The mammalian genome has a complex, functional 3D organization. However, it remains largely unknown how DNA contacts are orchestrated by chromatin organizers. Here, we infer from only Hi-C the cell-type-specific arrangement of DNA binding sites sufficient to recapitulate, through polymer physics, contact patterns genome wide. Our model is validated by its predictions in a set of duplications at Sox9 against available independent data. The binding site types fall in classes that well match chromatin states from segmentation studies, yet they have an overlapping, combinatorial organization along chromosomes necessary to accurately explain contact specificity. The chromatin signatures of the binding site types return a code linking chromatin states to 3D architecture. The code is validated by extensive de novo predictions of Hi-C maps in an independent set of chromosomes. Overall, our results shed light on how 3D information is encrypted in 1D chromatin via the specific combinatorial arrangement of binding sites.
Polymer physics reveals a combinatorial code linking 3D chromatin architecture to 1D chromatin states / Esposito, Andrea; Bianco, Simona; Chiariello, Andrea M.; Abraham, Alex; Fiorillo, Luca; Conte, Mattia; Campanile, Raffaele; Nicodemi, Mario. - In: CELL REPORTS. - ISSN 2211-1247. - 38:13(2022), p. 110601. [10.1016/j.celrep.2022.110601]
Polymer physics reveals a combinatorial code linking 3D chromatin architecture to 1D chromatin states
Esposito, AndreaPrimo
;Bianco, Simona;Chiariello, Andrea M.;Abraham, Alex;Fiorillo, Luca;Conte, Mattia;Campanile, Raffaele;Nicodemi, Mario
2022
Abstract
The mammalian genome has a complex, functional 3D organization. However, it remains largely unknown how DNA contacts are orchestrated by chromatin organizers. Here, we infer from only Hi-C the cell-type-specific arrangement of DNA binding sites sufficient to recapitulate, through polymer physics, contact patterns genome wide. Our model is validated by its predictions in a set of duplications at Sox9 against available independent data. The binding site types fall in classes that well match chromatin states from segmentation studies, yet they have an overlapping, combinatorial organization along chromosomes necessary to accurately explain contact specificity. The chromatin signatures of the binding site types return a code linking chromatin states to 3D architecture. The code is validated by extensive de novo predictions of Hi-C maps in an independent set of chromosomes. Overall, our results shed light on how 3D information is encrypted in 1D chromatin via the specific combinatorial arrangement of binding sites.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.