Diastereoselective synthesis of pyridone ribo‐C‐nucleosides via Heck reaction and oxidation

Nucleosides find applications in medicinal chemistry, chemical biology and diagnostics. Among the nucleosides, C ‐nucleosides have attracted particular attention because their carbon‐carbon bond between nucleobase and ribose provides stability against degradation. While several well‐established methods exist for the synthesis of 2′‐deoxy‐ C ‐nucleosides, the preparation of their ribofuranosyl counterparts is more challenging. Established methods for their synthesis give mixtures of anomers and require harsh reagents or conditions. Here we report a diastereoselective glycosylation method involving a Heck reaction between a glycal and an aryl iodide, followed by oxidation of the silyl enol ether with methyl(trifluoromethyl)dioxirane (TFDO). The resulting ketone is then diastereoselectively reduced to the ribonucleoside. The new route has been applied to pyridones and is expected to also yield other ribo‐ C ‐nucleosides in diastereoselective fashion.German Research Foundation (DFG

2′/3′ regioselectivity of enzyme‐free copying of RNA detected by NMR

The RNA‐templated extension of oligoribonucleotides by nucleotides produces either a 3′,5′ or a 2′,5′‐phosphodiester. Nature controls the regioselectivity during RNA chain growth with polymerases, but enzyme‐free versions of genetic copying have modest specificity. Thus far, enzymatic degradation of products, combined with chromatography or electrophoresis, has been the preferred mode of detecting 2′,5′‐diesters produced in enzyme‐free reactions. This approach hinges on the substrate specificity of nucleases, and is not suitable for in situ monitoring. Here we report how 1H NMR spectroscopy can be used to detect the extension of self‐templating RNA hairpins and that this reveals the regioisomeric nature of the newly formed phosphodiesters. We studied several modes of activating nucleotides, including imidazolides, a pyridinium phosphate, an active ester, and in situ activation with carbodiimide and organocatalyst. Conversion into the desired extension product ranged from 20 to 90 %, depending on the leaving group. Integration of the resonances of H1′ protons of riboses and H5 protons of pyrimidines gave regioselectivities ranging from 40:60 to 85:15 (3′,5′ to 2′,5′ diester), but no simple correlation between 3′,5′ selectivity and yield. Our results show how monitoring with a high‐resolution technique sheds a new light on a process that may have played an important role during the emergence of life.Deutsche Forschungsgemeinschaf

Caging of a strongly pairing fluorescent thymidine analog with soft nucleophiles

Controlling the pairing strength of nucleobases in DNA through reactions with compounds found inside the cell is a formidable challenge. Here we report how a thiazolyl substituent turns a strongly pairing ethynylpyridone C‐nucleoside into a reactive residue in oligonucleotides. The thiazolyl‐bearing pyridone reacts with soft nucleophiles, such as glutathione, but not with hard nucleophiles like hydroxide or carbonate. The addition products pair much more weakly with adenine in a complementary strand than the starting material, and also change their fluorescence. This makes oligonucleotides containing the new deoxynucleoside interesting for controlled release. Due to its reactivity toward N, P, S, and Se‐nucleophiles, and the visual signal accompanying chemical conversion, the fluorescent nucleotide reported here may also have applications in chemical biology, sensing and diagnostics.Deutsche ForschungsgemeinschaftVolkswagen FoundationProjekt DEA

Absolute configuration of small molecules by co‐crystallization

The most reliable method to determine the absolute configuration of chiral molecules is X‐ray crystallography, but small molecules can be difficult to crystallize. We report rapid co‐crystallization of tetraaryladamantanes with small molecules as different as n‐decane to nicotine to produce crystals for X‐ray analysis and the assignment of absolute configuration when the molecules are chiral. A screen of 52 diverse compounds gave inclusion in co‐crystals for 88 % of all cases and a high‐resolution structure in 77 % of cases. Furthermore, starting from three milligrams of analyte, a combination of NMR spectroscopy and X‐ray crystallography produced a full structure in less than three days using an adamantane crystallization chaperone that encapsulates the analyte at room temperature.Deutsche Forschungsgemeinschaf

Synthesis of peptido RNAs from unprotected peptides and oligoribonucleotides via coupling in aqueous solution

Peptido RNAs are hybrid molecules with a phosphoramidate link between the N‐terminus of a peptide and the 5'‐phosphate of an oligoribonucleotide. Such species are formed in spontaneous co‐oligomerizations of amino acids and ribonucleotides in aqueous condensation buffer. To shed light on the properties of these fascinating molecules, a synthetic method for their preparation in monodisperse form is needed. Herein, we report how peptido RNAs can be prepared via solution‐phase coupling of unprotected peptides and oligoribonucleotides in aqueous solution. The preferred protocol uses pre‐activation of the 5'‐phosphate of the RNA as an imidazolide at pH 6.5, followed by precipitation and coupling to the peptide at pH 8 with an organocatalyst. The procedure gave peptido RNAs from water‐soluble peptides and synthetic oligoribonucleotides in up to 68 % yield. The method is convenient and inexpensive and can produce NMR quantities, opening the door to the systematic exploration of the chemistry of peptido RNAs.Deutsche ForschungsgemeinschaftVolkswagen FoundationProjekt DEA

Capturing and stabilizing folded proteins in lattices formed with branched oligonucleotide hybrids

The encapsulation of folded proteins in stabilizing matrices is one of the challenges of soft‐matter materials science. Capturing such fragile bio‐macromolecules from aqueous solution, and embedding them in a lattice that stabilizes them against denaturation and decomposition is difficult. Here, we report that tetrahedral oligonucleotide hybrids as branching elements, and connecting DNA duplexes with sticky ends can assemble into materials. The material‐forming property was used to capture DNA‐binding proteins selectively from aqueous protein mixtures. The three‐dimensional networks also encapsulate guest molecules in a size‐selective manner, accommodating proteins up to a molecular weight of approximately 159 kDa for the connecting duplex lengths tested. Exploratory experiments with green fluorescent protein showed that, when embedded in the DNA‐based matrix, the protein is more stable toward denaturation than in the free form, and retains its luminescent properties for at least 90 days in dry form. The noncrystalline biohybrid matrices presented herein may be used for capturing other proteins or for producing functional materials

Synthesis of a peptidoyl RNA hairpin via a combination of solid‐phase and template‐directed chain assembly

Peptidoyl RNAs are the products of ribosome‐free, single‐nucleotide translation. They contain a peptide in the backbone of the oligoribonucleotide and are interesting from a synthetic and a bioorganic point of view. A synthesis of a stabilized version of peptidoyl RNA, with an amide bond between the C‐terminus of a peptide and a 3′‐amino‐2′,3′‐dideoxynucleoside in the RNA chain was developed. The preferred synthetic route used an N‐Teoc‐protected aminonucleoside support and involved a solution‐phase coupling of the amino‐terminal oligonucleotide to a dipeptido dinucleotide. Exploratory UV‐melting and NMR analysis of the hairpin 5′‐UUGGCGAAAGCdC‐LeuLeu‐AA‐3′ indicated that the peptide‐linked RNA segments do not fold in a cooperative fashion. The synthetic access to doubly RNA‐linked peptides on a scale sufficient for structural biology opens the door to the exploration of their structural and biochemical properties.Volkswagen FoundationDeutsche Forschungsgemeinschaft (DFG)State of Hess

Transitions in solvate crystals of a tetraaryladamantane

Obtaining high-resolution structures of liquid compounds can be difficult. Encapsulating them in the lattice of a larger organic molecule acting as crystallization chaperone is one option to overcome this difficulty. Tetraaryladamantane ethers can play the role of chaperones, accommodating a range of different guest molecules in their crystals. How well-ordered crystalline arrangements for molecules of different shape are achieved is not clear. Cases in which more than one structure is found may shed light on this phenomenon. Here, we report low-order cubic crystal structures of 1,3,5,7-tetrakis(2,4-dimethoxyphenyl)adamantane (TDA) encapsulating ortho-xylene or cyclohexane, together with better ordered structures obtained after warming the crystals to 60 °C. Evidence for cubic crystal systems was also found for limonene, hexachlorobutadiene and eucalyptol, with a transition to a triclinic system for the former two, but no transition up to 70 °C for the latter. These findings indicate that some solvate structures of TDA can readily undergo structural transitions to less solvated, better ordered systems. Crystals obtained by rapid thermal crystallization may be in kinetically trapped states, and the transition to a solvate-free crystal system appears to have a kinetic barrier that depends strongly on the structure of the liquid guest molecules encapsulated in the lattice.Deutsche ForschungsgemeinschaftProjekt DEA