Selective Targeting of Non-centrosomal AURKA Functions Through Use of a Targeted Protein Degradation Tool

Overview

Journal Commun Biol

Specialty Biology

Date 2021 May 29

PMID 34050235

Citations 16

Authors

Richard Wang

Camilla Ascanelli

Ahmed Abdelbaki

Alex Fung

Tim Rasmusson

Iacovos Michaelides

Karen Roberts

Catherine Lindon

Affiliations

Soon will be listed here.

Abstract

Targeted protein degradation tools are becoming a new therapeutic modality, allowing small molecule ligands to be reformulated as heterobifunctional molecules (PROteolysis Targeting Chimeras, PROTACs) that recruit ubiquitin ligases to targets of interest, leading to ubiquitination and destruction of the targets. Several PROTACs against targets of clinical interest have been described, but detailed descriptions of the cell biology modulated by PROTACs are missing from the literature. Here we describe the functional characterization of a PROTAC derived from AURKA inhibitor MLN8237 (alisertib). We demonstrate efficient and specific destruction of both endogenous and overexpressed AURKA by Cereblon-directed PROTACs. At the subcellular level, we find differential targeting of AURKA on the mitotic spindle compared to centrosomes. The phenotypic consequences of PROTAC treatment are therefore distinct from those mediated by alisertib, and in mitotic cells differentially regulate centrosome- and chromatin- based microtubule spindle assembly pathways. In interphase cells PROTAC-mediated clearance of non-centrosomal AURKA modulates the cytoplasmic role played by AURKA in mitochondrial dynamics, whilst the centrosomal pool is refractory to PROTAC-mediated clearance. Our results point to differential sensitivity of subcellular pools of substrate, governed by substrate conformation or localization-dependent accessibility to PROTAC action, a phenomenon not previously described for this new class of degrader compounds.

Citing Articles

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Workflow for E3 Ligase Ligand Validation for PROTAC Development.

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Targeting N-Myc in neuroblastoma with selective Aurora kinase A degraders.

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Identification of suitable target/E3 ligase pairs for PROTAC development using a rapamycin-induced proximity assay (RiPA).

Adhikari B, Schneider K, Diebold M, Sotriffer C, Wolf E Elife. 2024; 13.

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Crystal structures of DCAF1-PROTAC-WDR5 ternary complexes provide insight into DCAF1 substrate specificity.

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