Using the Ubiquitin-modified Proteome to Monitor Distinct and Spatially Restricted Protein Homeostasis Dysfunction

Gendron, Joshua M.; Webb, Kristofor; Yang, Bing; Rising, Lisa; Zuzow, Nathan; Bennett, Eric J.

doi:10.1074/mcp.m116.058420

Cited by 41 publications

(44 citation statements)

References 63 publications

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“…The suggestion that there is spare proteasomal capacity in cells is in agreement with cryo-electron microscopy studies that estimate that about 20% of proteasomes in hippocampal neurons are in a substrate-engaged conformation 38 . And the observation that proteins that are targeted for proteasomal degradation accumulate only after more than 60% of cellular proteasomal activity is inhibited is consistent with the idea that the excess capacity for degradation exists to buffer cells from fluctuations in proteome stress 39 .…”

Section: Causes Of Proteome Imbalancesupporting

confidence: 78%

Proteome complexity and the forces that drive proteome imbalance

Harper

Bennett

2016

Nature

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213

175

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Summary The cellular proteome is a complex microcosm of structural and regulatory networks that requires continuous surveillance and modification to meet the dynamic needs of the cell. It is therefore crucial that the protein flux of the cell remains in balance to ensure proper cell function. Genetic alterations that range from chromosome imbalance to oncogene activation can affect the speed, fidelity and capacity of protein biogenesis and degradation systems, which often results in proteome imbalance. An improved understanding of the causes and consequences of proteome imbalance is helping to reveal how these systems can be targeted to treat diseases such as cancer.

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Section: Causes Of Proteome Imbalancesupporting

confidence: 78%

Proteome complexity and the forces that drive proteome imbalance

Harper

Bennett

2016

Nature

Self Cite

213

175

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“…We utilized our ZNF598-KO and rescue cells to perform quantitative proteomic profiling of alterations to both the total and ubiquitin-modified proteome upon loss or gain of ZNF598 function (Figure 2C; Gendron et al, 2016; Kim et al, 2011). We reasoned that ZNF598 substrates would show decreased ubiquitylation in ZNF598-KO and that the decrease would be reversed upon expression of wild-type but not mutant ZNF598.…”

Section: Resultsmentioning

confidence: 99%

ZNF598 and RACK1 Regulate Mammalian Ribosome-Associated Quality Control Function by Mediating Regulatory 40S Ribosomal Ubiquitylation

et al. 2017

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SUMMARY Ribosomes that experience terminal stalls during translation are resolved by ribosome-associated quality control (QC) pathways that oversee mRNA and nascent chain destruction and recycle ribosomal subunits. The proximal factors that sense stalled ribosomes and initiate mammalian ribosome-associated QC events remain undefined. We demonstrate that the ZNF598 ubiquitin ligase and the 40S ribosomal protein RACK1 help to resolve poly(A)-induced stalled ribosomes. They accomplish this by regulating distinct and overlapping regulatory 40S ribosomal ubiquitylation events. ZNF598 primarily mediates regulatory ubiquitylation of RPS10 and RPS20, whereas RACK1 regulates RPS2, RPS3, and RPS20 ubiquitylation. Gain or loss of ZNF598 function or mutations that block RPS10 or RPS20 ubiquitylation result in defective resolution of stalled ribosomes and subsequent readthrough of poly(A)-containing stall sequences. Together, our results indicate that ZNF598, RACK1, and 40S regulatory ubiquitylation plays a pivotal role in mammalian ribosome-associated QC pathways.

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“…For affinity purification, ~100ul of streptavidin magnetic beads (Pierce, PI88817) were washed once in 2M urea buffer, resuspended directly in the sample, incubated for 2h at room temperature and washed 8 times in 2M urea buffer. Samples were digested directly off the beads and processed as described in Gendron et al, 2016).…”

Section: Apex-mediated Biotinylationmentioning

confidence: 99%

Proximity labeling reveals an extensive steady-state stress granule interactome and insights to neurodegeneration

Markmiller

Soltanieh

Server

et al. 2017

Preprint

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Stress granules (SGs) are transient ribonucleoprotein (RNP) aggregates that form in response to proteotoxic stress. Although SGs are distinct from aggregates observed in neurodegenerative disorders, they share protein components. We used APEX-mediated proximity labeling combined with quantitative mass spectrometry and high-throughput imaging to identify >100 previously unknown SG proteins in human cells, about 10% of which localize to SGs in a cell type-or stress type-dependent manner.Supporting a link between SG proteins and neurodegeneration, we demonstrate aberrant SG composition and subcellular distribution in iPSC-derived motor neurons from ALS patients, and identify several known and previously unidentified SG proteins that modify toxicity of mutant FUS and TDP-43 overexpression in Drosophila. We show that even in an unstressed steady-state, SG proteins form a densely-connected protein interaction network (PIN) and propose a model in which existing RNPs coalesce rapidly into microscopically visible granules that can act as gateways to pathological protein aggregation.

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Using the Ubiquitin-modified Proteome to Monitor Distinct and Spatially Restricted Protein Homeostasis Dysfunction

Cited by 41 publications

References 63 publications

Proteome complexity and the forces that drive proteome imbalance

Proteome complexity and the forces that drive proteome imbalance

ZNF598 and RACK1 Regulate Mammalian Ribosome-Associated Quality Control Function by Mediating Regulatory 40S Ribosomal Ubiquitylation

Proximity labeling reveals an extensive steady-state stress granule interactome and insights to neurodegeneration

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