Gene Regulation During Development

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Gene Control in Development

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Presentation transcript:

Gene Regulation During Development Chapter 18 Gene Regulation During Development 7 and 9 November, 2004

Overview Differences in cell type are fundamentally differences in gene expression. These expression differences are often monitored using microarray hybridization. Differential gene expression is initiated by asymmetrical mRNA distribution, cell-cell contact, or by diffusible signals. Gradients of signaling molecules can give location information to cells. Asymmetrically distributed mRNAs use the cytoskeleton for localization. Drosophila embryogenesis is a well-understood system of animal development. A morphogen gradient controls dorsal-ventral orientation in Drosophila. Asymmetrically distributed mRNAs control anterior-posterior orientation and ultimately segmentation. Segmentation also depends on the interplay of regulators at the control regions of genes. Bioinformatics tools are useful in identifying genes that are developmentally regulated.

Signaling Differentiation

Transducing the Signal

Regualtion in a Morphogen Gradient

Regulation by Asymmetrically Distributed mRNA

Regulation by Asymmetrically Distributed mRNA

Polar Cytoskeletal Elements

Regulation by Cell-cell contact in B. subtilis

Regulation by Cell-cell contact in Animal Development

Regulation by Cell-cell contact in Animal Development

Morphogen Gradient

Drosophila Development

Spätzle-Toll create a gradient of Dorsal in nuclei.

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Bicoid regulates orthodenticle and zygotic hunchback.

Maternal hunchback mRNA is evenly distributed, but translationally repressed by the posteriorly concentrated nanos.

The hunchback gradient regulates gap genes as a transcriptional repressor.

Gap genes direct the expression of pair-rule genes.

Gap genes direct the expression of pair-rule genes.

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Enhancer autonomy requires short-range repression.

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