Excising the Mystery of Single-Guide RNA Processing

Over the past 10 years, utilization of CRISPR-Cas9 genome editing in plants has rapidly and significantly altered the scale and scope of both basic research and crop development. The transformative nature of genome editing technology has led to a great appetite for optimization. Many researchers


Excising the Mystery of Single-Guide RNA Processing
Over the past 10 years, utilization of CRISPR-Cas9 genome editing in plants has rapidly and significantly altered the scale and scope of both basic research and crop development. The transformative nature of genome editing technology has led to a great appetite for optimization. Many researchers have contributed to the development of CRISPR-Cas9 methods, using different techniques with variable success rates. There are a number of strategies for eukaryotic deployment of the Cas9 protein and the guide RNA elements, as well as attempts to increase editing efficiency and germline transmission of edited alleles (Mao et al., 2019). One area of focus in this optimization effort is the delivery of multiplexed single-guide RNAs (sgRNAs), the singlestranded RNAs that guide the Cas9 enzyme to specific DNA targets.
Clever solutions for sgRNA delivery have included interspersing an array of sgRNAs with flanking selfcleaving ribozymes, tRNAs, or directed-cleavage sequences. Another broadly implemented strategy is to drive nuclear expression of a single mature sgRNA with a U6 promoter, to be transcribed by RNA Polymerase III (Mao et al., 2019). Over time, however, researchers have noticed that these approaches appear to be unnecessary, as delivery of Cas9 and an array of sgRNAs in a single transcriptional unit without any special flanking sequences is just as efficient for Cas9 targeting and generation of DNA double-stranded breaks (Mikami, Toki, and Endo 2017;Wang et al., 2018). This finding pointed strongly to the existence of an unknown mechanism for sgRNA maturation in eukaryotes.
In this issue of Plant Physiology, Cody and Scholthof (2020) thoroughly and convincingly demonstrate the presence of native sgRNA processing in plants and present a highly anticipated model for this activity. Working in vitro, Cody and Scholthof (2020) verified the longstanding assumption that the presence of extra nucleotides 59 of the sgRNA inhibits Cas9 DNA cleavage. However, in Nicotiana benthamiana, sgRNAs transcribed with 59 overhangs are still functional, and Cas9-sgRNA complexes immunoprecipitated from the plant lack the overhangs, confirming that processing occurs.
To probe the mechanism of 59 processing, Cody and Scholthof (2020) conducted a series of in vitro experiments exposing sgRNA sequences to 59-39 exoribonuclease. They found that immature sgRNA containing the extra 59 sequence is readily digested, while mature sgRNA and Cas9-sgRNA complexes immunoprecipitated from plants are inherently resistant to 59-39 exoribonuclease activity. These observations led Cody and Scholthof (2020) to suggest two possible models: (1) Cas9 protects the bound sgRNA fragment from exonuclease during processing; and (2) mature sgRNA in vivo resists digestion through unknown 39 processing or folding mechanisms. These models are not mutually exclusive, and both allow for efficient processing of sgRNAs without the need for encoded signals to direct RNA cleavage. Cody and Scholthof (2020) then demonstrated in vitro that the required 59-39 exonuclease activity could be accomplished by a member of the XRN family, the predominant 59-39 exoribonucleases found in plants and mammals.
This model (Fig. 1) simultaneously offers timely answers to questions about sgRNA processing and highlights the need for further investigation into the mechanism, including genetic studies to identify the precise enzymes responsible for the activities observed. In order to function, XRN exonucleases Figure 1. Model of in planta processing of sgRNA (adapted from Cody and Scholthof, 2020). Following transcription (A), the sgRNAcontaining transcript is either bound to Cas9 or remains unbound (B). First, endonucleases remove the 59 cap (C) followed by removal of the 59 additional nucleotides through endogenous exonucleases (XRN1-like; D) to become catalytically active (E). require a 59 phosphate group, which implies a need for an unknown endonuclease to initiate sgRNA maturation, either by removing the 59 cap or by cleaving between an array of guides. Additionally, Cody and Scholthof (2020) make no claims about the 39 maturation of sgRNAs, which will need to be further investigated.
The enthusiasm of plant biologists for CRISPR-Cas9 technology has outpaced our understanding of its in planta mechanism, leaving a gap to be filled by basic science. By demonstrating that eukaryotic processing of sgRNAs could occur through highly conserved enzymatic activities, Cody and Scholthof (2020) are encouraging a shift in focus from Cas9 vector engineering to simplified delivery systems and back-tobasics approaches to CRISPR-Cas9. Cody and Scholthof (2020) also opened the door for optimization of genome editing through enhancing the plant's capacity to execute editing, which could improve the speed and efficiency of genome editing for model organisms, and possibly help to encourage editing in recalcitrant plant systems.