A proximity-dependent biotinylation map of a human cell: an interactive web resource

Go, Christopher D.; Knight, James D.R.; Rajasekharan, Archita; Rathod, Bhavisha; Hesketh, Geoffrey G.; Abe, Kento T.; Youn, Ji‐Young; Samavarchi-Tehrani, Payman; Zhang, Hui; Zhu, Licheng; Popiel, Evelyn; Lambert, Jean‐Philippe; Coyaud, Étienne; Cheung, Sally W.T.; Rajendran, Dushyandi; Wong, Cassandra; Antonická, Hana; Pelletier, Laurence; Palazzo, Alexander F.; Shoubridge, Eric A.; Raught, Brian; Gingras, Anne‐Claude

doi:10.1101/796391

Cited by 55 publications

(84 citation statements)

References 68 publications

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“…Proximity labeling could capture weaker, more transient interactions and aid study of multi-pass membrane proteins. Indeed, large-scale proximity labeling is underway to define proteome spatial organization (Go et al, 2019), providing a complementary view of protein interactions.…”

Section: Toward a Broader View Of Interactome Dynamicsmentioning

confidence: 99%

Dual Proteome-scale Networks Reveal Cell-specific Remodeling of the Human Interactome

Huttlin

Bruckner

Navarrete‐Perea

et al. 2020

Preprint

161

233

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SUMMARYThousands of interactions assemble proteins into modules that impart spatial and functional organization to the cellular proteome. Through affinity-purification mass spectrometry, we have created two proteome-scale, cell-line-specific interaction networks. The first, BioPlex 3.0, results from affinity purification of 10,128 human proteins – half the proteome – in 293T cells and includes 118,162 interactions among 14,586 proteins; the second results from 5,522 immunoprecipitations in HCT116 cells. These networks model the interactome at unprecedented scale, encoding protein function, localization, and complex membership. Their comparison validates thousands of interactions and reveals extensive customization of each network. While shared interactions reside in core complexes and involve essential proteins, cell-specific interactions bridge conserved complexes, likely ‘rewiring’ each cell’s interactome. Interactions are gained and lost in tandem among proteins of shared function as the proteome remodels to produce each cell’s phenotype. Viewable interactively online through BioPlexExplorer, these networks define principles of proteome organization and enable unknown protein characterization.

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Section: Toward a Broader View Of Interactome Dynamicsmentioning

confidence: 99%

Dual Proteome-scale Networks Reveal Cell-specific Remodeling of the Human Interactome

Huttlin

Bruckner

Navarrete‐Perea

et al. 2020

Preprint

161

233

View full text Add to dashboard Cite

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“…Correll and colleagues present a comprehensive review of the structure and function of the human nucleolus [1]. Integrating classic ultrastructural and biochemical evidence with recent advances from modern biophysical techniques and cryoEM, these authors describe a compartment that remains intact despite the continuous exchange of components and rapid flux of ribosome intermediates.…”

Section: Subcompartmentalization and Ribosome Biogenesismentioning

confidence: 99%

“…Recent studies in vitro and in vivo provided new insights that further substantiate the importance of nucleoli for senescence and aging at the cellular or organismal level. These studies are being discussed in several reviews published in Cells, including this Special Issue and previous publications [1,9,22,25].…”

Section: Stress Aging and Longevitymentioning

confidence: 99%

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Nucleolar Organization and Functions in Health and Disease

Stochaj

Weber

2020

Cells

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The nucleolus is a prominent, membraneless compartment found within the nucleus of eukaryotic cells. It forms around ribosomal RNA (rRNA) genes, where it coordinates the transcription, processing, and packaging of rRNA to produce ribosomal subunits. Recent efforts to characterize the biophysical properties of the nucleolus have transformed our understanding of the assembly and organization of this dynamic compartment. Indeed, soluble macromolecules condense from the nucleoplasm to form nucleoli through a process called liquid–liquid phase separation. Individual nucleolar components rapidly exchange with the nucleoplasm and separate within the nucleolus itself to form distinct subcompartments. In addition to its essential role in ribosome biogenesis, the nucleolus regulates many aspects of cell physiology, including genome organization, stress responses, senescence and lifespan. Consequently, the nucleolus is implicated in several human diseases, such as Hutchinson–Gilford progeria syndrome, Diamond–Blackfan anemia, and various forms of cancer. This Special Issue highlights new insights into the physical and molecular mechanisms that control the architecture and diverse functions of the nucleolus, and how they break down in disease.

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“…Nevertheless, BioID has proven effective for examining proximal interactors of individual proteins and larger complexes that are typically difficult to study, such as cell-cell contacts, the centrosome, and IACs (Chastney et al, 2020;Dong et al, 2016;Gupta et al, 2015;Van Itallie et al, 2013). In larger-scale network mapping studies, multiplexed BioID has been used to reveal the spatial relationships between components of large complexes, and even between multiple organelles (Chastney et al, 2020;Go et al, 2019;Gupta et al, 2015;Youn et al, 2018). In such initiatives, careful analysis is required to interpret the data and to infer potential biological insight.…”

Section: Commentary Background Informationmentioning

confidence: 99%

Multiplexed Proximity Biotinylation Coupled to Mass Spectrometry for Defining Integrin Adhesion Complexes

2020

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BioID, a proximity biotinylation technique, offers a valuable approach to examine the interactions occurring within protein complexes that complements traditional protein biochemical methods. BioID has various advantages that are beneficial to the study of complexes, including an ability to detect insoluble and transient proteins. We have applied BioID to the study of integrin adhesion complexes (IACs), which are located at the junction between the plasma membrane and actin cytoskeleton. The use of multiple BioID baits enables a complex‐wide, spatial annotation of IACs, which in turn facilitates the detection of novel proximal interactors and provides insights into IAC architecture. This article describes the labeling and affinity purification of IAC‐proximal proteins and their analysis by label‐free quantitative mass spectrometry. The article also outlines steps to identify high‐confidence proximity interactors, and to interrogate the topology and functional relevance of proximity interaction networks through bioinformatic analyses. © 2020 The Authors. Basic Protocol 1: Proximity biotinylation of integrin adhesion complex components Basic Protocol 2: Mass spectrometry data processing by MaxQuant and detection of high‐confidence proximal interactors Basic Protocol 3: Bioinformatic analysis and data visualization

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A proximity-dependent biotinylation map of a human cell: an interactive web resource

Cited by 55 publications

References 68 publications

Dual Proteome-scale Networks Reveal Cell-specific Remodeling of the Human Interactome

Dual Proteome-scale Networks Reveal Cell-specific Remodeling of the Human Interactome

Nucleolar Organization and Functions in Health and Disease

Multiplexed Proximity Biotinylation Coupled to Mass Spectrometry for Defining Integrin Adhesion Complexes

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