Reprint of: CYP1A protein expression and catalytic activity in double-crested cormorants experimentally exposed to Deepwater Horizon Mississippi Canyon 252 oil

Alexander, Courtney R.; Hooper, Michael J.; Cacela, Dave; Smelker, Kim D.; Calvin, Caleshia S.; Dean, Karen; Bursian, S. J.; Cunningham, Fred L.; Hanson‐Dorr, Katie C.; Horak, Katherine E.; Isanhart, John P.; Link, Jane E.; Shriner, Susan A.; Godard-Codding, Céline A.J.

doi:10.1016/j.ecoenv.2017.05.015

Cited by 14 publications

(3 citation statements)

References 67 publications

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“…Orally dosed birds received 5.2 ± 0.3 ml oil/kg BW and 8.4 + 0.9 ml oil/kg BW per day totaling 208 and 235 ml respectively, while the externally dosed birds likely only consumed (based on Hartung, 1963) a total of 38-38.5 g over 21 days , or approximately 0.9 ml/kg BW daily. There were additional signs and symptoms of this toxicity reported in other manuscripts describing these studies (Alexander et al, 2017;Cunningham et al, 2017;Harr et a, 2017a, c, d;Pritsos et al, 2017). These include increases in relative organ weight, hypertrophy and histopathological changes at necropsy, development of hemolytic anemia, inflammation and atrophy (Harr et al, 2017a(Harr et al, , 2017c, as well as newly documented clotting dysfunction, cardiomyopathy and associated functional losses (Harr et al, 2017d).…”

Section: Discussionmentioning

confidence: 95%

Changes in white cell estimates and plasma chemistry measurements following oral or external dosing of double-crested cormorants, Phalacocorax auritus , with artificially weathered MC252 oil

Dean

Bursian

Cacela

et al. 2017

Ecotoxicology and Environmental Safety

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A B S T R A C TScoping studies were designed whereby double-crested cormorants (Phalacocorax auritus) were dosed with artificially weathered Deepwater Horizon (DWH) oil either daily through oil injected feeder fish, or by application of oil directly to feathers every three days. Preening results in oil ingestion, and may be an effective means of orally dosing birds with toxicant to improve our understanding of the full range of physiological effects of oral oil ingestion on birds. Blood samples collected every 5-6 days were analyzed for a number of clinical endpoints including white blood cell (WBC) estimates and differential cell counts. Plasma biochemical evaluations were performed for changes associated with oil toxicity. Oral dosing and application of oil to feathers resulted in clinical signs and statistically significant changes in a number of biochemical endpoints consistent with petroleum exposure. In orally dosed birds there were statistically significant decreases in aspartate amino transferase (AST) and gamma glutamyl transferase (GGT) activities, calcium, chloride, cholesterol, glucose, and total protein concentrations, and increases in plasma urea, uric acid, and phosphorus concentrations. Plasma electrophoresis endpoints (pre-albumin, albumin, alpha-2 globulin, beta globulin, and gamma globulin concentrations and albumin: globulin ratios) were decreased in orally dosed birds. Birds with external oil had increases in urea, creatinine, uric acid, creatine kinase (CK), glutamate dehydrogenase (GLDH), phosphorus, calcium, chloride, potassium, albumin, alpha-1 globulin and alpha-2 globulin. Decreases were observed in AST, beta globulin and glucose. WBC also differed between treatments; however, this was in part driven by monocytosis present in the externally oiled birds prior to oil treatment.

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Section: Discussionmentioning

confidence: 95%

Changes in white cell estimates and plasma chemistry measurements following oral or external dosing of double-crested cormorants, Phalacocorax auritus , with artificially weathered MC252 oil

Dean

Bursian

Cacela

et al. 2017

Ecotoxicology and Environmental Safety

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“…Polycyclic aromatic hydrocarbons are known to bind to and activate the AhR, and the xenobioticmetabolizing monooxygenases, cytochrome P450 (CYP) 1A and 1B, bioactivate PAHs to more toxic metabolites after AhR activation (Schimada and Fujii-Kuiyama 2004). Activation of the PAH-responsive AhR pathway and a phase I response have been previously documented in other species of oil-exposed birds (e.g., Seaside Sparrow [Ammospiza maritima], Perez-Umphrey et al 2018; Bonisoli-Alquati et al 2020; double-crested cormorant, Alexander et al 2017). In addition, CYP1A activity is frequently measured as EROD induction, a common biomarker for PAH exposure in birds (Head et al 2015), and Bianchini and Morrissey (2018) reported elevated EROD activity in the high-dose group relative to controls in these same birds.…”

Section: Ahr Activationmentioning

confidence: 98%

Polycyclic Aromatic Hydrocarbons Alter the Hepatic Expression of Genes Involved in Sanderling (Calidris alba) Pre‐migratory Fueling

Bianchini

Crump

Farhat

et al. 2021

Enviro Toxic and Chemistry

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Polycyclic aromatic hydrocarbons (PAHs) impaired pre-migratory fueling in 49 orally dosed Sanderling (Calidris alba). In the present study, 8 genes related to fat deposition and PAH exposure were measured in liver subsamples from these same shorebirds. At the highest dose (1260 µg total PAH [tPAH]/kg body wt/day), PAH exposure decreased liver basic fatty acid binding protein 1 (Lbfabp) and hepatic lipase (Lipc) expression. The present study reveals candidate molecularlevel pathways for observed avian pre-migratory refueling impairment.

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“…Short of proving lethal, however, external (dermal) oil-contamination and respiratory exposures in birds induces increased lung-epithelial CYP1A expression, skin irritation, conjunctivitis and corneal ulcers, and also reduces the feathers' capacity to repel water, which leads to increased heat loss, and reductions in insulating capacities, buoyancy, and flight performance (Leighton, 1993;Jenssen, 1994;O'Hara and Morandin, 2010;Munilla et al, 2011;Fiorello et al, 2016;Maggini et al, 2017b;Dubansky et al, 2018). Beyond these effects of dermal and respiratory oil exposures, after an oil spill many birds continue being orally exposed for months and even for decades to varying concentrations of petroleum leading also for sublethal effects (Alexander et al, 2017;Esler et al, 2018). Oral exposure to oil occurs via ingestion of contaminated prey, grit and water during foraging, and also occurs during attempts for cleaning (preening) of oilcontaminated feathers (Hartung and Hunt, 1966;Pritsos et al, 2017b).…”

Section: Introductionmentioning

confidence: 99%

Dietary Exposure to Low Levels of Crude Oil Affects Physiological and Morphological Phenotype in Adults and Their Eggs and Hatchlings of the King Quail (Coturnix chinensis)

et al. 2021

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Despite the current knowledge of the devastating effects of external exposure to crude oil on animal mortality, the study of developmental, transgenerational effects of such exposure has received little attention. We used the king quail as an animal model to determine if chronic dietary exposure to crude oil in a parental population would affect morpho-physiological phenotypic variables in their immediate offspring generation. Adult quail were separated into three groups: (1) Control, and two experimental groups dietarily exposed for at least 3 weeks to (2) Low (800 PAH ng/g food), or (3) High (2,400 PAH ng/g food) levels of crude oil. To determine the parental influence on their offspring, we measured metabolic and respiratory physiology in exposed parents and in their non-exposed eggs and hatchlings. Body mass and numerous metabolic (e.g., O2 consumption, CO2 production) and respiratory (e.g., ventilation frequency and volume) variables did not vary between control and oil exposed parental groups. In contrast, blood PO2, PCO2, and SO2 varied among parental groups. Notably, water loss though the eggshell was increased in eggs from High oil level exposed parents. Respiratory variables of hatchlings did not vary between populations, but hatchlings obtained from High oil-exposed parents exhibited lower capacities to maintain body temperature while exposed to a cooling protocol in comparison to hatchlings from Low- and Control-derived parents. The present study demonstrates that parental exposure to crude oil via diet impacts some aspects of physiological performance of the subsequent first (F1) generation.

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Reprint of: CYP1A protein expression and catalytic activity in double-crested cormorants experimentally exposed to Deepwater Horizon Mississippi Canyon 252 oil

Cited by 14 publications

References 67 publications

Changes in white cell estimates and plasma chemistry measurements following oral or external dosing of double-crested cormorants, Phalacocorax auritus , with artificially weathered MC252 oil

Changes in white cell estimates and plasma chemistry measurements following oral or external dosing of double-crested cormorants, Phalacocorax auritus , with artificially weathered MC252 oil

Polycyclic Aromatic Hydrocarbons Alter the Hepatic Expression of Genes Involved in Sanderling (Calidris alba) Pre‐migratory Fueling

Dietary Exposure to Low Levels of Crude Oil Affects Physiological and Morphological Phenotype in Adults and Their Eggs and Hatchlings of the King Quail (Coturnix chinensis)

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