Michael A. Horner scite author profile

Xenobiotic compounds pose a constant threat to the survival of all organisms and to overcome this, animals mount an elaborate transcriptional response, regulating a battery of enzymes that detoxify these compounds. Several transcription factors have been identified in vertebrates that regulate this response. In contrast, little is known about this pathway in insects. We show that the Drosophila Nrf2 ortholog, CncC, is a central regulator of xenobiotic detoxification responses. A binding site for CncC and its heterodimer partner Maf is sufficient and necessary for robust transcriptional responses to three xenobiotic compounds, phenobarbital (PB), chlorpromazine, and caffeine. Genetic manipulations that alter the levels of CncC, or its negative regulator Keap1, lead to predictable changes in xenobiotic‐inducible gene expression. Transcriptional profiling studies reveal that more than half of the genes regulated by PB are also controlled by CncC. Consistent with these effects on detoxification gene expression, activation of the CncC/Keap1 pathway in Drosophila is sufficient to confer resistance to the pesticide malathion. Further, in the two pesticide‐resistant strains of Drosophila, the pathway is constitutively active, leading to overexpression of several detoxification genes. Our current efforts are aimed at identifying the mutations that constitutively activate the pathway in these strains.

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pha-4, anHNF-3 homolog, specifies pharyngeal organ identity inCaenorhabditis elegans

Horner¹,

Quintin²,

Domeier³

et al. 1998

Genes Dev.

198

254

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To build complex organs, embryos have evolved mechanisms that integrate the development of cells unrelated to one another by cell type or ancestry. Here we show that the pha-4 locus establishes organ identity for the Caenorhabditis elegans pharynx. In pha-4 mutants, pharyngeal cells are transformed into ectoderm. Conversely, ectopic pha-4 expression produces excess pharyngeal cells. pha-4 encodes an HNF-3 homolog selectively expressed in the nascent digestive tract, including all pharynx precursors at the time they are restricted to a pharyngeal fate. We suggest that pha-4 is a key component of a transcription-based mechanism to endow cells with pharyngeal organ identity.

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The DHR96 nuclear receptor regulates xenobiotic responses in Drosophila

et al. 2006

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Exposure to xenobiotics such as plant toxins, pollutants, or prescription drugs triggers a defense response, inducing genes that encode key detoxification enzymes. Although xenobiotic responses have been studied in vertebrates, little effort has been made to exploit a simple genetic system for characterizing the molecular basis of this coordinated transcriptional response. We show here that approximately 1000 transcripts are significantly affected by phenobarbital treatment in Drosophila. We also demonstrate that the Drosophila ortholog of the human SXR and CAR xenobiotic receptors, DHR96, plays a role in this response. A DHR96 null mutant displays increased sensitivity to the sedative effects of phenobarbital and the pesticide DDT as well as defects in the expression of many phenobarbital-regulated genes. Metabolic and stress-response genes are also controlled by DHR96, implicating its role in coordinating multiple response pathways. This work establishes a new model system for defining the genetic control of xenobiotic stress responses.

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Whole-Genome Analysis of Temporal Gene Expression during Foregut Development

et al. 2004

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We have investigated the cis-regulatory network that mediates temporal gene expression during organogenesis. Previous studies demonstrated that the organ selector gene pha-4/FoxA is critical to establish the onset of transcription of Caenorhabditis elegans foregut (pharynx) genes. Here, we discover additional cis-regulatory elements that function in combination with PHA-4. We use a computational approach to identify candidate cis-regulatory sites for genes activated either early or late during pharyngeal development. Analysis of natural or synthetic promoters reveals that six of these sites function in vivo. The newly discovered temporal elements, together with predicted PHA-4 sites, account for the onset of expression of roughly half of the pharyngeal genes examined. Moreover, combinations of temporal elements and PHA-4 sites can be used in genome-wide searches to predict pharyngeal genes, with more than 85% accuracy for their onset of expression. These findings suggest a regulatory code for temporal gene expression during foregut development and provide a means to predict gene expression patterns based solely on genomic sequence.

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Michael A. Horner

Transcriptional regulation of xenobiotic detoxification in Drosophila

pha-4, anHNF-3 homolog, specifies pharyngeal organ identity inCaenorhabditis elegans

The DHR96 nuclear receptor regulates xenobiotic responses in Drosophila

Whole-Genome Analysis of Temporal Gene Expression during Foregut Development

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