Stability of the Sp3-DNA complex is promoter-specific: Sp3 efficiently competes with Sp1 for binding to promoters containing multiple Sp-sites

doi:10.1093/nar/gkg706

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Nucleic Acids Research, 2003, Vol. 31, No. 18 5368-5376
© 2003 Oxford University Press

Stability of the Sp3–DNA complex is promoter-specific: Sp3 efficiently competes with Sp1 for binding to promoters containing multiple Sp-sites

Bo Yu, Pran K. Datta and Srilata Bagchi^*

Center for Molecular Biology of Oral Diseases, College of Dentistry (M/C 860), University of Illinois at Chicago, 801 South Paulina Street, Chicago, IL 60612, USA

*To whom correspondence should be addressed. Tel: +1 312 413 0683; Fax: +1 312 413 1604; Email: sbagchi{at}uic.edu
Present address:
Pran K. Datta, Vanderbilt Cancer Center, Nashville, TN 37232-6838, USA

The transcription regulatory protein Sp3 shares more than 90%sequence homology with Sp1 in the DNA-binding domain and theybind to the same cognate DNA-element. However, the transcriptionalactivities of these two Sp-family factors are not equivalent.While Sp1 functions strictly as a transcriptional activator,Sp3 has been shown to be transcriptionally inactive for promoterscontaining multiple Sp-binding sites. In the present study,we show that the DNA-binding property of Sp3 is promoter dependentand is different from Sp1. The 116 kDa Sp3 polypeptide bindsas a monomer to a single Sp-binding site but readily forms slowermigrating complexes with adjacent Sp-binding sites. The slowermigrating Sp3–DNA complexes are significantly more stablethan monomeric Sp3–DNA complexes or multimeric Sp1–DNAcomplexes. As a consequence, Sp3 can efficiently compete withSp1 for binding to regions containing multiple Sp sites. Thetranscription regulatory function of Sp3 is also significantlydifferent from Sp1. Unlike Sp1, Sp3 does not synergisticallyactivate transcription of promoters containing multiple Sp-bindingsites. Therefore, although Sp3 is a transcription activator,Sp3 reduces Sp1-dependent transcription of promoters containingadjacent Sp-binding sites by competing with Sp1 for promoteroccupancy and thereby blocking the synergistic transactivationfunction of Sp1. Taken together, this study provides a possiblemechanism of the promoter-specific transcription repressionfunction of Sp3.

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