Role of mRNA structure in the control of protein folding

Faure, Guilhem; Ogurtsov, Aleksey Y.; Shabalina, Svetlana A.; Koonin, Eugene V.

doi:10.1093/nar/gkw671

Cited by 94 publications

(89 citation statements)

References 106 publications

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“…There are many factors that can affect ribosome profiling results such as growth conditions, coverage, cloning and sequencing biases, methods of bioinformatics analysis, and experimental noise [18,52,53]. Importantly, these structures may serve to reduce ribosome speed when the nascent peptide requires additional time to fold to its correct conformation [58]. Additionally, our study along with others' suggests that slower elongation of ribosome is a key feature of mRNA stability.…”

Section: Investigating the System Of Codon Bias In Humansmentioning

confidence: 67%

“…These obstacles for ribosome elongation are reversible and dynamically regulated by RNA helicases [56,57]. Importantly, these structures may serve to reduce ribosome speed when the nascent peptide requires additional time to fold to its correct conformation [58]. Furthermore, it has been shown in Neurospora that codon usage can regulate co-translational protein folding and, subsequently, its function [59].…”

Section: Investigating the System Of Codon Bias In Humansmentioning

confidence: 99%

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Codon bias confers stability to human mRNA s

et al. 2019

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Codon bias has been implicated as one of the major factors contributing to mRNA stability in several model organisms. However, the molecular mechanisms of codon bias on mRNA stability remain unclear in humans. Here, we show that human cells possess a mechanism to modulate RNA stability through a unique codon bias. Bioinformatics analysis showed that codons could be clustered into two distinct groups-codons with G or C at the third base position (GC3) and codons with either A or T at the third base position (AT3): the former stabilizing while the latter destabilizing mRNA. Quantification of codon bias showed that increased GC3-content entails proportionately higher GC-content. Through bioinformatics, ribosome profiling, and in vitro analysis, we show that decoupling the effects of codon bias reveals two modes of mRNA regulation, one GC3-and one GC-content dependent. Employing an immunoprecipitation-based strategy, we identify ILF2 and ILF3 as RNA-binding proteins that differentially regulate global mRNA abundances based on codon bias. Our results demonstrate that codon bias is a two-pronged system that governs mRNA abundance.

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Section: Investigating the System Of Codon Bias In Humansmentioning

confidence: 67%

Section: Investigating the System Of Codon Bias In Humansmentioning

confidence: 99%

Codon bias confers stability to human mRNA s

et al. 2019

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“…Polyadenylation signal AATAAA is the best known of all regulatory elements in the 3 ′ UTR of mammalian mRNA and is required for efficient termination of transcription, cleavage at a specific site downstream of the signal, and addition of generally 150-250 adenosine nucleotides to the 3 ′ end (Bienroth, Keller, & Wahle, 1993;Guhaniyogi & Brewer, 2001). The poly(A) tail has a role in mRNA stability and translation efficiency (Faure, Ogurtsov, Shabalina, & Koonin, 2016;Yang et al, 2003). Polyadenylation signal sequence is highly conserved in human genes.…”

Section: Introductionmentioning

confidence: 99%

“…Other sequences in the 3 ′ UTR can play roles in various posttranscriptional regulation mechanisms including stability, nuclear transport, and subcellular localization (Kislauskis, Li, Singer, & Taneja, 1993). Some of those functions are hypothesized to mainly depend on the secondary structure of the molecule, for example, by rendering cis elements such as target sequences of miRNAs more exposed (Haas, Sczakiel, & Laufer, 2012) or impairing the rate of translation (Faure et al, 2016). Thus, sequence alterations in the 3 ′ UTRs of many genes have been reported to lead to disease.…”

Section: Introductionmentioning

confidence: 99%

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STUB1polyadenylation signal variant AACAAA does not affect polyadenylation but decreasesSTUB1translation causing SCAR16

et al. 2018

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We present three siblings afflicted with a disease characterized by cerebellar ataxia, cerebellar atrophy, pyramidal tract damage with increased lower limb tendon reflexes, and onset of 31 to 57 years, which is not typical for a known disease. In a region of shared homozygosity in patients, exome sequencing revealed novel homozygous c.*240T > C variant in the 3'UTR of STUB1, the gene responsible for autosomal recessive spinocerebellar ataxia 16 (SCAR16). In other genes, such an alteration of the evolutionarily highly conserved polyadenylation signal from AATAAA to AACAAA is known to highly impair polyadenylation. In contrast, RNA sequencing and quantification revealed that neither polyadenylation nor stability of STUB1 mRNA is affected. In silico analysis predicted that the secondary structure of the mRNA is altered. We propose that this change underlies the extremely low amounts of the encoded protein in patient leukocytes.

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Dynamic Regulation of Biosystems by Nucleic Acids with Non‐canonical Structures

2021

Chemistry and Biology of Non‐Canonical Nucleic Acids

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Role of mRNA structure in the control of protein folding

Cited by 94 publications

References 106 publications

Codon bias confers stability to human mRNA s

Codon bias confers stability to human mRNA s

STUB1polyadenylation signal variant AACAAA does not affect polyadenylation but decreasesSTUB1translation causing SCAR16

Dynamic Regulation of Biosystems by Nucleic Acids with Non‐canonical Structures

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