high B6 intake augmented the antioxidant potential and decreased sensitivity to colon carcinogenesis. These findings suggest that high vitamin B6 plays an important therapeutic role in the compromised state of obesity.

colon cancer

vitamin B6

oxidative stress

protein

ACF

obesity

Zucker Obese rats

Biology

Oxidative stress : natural history and modulation In surgery and trauma patients

Obayan, Adebola Okunola Emeka

31 August 2004

Oxidative stress has been associated with many disease conditions in adults and neonates based on clinical and post mortem studies. Trauma is the commonest cause of oxidative stress. However a gap in knowledge of the natural history of oxidative stress in humans was identified as most studies have been post mortem or in animals. <p>The aim of this research is to understand treat and oxidative stress in trauma and surgical patients. The study involved three components including: the development and evaluation of the novel oxistress assay; study of clinical trauma and oxidative stress; and clinical trial of alanyl-glutamine supplementation following major surgery. The novel oxistress assay was used on urine samples in the normal population to determine reference values and subsequently on hospital patients to determine sensitivity and specificity. The study of clinical trauma and oxidative stress evaluated plasma antioxidants (FRAP assay), red cell glutathione (Asensis method), plasma and urine protein carbonyl (Levines method) and total oxidants in plasma and urine (oxistress assay) over 7 day period following trauma. The clinical trial was a double blind study of 69 major surgery patients evaluating biochemical and clinical parameters over 7 day period in comparison with pre-operative status. <p>The novel oxistress assay proves to be a sensitive and accurate bedside diagnostic tool for oxidative stress. It can also be used in the laboratory setting. Oxidative stress is associated with increased trauma severity resulting in antioxidant depletion, strong oxidant production and protein degradation. The presence of pre-morbid medical factors also increased oxidative stress in trauma patients. Oral alanyl-glutamine supplementation (0.3 g/kg) increased plasma glutamine and antioxidant levels while decreasing urine oxidant levels. It significantly reduced hospital stay in non-cancer and higher disease complexity patients. The intervention also reduced the resource intensity weighting (RIW) score. <p>Oxidative stress is a clinical problem in surgery and trauma patients that can now be easily diagnosed at the bedside using the novel oxistress assay. Treatment with alanyl-glutamine is effective in reducing oxidative stress and improving clinical outcome. It is highly recommended probably at a higher dose in order to achieve optimal results.

Oxistress Assay

Enteral Alanyl-glutamine supplementation

Post-surgery

Free radicals

Antioxidants

Trauma

Oxidative Stress

Cardiovascular effects of environmental tobacco smoke and benzo[a]pyrene exposure in rats

Gentner, Nicole Joy

08 April 2010

Smoking and environmental tobacco smoke (ETS) exposure are major risk factors for cardiovascular disease (CVD), although the exact components and pathophysiological mechanisms responsible for this association remain unclear. Polycyclic aromatic hydrocarbons (PAHs), including benzo[a]pyrene (BaP), are ubiquitous environmental contaminants that form during organic material combustion and are thus found in cigarette smoke, vehicle exhaust particles, and air pollution. We hypothesize that PAHs are key agents responsible for mediating the cigarette smoke effects in the cardiovascular system, including increased oxidative stress, inflammation, and arterial stiffness.<p> Arterial stiffness is a powerful, independent predictor of cardiovascular risk and is regulated, in part, by vasoactive mediators derived from the endothelium. The first objective of this project was to determine whether pulse wave dP/dt collected from radiotelemetry-implanted rats is a reliable indicator of changes in arterial stiffness following administration of vasoactive drugs or acute ETS exposure. Anaesthetized rats were administered a single dose of saline (vehicle control), acetylcholine, norepinephrine, and N(G)-nitro-L-arginine methyl ester (L-NAME) via the tail vein, allowing a washout period between injections. Acetylcholine decreased and norepinephrine increased dP/dt compared to saline vehicle. Injection of the nitric oxide (NO) synthase inhibitor L-NAME decreased plasma nitrate/nitrite (NOx), but transiently increased dP/dt. For the ETS experiment, rats were exposed for one hour to sham, low dose ETS, or high dose ETS. Exposure to ETS did not significantly alter dP/dt or plasma endothelin-1 (ET-1) levels, but increased plasma NOx levels at the high ETS exposure and increased plasma nitrotyrosine levels in both ETS groups. In conclusion, acute changes in NO production via acetylcholine or L-NAME alter the arterial pulse wave dP/dt consistently with the predicted changes in arterial stiffness. Although acute ETS appears to biologically inactivate NO, a concomitant increase in NO production at the high ETS exposure may explain why ETS did not acutely alter dP/dt.<p> The second objective of this project was to compare the effects of subchronic ETS and BaP exposure on circadian blood pressure patterns, arterial stiffness, and possible sources of oxidative stress in radiotelemetry-implanted rats. Pulse wave dP/dt was used as an indicator of arterial stiffness, and was compared to both structural (wall thickness) and functional (NO production and bioactivity, ET-1 levels) features of the arterial wall. In addition, histology of lung, heart, and liver were examined as well as pulmonary and hepatic detoxifying enzyme activity (cytochrome P450 specifically CYP1A1). Daily ETS exposure for 28 days altered the circadian pattern of heart rate and blood pressure in rats, with a loss in the normal dipping pattern of blood pressure during sleep. Subchronic ETS exposure also increased dP/dt in the absence of any structural modifications in the arterial wall. Although NO production and ET-1 levels were not altered by ETS, there was increased biological inactivation of NO via peroxynitrite production (as indicated by increased plasma nitrotyrosine levels). Thus, vascular stiffness and failure of blood pressure to dip precede structural changes in rats exposed to ETS for 28 days. Exposure to ETS also caused increased number of lung neutrophils as well as increased CYP1A1 activity in lung microsomes.<p> Since ETS-induced increases in arterial stiffness occurred as early as day 7, radiotelemetry-implanted rats were exposed daily to intranasal BaP for 7 days. Similar to ETS, BaP exposure altered circadian blood pressure patterns and reduced blood pressure dipping during sleep. Thus, in support of part of our hypothesis, the PAH component of cigarette smoke may be responsible for the ETS-induced increase in blood pressure and the loss of dipping pattern during sleep. Increased neutrophil recruitment was observed in the lungs of both ETS- and BaP-exposed rats, suggesting that lung inflammatory reactions may be involved in the disruption of circadian blood pressure rhythms. Unlike ETS however, BaP exposure did not significantly alter pulse wave dP/dt, endothelial function, or lung CYP1A1 activity. Thus, contrary to our hypothesis, the reduction in NO bioactivity and increased arterial stiffness caused by ETS cannot be explained by BaP at the dose and length of the exposure in the current study. Production of reactive metabolites in the lung following ETS exposure may be responsible, at least in part, for the increases in oxidative stress in the vasculature, leading to reduced NO bioactivity and increased arterial stiffness. Oxidative stress caused by BaP exposure may have been insufficient to reduce NO bioactivity in the peripheral vasculature. Therefore arterial stiffness was not increased and factors other than NO may be responsible for the increase in blood pressure observed with ETS and BaP exposure.

endothelial dysfunction

nitric oxide

benzo[a]pyrene

inflammation

oxidative stress

blood pressure

arterial stiffness

environmental tobacco smoke

Untersuchungen zu Glutathion-sensitiven Farbstoffen in der Meerschweinchen-Retina

Halfwassen, Kathrin

27 June 2012

Die Glutathionverhältnisse und -verschiebungen zwischen Gliazellen und Ganglienzellen vor und nach oxidativem Stress wurden erstmals im lebenden Zellverband, ex vivo, untersucht. Die Untersuchungen erfolgten an akut isoliertem Retinagewebe vom Meerschweinchen, von welchem Bilder am Laser scanning microscope (LSM) erstellt wurden. Über die Anwendung des in vivo-Fluoreszenzfarbstoffes CellTracker Green wurde dabei dessen Spezifität für Glutathion überprüft und bestätigt.

Glutathion

CellTracker Green

oxidativer Stress

Glutathion-Metabolismus

glutathione

CellTracker Green

oxidative stress

metabolism of glutathione

ddc:636.089

Evolutionary Implications and Genetic Basis of Peroxide Survival in Saccharomyces Cerevisiae

Diezmann, Stephanie

January 2009

<p>Hydrogen peroxide is used by animals and plants to deter the growth of microbial invaders by inflicting DNA lesions, protein oxidation and lipid membrane modifications. Pathogens protect themselves with enzymes and scavenging proteins. This study investigated population genetic, biochemical and genetic aspects of peroxide survival in <i>Saccharomyces cerevisiae </i> to address its importance for yeast biology and fungal pathogenicity.</p><p>Population genetic analyses of DNA sequences from five loci from 103 strains encompassing the known ecological spectrum of <i>S. cerevisiae</i> show that it is a recombining species with three divergent subgroups, which are associated with soil, fruit, and vineyards. Clinical isolates cluster with fruit isolates but are significantly more resistant to peroxide. Clinical isolates are genetically diverse, indicating multiple origins of the pathogenic lifestyle and eliminating the possibility that peroxide resistance is due to shared ancestry rather than it's importance for than its importance in colonizing the host.</p><p>Biochemical aspects of peroxide survival were studied in a resistant (high-survival) clinical isolate, a sensitive (low-survival) laboratory strain and their hybrid. Catalase activity and expression levels are indistinguishable among strains. Co-culture assays and growth curve records indicate that a secreted factor improves survival of the laboratory strain and that the phenotypic difference is most pronounced during exponential growth, excluding mechanisms of the General Stress Response effective during stationary phase. Semi-quantitative expression profiles of stress response candidate genes do not differ, suggesting a novel resistance mechanism.</p><p>To elucidate the genetic basis of peroxide survival, the hybrid was sporulated and 200 F1 segregants phenotyped and genotyped for oxidative stress candidate genes. Peroxide survival is a dominant quantitative trait and not linked to catalase, peroxidase or superoxide dismutase genes. 1,246 backcross segregants were phenotyped and 93 segregants selectively genotyped using microarrays. A 14-gene locus on chromosome XVI displayed marker-trait association. One gene, <i>RDS2</i>, encodes a zinc cluster protein acting as a regulator of drug sensitivity and contains a non-synonymous polymorphism whose exchange between the parental strains results a 15% decrease in survival in the clinical strain.</p><p>This work establishes a novel function for <i>RDS2</i> in oxidative stress response and demonstrates the effect a quantitative trait nucleotide has on a clinically relevant phenotype.</p> / Dissertation

Biology, Genetics

Biology, Microbiology

Evolution

Oxidative Stress

Quantitative Genetics

Saccharomyces cerevisiae

The Toxicological Effects of Engineered Nanoparticles, Quantum Dots, in Estuarine Fish

Blickley, Twyla Michelle

January 2010

<p>Engineered nanoparticles (ENPs) are a part of everyday life. They are incorporated into a wide array of products including sunscreens, clothing, electronics, paints, and automobiles. One particular type of ENP, quantum dots (QDs), are fluorescent semi&ndash;conducting nanocrystals, and are touted as the next generation of medical tracers and energy&ndash;efficient light bulbs. The continued development and expansion of commercial applications for QDs ensure that they will enter the aquatic environment following manufacture, use, and disposal. Unfortunately, very little information exists on the bioavailability and sub&ndash;lethal toxicological effects of QDs in aquatic organisms. The studies described in this dissertation focused on determining the toxicological effects of Lecithin&ndash;encapsulated CdSe/ZnS quantum dots in larval and adult <italic>Fundulus heteroclitus</italic> (the mummichog). </p> <p>Quantum dot dispersion is greatly influenced by environmental parameters such as pH, natural organic matter concentration, and ionic strength. Lecithin&ndash;encapsulated core&ndash;shell QDs aggregated and precipitated from suspension in 20 ppt seawater. QD aggregates adhered to the exterior chorion of <italic>Fundulus</italic> embryos in aqueous embryo exposures, but did not traverse the chorion and deposit into the body of the fry. Incidences of developmental abnormalities increased and hatching rates declined in embryos exposed to the highest concentration tested (100 &mu;g/ml). </p> <p>Dietary assessments showed that QDs were bioavailable to adult <italic>Fundulus</italic>. While QDs or their degradation products traversed the intestinal epithelial and were deposited to the liver, less than 0.01% of the cadmium from the QDs was retained in the liver and intestinal tissues. QD uptake did not cause significant changes in hepatic total glutathione or lipid peroxidation levels, nor did it statistically alter the expression of genes involved in metal metabolism and oxidative stress&mdash;metallothionein, glutathione&ndash;s&ndash;transferase, glutathione peroxidase, and superoxide dismutases. There was, however, a clear gender&ndash;specific trend in the level of Cu/Zn&ndash;superoxide dismutase transcription. In addition, QDs did impact fecundity presumably by feminizing male fish. Vitellogenin transcription was elevated and relative gonad size reduced in male <italic>Fundulus</italic> consuming 10 &mu;g QD per day. Lastly, QDs or their degradation products were maternally transferred to the eggs following six to eight weeks of parental exposure, thus posing a risk to <italic>Fundulus</italic> progeny. Based on the results of these studies, it is apparent that chronic exposure to QDs could result in adverse affects in teleosts and other organisms inhabiting estuarine environments.</p> / Dissertation

Environmental Sciences

Nanotechnology

engineered nanoparticles

environmental toxicology

Fundulus heteroclitus

oxidative stress

quantum dots

reproduction and development

Ecotoxicology of Natural and Anthropogenic Extreme Environments

Osterberg, Joshua Samuel

January 2010

<p>Reactive oxygen species (ROS) are produced endogenously in all aerobes and are induced by environmental stressors. ROS oxidize and disable essential cellular components such as DNA, proteins, and lipid membranes. Exposure to metals, polycyclic aromatic hydrocarbons (PAHs), and some pesticides can induce oxidative stress in marine invertebrates. All aerobic organisms have a network of antioxidants and enzymes to quench ROS and prevent oxidative damage. This dissertation examines antioxidant and oxidative stress biomarkers in endemic molluscs and crabs from two natural extreme environments: deep-sea hydrothermal vents in the Lau and North Fiji Basin, and cold seeps in the Gulf of Mexico. In addition, the acute toxicity and sub-lethal effects of four insecticides and an herbicide are examined in the estuarine blue crab, <italics>Callinectes sapidus</italics>. Blue crabs are North Carolina's most important fishery species and are frequently found in agricultural drainage ditches, an example of an anthropogenic extreme environment. </p> <p>Total glutathione, catalase, superoxide dismutase, and lipid peroxidation levels were of the same respective order of magnitude in the two vent gastropods, <italics>Alviniconcha</italics> sp. and <italics>Ifremeria nautilei</italics>, and vent mussel, <italics>Bathymodiolus brevior</italics>. These biomarkers activities were similar to those from previous reports on Mid-Atlantic Ridge mussels, except for ~100-fold higher lipid peroxidation levels among Lau molluscs. Principal component analysis (PCA) of mollusc tissue-specific biomarker levels grouped individuals by species rather than by site. </p> <p>Biomarker levels in the seep mussels <italics>Bathymodiolus childressi, B. brooksi</italics>, and <italics>B. heckerae</italics> were similar across species except for elevated foot and gill cytosolic SOD in mussels from MC-640 compared to those from AC-645. PCA of seep mussel biomarker levels differentiated by species with <italics>B. childressi</italics> isolated from <italics>B. brooksi</italics> and <italics>B. heckerae</italics>. The addition of <italics>B. brevior</italics> biomarker data to the PCA showed them grouping around <italics>B. brooksi</italics> and <italics>B. heckerae</italics>. <italics>Bathymodiolus childressi</italics> is ancestral to the other species and contains only methanotrophic endosymbionts. Whether symbionts play a role in alleviating possible toxic conditions remains unknown.</p> <p>Pesticides were acutely toxic to blue crabs in the order of Lambda-cyhalothrin > imidacloprid &#8776; aldicarb > acephate &#8776; Roundup® (glyphosate). Megalopae were almost always more sensitive to pesticides than early stage juveniles. Commercial formations of pesticides generally showed similar toxicity to active ingredients alone. Exposure to LC₂₀ levels of acephate, aldicarb, imidacloprid and Roundup significantly increased the frequency of juvenile mortality after molting. There was no significant change in total glutathione or lipid peroxidation of exposed megalopae. Lambda-cyhalothrin-, imidacloprid-, and aldicarb-based products have the potential to cause acute toxicity and molting-related mortality in shallow creeks and ditches.</p> / Dissertation

Biology, Oceanography

Biology, Ecology

Biology, Physiology

Anitoxidant

Bathymodiolus

Callinectes sapidus

Hydrothermal vent

Oxidative stress

Toxicity

Masked Metal Chelators of Variable Denticity to Prevent Oxidative Stress

Dickens, Marina Grace

January 2010

<p>Cellular damage due to oxidative stress is implicated in a wide variety of conditions including degenerative diseases like Alzheimer's and Parkinson's Diseases. One source of oxidative stress is the interaction of redox-active metals such as copper and iron with hydrogen peroxide to produce hydroxyl radicals. Preventing metal-induced oxidative stress by metal chelation is one potential approach to treat some of these diseases, but there remain significant challenges in designing chelators that target damaging metals while not disturbing healthy metal ion distribution.</p><p>To overcome this challenge, prochelators that are responsive to conditions of oxidative stress have been introduced. By designing ligands that only bind metal ions in the presence of oxidants, damaging metals can be bound and removed while not perturbing the metals necessary for cell function. Masking the phenol of a chelator with a boronic ester creates a prochelator that has little to no affinity for metal ions until exposure to H₂O₂ converts the prochelator to the chelator, which is then available to bind metal ions. Described here is the development of boronate-based prochelators that react with H₂O₂ to produce chelating agents of variable denticity, ranging from 2 to 6.</p><p>Quinoline boronic acid pinanediol ester, or QBP, is a new bidentate prochelator introduced here that reacts with H₂O₂ with a rate of 0.22 M<super>-1</super>s<super>-1</super> to produce 8-hydroxyquinoline, a known metal-binding agent. Results in Chapter 2 show that QBP can be activated in vitro under conditions that mimic early Alzheimer's Disease pathology where copper, amyloid beta peptide, and ascorbic acid exacerbate formation of reactive oxygen species. QBP does not bind metal ions, nor does it disaggregate metal-promoted amyloid beta peptide aggregates. However, the released 8-hydroxyquinoline sequesters copper from amyloid beta and both diminishes further formation of reactive oxygen species and inhibits further aggregation of amyloid-beta.</p><p>The syntheses and crystal structures of hexadentate prochelators are described in Chapter 3, along with their rates of oxidation in response to hydrogen peroxide exposure and their ability to protect against hydroxyl radicals formed in vitro by iron (or copper), ascorbic acid, and hydrogen peroxide. The hexadentate chelators are based on a tripodal architecture in which three phenol moieties are linked via nitrogens on three alkyl arms to a central nitrogen to provide an N₃O₃ donor set for metal complexation. Of three prochelator/chelator pairs prepared, the pair (trenBsalam/trensalam) with amine linkages was deemed most suitable for potential biological studies. The prochelator trenBsalam oxidizes at a rate of 0.72 M<super>-1</super>s<super>-1</super> to produce the chelator trensalam in the presence of hydrogen peroxide. The transition metal coordination chemistry and metal ion affinities of trensalam were further studied in Chapter 4 by x-ray crystallography, UV/Vis spectroscopy and cyclic voltammetry.</p><p>The response of a series of bidentate prochelators to various oxidants, including hydrogen peroxide, superoxide, peroxynitrite and hypochlorite, was evaluated by UV/Vis spectroscopy in Chapter 5. Varying the diol that is appended to the boronic ester results in hydrogen peroxide oxidation rates ranging from 0.018 to 1.27 M<super>-1</super>s<super>-1</super>. Lastly, the stability of different boronic acid and diol combinations was probed by spectroscopic techniques and indicate that boronic esters formed with pinanediol form the most stable prochelators under physiological conditions.</p> / Dissertation

Chemistry, Inorganic

Chemistry, Organic

Chemistry, General

Alzheimer's Disease

Chelators

Metals

Oxidative Stress

Response of antioxidative defense system in two ecotypes of Arabidopsis thaliana (Col-0 & Ler-0) during mercury-induced oxidative stress

Liu, Chien-Shin

28 July 2011

Generation of reactive oxygen species (ROS) is an important view point to evaluate heavy metal toxicity and resistance in plants. Arabidopsis thaliana is a fully sequenced model plant, and the characteristic between ecotypes due to adaptation towards varied environment can be used as a material for comparing physiological differences. In this experiments, two ecotypes of A. thaliana: Columbia (Col-0) and Landsberg erecta (Ler-0) is observed for the roots growth inhibition, plasma membrane integrity and lipid peroxidation after treated with different concentration of HgCl2 (0, 2, 4, 8 £gM), in attempt to compare the anti-oxidation defensive mechanism of two ecotypes and understand mercury-induced oxidative stress. ROS and Ca2+ generation is determined with CM-H2DCF-DA and Oregon Green 488 BAPTA-1 is under confocal microscopy. Some anti-oxidant enzymes such as superoxide dismutase (SOD EC 1.15.1.1), peroxidase (POD EC1.11.1.7) and ascorbate peroxidase (APX EC 1.11.1.11) are examined for the activity under protein gel electrophoresis. Experiment results showed that mercury-induced inhibition of root growth is more significant in Ler-0. ROS in roots of both ecotypes shows different trends under 8 £gM HgCl2 , however increment of ROS level below 4 £gM HgCl2 ; Ca2+ shows the similar result as ROS. Activity of SOD isoforms reached a peak at 2-4 £gM HgCl2. Expression of POD is correlated to the mercury concentration in both ecotypes. There are two types of APXs expression, one decreased as mercury concentration increased, another increased under 2 £gM HgCl2 and decreased as the concentration getting higher. According to the observation on expression of ROS generations and anti-oxidation system, we speculated that tolerance of Ler-0 towards mercury is weaker than Col-0. The results can be used as a basis for further discussion on influence of mercury towards different anti-oxidation enzymes and the signaling pathways.

Reactive oxygen species (ROS)

Oxidative stress

Mercury

Arabidopsis thaliana

Antioxidative defense system

Proteomics of Oxidative Stress Using Inducible CYP2E1 Expressing HepG2 Cells and 3T3-L1 Adipocytes as Model Systems

Newton, Billy Walker

2011 May 1900

The overall goal of this research was to investigate oxidative stress related changes to the proteomes of 3T3-L1 adipocytes and an inducible CYP2E1 expressing HepG2 cells. Enhanced oxidative stress in hypertrophic adipocytes is associated with metabolic dysregulation and insulin resistance. Because mitochondria generate reactive oxygen species (ROS), we monitored changes to the adipocyte mitochondrial proteome during differentiation and enlargement. We labeled mitochondrial extracts from 3T3-L1 cells that were 0, 4, 7, 10, 14, and 18 days post differentiation with iTRAQ, followed by MS based identification. We found citric acid cycle proteins such as pyruvate carboxylase, citrate synthase, as well as beta-oxidation enzymes; cartinine acyl transferase and long-chain enoyl-CoA hydratase up-regulated from 7 through 18 days post differentiation onset. These data indicate TCA up-regulation for enhanced metabolic and citrate output necessary for lipid synthesis in adipocytes. Paradoxically, the data also show the simultaneous increase in the fatty acid oxidation, indicating a metabolic overdrive state. Biochemical assays showing peaks in ATP and ROS generation in 3 day old adipocytes provide further evidence of this overdrive state. A second peak in ROS generation occurred in 10 day old adipocytes; concurrent ATP generation reduced to near pre-adipocyte levels and this may indicate a metabolic shift that may be responsible for increased oxidative stress in hypertrophic adipocytes. We developed a doxycycline inducible CYP2E1 expressing HepG2 cell line using the pTet-On/pRevTRE expression system to allow greater control and sensitivity in the generation CYP2E1 mediated oxidative stress. Our cell line (RD12) demonstrated stability and tight expression control. After induction, RD12 cells showed 30 percent higher CYP2E1 activity when compared to the constitutive E47 cell line. RD12 cells showed 30 percent greater toxicity than E47 cells and 25 percent less free glutathione when exposed to 20 mM acetaminophen, indicating RD12 cells are more sensitive to the effects reactive intermediates and oxidative stress generated by CYP2E1. We conducted a survey of the toxicity of dietary fatty acids (oleic, linoleic, and palmitic) on HepG2 cells to determine fatty acid doses that induced metabolic changes, but did not cause excessive cell death. The dose of 0.20 mM linoleic and palmitic acid for 48 hours produced low toxicity, but oleic acid actually produced lower toxicity than untreated cells. After exposure cells were treated with a pro-oxidant to determine which fatty acid increased the susceptibility to protein carbonylation. The carbonylated protein isolation procedure indicated the palmitic acid may induce more carbonylation than oleic acid, but greater efficiency in the isolation procedure is required for a confidant determination.

proteomics

3T3-L1

adipocyte

HepG2

oxidative stress

iTRAQ

quantitative

mass spectrometry

mitochondria

metabolism

CYP2E1