Targeted Degradation of Glucose Transporters Protects against Arsenic Toxicity

Jochem, Marco; Ende, Lukas; Isasa, Marta; Ang, Jessie; Schnell, Helena M.; Guerra-Moreno, Ángel; Micoogullari, Yagmur; Bhanu, Meera K.; Gygi, Steven P.; Hanna, John

doi:10.1128/mcb.00559-18

Cited by 20 publications

(27 citation statements)

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“…These data suggest that restricting cellular accumulation of this metalloid is an important means to protect the proteome from As(III)-induced damage and toxicity. The finding that cells respond to As(III) by downregulating arsenic influx pathways ( Jochem et al, 2019 ; Wysocki et al, 2001 ) and by increasing expression of arsenic export and sequestration systems ( Talemi et al, 2014 ; Thorsen et al, 2007 ) supports this notion. Besides arsenic influx and efflux, additional mechanisms to mitigate proteotoxicity exist; selected mutants affected in transcriptional and translational control had a clear impact on As(III)-induced protein aggregation and toxicity with intracellular arsenic levels comparable to wild-type cells ( …”

Section: Discussionmentioning

confidence: 74%

Genome-wide imaging screen uncovers molecular determinants of arsenite-induced protein aggregation and toxicity

Andersson

Romero

Rodrigues

et al. 2021

Journal of Cell Science

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The toxic metalloid arsenic causes widespread misfolding and aggregation of cellular proteins. How these protein aggregates are formed in vivo, the mechanisms by which they affect cells, and how cells prevent their accumulation is not fully understood. To find components involved in these processes, we performed a genome-wide imaging screen and identified yeast deletion mutants with either enhanced or reduced protein aggregation levels during arsenite exposure. We show that many of the identified factors are crucial to safeguard protein homeostasis (proteostasis) and to protect cells against arsenite toxicity. The hits were enriched for various functions including protein biosynthesis and transcription, and dedicated follow-up experiments highlight the importance of accurate transcriptional and translational control for mitigating protein aggregation and toxicity during arsenite stress. Some of the hits are associated with pathological conditions, suggesting that arsenite-induced protein aggregation may affect disease processes. The broad network of cellular systems that impinge on proteostasis during arsenic stress identified in this current study provides a valuable resource and a framework for further elucidation of the mechanistic details of metalloid toxicity and pathogenesis.

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Section: Discussionmentioning

confidence: 74%

Genome-wide imaging screen uncovers molecular determinants of arsenite-induced protein aggregation and toxicity

Andersson

Romero

Rodrigues

et al. 2021

Journal of Cell Science

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“…Collectively, these data strongly suggest that intracellular arsenic is a direct cause of protein aggregation and that restricting the cellular accumulation of this metalloid is an important means for cells to protect their proteome from As(III)-induced damage and toxicity. Indeed, cells respond to As(III) by downregulating arsenic influx pathways [39,68] and by increasing expression of arsenic export and sequestration systems [48,69]. An important aspect of future work will be to systematically measure intracellular arsenic in all ~400 mutants identified in this study to pin-point pathways and regulators associated with arsenic uptake, efflux, intracellular distribution and sequestration.…”

Section: Protein Aggregation Is Correlated With Intracellular Arsenic Levels and As(iii) Toxicitymentioning

confidence: 99%

Genome-wide imaging screen uncovers molecular determinants of arsenite-induced protein aggregation and toxicity and an important role for transcriptional and translational control

Andersson

Romero

Rodrigues

et al. 2020

Preprint

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Exposure to toxic metals and metalloids such as cadmium and arsenic results in widespread misfolding and aggregation of cellular proteins. How these protein aggregates are formed in vivo, the mechanisms by which they affect cells, and how cells prevent their accumulation during environmental stress is not fully understood. To find components involved in these processes, we performed a genome-wide imaging screen and identified yeast deletion mutants with either enhanced or reduced protein aggregation levels during arsenite exposure. Mutants with reduced aggregation levels were enriched for functions related to protein biosynthesis and transcription, whilst functions related to cellular signalling, metabolism, and protein folding and degradation were overrepresented among mutants with enhanced aggregation levels. On a genome-wide scale, protein aggregation correlated with arsenite resistance and sensitivity, indicating that many of the identified factors are crucial to safeguard protein homeostasis (proteostasis) and to protect against arsenite toxicity. Dedicated follow-up experiments indicated that intracellular arsenic is a direct cause of protein aggregation and that accurate transcriptional and translational control are crucial for proteostasis during arsenite stress. Specifically, we provide evidence that global transcription affects protein aggregation levels, that loss of transcriptional control impacts proteostasis through distinct mechanisms, and that translational repression is central to control protein aggregation and cell viability. Some of the identified factors are associated with pathological conditions suggesting that arsenite-induced protein aggregation may impact disease processes. The broad network of cellular systems that impinge on proteostasis during arsenic stress provides a valuable resource and a framework for further elucidation of the mechanistic details of metalloid toxicity and pathogenesis.AUTHOR SUMMARYHuman exposure to poisonous metals is increasing in many parts of the world and chronic exposure is associated with certain protein folding-associated disorders such as Alzheimer’s disease and Parkinson’s disease. While the toxicity of many metals is undisputed, their molecular modes of action have remained unclear. Recent studies revealed that toxic metals such as arsenic and cadmium profoundly affect the correct folding of proteins, resulting in the accumulation of toxic protein aggregates. In this study, we used high-content microscopy to identify a broad network of cellular systems that impinge on protein homeostasis and cell viability during arsenite stress. Follow-up experiments highlight the importance of accurate transcriptional and translational control for mitigating arsenite-induced protein aggregation and toxicity. Some of the identified factors are associated with pathological conditions suggesting that arsenite-induced protein aggregation may impact disease processes. The broad network of cellular systems that impinge on proteostasis during arsenic stress provides a valuable resource and a framework for further elucidation of the mechanistic details of metal toxicity and pathogenesis.

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“…Arsenic trioxide is very toxic. It is also a potent carcinogen [41]. It is advisable to replace arsenic trioxide with the more effective and less toxic DHIs we have described [16,42].…”

Section: Destabilization Of Abnormal Mes As An Effective Approach For Cancer Therapymentioning

confidence: 99%

Destabilization of Abnormal Methylation Enzymes: Nature’s Way to Eradicate Cancer Stem Cells

Liau¹,

Kim

Fruehauf

2019

OJCAM

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Targeted Degradation of Glucose Transporters Protects against Arsenic Toxicity

Cited by 20 publications

References 50 publications

Genome-wide imaging screen uncovers molecular determinants of arsenite-induced protein aggregation and toxicity

Genome-wide imaging screen uncovers molecular determinants of arsenite-induced protein aggregation and toxicity

Genome-wide imaging screen uncovers molecular determinants of arsenite-induced protein aggregation and toxicity and an important role for transcriptional and translational control

Destabilization of Abnormal Methylation Enzymes: Nature’s Way to Eradicate Cancer Stem Cells

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