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Structural mechanism of bivalent histone H3K4me3K9me3 recognition by the Spindlin1/C11orf84 complex in rRNA transcription activation

Yongming Du, Yinxia Yan, Si Xie, Hao Huang, Xin Wang, Ray Kit Ng, Ming‐Ming Zhou, Chengmin Qian

2021Nature Communications32 citationsDOIOpen Access PDF

Abstract

Spindlin1 is a unique multivalent epigenetic reader that facilitates ribosomal RNA transcription. In this study, we provide molecular and structural basis by which Spindlin1 acts in complex with C11orf84 to preferentially recognize non-canonical bivalent mark of trimethylated lysine 4 and lysine 9 present on the same histone H3 tail (H3K4me3K9me3). We demonstrate that C11orf84 binding stabilizes Spindlin1 and enhances its association with bivalent H3K4me3K9me3 mark. The functional analysis suggests that Spindlin1/C11orf84 complex can displace HP1 proteins from H3K4me3K9me3-enriched rDNA loci, thereby facilitating the conversion of these poised rDNA repeats from the repressed state to the active conformation, and the consequent recruitment of RNA Polymerase I for rRNA transcription. Our study uncovers a previously unappreciated mechanism of bivalent H3K4me3K9me3 recognition by Spindlin1/C11orf84 complex required for activation of rRNA transcription.

Topics & Concepts

Bivalent (engine)Transcription (linguistics)RNA polymerase IIHistoneBiologyHistone H3Ribosomal RNATranscription preinitiation complexGeneticsRNA polymerase IRNARNA polymeraseCell biologyMolecular biologyChemistryDNAPromoterGeneGene expressionLinguisticsPhilosophyMetalOrganic chemistryRNA modifications and cancerGenomics and Chromatin DynamicsRNA and protein synthesis mechanisms
Structural mechanism of bivalent histone H3K4me3K9me3 recognition by the Spindlin1/C11orf84 complex in rRNA transcription activation | Litcius