Lukas Jud scite author profile

The chemical synthesis of ribonucleic acids (RNA) with novel chemical modifications is largely driven by the motivation to identify eligible functional probes for the various applications in life sciences. To this end, we have a strong focus on the development of novel fluorinated RNA derivatives that are powerful in NMR spectroscopic analysis of RNA folding and RNA ligand interactions. Here, we report on the synthesis of 2′-SCF3 pyrimidine nucleoside containing oligoribonucleotides and the comprehensive investigation of their structure and base pairing properties. While this modification has a modest impact on thermodynamic stability when it resides in single-stranded regions, it was found to be destabilizing to a surprisingly high extent when located in double helical regions. Our NMR spectroscopic investigations on short single-stranded RNA revealed a strong preference for C2′-endo conformation of the 2′-SCF3 ribose unit. Together with a recent computational study (L. Li, J. W. Szostak, J. Am. Chem. Soc. 2014, 136, 2858–2865) that estimated the extent of destabilization caused by a single C2′-endo nucleotide within a native RNA duplex to amount to 6 kcal mol−1 because of disruption of the planar base pair structure, these findings support the notion that the intrinsic preference for C2′-endo conformation of 2′-SCF3 nucleosides is most likely responsible for the pronounced destabilization of double helices. Importantly, we were able to crystallize 2′-SCF3 modified RNAs and solved their X-ray structures at atomic resolution. Interestingly, the 2′-SCF3 containing nucleosides that were engaged in distinct mismatch arrangements, but also in a standard Watson–Crick base pair, adopted the same C3′-endo ribose conformations as observed in the structure of the unmodified RNA. Likely, strong crystal packing interactions account for this observation. In all structures, the fluorine atoms made surprisingly close contacts to the oxygen atoms of the corresponding pyrimidine nucleobase (O2), and the 2′-SCF3 moieties participated in defined water-bridged hydrogen-bonding networks in the minor groove. All these features allow a rationalization of the structural determinants of the 2′-SCF3 nucleoside modification and correlate them to base pairing properties.

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Expanding the Scope of 2′‐SCF₃ Modified RNA

Jud

Košutić

Schwarz

et al. 2015

Chemistry A European J

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The 2′-trifluoromethylthio (2′-SCF3) modification endows ribonucleic acids with exceptional properties and has attracted considerable interest as a reporter group for NMR spectroscopic applications. However, only modified pyrimidine nucleosides have been generated so far. Here, the syntheses of 2′-SCF3 adenosine and guanosine phosphoramidites of which the latter was obtained in highly efficient manner by an unconventional Boc-protecting group strategy, are reported. RNA solid-phase synthesis provided site-specifically 2′-SCF3-modified oligoribonucleotides that were investigated intensively. Their excellent behavior in 19F NMR spectroscopic probing of RNA ligand binding was exemplified for a noncovalent small molecule–RNA interaction. Moreover, comparably to the 2′-SCF3 pyrimidine nucleosides, the purine counterparts were also found to cause a significant thermodynamic destabilization when located in double helical regions. This property was considered beneficial for siRNA design under the aspect to minimize off-target effects and their performance in silencing of the BASP1 gene was demonstrated.

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An Unconventional Acid‐Labile Nucleobase Protection Concept for Guanosine Phosphoramidites in RNA Solid‐Phase Synthesis

Jud

Micura

2017

Chemistry A European J

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We present an innovative O 6 -tert-butyl/N 2 -tert-butyloxycarbonyl protection concept for guanosine (G) phosphoramidites. This concept is advantageous for 2′-modified G building blocks because of very efficient synthetic access when compared with existing routes that usually employ O 6 -(4-nitrophenyl)ethyl/N 2 -acyl protection or that start from 2-aminoadenosine involving enzymatic transformation into guanosine later on in the synthetic path. The new phosphoramidites are fully compatible with 2′-O-tBDMS or TOM phosphoramidites in standard RNA solid-phase synthesis and deprotection, and provide excellent quality of tailored RNAs for the growing range of applications in RNA biophysics, biochemistry, and biology.

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From novel RNA modifications to riboswitch function

Santner¹,

Rigger²,

Flür³

et al. 2014

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Lukas Jud

Surprising Base Pairing and Structural Properties of 2′-Trifluoromethylthio-Modified Ribonucleic Acids

Expanding the Scope of 2′‐SCF₃ Modified RNA

An Unconventional Acid‐Labile Nucleobase Protection Concept for Guanosine Phosphoramidites in RNA Solid‐Phase Synthesis

From novel RNA modifications to riboswitch function

Contact Info

Product

Resources

About

Lukas Jud

Surprising Base Pairing and Structural Properties of 2′-Trifluoromethylthio-Modified Ribonucleic Acids

Expanding the Scope of 2′‐SCF3 Modified RNA

An Unconventional Acid‐Labile Nucleobase Protection Concept for Guanosine Phosphoramidites in RNA Solid‐Phase Synthesis

From novel RNA modifications to riboswitch function

Contact Info

Product

Resources

About

Expanding the Scope of 2′‐SCF₃ Modified RNA