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Connecting a promoter-bound protein to TBP bypasses the need for a transcriptional activation domain. Chatterjee, Sukalyan; Struhl, Kevin [Letter] Nature. 374(6525):820-822, April 27, 1995.
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Biochemical analyses have suggested potential targets for transcriptional activation domains, which include several components of the RNA polymerase II machinery *RF 1-7*, as well as the chromatin template [8-12]. Here we examine the mechanism of transcriptional activation in yeast cells by connecting a heterologous DNA-binding domain (LexA) to the TATA-binding protein (TBP). LexA-TBP efficiently activates transcription from a promoter containing a LexA operator upstream of a TATA element. Activation is promoter-specific and is sensitive to mutations on the DNA-binding surface of TBP; hence it is not due to a fortuitous activation domain on TBP. Thus a promoter-bound protein lacking an activation domain can stimulate transcription if it is directly connected to TBP. This suggests that recruitment of TBP to the promoter can be a rate-limiting step for transcription in vivo, and that interactions between activation domains and factors that function after TBP recruitment can be bypassed for activation.
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