“Superwobbling” and tRNA-34 Wobble and tRNA-37 Anticodon Loop Modifications in Evolution and Devolution of the Genetic Code

Lei, Lei; Burton, Zachary F.

doi:10.3390/life12020252

Cited by 12 publications

(10 citation statements)

References 84 publications

(258 reference statements)

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“…4B). After the resulting ribonucleopeptide (RNP) transition, evolution to modern translation and the full SGC is enabled, requiring exquisite adaptation between proteins and RNAs (55) and wide-ranging ribonucleotide refinement for coding (56, 57), but not radical evolutionary innovation.…”

Section: Discussionmentioning

confidence: 99%

“…Accordingly, the Initial Darwinian Ancestor emerges (95). These events are accompanied by nucleotide modifying enzymes that refine the codon-anticodon complex (56, 57). One complete code becomes the universal SGC (96) and diverges from LUCA to produce a modern multi-domain biota employing the Standard Genetic Code (97).…”

Section: Discussionmentioning

confidence: 99%

“…These data therefore suggest that an initial code relying on RNA chemistry encoded and used polypeptides with major structural and enzymatic capabilities. After this ribonucleopeptide (RNP) transition, evolution to modern translation and the full SGC is accessible, requiring extensive refinement (Grosjean and Westhof 2016; Lei and Burton 2022), but not radical evolutionary innovation.…”

Section: Discussionmentioning

confidence: 99%

“…Translation initiation (Schmitt et al 2019) and termination (Burroughs and Aravind 2019) evolve over a prolonged period, and become late coding events, their evolution continuing after the separation of major biological domains. Near-modern coding capabilities produce the protein aaRS (Ribas de Pouplana 2020), and deoxyribonucleotides (Poole et al 2014), as well as nucleotide modifying enzymes that refine the codon-anticodon complex (Grosjean and Westhof 2016; Lei and Burton 2022). One complete code becomes universal (Vetsigian et al 2006) and diverges from LUCA to produce multi-domain modern biota (Crapitto et al 2022)…”

Section: Discussionmentioning

confidence: 99%

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From initial RNA encoding to the Standard Genetic Code

Yarus

2023

Preprint

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Multiple prior experiments show that RNA binds chemically varied amino acids within specific ribo-oligonucleotide sequences. The smallest, simplest, and therefore most likely primitive RNA binding sites contain functional triplets corresponding to the Standard Genetic Code (SGC). Here, the implications of such observed coding triplets are calculated, combining them with an optimized kinetic model for SGC evolution. RNA-amino acid interactions at known frequencies both choose an SGC-like code, and by the same mechanism, effectively resist alternative triplet assignments. Resistance to external coding is evident in varied code initiation scenarios. Observed RNA-mediated assignments are also likely sufficient to produce the “ribonucleopeotide (RNP) transition” to a modern RNP code. This can fully account for extreme selection of the SGC among its astronomical code possibilities; very SGC-like codes are ≈ 1/50 to 1/5 of codes within such a population. Nevertheless, complete accounting will depend on RNA affinities still unknown. Such a code begins as mostly stereochemical, excludes other assignments, and critically relies on properties unique to fusible microbes. After its RNP transition, other assignment mechanisms (adaptation, co-evolution, revised stereochemistry, LGT) likely expand the code because cellular intermediates with ≥ 1 code exist, allowing time for mutual code exchanges. The 83 order-of-magnitude focus required to find an SGC was therefore spanned by at least two assignment mechanisms, in at least two successive eras.

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Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

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From initial RNA encoding to the Standard Genetic Code

Yarus

2023

Preprint

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“…The anticodons of these tRNAs have either a G34 or I34 (inosine 34) nucleotide, both of which can base pair with the wobble U or C nucleotides of the mRNA A-site codon. I34 (adenine 34 converted to inosine 34) is a eukaryote innovation that is used by NNU/C codon pairs in cases where the corresponding NNA codon also codes for the same amino acid (because inosine can also base pair with wobble A [10]). NNU codons are significantly more abundant than NNC in yeast ORFs (Fig S1A ), although for NNU codons that utilize tRNA G34 this trend is less strong in ORFs of genes with high protein expression (Fig S1B , C).…”

Section: Nnu Codons Have Distinctive Propertiesmentioning

confidence: 99%

GNN codon adjacency regulates protein translation

Sun,

Hwang,

Sakkas

et al. 2024

Preprint

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The central dogma treats the ribosome as a molecular machine that reads one mRNA codon at a time as it adds each amino acid to its growing peptide chain. However, this and previous studies suggest that ribosomes actually perceive pairs of adjacent codons as they take three-nucleotide steps along the mRNA. We examined GNN codons which we find are surprisingly overrepresented in eukaryote protein-coding open reading frames (ORFs), especially immediately after NNU codons. Ribosome profiling experiments in yeast revealed that ribosomes with NNU at their aminoacyl (A) site have particularly elevated densities when NNU is immediately followed (3') by a GNN codon, indicating slower mRNA threading of the NNU codon from the ribosome's A to peptidyl (P) sites. Moreover, if the assessment was limited to ribosomes that have only recently arrived at the next codon, by examining 21-nucleotide ribosome footprints (21-nt RFPs), elevated densities were observed for multiple codon classes when followed by GNN. This striking translation slowdown at adjacent 5'-NNN GNN codon pairs is likely mediated in part by the ribosome's CAR surface which acts as an extension of the A-site tRNA anticodon during ribosome translocation and interacts through hydrogen bonding and pi stacking with the GNN codon. The functional consequences of 5'-NNN GNN codon adjacency are expected to influence the evolution of protein coding sequences.

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On the minimal elements of the genetic code and their semiotic functions (degeneracy, complementarity, wobbling)

Zolyan

2023

Biosystems

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“Superwobbling” and tRNA-34 Wobble and tRNA-37 Anticodon Loop Modifications in Evolution and Devolution of the Genetic Code

Cited by 12 publications

References 84 publications

From initial RNA encoding to the Standard Genetic Code

From initial RNA encoding to the Standard Genetic Code

GNN codon adjacency regulates protein translation

On the minimal elements of the genetic code and their semiotic functions (degeneracy, complementarity, wobbling)

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