posted on 2022-11-21, 22:33authored byAlexandre Goyon, Daniel Nguyen, Sara Boulanouar, Peter Yehl, Kelly Zhang
The chemistry of guide RNA (gRNA) affects the performance
of the
clustered regularly interspaced short palindromic repeats (CRISPR)-Cas9
genome editing technique. However, the literature is very scarce about
the study of gRNA degradation and in particular at the single nucleotide
level. In this work, we developed a workflow to characterize the impurities
of large RNAs at the single nucleotide level and identified the residues
prone to degradation. Our strategy involves (i) the reduction of RNA
length, (ii) a chromatographic mode able to capture subtle changes
in impurity polarity, and (iii) a streamlined data treatment. To illustrate
the approach, stressed gRNA samples were analyzed by coupling an immobilized
ribonuclease T1 cartridge to a hydrophilic interaction liquid chromatography
(HILIC) column hyphenated with tandem mass spectrometry (MS/MS). Critical
findings were made possible by the presented technology. In particular,
the desulfurization of phosphorothioate (PS) linkages was the major
degradation observed at the single nucleotide level while no change
in purity profile could be observed when using conventional ion-pairing
reversed-phase (IPRP) liquid chromatography. To our knowledge, this
is the first time that several impurity types are screened for a large
RNA molecule using an automated online digestion analysis approach.