Designing Transcription Factor Architectures For Drug Discovery

doi:10.1124/mol.104.002758

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First published on August 31, 2004; DOI: 10.1124/mol.104.002758

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Received for publication May 20, 2004.
Revised August 19, 2004.
Accepted for publication August 25, 2004.

Designing Transcription Factor Architectures For Drug Discovery

pilar blancafort ¹, david j segal ², Carlos F. Barbas III ¹^*

¹ The Scripps Research Institute, BCC-550 ² university of arizona

^* Address correspondence to: E-mail: carlos{at}scripps.edu

Abstract

Recent advances in the design, selection, and engineering ofDNA binding proteins have led to the emerging field of designertranscription factors (TFs). Modular DNA-binding protein domainscan be assembled to recognize a given sequence of a DNA in aregulatory region of a targeted gene. TFs can be readily preparedby linking the DNA-binding protein to a variety of effectordomains (ED) that mediate transcriptional activation or repression.Furthermore, the interaction between the TF and the genomicDNA can be regulated by several approaches, including chemicalregulation by a variety of small molecules. Genome-wide singletarget specificity has been demonstrated using arrays of sequence-specificzinc finger (ZF) domains, polydactyl proteins. Any laboratorytoday can easily construct polydactyl ZF proteins by linkageof predefined ZF units that recognize specific triplets of DNA.The potential of this technology to alter the transcriptionof specific genes, to discover new genes, and to induce phenotypesin cells and organisms is now being applied in the areas ofmolecular therapeutics, pharmacology, biotechnology and functionalgenomics.

Key words: DNA binding sites, Promoter analysis, Phage display, Regulation of gene expression, Knockout, Overexpression, RNA/siRNA, Oncogenes, Transcription targets, Angiogenesis

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