The Nucleosome Remodeling and Deacetylase complex has an asymmetric, dynamic, and modular architecture

Low, Jason K. K.; Silva, Ana Pg; Tabar, Mehdi Sharifi; Torrado, Mario; Webb, Sarah R.; Parker, Benjamin L.; Sana, Maryam; Smits, C.; Schmidberger, J.W.; Brillault, Lou; Jackman, Matthew J.; Williams, David C.; Blobel, Gerd A.; Shepherd, Nicholas E.; Landsberg, Michael J.; Mackay, J.P.

doi:10.1101/2020.02.17.951822

Cited by 11 publications

(57 citation statements)

References 64 publications

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“…Considerable diversity is observed in subunit isoforms and NuRD-associated factors across tissues (Burgold et al, 2019; Denslow and Wade, 2007; Hoffmann and Spengler, 2019). NuRD comprises two catalytic modules - a histone deacetylase module and ATP-dependent chromatin-remodeling module (Burgold et al, 2019; Denslow and Wade, 2007; Low et al, 2020). The deacetylase module contains metastasis-associated proteins (MTA1/2/3) that form a dimeric scaffold for the histone deacetylases (HDAC1/2).…”

Section: Introductionmentioning

confidence: 99%

“…It also contains the chaperones RBBP4/7, which mediate interactions of NuRD with histone tails and transcription factors (Basta and Rauchman, 2017, 2015; Hong et al, 2005). The chromatin-remodeling module contains methyl-CpG DNA binding proteins (MBD2/3) that recruit NuRD to methylated and/or hemi-methylated DNA, GATA-type zinc-finger proteins (GATAD2A/B), and an ATP-dependent DNA translocase (CHD3/4/5) (Burgold et al, 2019; Low et al, 2020).…”

Section: Introductionmentioning

confidence: 99%

“…Several attempts made to determine the stoichiometry of the endogenous NuRD complex have returned variable results (Bode et al, 2016; Guo et al, 2019; Kloet et al, 2015; Sharifi Tabar et al, 2019; Smits et al, 2013; Spruijt et al, 2016; Zhang et al, 2016). A recent characterization by quantitative mass spectrometry from (Low et al, 2020) reported a 2:2:4:1:1:1 (MTA1:HDAC1:RBBP4:MBD3:GATAD2A:CHD4) stoichiometry for the full NuRD complex. Atomic structures of parts of the NuRD complex, including the MTA1-HDAC1 dimer, RBBP4 bound to MTA1, the MBD domain of MBD3, and the coiled-coil dimer of MBD2 and GATAD2A have been determined by X-ray crystallography and NMR spectroscopy (Alqarni et al, 2014; Cramer et al, 2014; Gnanapragasam et al, 2011; Millard et al, 2016, 2013).…”

Section: Introductionmentioning

confidence: 99%

“…Atomic structures of parts of the NuRD complex, including the MTA1-HDAC1 dimer, RBBP4 bound to MTA1, the MBD domain of MBD3, and the coiled-coil dimer of MBD2 and GATAD2A have been determined by X-ray crystallography and NMR spectroscopy (Alqarni et al, 2014; Cramer et al, 2014; Gnanapragasam et al, 2011; Millard et al, 2016, 2013). Structures of the 2:2 MTA1-HDAC1 dimer, the 2:2:4 MTA1-HDAC1-RBBP4 complex (MHR), the 2:2:2 MTA1 N -HDAC1-MBD3 GATAD2CC (MHM) complex, the 2:2:4:1:1 MTA1-HDAC1-RBBP4-MBD3-GATAD2 (NuDe complex), and CHD4 bound to a nucleosome substrate have also been characterized at various resolutions by negative stain and/or cryo-electron microscopy (Farnung et al, 2020; Low et al, 2020; Millard et al, 2020, 2016).…”

Section: Introductionmentioning

confidence: 99%

“…Pairwise interactions between domains and subunits within the MHR, MHM, NuDe, and the endogenous NuRD complexes have also been characterized by chemical crosslinking and mass spectrometry (XLMS) (Low et al, 2020; Millard et al, 2016). A model of the MHM complex, based on crosslinks-driven rigid-body docking of known atomic structures with a pair of MTA1-RBBP4 structures manually placed, has also been reported (Low et al, 2020). While this represents the most complete model of NuRD architecture, it still only accounts for 30% of residues in the NuRD complex.…”

Section: Introductionmentioning

confidence: 99%

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Molecular architecture of nucleosome remodeling and deacetylase sub-complexes by integrative structure determination

Arvindekar

Jackman

Low

et al. 2021

Preprint

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The Nucleosome Remodeling and Deacetylase (NuRD) complex is a chromatin-modifying assembly that regulates gene expression and DNA damage repair. Despite its importance, limited structural information is available on the complex and a detailed understanding of its mechanism is lacking. We investigated the molecular architecture of three NuRD sub-complexes: MTA1-HDAC1-RBBP4 (MHR), MTA1N-HDAC1-MBD3GATAD2CC (MHM), and MTA1-HDAC1-RBBP4-MBD3-GATAD2 (NuDe) using Bayesian integrative structure determination with IMP (Integrative Modeling Platform), drawing on information from SEC-MALLS, DIA-MS, XLMS, negative stain EM, X-ray crystallography, NMR spectroscopy, secondary structure and homology predictions. The structures were corroborated by independent cryo-EM maps, biochemical assays, and known cancer-associated mutations. Our integrative structure of the 2:2:2 MHM complex shows asymmetric binding of MBD3, whereas our structure of the NuDe complex shows MBD3 localized precisely to a single position distant from the MTA1 dimerization interface. Our models suggest a possible mechanism by which asymmetry is introduced in NuRD, and indicate three previously unrecognized subunit interfaces in NuDe: HDAC1C-MTA1BAH, MTA1BAH-MBD3, and HDAC160-100-MBD3. We observed that a significant number of cancer-associated mutations mapped to protein-protein interfaces in NuDe. Our approach also allows us to localize regions of unknown structure, such as HDAC1C and MBD3IDR, thereby resulting in the most complete structural characterization of these NuRD sub-complexes so far.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Molecular architecture of nucleosome remodeling and deacetylase sub-complexes by integrative structure determination

Arvindekar

Jackman

Low

et al. 2021

Preprint

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Mapping oncogenic protein interactions for precision medicine

Tabar

Francis

Yeo

et al. 2022

Intl Journal of Cancer

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Normal protein-protein interactions (normPPIs) occur with high fidelity to regulate almost every physiological process. In cancer, this highly organised and precisely regulated network is disrupted, hijacked or reprogrammed resulting in oncogenic protein-protein interactions (oncoPPIs). OncoPPIs, which can result from genomic alterations, are a hallmark of many types of cancers. Recent technological advances in the field of mass spectrometry (MS)-based interactomics, structural biology and drug discovery have prompted scientists to identify and characterise oncoPPIs. Disruption of oncoPPI interfaces has become a major focus of drug discovery programs and has resulted in the use of PPI-specific drugs clinically. However, due to several technical hurdles, studies to build a reference oncoPPI map for various cancer types have not been undertaken. Therefore, there is an urgent need for experimental workflows to overcome the existing challenges in studying oncoPPIs in various cancers and to build comprehensive reference maps. Here, we discuss the important hurdles for characterising oncoPPIs and propose a three-phase multidisciplinary workflow to identify and characterise oncoPPIs. Systematic identification of cancertype-specific oncogenic interactions will spur new opportunities for PPI-focused drug discovery projects and precision medicine.

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Molecular architecture of nucleosome remodeling and deacetylase sub‐complexes by integrative structure determination

et al. 2022

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The nucleosome remodeling and deacetylase (NuRD) complex is a chromatin‐modifying assembly that regulates gene expression and DNA damage repair. Despite its importance, limited structural information describing the complete NuRD complex is available and a detailed understanding of its mechanism is therefore lacking. Drawing on information from SEC‐MALLS, DIA‐MS, XLMS, negative‐stain EM, X‐ray crystallography, NMR spectroscopy, secondary structure predictions, and homology models, we applied Bayesian integrative structure determination to investigate the molecular architecture of three NuRD sub‐complexes: MTA1‐HDAC1‐RBBP4, MTA1N‐HDAC1‐MBD3GATAD2CC, and MTA1‐HDAC1‐RBBP4‐MBD3‐GATAD2A [nucleosome deacetylase (NuDe)]. The integrative structures were corroborated by examining independent crosslinks, cryo‐EM maps, biochemical assays, known cancer‐associated mutations, and structure predictions from AlphaFold. The robustness of the models was assessed by jack‐knifing. Localization of the full‐length MBD3, which connects the deacetylase and chromatin remodeling modules in NuRD, has not previously been possible; our models indicate two different locations for MBD3, suggesting a mechanism by which MBD3 in the presence of GATAD2A asymmetrically bridges the two modules in NuRD. Further, our models uncovered three previously unrecognized subunit interfaces in NuDe: HDAC1C‐MTA1BAH, MTA1BAH‐MBD3MBD, and HDAC160–100‐MBD3MBD. Our approach also allowed us to localize regions of unknown structure, such as HDAC1C and MBD3IDR, thereby resulting in the most complete and robustly cross‐validated structural characterization of these NuRD sub‐complexes so far.

show abstract

The Nucleosome Remodeling and Deacetylase complex has an asymmetric, dynamic, and modular architecture

Cited by 11 publications

References 64 publications

Molecular architecture of nucleosome remodeling and deacetylase sub-complexes by integrative structure determination

Molecular architecture of nucleosome remodeling and deacetylase sub-complexes by integrative structure determination

Mapping oncogenic protein interactions for precision medicine

Molecular architecture of nucleosome remodeling and deacetylase sub‐complexes by integrative structure determination

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