Identification and use of zinc finger transcription factors that increase production of recombinant proteins in yeast and mammalian cells.

Randomized ZFP-TF libraries could induce a specific phenotype without detailed knowledge about the phenotype of interest because, theoretically, the libraries could modulate any gene in the target organism. We have developed a novel method for enhancing the efficiency of recombinant protein production in mammalian and microbial cells using combinatorial libraries of zinc finger protein transcription factors. To this end, we constructed tens of thousands of zinc finger proteins (ZFPs) with distinct DNA-binding specificities and fused these ZFPs to either a transcriptional activation or repression domain to make transcriptional activators or repressors, respectively.

Phenotypic alteration of eukaryotic cells using randomized libraries of artificial transcription factors.

We have developed a method in which randomized libraries of zinc finger-containing artificial transcription factors are used to induce phenotypic variations in yeast and mammalian cells. By linking multiple zinc-finger domains together, we constructed more than 100,000 zinc-finger proteins with diverse DNA-binding specificities and fused each of them to either a transcription activation or repression domain. The resulting transcriptional regulatory proteins were expressed individually in cells, and the transfected cells were screened for various phenotypic changes, such as drug resistance, thermotolerance or osmotolerance in yeast, and differentiation in mammalian cells.

Human zinc fingers as building blocks in the construction of artificial transcription factors.

We describe methods for generating artificial transcription factors capable of up- or downregulating the expression of genes whose promoter regions contain the target DNA sequences. To accomplish this, we screened zinc fingers derived from sequences in the human genome and isolated 56 zinc fingers with diverse DNA-binding specificities. We used these zinc fingers as modular building blocks in the construction of novel, sequence-specific DNA-binding proteins.