1-Deazaguanosine-Modified RNA: The Missing Piece for Functional RNA Atomic Mutagenesis

Bereiter, Raphael; Renard, Eva; Breuker, Kathrin; Kreutz, Christoph; Ennifar, Eric; Micura, Ronald

doi:10.1021/jacs.2c01877

Cited by 10 publications

(24 citation statements)

References 64 publications

(125 reference statements)

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“…RNA atomic mutagenesis of the functionality that is responsible for guanosine acid-base catalysis (namely, the N1-H moiety of guanine) have been lacking until recently. [37] The present study provides scaling of catalytic contributions for the pistol ribozyme class with unprecedented precision. Although it is tempting to assume that in general γ-and δ-catalysis-jointly constituting concerted general acid-base catalysis-make the largest contribution to the catalytic rate enhancement, [8] for pistol ribozymes this is not the case.…”

Section: Discussionmentioning

confidence: 90%

“…To achieve our goals, synthetic hurdles had to be taken first; those concerned access to the phosphoramidites of 1‐deazaguanosine (c 1 G), 3‐deazaguanosine (c 3 G), and xanthosine (X) needed for RNA solid‐phase synthesis. Since only for c 3 G containing RNA synthetic procedures were published, [35, 36] we have developed novel protocols for c 1 G and X modified RNA [37, 38] . A further requirement for our undertaking was the set‐up of a reliable and robust real‐time assay for direct monitoring of pistol ribozyme cleavage.…”

Section: Resultsmentioning

confidence: 99%

“…To date, only one other ribozyme class has been scaled for catalytic contributions with high precision. This is twister where “general base knockout” using c 1 G atomic mutagenesis caused a 275‐fold reduction in cleavage rate [37] . The precatalytic crystal structure of twister shows a hydrogen bond (2.6 Å) between the N1 atom of the active site guanine and the nonbridging pro ‐R oxygen of the scissile phosphate, [63] and hence, implicates that this guanine (G48) plays a significant role in phosphorane transition state stabilization (β‐catalysis).…”

Section: Discussionmentioning

confidence: 99%

“…One reason for this is that experimental means, i.e. RNA atomic mutagenesis of the functionality that is responsible for guanosine acid‐base catalysis (namely, the N1‐H moiety of guanine) have been lacking until recently [37] …”

Section: Discussionmentioning

confidence: 99%

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Scaling Catalytic Contributions of Small Self‐Cleaving Ribozymes

et al. 2022

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Nucleolytic ribozymes utilize general acid-base catalysis to perform phosphodiester cleavage. In most ribozyme classes, a conserved active site guanosine is positioned to act as general base, thereby activating the 2'-OH group to attack the scissile phosphate (γ-catalysis). Here, we present an atomic mutagenesis study for the pistol ribozyme class. Strikingly, "general base knockout" by replacement of the guanine N1 atom by carbon results in only 2.7-fold decreased rate. Therefore, the common view that γ-catalysis critically depends on the N1 moiety becomes challenged. For pistol ribozymes we found that γ-catalysis is subordinate in overall catalysis, made up by two other catalytic factors (α and δ). Our approach allows scaling of the different catalytic contributions (α, β, γ, δ) with unprecedented precision and paves the way for a thorough mechanistic understanding of nucleolytic ribozymes with active site guanines.

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Section: Discussionmentioning

confidence: 90%

Section: Resultsmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

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Scaling Catalytic Contributions of Small Self‐Cleaving Ribozymes

et al. 2022

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“…Previously published routes toward these compounds focused on ring closure of the imidazole part of the purine system after the pyrimidine core had been functionalized, however, the drawback of this approach is the passage of rather hazardous/explosive intermediates. Here, we present a new tactic for the syntheses of 1-deazaguanine and 1-deazahypoxanthine stimulated by a recently published route of our research group for the corresponding nucleosides [16,17], employing the same key reaction, namely the copper-catalyzed coupling of an aryl iodide with benzyl alcohol. We build on a commercially available imidazopyridine derivative and conceived a protecting group strategy to enhance solubility and selectivity to orchestrate the installation of the exocyclic amino and hydroxy groups.…”

Section: Introductionmentioning

confidence: 99%

A new route for the synthesis of 1-deazaguanine and 1-deazahypoxanthine

Bereiter¹,

Oberlechner²,

Micura³

2022

Beilstein J. Org. Chem.

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Imidazopyridines and pyrrolopyrimidines are an important class of compounds in medicinal chemistry. They can also be considered as deaza-modified purine nucleobases, and as such have attracted a lot of interest recently in the context of RNA atomic mutagenesis. In particular, for 1-deazaguanine (c1G base), a significant increase in demand is apparent. Synthetic access is challenging and the few reports found in the literature suffer from the requirement of hazardous intermediates and harsh reaction conditions. Here, we report a new six-step synthesis for c1G base, starting from 6-iodo-1-deazapurine. The key transformations are copper catalyzed C–O-bond formation followed by site-specific nitration. A further strength of our route is divergency, additionally enabling the synthesis of 1-deazahypoxanthine (c1I base).

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Chemical Synthesis of Modified RNA

Flemmich,

Bereiter,

Micura

2024

Angewandte Chemie

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Ribonucleic acids play a vital role in living organisms. Many of their cellular functions depend critically on chemical modification. Methods to modify RNA in a controlled manner – both in vitro and in vivo – are thus essential to evaluate and understand RNA biology at the molecular and mechanistic levels. The diversity of modifications, combined with the size and uniformity of RNA (made up of only 4 nucleotides) makes its site‐specific modification a challenging task that needs to be addressed by complementary approaches. One such approach is solid‐phase RNA synthesis. We discuss recent developments in this field, starting with new protection concepts in the ongoing effort to overcome current size limitations. We continue with selected modifications that have posed significant challenges for their incorporation into RNA. These include deazapurine bases required for atomic mutagenesis to elucidate mechanistic aspects of catalytic RNAs, and RNA containing xanthosine, N4‐acetylcytidine, 5‐hydroxymethylcytidine, 3‐methylcytidine, 2’‐OCF3, and 2’‐N3 ribose modifications. We also discuss the all‐chemical synthesis of 5’‐capped mRNAs and the enzymatic ligation of chemically synthesized oligoribonucleotides to obtain long RNA with multiple distinct modifications, such as those needed for single‐molecule FRET‐studies. Finally, we highlight promising developments in RNA‐catalyzed RNA modification using cofactors that transfer bioorthogonal functionalities.

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1-Deazaguanosine-Modified RNA: The Missing Piece for Functional RNA Atomic Mutagenesis

Cited by 10 publications

References 64 publications

Scaling Catalytic Contributions of Small Self‐Cleaving Ribozymes

Scaling Catalytic Contributions of Small Self‐Cleaving Ribozymes

A new route for the synthesis of 1-deazaguanine and 1-deazahypoxanthine

Chemical Synthesis of Modified RNA

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