17β‐Trenbolone exposure programs metabolic dysfunction in larval medaka

Mizukami-Murata, Satomi; Kishi-Kadota, Katsuyuki; Nishida, Takashi

doi:10.1002/tox.22158

Cited by 8 publications

(6 citation statements)

References 40 publications

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“…Production of phenotypic males was more sensitive in zebrafish (100% males at 0.05 μg/L) compared with medaka (no effect at 0.05 μg/L). Mizukami‐Murata et al () confirmed in a developmental study (exposure 0–60 d post fertilization) the relative insensitivity of Japanese medaka, with phenotypic masculinization occurring only at concentrations >0.1 μg 17β‐trenbolone/L. The enhanced sensitivity to 17β‐trenbolone during sex differentiation in zebrafish could be a consequence of the extended period of juvenile hermaphroditism that occurs in this species compared with medaka.…”

Section: Summary Of Available Literaturementioning

confidence: 84%

“…A number of studies have evaluated changes in gene expression in 17β‐trenbolone‐exposed fish at different life stages, using both targeted (polymerase chain reaction [PCR]) and nontargeted (e.g., microarray) techniques (Hook et al ; Garcia‐Reyero et al ; Dorts et al ; Ekman et al ; Brockmeier et al ; Leet et al ; Mizukami‐Murata et al ). For example, Leet et al () observed down‐regulation of several genes involved in steroid synthesis in larval fathead minnows exposed to 17β‐trenbolone, consistent with a compensatory response to overstimulation of the HPG axis by exogenous steroids.…”

Section: Summary Of Available Literaturementioning

confidence: 99%

“…Similarly, Brockmeier et al () used a custom microarray to investigate transcriptomic responses in the liver of female mosquitofish exposed to 17β‐trenbolone for 14 d. Many metabolic processes not necessarily directly linked to the androgen receptor were increased in response to 17β‐trenbolone exposure, including lipid metabolic processes, regulation of protein metabolic processes, lipoprotein metabolic processes, cholesterol biosynthesis processes, and cholesterol transport and metabolism. Finally, Mizukami‐Murata et al () used both microarray and PCR measurements to evaluate the effects of 17β‐trenbolone on 10 genes related to cholesterol synthesis and observed an induction of these genes, which could be a secondary response to depletion of cellular cholesterol stores.…”

Section: Summary Of Available Literaturementioning

confidence: 99%

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A critical review of the environmental occurrence and potential effects in aquatic vertebrates of the potent androgen receptor agonist 17β‐trenbolone

Ankley

Coady

Gross³

et al. 2018

Enviro Toxic and Chemistry

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Trenbolone acetate is widely used in some parts of the world for its desirable anabolic effects on livestock. Several metabolites of the acetate, including 17b-trenbolone, have been detected at low nanograms per liter concentrations in surface waters associated with animal feedlots. The 17b-trenbolone isomer can affect androgen receptor signaling pathways in various vertebrate species at comparatively low concentrations/doses. The present article provides a comprehensive review and synthesis of the existing literature concerning exposure to and biological effects of 17b-trenbolone, with an emphasis on potential risks to aquatic animals. In vitro studies indicate that, although 17b-trenbolone can activate several nuclear hormone receptors, its highest affinity is for the androgen receptor in all vertebrate taxa examined, including fish. Exposure of fish to nanograms per liter water concentrations of 17b-trenbolone can cause changes in endocrine function in the short term, and adverse apical effects in longer exposures during development and reproduction. Impacts on endocrine function typically are indicative of inappropriate androgen receptor signaling, such as changes in sex steroid metabolism, impacts on gonadal stage, and masculinization of females. Exposure of fish to 17b-trenbolone during sexual differentiation in early development can greatly skew sex ratios, whereas adult exposures can adversely impact fertility and fecundity. To fully assess ecosystem-level risks, additional research is warranted to address uncertainties as to the degree/breadth of environmental exposures and potential population-level effects of 17b-trenbolone in sensitive species.

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Section: Summary Of Available Literaturementioning

confidence: 84%

Section: Summary Of Available Literaturementioning

confidence: 99%

Section: Summary Of Available Literaturementioning

confidence: 99%

See 1 more Smart Citation

A critical review of the environmental occurrence and potential effects in aquatic vertebrates of the potent androgen receptor agonist 17β‐trenbolone

Ankley

Coady

Gross³

et al. 2018

Enviro Toxic and Chemistry

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“…Zebrafish ( Danio rerio ) exposed to trenbolone (TRB) during sexual differentiation develop skewed sex ratios and all male populations at 0.01 μg/L and above ( Larsen and Baatrup 2010 ; Morthorst et al 2010 ; Boettcher 2011 ; Baumann et al 2015 ) this phenotypic sex change is irreversible ( Larsen and Baatrup 2010 ; Morthorst et al 2010 ; Baumann et al 2015 ). The TRB-induced reversal to a male phenotype appears more sensitive in zebrafish than in medaka ( Örn et al 2006 ; Mizukami-Murata et al 2015 ). Other endocrine mechanisms can also lead to masculinisation in fish (for a review see Matthiessen and Weltje 2015 ).…”

Section: Delayed Effectsmentioning

confidence: 99%

Uncertainties in biological responses that influence hazard and risk approaches to the regulation of endocrine active substances

Parrott

Bjerregaard

Brugger

et al. 2017

Integr Environ Assess Manag

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Endocrine‐disrupting substances (EDS) may have certain biological effects including delayed effects, multigenerational effects, and may display nonmonotonic dose–response (NMDR) relationships that require careful consideration when determining environmental hazards. Endocrine disrupting substances can have specific and profound effects when exposure occurs during sensitive windows of the life cycle (development, reproduction). This creates the potential for delayed effects that manifest when exposure has ceased, possibly in a different life stage. This potential underscores the need for testing in appropriate (sensitive) life stages and full life cycle designs. Such tests are available in the Organisation for Economic Co‐operation and Development (OECD) tool box and should be used to derive endpoints that can be considered protective of all life stages. Similarly, the potential for effects to be manifest in subsequent generations (multigenerational effects) has also been raised as a potential issue in the derivation of appropriate endpoints for EDS. However, multigenerational studies showing increasing sensitivity of successive generations are uncommon. Indeed this is reflected in the design of new higher tier tests to assess endocrine active substances (EAS) that move to extended one‐generation designs and away from multi‐generational studies. The occurrence of NMDRs is also considered a limiting factor for reliable risk assessment of EDS. Evidence to date indicates NMDRs are more prevalent in in vitro and mechanistic data, not often translating to adverse apical endpoints that would be used in risk assessment. A series of steps to evaluate NMDRs in the context of endocrine hazard and risk assessment procedures is presented. If careful consideration of delayed, multigenerational effects and NMDRs is made, it is feasible to assess environmental endocrine hazards and derive robust apical endpoints for risk assessment procedures ensuring a high level of environmental protection. Integr Environ Assess Manag 2017;13:293–301. © 2016 The Authors. Integrated Environmental Assessment and Management published by Wiley Periodicals, Inc. on behalf of Society of Environmental Toxicology & Chemistry (SETAC)

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“…However, there are no reports on body burden of 17β‐trenbolone in birds in the environment. Whereas effects of 17β‐trenbolone have been well characterized in fish (Ankley et al 2003; Ekman et al 2011; Mizukami‐Murata et al 2016), there have been few studies in avian species, primarily using Japanese quail ( Coturnix japonica ; Quinn et al 2007a; Henry et al 2012; Karouna‐Renier et al 2017). Similar to results in fish, these studies also demonstrated deleterious effects on plasma hormone levels and reproductive behavior, as well as decreased egg production.…”

Section: Introductionmentioning

confidence: 99%

Sex‐ and Developmental Stage–Related Differences in the Hepatic Transcriptome of Japanese Quail (Coturnix japonica) Exposed to 17β‐Trenbolone

Mittal

Henry

Cornman

et al. 2021

Enviro Toxic and Chemistry

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Endocrine‐disrupting chemicals can cause transcriptomic changes that may disrupt biological processes associated with reproductive function including metabolism, transport, and cell growth. We investigated effects from in ovo and dietary exposure to 17β‐trenbolone (at 0, 1, and 10 ppm) on the Japanese quail (Coturnix japonica) hepatic transcriptome. Our objectives were to identify differentially expressed hepatic genes, assess perturbations of biological pathways, and examine sex‐ and developmental stage–related differences. The number of significantly differentially expressed genes was higher in embryos than in adults. Male embryos exhibited greater differential gene expression than female embryos, whereas in adults, males and females exhibited similar numbers of differentially expressed genes (>2‐fold). Vitellogenin and apovitellenin‐1 were up‐regulated in male adults exposed to 10 ppm 17β‐trenbolone, and these birds also exhibited indications of immunomodulation. Functional grouping of differentially expressed genes identified processes including metabolism and transport of biomolecules, enzyme activity, and extracellular matrix interactions. Pathway enrichment analyses identified as perturbed peroxisome proliferator–activated receptor pathway, cardiac muscle contraction, gluconeogenesis, growth factor signaling, focal adhesion, and bile acid biosynthesis. One of the primary uses of 17β‐trenbolone is that of a growth promoter, and these results identify effects on mechanistic pathways related to steroidogenesis, cell proliferation, differentiation, growth, and metabolism of lipids and proteins. Environ Toxicol Chem 2021;40:2559–2570. © 2021 SETAC. This article has been contributed to by US Government employees and their work is in the public domain in the USA.

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17β‐Trenbolone exposure programs metabolic dysfunction in larval medaka

Cited by 8 publications

References 40 publications

A critical review of the environmental occurrence and potential effects in aquatic vertebrates of the potent androgen receptor agonist 17β‐trenbolone

A critical review of the environmental occurrence and potential effects in aquatic vertebrates of the potent androgen receptor agonist 17β‐trenbolone

Uncertainties in biological responses that influence hazard and risk approaches to the regulation of endocrine active substances

Sex‐ and Developmental Stage–Related Differences in the Hepatic Transcriptome of Japanese Quail (Coturnix japonica) Exposed to 17β‐Trenbolone

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