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DNA-mediated cooperativity facilitates the co-selection of cryptic enhancer sequences by SOX2 and PAX6 transcription factors

journal contribution
submitted on 2024-09-05, 12:45 and posted on 2024-09-05, 12:46 authored by Kamesh Narasimhan, Shubhadra Pillay, Yong-Heng Huang, Sriram Jayabal, Barath Udayasuryan, Veeramohan Veerapandian, Prasanna Kolatkar, Vlad Cojocaru, Konstantin Pervushin, Ralf Jauch

Sox2 and Pax6 are transcription factors that direct cell fate decision during neurogenesis, yet the mechanism behind how they cooperate on enhancer DNA elements and regulate gene expression is unclear. By systematically interrogating Sox2 and Pax6 interaction on minimal enhancer elements, we found that cooperative DNA recognition relies on combinatorial nucleotide switches and precisely spaced, but cryptic composite DNA motifs. Surprisingly, all tested Sox and Pax paralogs have the capacity to cooperate on such enhancer elements. NMR and molecular modeling reveal very few direct protein–protein interactions between Sox2 and Pax6, suggesting that cooperative binding is mediated by allosteric interactions propagating through DNA structure. Furthermore, we detected and validated several novel sites in the human genome targeted cooperatively by Sox2 and Pax6. Collectively, we demonstrate that Sox–Pax partnerships have the potential to substantially alter DNA target specificities and likely enable the pleiotropic and context-specific action of these cell-lineage specifiers.

Other Information

Published in: Nucleic Acids Research
License: http://creativecommons.org/licenses/by/4.0/
See article on publisher's website: https://dx.doi.org/10.1093/nar/gku1390

Funding

Open Access funding provided by MOST China-EU Science and Technology Cooperation Program (2013DFE33080).

Max Planck Society and the Deutsche Forschungsgemeinschaft (SPP1356 - CO 975/1-1).

History

Language

  • English

Publisher

Oxford University Press

Publication Year

  • 2015

License statement

This Item is licensed under the Creative Commons Attribution 4.0 International License.

Institution affiliated with

  • Hamad Bin Khalifa University
  • Qatar Biomedical Research Institute - HBKU