Adam J. Kuhl scite author profile

In fish, exposure to estrogen or estrogen-mimicking chemicals (xenoestrogens) during a critical period of development can irreversibly invert sex differentiation. In medaka, a male-to-female reversal upon exposure to a xenoestrogen is accompanied by an increase in brain aromatase expression and activity. However, whether this increase is the direct cause of sex reversal is unknown. In this study we further examined the role brain aromatase plays in genesis of developmental abnormalities in response to endocrine-disrupting chemicals (EDCs). Further, the effects of a mixture of apparent antagonistic environmentally relevant EDCs on development were examined to determine if their combined actions could lessen each other’s impacts. To this end, hatchling medaka were subjected in a 2-week flow-through immersion exposure to an estrogen mimic [dichlorodiphenyltrichloroethane (o,p′-DDT)] and to pharmaceutical [fadrozole (FAD)] and environmental aromatase inhibitors [tributyltin (TBT)] alone and in combination. Brain aromatase expression and enzyme activity were measured on exposure days 5, 9, and 14 by real-time reverse-transcriptase polymerase chain reaction and tritiated water release assay, respectively. We recorded sex reversals at sexual maturity by examining the phenotypic and genotypic sex of d-rR–strain medaka. Results indicate that FAD and TBT inhibit aromatase activity in o,p′-DDT–treated fish but do not prevent feminization, indicating that increased brain aromatase activity is not critical to EDC-induced male-to-female sex inversion. The observation that estradiol biosynthesis inhibitors do not block the effect of the xenoestrogen suggests that in the environment, exposure to seemingly antagonistic EDCs does not necessarily lessen the harmful impacts of these compounds.

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CCAAT/Enhancer Binding Protein β, But Not Steroidogenic Factor-1, Modulates the Phthalate-Induced Dysregulation of Rat Fetal Testicular Steroidogenesis

Kuhl

Ross

Gaido

2007

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Prolonged in utero exposure of fetal male rats to dibutyl phthalate (DBP) can result in a feminized phenotype characterized by malformed epididymides, hypospadias, cryptorchidism, and retained thoracic nipples, among others. These symptoms likely result, in part, from decreased expression of steroidogenic enzymes and, therefore, reduced testosterone biosynthesis. However, the molecular mechanisms involved in these changes in gene expression profiles are unknown. To understand these mechanisms in rats, in vivo DNase footprinting was adapted to provide a semiquantitative map of changes in DNA-protein interactions in the promoter region of steroidogenic genes, including steroidogenic acute regulatory, scavenger receptor B-1, cytochrome P450 side chain cleavage, and cytochrome P450 17A1, that are down-regulated after an in utero DBP exposure. Regions with altered DNase protection were coordinated with a specific DNA binding protein event by EMSA, and binding activity confirmed with chromatin immunoprecipitation. Results demonstrated altered DNase protection at regions mapping to CCAAT/enhancer binding protein β (c/ebp β) and steroidogenic factor-1 (SF-1). Chromatin immunoprecipitation confirmed declines in DNA-protein interactions of c/ebp β in DBP treated animals, whereas SF-1 was reduced in both diethyl phthalate (nontoxic) and DBP (toxic) treatments. These results suggest that inhibition of c/ebp β, and not SF-1, is critical in DBP induced inhibition of steroidogenic genes. In addition, these observations suggest a pathway redundancy in the regulation of steroidogenesis in fetal testis. In conclusion, this study presents a snapshot of changes in the structure of transcriptional machinery and proposes a mechanism of action resulting from DBP exposure.

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Using a comparative in vivo DNase I footprinting technique to analyze changes in protein–DNA interactions following phthalate exposure

Kuhl

Ross

Gaido

2007

J Biochem & Molecular Tox

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Exposure to environmental chemicals often induces changes in gene expression leading to a variety of developmental and physiological problems. Understanding the underlying mechanism of these changes will aid in assessing human risk to these chemicals. Traditional methods for analyzing protein-DNA interactions include in vivo footprinting and chromatin immunoprecipitation (ChIP). However, ChIP does not provide binding location, and conventional footprinting is too subjective and time consuming for comparing protein binding in toxicological studies. Here, in vivo DNase I footprinting is adapted for use with the automated DNA sequencer to provide a semiquantitative map of changes in DNA-protein interactions in the promoter of steroidogenic acute regulatory (StAR) protein. StAR is the rate-limiting step in testosterone biosynthesis and is downregulated following in utero di-butyl phthalate (DBP) treatment in rats through an unknown mechanism. In vivo footprinting identified three regions of altered DNase digestibility following DBP treatment, and EMSA identified the corresponding transcription factors as SF-1, c/ebp beta, and GATA4. ChIP assays confirmed changes in protein-binding activity of SF-1 and c/ebp beta, but only c/ebp beta gesponds to only DBP. This suggests that c/ebp beta ginding is involved in DBP-induced transcriptional changes. By tailoring in vivo footprinting for toxicological studies, it can provide a detailed and accurate map of protein-DNA interactions and is an excellent first step in determining the changes in the structure of transcriptional machinery following an exogenous chemical treatment.

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Adam J. Kuhl

Brain aromatase in Japanese medaka (Oryzias latipes): Molecular characterization and role in xenoestrogen-induced sex reversal

Antiestrogens Inhibit Xenoestrogen-Induced Brain Aromatase Activity but Do Not Prevent Xenoestrogen-Induced Feminization in Japanese Medaka ( Oryzias latipes )

CCAAT/Enhancer Binding Protein β, But Not Steroidogenic Factor-1, Modulates the Phthalate-Induced Dysregulation of Rat Fetal Testicular Steroidogenesis

Using a comparative in vivo DNase I footprinting technique to analyze changes in protein–DNA interactions following phthalate exposure

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