Renee E. Metzler scite author profile

Renee E. Metzler

2Publications

32Citation Statements Received

137Citation Statements Given

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137

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California Institute of Technology, University of Wisconsin–Madison

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Unraveling the Mechanism of a Potent Transcriptional Activator

Lü¹,

Rowe

Brennan

et al. 2005

Journal of Biological Chemistry

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Despite their enormous potential as novel research tools and therapeutic agents, artificial transcription factors (ATFs) that up-regulate transcription robustly in vivo remain elusive. In investigating an ATF that does function exceptionally well in vivo, we uncovered an unexpected relationship between transcription function and a binding interaction between the activation domain and an adjacent region of the DNA binding domain. Disruption of this interaction leads to complete loss of function in vivo, even though the activation domain is still able to bind to its target in the transcriptional machinery. We propose that this interaction parallels those between natural activation domains and their regulatory proteins, concealing the activation domain from solvent and the cellular milieu until it binds to its transcriptional machinery target. Inclusion of this property in the future design of ATFs should enhance their efficacy in vivo.

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Temperature-sensitive protein–DNA dimerizers

Hauschild

Metzler

Arndt

et al. 2005

Proc. Natl. Acad. Sci. U.S.A.

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Programmable DNA-binding polyamides coupled to short peptides have led to the creation of synthetic artificial transcription factors. A hairpin polyamide-YPWM tetrapeptide conjugate facilitates the binding of a natural transcription factor Exd to an adjacent DNA site. Such small molecules function as protein-DNA dimerizers that stabilize complexes at composite DNA binding sites. Here we investigate the role of the linker that connects the polyamide to the peptide. We find that a substantial degree of variability in the linker length is tolerated at lower temperatures. At physiological temperatures, the longest linker tested confers a ''switch''-like property on the protein-DNA dimerizer, in that it abolishes the ability of the YPWM moiety to recruit the natural transcription factor to DNA. These observations provide design principles for future artificial transcription factors that can be externally regulated and can function in concert with the cellular regulatory circuitry.DNA recognition ͉ extradenticle ͉ HOX proteins ͉ polyamide

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Renee E. Metzler

Unraveling the Mechanism of a Potent Transcriptional Activator

Temperature-sensitive protein–DNA dimerizers

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