MassIVE MSV000096487
Complete Public PXD058144Asymmetric Engagement of Dimeric CRL3KBTBD4 by the Molecular Glue UM171 Licenses Degradation of HDAC1/2 Complexes
Description
UM171 is a potent small molecule agonist of ex vivo human hematopoietic stem cell
(HSC) self-renewal, a process that is tightly controlled by epigenetic regulation. By co
opting KBTBD4, a substrate receptor of the CULLIN3-RING E3 ubiquitin ligase complex,
UM171 promotes the degradation of members of the CoREST transcriptional
corepressor complex, thereby limiting HSC attrition. However, the direct target and
mechanism of action of UM171 remain unclear. Here, we reveal that UM171 acts as a
molecular glue to induce high-affinity interactions between KBTBD4 and HDAC1/2 to
promote the degradation of select corepressor complexes. Through proteomics and
chemical inhibitor studies, we discover that the principal target of UM171 is HDAC1/2.
Cryo-electron microscopy (cryo-EM) analysis of dimeric KBTBD4 bound to UM171 and
the LSD1-HDAC1-CoREST complex unveils an unexpected asymmetric assembly, in
which a single UM171 molecule enables a pair of KELCH-repeat propeller domains
from the structurally plastic KBTBD4 dimer to recruit HDAC1 by clamping on its catalytic
domain. One of the KBTBD4 propellers partially masks the rim of the HDAC1 active site
pocket, which is exploited by UM171 to extend the E3-neo-substrate interface. The
other propeller cooperatively strengthens HDAC1 binding via a separate and distinct
interface. The overall neomorphic interaction is further buttressed by an endogenous
cofactor of HDAC1-CoREST, inositol hexakisphosphate, which makes direct contacts
with KBTBD4 and acts as a second molecular glue. The functional relevance of the
quaternary complex interaction surfaces defined by cryo-EM is demonstrated by in situ
base editor scanning of KBTBD4 and HDAC1. By delineating the direct target of UM171
and its mechanism of action, our results reveal how the cooperativity offered by a large
dimeric CRL E3 family can be leveraged by a small molecule degrader and establish for
the first time a dual molecular glue paradigm.
[doi:10.25345/C5P26QG0N]
[dataset license: CC0 1.0 Universal (CC0 1.0)]
Keywords: UM171 ; DatasetType:Proteomics
Contact
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Principal Investigators: (in alphabetical order) |
Liron Bar-Peled, Massachusetts General Hospital Cancer Center, USA |
| Submitting User: | hbc8 |
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