Codon-specific translation reprogramming promotes resistance to targeted therapy

Rapino, Francesca; Delaunay, Sylvain; Rambow, Florian; Zhou, Zhaoli; Tharun, Lars; Tullio, Pascal De; Sin, Olga; Shostak, Kateryna; Schmitz, Sebastian; Piepers, Jolanda; Ghesquière, Bart; Karim, Latifa; Charloteaux, Benoît; Jamart, Diane; Florin, Alexandra; Lambert, Charles; Rorive, Andrée; Jérusalem, Guy; Leucci, Eleonora; Dewaele, Michael; Vooijs, Marc; Leidel, Sebastian A.; Georges, Michel; Voz, Marianne L.; Peers, Bernard; Büttner, Reinhard; Marine, Jean–Christophe; Chariot, Alain; Close, Pierre

doi:10.1038/s41586-018-0243-7

Cited by 203 publications

(220 citation statements)

References 33 publications

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“…Thus far, our data point out that regulation of mcm 5 s 2 ‐U34 tRNA‐modifying enzymes plays a major role in translational offsetting as a function of alterations in ERα signaling. Intriguingly however, ERα‐dependent suppression or decrease in the expression of U34‐modifying enzymes did not correlate with global changes in mcm 5 s 2 ‐U‐modified tRNAs as quantified by the [(N‐acryloylamino)phenyl]mercuric chloride (APM) method [Igloi, ; as reported in a recent study (Rapino et al , )] or mass spectrometry (Appendix Fig S6A and B). We reasoned that this may be a consequence of accumulation of modified tRNAs during chronic ERα depletion (e.g., due to reduction in global protein synthesis).…”

Section: Resultsmentioning

confidence: 96%

Translational offsetting as a mode of estrogen receptor α‐dependent regulation of gene expression

et al. 2019

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Estrogen receptor alpha (ERα) activity is associated with increased cancer cell proliferation. Studies aiming to understand the impact of ERα on cancer‐associated phenotypes have largely been limited to its transcriptional activity. Herein, we demonstrate that ERα coordinates its transcriptional output with selective modulation of mRNA translation. Importantly, translational perturbations caused by depletion of ERα largely manifest as “translational offsetting” of the transcriptome, whereby amounts of translated mRNAs and corresponding protein levels are maintained constant despite changes in mRNA abundance. Transcripts whose levels, but not polysome association, are reduced following ERα depletion lack features which limit translation efficiency including structured 5′UTRs and miRNA target sites. In contrast, mRNAs induced upon ERα depletion whose polysome association remains unaltered are enriched in codons requiring U34‐modified tRNAs for efficient decoding. Consistently, ERα regulates levels of U34‐modifying enzymes and thereby controls levels of U34‐modified tRNAs. These findings unravel a hitherto unprecedented mechanism of ERα‐dependent orchestration of transcriptional and translational programs that may be a pervasive mechanism of proteome maintenance in hormone‐dependent cancers.

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Section: Resultsmentioning

confidence: 96%

Translational offsetting as a mode of estrogen receptor α‐dependent regulation of gene expression

et al. 2019

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“…The mechanisms that control this metabolic reprogramming by immediate changes in specific gene expression programs remain less clear. Now, an exciting new study by Rapino et al () provides evidence for an unexpected role of enzymes that modify transfer RNA (tRNA) in this process. Specifically, they show that enzymes modifying uridine 34 (U 34 ) of tRNA are important for the maintenance and therapeutic resistance of an aggressive skin cancer known as melanoma.…”

Section: Codon‐dependent Translation Regulation Of Hif1α Couples Glycmentioning

confidence: 99%

“…While U 34 tRNA‐modifying enzymes have been implicated in metabolism, DNA damage response, and exocytosis (Esberg et al , ; Begley et al , ; Laxman et al , ), their role in cancer has not been extensively studied until now. By employing a combination of approaches and patient samples, Rapino et al () demonstrate that key enzymes required for U 34 tRNA modifications are increased in melanomas exhibiting highly glycolytic phenotypes that are often associated with mutations in BRAF (one of the most commonly mutated genes in melanoma patients). Rapino and colleagues provide compelling evidence that BRAF V600E melanomas are “addicted” to high levels of U 34 tRNA‐modifying enzymes.…”

Section: Codon‐dependent Translation Regulation Of Hif1α Couples Glycmentioning

confidence: 99%

“…An exciting question arises as to why a reduction in U 34 tRNA‐modifying enzymes elucidates such a profound growth inhibition phenotype in highly metabolic melanomas. Rapino et al () employ an elegant combination of proteomics and ribosome profiling experiments to identify a role for specific codons in rewiring translation mediated by U 34 tRNA‐modifying enzymes in skin cancer cells. The authors show that the abundance of proteins enriched in codons, known to require thiolated tRNAs for decoding, such as Gln, Glu, and Lys codons, are significantly increased in BRAF V600E ‐driven melanoma.…”

Section: Codon‐dependent Translation Regulation Of Hif1α Couples Glycmentioning

confidence: 99%

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A wobbly road to drug resistance in melanoma: tRNA ‐modifying enzymes in translation reprogramming

McMahon

Ruggero

2018

The EMBO Journal

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Alterations in transcript‐specific translation are emerging as a driver of cellular transformation and cancer etiology. A new study provides evidence for enhanced codon‐dependent translation of hypoxia‐inducible factor 1α in promoting glycolytic metabolism and drug resistance in melanoma cells. This specialized translation reprogramming relies, in part, on mTORC2‐mediated phosphorylation of enzymes modifying the wobble position of the transfer RNA anticodon.

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“…Lastly, recent studies demonstrated that tRNA‐modifying enzymes can be implicated in disease. For example, a recent study provided evidence that certain wobble‐modifying enzymes are involved in resistance to cancer targeted therapy (Rapino et al , ). Since queuine is obtained from the diet, it will be interesting to determine whether Q deficiency or excess can result in disease.…”

Section: Dietary Queuine and Gut Microbiota‐derived Queuine Regulate mentioning

confidence: 99%

Queuing up the ribosome: nutrition and the microbiome control protein synthesis

Kozlovski

Agami

2018

The EMBO Journal

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The health of an organism is intricately linked to its gut microbiome. However, the mechanisms by which the microbiome affect the host gene regulation are still not well established. A new study by Tuorto (2018) shows that queuine, a nitrogenous base obtained from the gut microbiota, is used to modify tRNAs and affects cellular behavior. Dietary queuine is required for proper protein synthesis, and its depletion activates cellular stress responses and .

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Codon-specific translation reprogramming promotes resistance to targeted therapy

Cited by 203 publications

References 33 publications

Translational offsetting as a mode of estrogen receptor α‐dependent regulation of gene expression

Translational offsetting as a mode of estrogen receptor α‐dependent regulation of gene expression

A wobbly road to drug resistance in melanoma: tRNA ‐modifying enzymes in translation reprogramming

Queuing up the ribosome: nutrition and the microbiome control protein synthesis

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