Hierarchical groove discrimination by Class I and II aminoacyl-tRNA synthetases reveals a palimpsest of the operational RNA code in the tRNA acceptor-stem bases

Carter, Charles W.; Wills, Peter R.

doi:10.1093/nar/gky600

Cited by 43 publications

(60 citation statements)

References 71 publications

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“…Urzyme structures inferred from extant crystal structures suggest that ancestral secondary structural differences between the two synthetase classes do actually reinforce the acceptor‐stem structures observed in productive cocrystals . The Class I Urzyme Rossmann‐fold architecture creates a positively charged pocket for the A76 5′ phosphate at the N‐terminus of the “specificity‐determining helix” (Fig.…”

Section: Aars Structures Reinforce the Rulesmentioning

confidence: 94%

“…Codon-anticodon pairing in the acceptor stem may have allowed coded translation to begin before tRNAs acquired anticodons, along lines advocated by DiGiulio (18)(19)(20). Use of that pairing may also reflect a transitional mechanism for bidirectional coding via formation of triple helices (4).…”

Section: Conclusion Future Directionsmentioning

confidence: 97%

“…to recognize the G3‐U70 base pair from both grooves . We have argued that this modification of the synthetase–tRNA complex involves more recently acquired domains, and hence that it evolved after the establishment and early expansion of the genetic code.…”

Section: Aars Structures Reinforce the Rulesmentioning

confidence: 99%

“…Groove recognition is dictated, surprisingly, by just the four topmost bases of the ancestral tRNA acceptor stem, which facilitate a hierarchical set of “rules” (Table ). We have reviewed here the evidence that the original cognate pairs resulted from a combination of thermodynamic conformational preferences induced by patterns of acceptor stem purines and pyrimidines in the topmost four bases that enable hairpin formation by tRNA acceptor stems of ancestral Class I aaRS, and class‐specific synthetase secondary structures in both classes that reinforced the resulting differential thermodynamic tendencies.…”

Section: Conclusion Future Directionsmentioning

confidence: 99%

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Class I and II aminoacyl‐tRNA synthetase tRNA groove discrimination created the first synthetase–tRNA cognate pairs and was therefore essential to the origin of genetic coding

Carter

Wills

2019

IUBMB Life

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The genetic code likely arose when a bidirectional gene replicating as a quasi‐species began to produce ancestral aminoacyl‐tRNA synthetases (aaRS) capable of distinguishing between two distinct sets of amino acids. The synthetase class division therefore necessarily implies a mechanism by which the two ancestral synthetases could also discriminate between two different kinds of tRNA substrates. We used regression methods to uncover the possible patterns of base sequences capable of such discrimination and find that they appear to be related to thermodynamic differences in the relative stabilities of a hairpin necessary for recognition of tRNA substrates by Class I aaRS. The thermodynamic differences appear to be exploited by secondary structural differences between models for the ancestral aaRS called synthetase Urzymes and reinforced by packing of aromatic amino acid side chains against the nonpolar face of the ribose of A76 if and only if the tRNA CCA sequence forms a hairpin. The patterns of bases 1, 2, and 73 and stabilization of the hairpin by structural complementarity with Class I, but not Class II, aaRS Urzymes appear to be necessary and sufficient to have enabled the generation of the first two aaRS–tRNA cognate pairs, and the launch of a rudimentary binary genetic coding related recognizably to contemporary cognate pairs. As a consequence, it seems likely that nonrandom aminoacylation of tRNAs preceded the advent of the tRNA anticodon stem‐loop. Consistent with this suggestion, coding rules in the acceptor‐stem bases also reveal a palimpsest of the codon–anticodon interaction, as previously proposed. © 2019 IUBMB Life, 2019 © 2019 IUBMB Life, 71(8):1088–1098, 2019

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Section: Aars Structures Reinforce the Rulesmentioning

confidence: 94%

Section: Conclusion Future Directionsmentioning

confidence: 97%

Section: Aars Structures Reinforce the Rulesmentioning

confidence: 99%

Section: Conclusion Future Directionsmentioning

confidence: 99%

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Class I and II aminoacyl‐tRNA synthetase tRNA groove discrimination created the first synthetase–tRNA cognate pairs and was therefore essential to the origin of genetic coding

Carter

Wills

2019

IUBMB Life

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“…To address this question we used statistical regression methods, similar to those used to map the amino acid phase transfer free energies to the acceptor stem and anticodon (10,42), to show that this primordial differentiation is coded in the three topmost tRNA acceptor stem bases (3). As new amino acids entered the code, they overwrote that ancestral tRNA duality, turning the acceptorstem bases into a Palimpsest, derived from the Greek verb "psen", "to scrape out".…”

mentioning

confidence: 99%

Class I and II aminoacyl-tRNA synthetase tRNA groove discrimination created the first synthetase•tRNA cognate pairs and was therefore essential to the origin of genetic coding

Carter

Wills

2019

Preprint

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The genetic code likely arose when a bidirectional gene began to produce ancestral aminoacyl-tRNA synthetases (aaRS) capable of distinguishing between two distinct sets of amino acids. The synthetase Class division therefore necessarily implies a mechanism by which the two ancestral synthetases could also discriminate between two different kinds of tRNA substrates. We used regression methods to uncover the possible patterns of base sequences capable of such discrimination and find that they appear to be related to thermodynamic differences in the relative stabilities of a hairpin necessary for recognition of tRNA substrates by Class I aaRS. The thermodynamic differences appear to be exploited by secondary structural differences between models for the ancestral aaRS called synthetase Urzymes and reinforced by packing of aromatic amino acid side chains against the nonpolar face of the ribose of A76 if and only if the tRNA CCA sequence forms a hairpin. The patterns of bases 1, 2 and 73 and stabilization of the hairpin by structural complementarity with Class I, but not Class II aaRS Urzymes appears to be necessary and sufficient to have enabled the generation of the first two aaRS•tRNA cognate pairs, and the launch of a rudimentary binary genetic coding related recognizably to contemporary cognate pairs. As a consequence, it seems likely that non-random aminoacylation of tRNAs preceded the advent of the tRNA anticodon stem-loop. Consistent with this suggestion, coding rules in the acceptorstem bases also reveal a palimpsest of the codon•anticodon interaction, as previously proposed.

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The Ancient Operational Code is Embedded in the Amino Acid Substitution Matrix and aaRS Phylogenies

Shore¹,

Holland²,

Sumner³

et al. 2019

J Mol Evol

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The underlying structure of the canonical amino acid substitution matrix (aaSM) is examined by considering stepwise improvements in the differential recognition of amino acids according to their chemical properties during the branching history of the two aminoacyl-tRNA synthetase (aaRS) superfamilies. The evolutionary expansion of the genetic code is described by a simple parameterization of the aaSM, in which (i) the number of distinguishable amino acid types, (ii) the matrix dimension, and (iii) the number of parameters, each increases by one for each bifurcation in an aaRS phylogeny. Parameterized matrices corresponding to trees in which the size of an amino acid sidechain is the only discernible property behind its categorization as a substrate, exclusively for a Class I or II aaRS, provide a significantly better fit to empirically determined aaSM than trees with random bifurcation patterns. A second split between polar and nonpolar amino acids in each Class effects a vastly greater further improvement. The earliest Class-separated epochs in the phylogenies of the aaRS reflect these enzymes' capability to distinguish tRNAs through the recognition of acceptor stem identity elements via the minor (Class I) and major (Class II) helical grooves, which is how the ancient Operational Code functioned. The advent of tRNA recognition using the anticodon loop supports the evolution of the optimal map of amino acid chemistry found in

show abstract

Hierarchical groove discrimination by Class I and II aminoacyl-tRNA synthetases reveals a palimpsest of the operational RNA code in the tRNA acceptor-stem bases

Cited by 43 publications

References 71 publications

Class I and II aminoacyl‐tRNA synthetase tRNA groove discrimination created the first synthetase–tRNA cognate pairs and was therefore essential to the origin of genetic coding

Class I and II aminoacyl‐tRNA synthetase tRNA groove discrimination created the first synthetase–tRNA cognate pairs and was therefore essential to the origin of genetic coding

Class I and II aminoacyl-tRNA synthetase tRNA groove discrimination created the first synthetase•tRNA cognate pairs and was therefore essential to the origin of genetic coding

The Ancient Operational Code is Embedded in the Amino Acid Substitution Matrix and aaRS Phylogenies

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