Augmented genetic decoding: global, local and temporal alterations of decoding processes and codon meaning

Baranov, Pavel V.; Atkins, John F.; Yordanova, Martina M.

doi:10.1038/nrg3963

Cited by 86 publications

(95 citation statements)

References 188 publications

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“…ORF-situated G4s are reported to act as roadblock for elongating ribosomes 153; 154 . RNA G4s also stimulate ribosomal frameshifting 155 , the recoding event when ribosomes are forced to move backward or forward leading to alternative ORF on the same mRNA 156 . In contrast, poorly studied RGG domain-containing RBP Aven recognizes ORF-situated G4s in its mRNA targets to stimulate translation 157 .…”

Section: Proposed Functions Of Rna G-quadruplexesmentioning

confidence: 99%

RNA G-Quadruplexes in Biology: Principles and Molecular Mechanisms

Fay

Lyons

Ivanov

2017

Journal of Molecular Biology

360

306

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G-quadruplexes are extremely stable DNA or RNA secondary structures formed by sequences rich in guanine. These structures are implicated in many essential cellular processes and the number of biological functions attributed to them continues to grow. While DNA G-quadruplexes are well understood on structural and to some extent on functional levels, RNA G-quadruplexes and their functions have received less attention. The presence of bona fide RNA G-quadruplexes in cells has long been a matter of debate. The development of G-quadruplex-specific antibodies and ligands hinted on their presence in vivo but recent advances in RNA sequencing coupled with chemical footprinting suggested the opposite. In this review, we will critically discuss the biology of RNA G-quadruplexes focusing on the molecular mechanisms underlying their proposed functions.

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Section: Proposed Functions Of Rna G-quadruplexesmentioning

confidence: 99%

RNA G-Quadruplexes in Biology: Principles and Molecular Mechanisms

Fay

Lyons

Ivanov

2017

Journal of Molecular Biology

360

306

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“…Subsequent studies defined some such cues, generally identified in an ad hoc manner or using reporter constructs, that were found to contribute to start and stop codon recognition beyond the initial simple rules put forth by the canonical translation model (Figure 1). A broad set of elegant studies thus defined global and specialized translation mechanisms and have also revealed gaps in our understanding of decoding rules and have suggested a greater role for context than is explained by standard translation rules (reviewed in (Baranov et al, 2015; Grosjean and Westhof, 2016)). Systematic approaches to define the degree to which codon context influences translation, however, have long been limited by available experimental and computational tools.…”

Section: The Canonical Model For Translationmentioning

confidence: 99%

“…Their translation results in a protein with an N-terminal extension of the canonical ORF-encoded protein product, rather than the short, possibly unstable peptide products expected to result from uORF translation (Figure 2B;(Brar et al, 2012; Fields et al, 2015; Ingolia et al, 2011; Ivanov et al, 2011; Menschaert et al, 2013)). The context cues leading to these cases of alternative initiation remain undefined and are likely to be similar to those seen for uORFs, but their biological significance is clearly different, as these translation initiation events result in extensions to proteins that may affect their properties, including localization (Baranov et al, 2015; Touriol et al, 2003). …”

Section: Initiation: Context Can Influence Start Site Selectionmentioning

confidence: 99%

“…With knowledge of an organism’s gene sequences and a few simplifying assumptions, this code could in principle allow prediction of the full set of proteins produced in that organism. Indications that additional or alternate information may lurk in mRNA sequences beyond the simple codon conversion rules have been long recognized in at least some instances (for examples, see (Baranov et al, 2015; Gouy and Gautier, 1982)), although the importance and prevalence of most such additional cues has been unclear. Recent research, however, has revealed broad and surprising complexity to genome decoding, including evidence for efficient translation initiation at unexpected sites, non-additive effects of codon pairs on translation elongation, regulated and prevalent translation readthrough of stop codons, widespread modifications to mRNA bases, and context-dependent amino acid incorporation.…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Beyond the Triplet Code: Context Cues Transform Translation

Brar

2016

Cell

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The elucidation of the genetic code remains among the most influential discoveries in biology. While innumerable studies have validated the general universality of the code and its value in predicting and analyzing protein coding sequences, established and emerging work has also suggested that full genome decryption may benefit from a greater consideration of a codon’s neighborhood within an mRNA than has been broadly applied. This review examines the evidence for context cues in translation, with a focus on several recent studies that reveal broad roles for mRNA context in programming translation start sites, the rate of translation elongation, and stop codon identity.

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“…Bypassing is a recoding event that overrules the collinearity of mRNA and protein sequence in gene expression ( 1 ). Although these events were thought to be extremely rare for a long time, recent work has identified multiple ribosome bypassing elements in yeast mitochondria ( 2 ).…”

Section: Introductionmentioning

confidence: 99%