Cas12a2 elicits abortive infection through RNA
Nature volume 613, pages 588–594 (2023)Cite this article
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Bacterial abortive-infection systems limit the spread of foreign invaders by shutting down or killing infected cells before the invaders can replicate1,2. Several RNA-targeting CRISPR–Cas systems (that is, types III and VI) cause abortive-infection phenotypes by activating indiscriminate nucleases3,4,5. However, a CRISPR-mediated abortive mechanism that leverages indiscriminate DNase activity of an RNA-guided single-effector nuclease has yet to be observed. Here we report that RNA targeting by the type V single-effector nuclease Cas12a2 drives abortive infection through non-specific cleavage of double-stranded DNA (dsDNA). After recognizing an RNA target with an activating protospacer-flanking sequence, Cas12a2 efficiently degrades single-stranded RNA (ssRNA), single-stranded DNA (ssDNA) and dsDNA. Within cells, the activation of Cas12a2 induces an SOS DNA-damage response and impairs growth, preventing the dissemination of the invader. Finally, we harnessed the collateral activity of Cas12a2 for direct RNA detection, demonstrating that Cas12a2 can be repurposed as an RNA-guided RNA-targeting tool. These findings expand the known defensive abilities of CRISPR–Cas systems and create additional opportunities for CRISPR technologies.
All domains of life use defence strategies that cause cells to enter dormancy or die to limit the spread of infectious agents1. In bacteria and archaea, this strategy is called abortive infection, and it is used by a vast variety of bacterial defence systems1,2. Recently, it was shown that CRISPR RNA (crRNA)-guided adaptive immune systems that target RNA cause abortive-infection phenotypes3,4,5,6. Type VI systems non-specifically degrade RNA, whereby the Cas13 single-effector nuclease acts as both a crRNA-guided effector and indiscriminate RNase3,7,8. In type III systems, target RNA binding triggers the production of cyclic oligoadenylate secondary messengers that in turn activate indiscriminate accessory RNases and ssDNases that can drive abortive infection4,5,9,10,11. Moreover, it has been proposed that abortive infection is mediated by indiscriminate dsDNases (such as NucC) activated through type III secondary messengers12,13 or by indiscriminate ssDNase activity from type V Cas12a single-effector nucleases14. However, type III CRISPR-mediated dsDNase activity has yet to be examined in vivo, and the ssDNase activity of Cas12a was recently shown to not cause abortive infection15.
Here we report that Cas12a2, a type V single-effector CRISPR-associated (Cas) nuclease, induces an abortive-infection phenotype when challenged with plasmids that are complementary to crRNA guides. Biochemical assays using recombinant protein revealed that Cas12a2 recognizes RNA targets, unleashing non-specific dsDNA-, ssDNA- and ssRNA-nuclease activities distinct from those of other single-subunit RNA-targeting (such as Cas13a) and dsDNA-targeting (such as Cas12a) Cas nucleases8,16,17. Furthermore, we show that the Cas12a2 non-specific nuclease activities damage bacterial DNA, triggering the SOS response and impairing cell growth. Collectively these results suggest that the dsDNase activity of Cas12a2 is instrumental in triggering the abortive-infection phenotype. As a proof-of-principle demonstration, we show that Cas12a2 can detect RNA at a sensitivity that is comparable to that of the RNA-targeting Cas13a nuclease at various temperatures.
Cas12a2 comprises a group of type V effector nucleases that are related to Cas12a16, with Cas12a2 orthologues previously being classified as Cas12a variants18. Our analyses similarly place them in a monophyletic clade that shares the last common ancestor with Cas12a nucleases (Fig. 1a and Extended Data Fig. 1). Further analysis revealed that CRISPR–Cas12a2 and CRISPR–Cas12a systems feature CRISPR repeats with a conserved 3′ end, and the nucleases possess homologous RuvC endonuclease domains and a similar predicted secondary structure in the N termini (Fig. 1b and Supplementary Fig. 2). Despite the conserved RuvC-like domains and N termini, Cas12a2 is distinguished from Cas12a by the presence of a large domain of unknown function located in place of the Cas12a bridge helix as well as a zinc-finger domain in place of the Cas12a Nuc domain (Fig. 1b and Supplementary Fig. 2). Considering their original classification combined with our phylogenetic analyses as well as recent structural results19, we named these distinct type V nucleases Cas12a2.
a, Maximum-likelihood phylogeny of identified Cas12a2 nucleases with Cas12a and Cas12b nucleases. The detailed phylogeny is shown in Extended Data Fig. 1. Systems with co-occurring Cas12a2 and Cas12a are indicated by filled red and blue circles. SuCas12a2 is indicated by an unfilled red circle. b, The domain architecture of SuCas12a2 in comparison to LbCas12a. aa, amino acids. c, Aligned direct repeats associated with representative Cas12a2 and Cas12a nucleases. The bold nucleotides indicate conserved positions within the processed repeats for both nucleases. The predicted pseudoknot structure of the Cas12a repeat is shown below. The loop of the hairpin (grey) is variable. Pre-crRNA processing by SuCas12a2 is shown in Extended Data Fig. 3. d, Gene organization of CRISPR–Cas systems within representative genomic loci encoding Cas12a2. Examples of systems encoding Cas12a2 as the sole Cas nuclease and those also encoding Cas12a are shown. e, Diagram of the traditional (top; target nuclease selection (tns)) and modified (bottom; nuclease selection (ns)) plasmid interference assay. Cm, chloramphenicol; Kan, kanamycin. f, The reduction in plasmid transformation for SuCas12a2 and LbCa12a2 under target plasmid and nuclease plasmid selection. g, The reduction in plasmid transformation of SuCas12a2 RuvC mutants under target plasmid and nuclease plasmid selection. For f and g, data are mean ± s.d. of at least three independent experiments started from separate colonies. P values were calculated using one-tailed Welch's t-tests; NS, P > 0.05; *P < 0.05, **P < 0.005.
Notably, some CRISPR–Cas systems contain both cas12a2 and cas12a genes in tandem next to a shared CRISPR array (Fig. 1c). From this observation and the conservation of CRISPR repeats from systems with either of the nucleases (Fig. 1d and Supplementary Fig. 3), we hypothesized that both proteins bind to and process similar crRNA guides. However, as the proteins diverge in other domains, we further hypothesized that Cas12a2 performs a defence function that is distinct from the dsDNA-targeting activity of Cas12a16.
To test these hypotheses, we encoded the cas12a2 gene from the sulfur-oxidizing epsilonproteobacterium Sulfuricurvum sp. PC08-66 (SuCas12a2) along with a CRISPR array into an expression plasmid, which we introduced into Escherichia coli cells. We next performed a traditional plasmid interference assay that depletes cells by selecting for the plasmid containing the nuclease and crRNA as well as a target plasmid (Fig. 1e). This assay detects broad immune system activity but cannot distinguish between defence activities that only deplete the target from those that activate abortive-infection phenotypes. To test whether Cas12a2 uses an abortive-infection mechanism, we modified the assay by selecting only for the nuclease plasmid (Fig. 1e). Consistent with our hypothesis that Cas12a2 functions differently compared with Cas12a, Cas12a2 depleted cells in both the traditional (about 1,900-fold reduction) and modified (around 1,300-fold reduction) plasmid interference assays, whereas Cas12a from Lachnospiraceae bacterium (LbCas12a) depleted cells only in the traditional assay (Fig. 1f). Similar trends were observed with different targets cloned into the same plasmid location, different Cas12a2 homologues and when comparing SuCas12a2 with the Cas12a homologue from Prevotella bryantii B14 (Pb2Cas12a) (Extended Data Fig. 2a,b). Moreover, mutating predicted active residues within any of the three RuvC motifs in SuCas12a2 impaired immune function (Fig. 1g). Collectively, these results indicate that Cas12a2 relies on a RuvC-nuclease domain and induces abortive infection through a mechanism that is distinct from that of Cas12a.
CRISPR systems that cause abortive-infection phenotypes (such as types III and VI) rely on indiscriminate nucleases activated by RNA targeting3,4,5. To determine whether Cas12a2 uses a similar mechanism, we recombinantly expressed and purified SuCas12a2 and tested its enzymatic activities in vitro (Fig. 2 and Supplementary Fig. 4). However, before examining the nucleic-acid-targeting activities, we needed to determine how Cas12a2 crRNAs are processed.
a, Direct targeting of different FAM-labelled nucleic-acid substrates by a purified SuCas12a2–crRNA complex. b, Collateral cleavage of FAM-labelled non-target nucleic-acid substrates by the SuCas12a2–crRNA complex with different target RNA substrates after 1 h. Target RNA, a non-self flanking sequence at the 3′ end; self flank, a flanking sequence mutated to the reverse complement of the crRNA repeat tag; no flank, only the reverse complement of the crRNA guide. For a and b, diagrams of target and non-target nucleic acids are shown on the right. c, Time-course analysis of RNA-triggered collateral cleavage of labelled non-target RNA, ssDNA or dsDNA. Representative gel images are provided in Extended Data Fig. 4c. Note that dsDNA contains twice as much ssDNA substrate as the RNA and ssDNA, but the same concentration of labelled strands. d, The effect of mutating each of the three RuvC motifs on RNA-triggered collateral cleavage of dsDNA. e, Time-course analysis of RNA-triggered collateral cleavage of non-target plasmid DNA. Plasmid DNA was visualized using ethidium bromide. For a–d, the asterisks indicate a FAM-labelled substrate, and the diagrams on the right indicate the substrates. All of the results are representative of three independent experiments. Gel source data are provided in Supplementary Fig. 1.
The CRISPR repeats of the Cas12a and Cas12a2 systems are highly conserved at the 3′ end (Fig. 1d and Supplementary Fig. 3), and sequence alignments predict that Cas12a2 shares secondary structure in the region of the Cas12a pre-crRNA-processing active site18,20 (Supplementary Fig. 5). Consistent with this prediction, RNA-sequencing analysis of pre-crRNAs processed by SuCas12a2 in vitro revealed that processing occurs one nucleotide downstream of the position cleaved by Cas12a (Extended Data Fig. 3a,b). The 3′ end of the spacer also underwent trimming in vivo to form an approximately 24-nucleotide guide (Extended Data Fig. 3b,c), possibly through host ribonucleases as observed for Cas9 crRNAs21. Mutating basic amino acids (Lys784 and Arg785) located in the predicted RNA-processing active site abolished activity22 (Extended Data Fig. 3d). Furthermore, plasmid interference assays revealed that Cas12a and Cas12a2 can interchange guides without impairing immunity (Extended Data Fig. 2c). Thus, the Cas12a2 nuclease processes its own crRNA guides like other type V effector nucleases20,23 and can share crRNAs with Cas12a.
To determine the nucleic-acid target preference of crRNA-guided Cas12a2, complementary ssRNA, ssDNA and dsDNA substrates containing an A/T-rich flanking sequence (paralleling Cas12a substrates)16,22 were fluorescently labelled with a FAM molecule and combined with crRNA-guided Cas12a2 (Fig. 2a). Similar to CRISPR–Cas systems that cause abortive infection—yet in contrast to the dsDNA-targeting Cas12a—Cas12a2 is activated only in the presence of complementary RNA targets. The potency of plasmid interference with SuCas12a2 (Fig. 1f) was notable given the lack of a defined promoter upstream of the target in this construct. However, we attribute the interference to spurious transcription of the encoding plasmid for two reasons: introducing an upstream terminator significantly reduced plasmid interference in E. coli (Extended Data Fig. 2d,e), and an upstream promoter was required to detect collateral activity in a cell-free transcription–translation assay24 (Extended Data Fig. 2f,g).
As other Cas abortive-infection mechanisms rely on collateral indiscriminate RNase activity, we examined whether specific RNA targeting by Cas12a2 induces indiscriminate nuclease activity. We found that SuCas12a2 robustly and indiscriminately degraded FAM-labelled ssRNA, ssDNA and dsDNA substrates bearing no complementarity to the crRNA guide. By contrast, other Cas nucleases indiscriminately degrade only ssRNA (Cas13a)8 or ssRNA and ssDNA (Cas12g)25 after RNA targeting, or only ssDNA after dsDNA targeting (Cas12a)14 (Fig. 2b and Extended Data Fig. 4a). Of the three collateral substrates, ssRNA and ssDNA appear to be more efficiently cleaved than dsDNA by Cas12a2 (Fig. 2c and Extended Data Fig. 4b). However, this difference could be explained by the presence of twice as many DNA strands in dsDNA substrates compared with ssDNA substrates for the same amount of nuclease. Also, similar to Cas13a8, complementary ssDNA and dsDNA do not activate any Cas12a2 non-specific nuclease activity (Extended Data Fig. 4a), and dsRNA is not a primary substrate of collateral cleavage (Extended Data Fig. 4c).
To examine whether Cas12a2 activity is reliant on detecting a ‘non-self’ signal adjacent to the target (called a protospacer-flanking sequence (PFS))8, we performed in vitro cleavage assays in which target RNA sequences were flanked on the 3′ side with a ‘self’ sequence complementary to the crRNA repeat (5′-AUCUA-3′), the non-self PFS used in our in vivo assay (5′-GAAAG-3′) or a ‘flankless’ RNA complementary to the guide region of the crRNA, but containing no PFS (Fig. 2b). Notably, only the RNA target containing the non-self PFS activated collateral nuclease activity, demonstrating that specific nucleotides at the 3′ end of the RNA target must be present to activate the collateral activity of Cas12a2. Moreover, introducing disruptive mutations to any of the three RuvC motifs or conserved cysteine residues within the putative zinc-finger domain abolished all non-specific cleavage (Fig. 2d and Extended Data Fig. 4d), consistent with our in vivo plasmid interference results (Fig. 1g).
Our biochemical assays demonstrated that Cas12a2 could quickly remove a FAM label from linear dsDNA substrates, but it was unclear whether Cas12a2 degrades DNA lacking available 5′ or 3′ ends. We therefore challenged crRNA-guided Cas12a2 with an RNA target and a supercoiled pUC19 plasmid. Importantly, pUC19 does not contain any sequence complementary to the Cas12a2 crRNA guide. We observed that SuCas12a2 rapidly nicked, linearized and degraded pUC19 DNA (Fig. 2e), but only in the presence of a cognate target and PFS and with an intact RuvC domain (Extended Data Fig. 4e). This rapid destruction of the supercoiled plasmid contrasts with the slow and incomplete linearization of plasmid DNA by Cas12a nucleases26. These data suggest a mechanism in which activated SuCas12a2 is able to robustly hydrolyse the phosphodiester backbone of non-specific DNA regardless of whether it is supercoiled, nicked or linear. A comparison with Cas12a (dsDNA targeting with collateral ssDNase), Cas13a (ssRNA targeting with collateral ssRNase) and Cas13g (ssRNA targeting with collateral ssRNase and ssDNase) demonstrated that the RNA-targeting ssRNase, ssDNase and dsDNase are unique to SuCas12a2 (Extended Data Fig. 4a). Collectively, these in vitro results reveal that crRNAs guide SuCas12a2 to RNA targets, activating RuvC-dependent cleavage of ssRNA, ssDNA and dsDNA. These activities, in part or in total, may underlie the abortive-infection phenotype.
Although our in vitro data indicated an underlying mechanism for the Cas12a2 abortive-infection phenotype, we wanted to understand the targeting limitations of these distinct enzymes. In particular, we investigated the stringency of non-self PFS sequence recognition and penalties for mismatches between the crRNA and target. We therefore challenged SuCas12a2 with a library of plasmids encoding all possible 1,024 flanking sequences at the 3′ end of the RNA target to the −5 position (Fig. 3a and Extended Data Fig. 5a,b). We found that SuCas12a2 depleted approximately half of all of the sequences in the library, suggesting a PFS-recognition mechanism that is more stringent than that of Cas13 but still more promiscuous than those of most DNA-targeting systems8,27. The depleted sequences were generally A rich, consistent with a 5′-GAAAG-3′ PFS, but could not be fully captured by a single consensus motif (Fig. 3a and Extended Data Fig. 5c). We further validated individual depleted sequences, including representatives within five unique motifs recognized by SuCas12a2 but not by Pb2Cas12a—a nuclease that is known for flexible PAM recognition24 (Fig. 3b and Extended Data Fig. 5d). Consistent with its function as an RNA-targeting nuclease, the recognized sequences were broad but did not follow the expected profile if Cas12a2 is principally evaluating tag–anti-tag complementarity. These results further support a mechanism in which PFS recognition by SuCas12a2 operates similar to type III systems that require recognition of a PFS or RNA PAM to activate28,29,30,31 and distinct from the evaluation of tag–anti-tag complementarity used by RNA-targeting Cas138,32 and other type III CRISPR–Cas systems33.
a, Experimentally determined PFSs and motifs recognized by SuCas12a2 in E. coli. Motifs capturing positions −4 to −1 of the PFS are shown, and are written 3′ to 5′. B represents C, G or U; K represents G or U; R represents G or A; W represents A or U; and Y represents C or U. Results are representative of two independent screens (Extended Data Fig. 5). b, Validation of selected PFSs identified in the screen and permissive of targeting by SuCas12a2 but not Pb2Cas12a. c, The effect of guide mismatches on plasmid targeting by SuCas12a2 in E. coli. d, The extent of inhibition by known AcrVA proteins against SuCas12a2. Acr proteins were confirmed to exhibit inhibitory activity against different Cas12a homologues in E. coli or in cell-free transcription–translation reactions (Extended Data Fig. 5). Data are mean ± s.d. of at least three independent experiments started from separate colonies. Statistical analysis was performed using one-tailed Welch's t-tests.
Most DNA- and RNA-targeting Cas nucleases have shown high sensitivity to mismatches within a seed region, in which a single mismatch between the crRNA guide and target disrupts binding8,17,34,35. Thus, to identify whether SuCas12a2 relies on a seed region, we evaluated how SuCas12a2 tolerates mismatches in our cell-based assay (Fig. 3c). Notably, SuCas12a2 accommodated single and double mismatches across the target, with PFS-distal mutations exerting more adverse effects on plasmid targeting. To completely disrupt SuCas12a2 targeting, four mismatches were needed throughout the guide (Fig. 3c) or up to 10 mismatches at the 3′ end of a 24-nucleotide guide (Extended Data Fig. 6a). The flexible PFS recognition and a tolerance for guide–target mismatches indicate that SuCas12a2 exhibits promiscuous target recognition and appears to lack a canonical seed that is hypersensitive to guide–target mismatches34,35. However, the necessary pairing with the 3′ end of the guide is consistent with this end being pre-ordered in the structure of the crRNA–Cas12a2 binary complex19 and possibly initiating base pairing with the target. Furthermore, the promiscuity further enabled SuCas12a2 to recognize target mutations that disrupt targeting by Cas12a (Extended Data Fig. 6b).
Collectively, the distinct activities of Cas12a2 compared with Cas12a suggested that tandem systems possessing both nucleases (Fig. 1d) may act cooperatively to broaden the effectiveness against foreign viruses and plasmids. In particular, we hypothesized that the unique structural features of Cas12a2 might prevent the escape of viruses encoding anti-CRISPR proteins that block Cas12a function36,37,38. Consistent with this hypothesis, only one (AcrVA2.1) out of seven Cas12a anti-CRISPR proteins was able to impair Cas12a2 function, albeit only partially (Fig. 3d and Supplementary Fig. 6a,b). Notably, AcrVA5 also exhibited no inhibitory activity despite SuCas12a2 possessing the conserved lysine residue in Cas12a that is chemically modified by this Acr to block PAM recognition39 (Fig. 3d and Supplementary Fig. 6c). The limited ability of Cas12a Acr proteins to inhibit SuCas12a2 further underscores the distinct properties of these nucleases and the ability of Cas12a and Cas12a2 to complement each other in immune defence.
Although our initial results indicate that Cas12a2 causes an abortive-infection phenotype, one scenario was that triggered Cas12a2 was selectively clearing all plasmids, enabling the cells to succumb to any introduced antibiotic selection. To assess this possibility, we evaluated the growth of E. coli in liquid culture under different antibiotic selection conditions (including a no-antibiotic condition) after induction of SuCas12a2 and LbCas12a using a targeting crRNA (Fig. 4a and Supplementary Fig. 7). SuCas12a2 but not LbCas12a suppressed culture growth in the absence of plasmid selection, further supporting induction of an abortive-infection phenotype by Cas12a2.
a, E. coli growth arrest in the presence of SuCas12a2, LbCas2a2 or LsCas13a plasmid under different targeting conditions and antibiotic regimes. A600, absorbance at 600 nm. b, The percentage of E. coli cells stained with propidium iodide (PI) indicative of viability loss before targeting (uninduced) and after 4 h of targeting (induced) without antibiotic selection. The gating strategy is shown in Supplementary Fig. 7. c, The varying extent of RNA degradation in E. coli by SuCas12a2, LbCas12a or LsCas13a2 2 h after induction without antibiotic selection. The results represent duplicate independent experiments. See Extended Data Fig. 7 for independent quadruplicates. The small RNA pool includes tRNAs and other small RNAs. d, SOS-responsive expression of GFP in E. coli after 4 h of plasmid targeting by SuCas12a2, LbCas12a or LsCas13a without antibiotic selection. Time-course data are shown in Supplementary Fig. 9. RFU, relative fluorescence units. e, Relative DNA content in E. coli after 4 h of targeting by SuCas12a2, LbCas12a or LsCas13a without antibiotic selection. 4′,6-diamidino-2-phenylindole (DAPI) fluorescence and cell size were measured using flow cytometry. Each circle or pair of vertically aligned circles represents major subpopulations from the same biological replicate. The corresponding contour plots are shown in Extended Data Fig. 8. FSC, forward scatter. f, RNA-detection assay. The limit of RNA detection with Cas12a2 incubated with a ssRNA beacon at room temperature (RT). Data are mean ± s.e.m. of three independent experiments. g, Nucleic-acid targets and reporters as well as the unamplified limit of detection (LOD) for Cas12a2 and other Cas detectors46. Aap, Alicyclobacillus acidiphilus; Lwa, Leptotrichia wadei; Lbu, Leptotrichia buccalis. h, The proposed model for promiscuous RNA targeting and collateral degradation by SuCas12a2 and its effect on the cell. For b and d, data are mean ± s.d. of four independent experiments started from separate colonies. Statistical analysis was performed using one-tailed Welch's t-tests. NT, non-target plasmid; T, target plasmid.
One open question is whether the abortive-infection phenotype was caused by cell dormancy or cell death. It was recently shown that, after recognizing an RNA target, Cas13a mediates widespread RNA degradation that drives cellular dormancy and suppresses phage infection3. We therefore introduced the representative Cas13a from Leptotrichia shahii (LsCas13a) into our liquid culture assay. Similar to SuCas12a2, LsCas13a suppressed growth even in the absence of plasmid selection (Fig. 4a and Supplementary Fig. 7).
Our comparison to LsCas13a suggested that the growth suppression by SuCas12a2 could occur through non-specific RNA cleavage, causing cell dormancy, whereas our in vitro data indicated that non-specific dsDNA cleavage could also suppress growth by causing cell death. To evaluate whether the cells containing SuCas12a2 were undergoing cell death, we performed a cell-viability assay using propidium iodide for both Cas12a2 and Cas13a. We observed only a small percentage (about 10%) of cell death for both Cas12a2 and Cas13a after 4 h (Fig. 4b and Supplementary Fig. 8). Thus, although the indiscriminate nuclease activities of Cas12a2 cause some cell death, the primary result of Cas12a2 activity is better described as a cell-dormancy phenotype.
Although Cas12a2 appears to cause dormancy, it was unclear which of the several indiscriminate nuclease activities are involved. To determine whether SuCas12a2 causes dormancy through RNA cleavage, total cellular RNAs were examined under targeting and non-targeting conditions. Whereas Cas13a significantly depleted both rRNAs and the small RNA pool (which includes tRNAs), Cas12a2 significantly depleted only the small RNA pool (Fig. 4c and Extended Data Fig. 7).
Given the observed differences in RNA degradation under targeting conditions, we examined whether the indiscriminate dsDNase activity of SuCas12a2 was detectable in the context of the abortive-infection phenotype. We reasoned that widespread dsDNA damage caused by SuCas12a2 would trigger an SOS response, impairing growth40,41. Consistent with this assertion, plasmid targeting using SuCas12a2 significantly induced GFP expression from an SOS-responsive reporter construct42 compared with a non-target control, whereas LbCas12a and LsCas13a negligibly induced GFP expression (Fig. 4d and Supplementary Fig. 9). Furthermore, SuCas12a2-targeting cultures diverged into two subpopulations in the absence of antibiotic selection: one represented by compact cells with reduced DNA content and another represented by filamentous cells with high DNA content (Fig. 4e and Extended Data Figs. 8 and 9). Cultures expressing LbCas12a and LsCas13a did not exhibit noticeable differences in cell size and DNA content for the target and non-target plasmids. Previous studies with other CRISPR–Cas systems that specifically targeted the bacterial chromosome observed similar morphological changes43,44,45, suggesting that these distinct morphologies are due to dsDNA damage. These results demonstrate that RNA targeting by SuCas12a2 causes dsDNA damage of the bacterial chromosome that in turn induces the SOS response and abortive infection in bacteria, reflecting a distinct mechanism of immunity that relies on indiscriminate dsDNase activity. Consistent with this observation, recent cryo-electron microscopy structures revealed that Cas12a2 binds to and cuts dsDNA through a mechanism that is completely distinct from all other CRISPR-associated nucleases, and structure-guided mutants with impaired in vitro collateral dsDNase but not ssRNase and ssDNase activities abolished in vivo defence activity against plasmids19.
CRISPR single-effector nucleases have been repurposed for many applications from gene editing to molecular diagnostics. To determine whether Cas12a2 could be repurposed as a biotechnological tool, we co-opted SuCas12a2 to detect RNA. We programmed apo SuCas12a2 with a crRNA guide complementary to an RNA target and incubated the complex with a ssDNA or ssRNA beacon that fluoresces after cleavage due to separation of a fluorophore and a quencher (Fig. 4f). Using this approach, we were able to detect RNA using both ssDNA and ssRNA probes at 37 °C and room temperature, with a limit of detection within the range observed for other single-subunit Cas nucleases46 (Fig. 4f and Extended Data Fig. 10a–c). Furthermore, we devised a modified detection assay that uses plasmid DNA and DNA nick translation47, introducing a distinct positive readout for CRISPR-based diagnostics (Extended Data Fig. 10d–f). These data indicate that Cas12a2 can be readily repurposed as a tool for applications in science, biotechnology, agriculture and medicine. We anticipate that the unique activities of this enzyme can be further leveraged to expand the CRISPR-based toolkit.
Collectively, our data support a model in which Cas12a2 nucleases exhibit RNA-triggered degradation of cytoplasmic dsDNA and small RNAs, impeding host cell growth and eliciting an abortive-infection phenotype (Fig. 4h). This mechanism contrasts with targeted invader clearance or abortive-infection activities exhibited by other CRISPR–Cas systems. Specifically, the mechanism exhibited by Cas12a2 is reminiscent of the recently described CBASS defence system, which relies on the indiscriminate double-stranded DNase NucC that degrades host cell DNA and kills the cell12. Notably, some type III systems encode NucC enzymes, suggesting that other CRISPR–Cas systems have convergently evolved to use a similar DNA-degrading abortive-infection mechanism13,48.
In addition to damaging the genome and inducing the SOS response, SuCas12a2 exhibits promiscuous RNA recognition through a flexible PFS and mismatch tolerance. This flexibility in target recognition mirrors the flexibility of tag–anti-tag complementarity observed with type III and VI systems8,33 and could be particularly advantageous against rapidly evolving phages, although Cas12a2 orthologues must be characterized to determine whether such promiscuity is a common feature of these nucleases. Although flexible, the PFS would still prevent self-recognition of spurious antisense transcription of the CRISPR array, as the corresponding PFS-containing portion of the repeat strongly diverges from the recognized PFS—a standard feature of self/nonself-recognition for PAMs in DNA-targeting CRISPR–Cas systems49. The flexibility in PFS and target recognition could further serve as a back-up mechanism if precise recognition and clearance of DNA targets by Cas12a fails in organisms that encode both Cas12a and Cas12a2 adjacent to a single CRISPR array (Fig. 1a,d and Extended Data Figs. 1 and 6b). This dual-nuclease strategy would be akin to bacteria encoding multiple CRISPR–Cas systems targeting the same invader50. However, further research is needed to understand how these two nucleases work together to counter infections.
The combination of nuclease-mediated crRNA biogenesis, RNA targeting and collateral cleavage of ssRNA, ssDNA and, in particular, dsDNA sets Cas12a2 apart from other known Cas nucleases. The apparent need to recognize the A-rich flanking sequence by SuCas12a2 to activate the indiscriminate RuvC nuclease activity strongly indicates that Cas12a2 must bind to a correct PFS adjacent to the RNA target to activate cleavage rather than rely solely on complementarity between the repeat tag and target anti-tag pair to distinguish self from non-self sequences, typical of several other RNA-targeting Cas nucleases and complexes8,33,51,52. Investigating the underlying molecular basis of target recognition and activation of collateral cleavage by Cas12a2 could reveal new mechanisms used by CRISPR nucleases to discriminate between self and non-self targets. Recent cryo-electron microscopy structures of Cas12a2 at stages of RNA targeting and collateral dsDNA capture are already fulfilling this need19.
Cas12a2 holds substantial potential for CRISPR technologies. As a proof-of-principle demonstration, we showed that SuCas12a2 can be repurposed for RNA detection with a limit of detection comparable to existing single-effector based tools46. Beyond the ability to detect RNA, we envision a variety of SuCas12a2 applications that expand and enhance the CRISPR-based tool kit. RNA-triggered dsDNA cleavage could enable programmable killing of prokaryotic and eukaryotic cells with various applications, including programmable shaping of microbial communities, cancer therapeutics and counterselection to enhance genome editing. Moreover, the ability of Cas12a2 and Cas12a to use the same crRNA sequence yet recognize distinct nucleic acid species (RNA versus ssDNA and dsDNA) and elicit distinct non-specific cleavage activities (ssRNA, ssDNA and dsDNA (Cas12a2) versus ssDNA (Cas12a)) could augment existing Cas12a applications by incorporating Cas12a2. By further exploring the properties of SuCas12a2 and its orthologues, we expect the advent of new and improved CRISPR technologies that could broadly benefit society.
Several Cas12a2 sequences were initially identified and tentatively classified as encoding Cas12a nucleases16. These Cas12a2 protein sequences were used as seeds for BLASTp searches of protein data in NCBI and for tBLASTn searches of metagenomic data in NCBI (https://www.ncbi.nlm.nih.gov) and JGI (https://img.jgi.doe.gov) to identify additional putative Cas12a2 nucleases.
The amino acid sequences of Cas12a2, Cas12a and Cas13b orthologues were aligned using MAFFT (v.7.490)53. The resulting alignment was trimmed using ClipKIT54 and used to create a maximum-likelihood phylogeny using RAxML-NG55 with the following parameters: --model JTT+G --bs-metric fbp, tbe --tree pars{60}, rand{60} --seed 12345 --bs-trees autoMRE. Cas13b sequences were used as an outgroup. The amino acid sequences used in the creation of the phylogeny are provided in Supplementary File 1.
Conserved motifs in SuCas12a2 were identified using MOTIF Search (https://www.genome.jp/tools/motif/, accessed on 15 June 2021) and Phyre 256 (accessed on 8 March 2021). HHpred secondary structure predictions of Cas12a2 orthologous amino acid sequences were performed to identify the common secondary structure between Cas12a2 and Cas12a that predicted the crRNA processing site of Cas12a257.
All of the in vivo experiments, unless indicated otherwise, were performed in E. coli BL21(AI). For propagation, the cultures were grown in LB medium at 37 °C with constant shaking at 225–250 rpm. E. coli strain TOP10 was used for plasmid cloning (Supplementary Table 1 (tab 1)). All primers, gBlocks and oligos were obtained from Integrated DNA Technologies, unless specified otherwise. Gibson assembly of plasmid construction was performed using the NEBuilder HiFi DNA Assembly Master Mix (New England Biolabs, E2621). Mutagenesis of the plasmids, including small insertions and nucleotide substitutions, was performed using the Q5 Site-Directed Mutagenesis Kit (New England Biolabs, E0554S). All of the nucleases together with crRNA, unless specified otherwise, were expressed from plasmids containing p15A origin-of-replication and a chloramphenicol-resistance marker. The expression of the nucleases and crRNA was controlled by a T7 promoter, unless otherwise specified. All of the target and non-target plasmids were created by introducing protospacer sequences and corresponding flanking sequences into pBR322 or sc101 origin-of-replication plasmids bearing a kanamycin-resistance cassette, unless otherwise specified. Sequences encoding Cas12a2 orthologues (Supplementary File 1) were codon-optimized and synthesized by Genscript. Sequences encoding Pb2Cas12a from P. bryantii B14 (NCBI: WP_039871282) LbCas12a from L. bacterium ND2006 (NCBI: WP_035635841.1), FnCas12a from Francisella tularensis (NCBI: WP_104928540.1), AsCas12a from Acidaminococcus sp. BV3L6 (NCBI: WP_021736722.1) and Mb3Cas13a from Moraxella bovoculi (NCBI: WP_080946945.1)16 were codon optimized for expression in E. coli and ordered as gBlocks from Integrated DNA Technologies. Sequences encoding anti-CRISPR proteins36,38 (Supplementary Tables 1 and 3) were codon-optimized for expression in E. coli and ordered as gBlocks from Integrated DNA Technologies. The acr genes were then PCR-amplified and introduced into the pBAD24 plasmid backbone carrying an ampicillin-resistance cassette58. The LsCas13a-encoding plasmid pCBS2091 was ordered from Addgene (79150)8. For detecting RecA-dependent SOS response in E. coli BL21(AI), reporter plasmids pCBS2000, pCBS3611 and pCBS3616 were created by introducing the recA promoter, included 100 bp upstream of the predicted LexA-binding site, upstream of the GFP-encoding gene into plasmid pCBS198. Plasmids pCBS3611 and pCBS3616 received an ampicillin-resistance cassette from plasmid pCB67224. The recA promoter sequence was identified in the genome of E. coli BL21(AI) between positions 2,635,525 and 2,635,347 (NCBI: CP047231.1). Control plasmids pCBS3616 and pCBS2002 without the GFP-reporter genes were generated by PCR amplification of pCBS2000 and pCBS3616 followed by KLD assembly (New England Biolabs, M0554). A full list of plasmids used in the study, including links to plasmid maps, is provided in Supplementary Tables 1 and 2. A list of relevant oligonucleotide, dsDNA and RNA sequences is provided in Supplementary Tables 1 and 3.
N-terminal 6×His-tagged SuCas12a2 WT and mutant constructs were expressed in E. coli Nico21(DE3) cells from a pACYC plasmid either lacking (apo) (plasmid 1416) or containing a three-spacer CRISPR array (crRNA-guided) (plasmid 1408) using either autoinduction or isopropyl β-d-1-thiogalactopyranoside (IPTG) induction. Autoinduction growth was performed according to previously reported guidelines59. In brief, a solution containing recommended concentrations of ZY media, MgSO4, metals mix, 5052 (0.5% glycerol, 0.05% glucose, 0.2% α-lactose) and NPS autoinduction buffers along with antibiotics needed for selection was inoculated with bacteria from a glycerol stock or a fresh transformation. The cells were grown for 5 h at 37 °C with shaking at around 250 rpm and then moved to 24 °C where they were incubated for 24 h before collection by centrifugation at 8,000 rpm for 25 min. Cell pellets were then stored at −80 °C until purification. For the IPTG induction, 1 l of TB medium was inoculated with 20 ml of overnight growth and was grown at 37 °C until an optical density at 600 nm (OD600) of 0.6. The cells were then cold-shocked on ice for 15 min and induced with 0.1 mM IPTG, followed by a 16–18 h incubation at 18 °C. Cells were collected by centrifugation. Cells were lysed by sonication in lysis buffer (25 mM Tris pH 7.2, 500 mM NaCl, 10 mM imidazole, 2 mM MgCl2, 10% glycerol) in the presence of leupeptin, aprotinin, pepstatin, AEBSF and lysozyme. The lysate was clarified by centrifugation at 36,400g for 35 min. Clarified lysate was added to 5 ml of Ni-NTA resin and batch bound at 4 °C for 30 min, and then washed with 100 ml of lysis buffer. The protein was eluted with 50 ml of Ni-elution buffer (25 mM Tris pH 7.2, 500 mM NaCl, 250 mM imidazole, 2 mM MgCl2, 10% glycerol). Fractions containing SuCas12a2 were desalted using the Hiprep 26/10 desalting column into low-salt buffer (25 mM Tris-pCas12a22, 50 mM NaCl, 2 mM MgCl2, 10% glycerol). SuCas12a2 + crRNA was then applied to a Hitrap Q HP column anion-exchange column, whereas the apo SuCas12a2 was applied to a Hitrap SP HP cation-exchange column. The column was washed with 10% high-salt buffer (25 mM Tris pH 7.2, 1 M NaCl, 2 mM MgCl2, 10% glycerol) followed by a gradient elution to 100% high-salt buffer 10 CV (50 ml). The fractions containing SuCas12a2 were concentrated using a 100 kDa MWKO concentrator to about 1 ml and then purified by size-exclusion column chromatography over a Hiload 26/600 Superdex 200 pg column equilibrated in SEC buffer (100 mM HEPES pH 7.2, 150 mM KCl, 2 mM MgCl2, 10% glycerol). The fractions containing SuCas12a2 were concentrated and stored at −80 °C.
For processing of a 3× pre-crRNA, SuCas12a2 pre-CRISPR×3 RNA was in vitro transcribed using the HiScribe T7 High Yield RNA Synthesis Kit (New England Biolabs). The template DNA was derived from Jackson Laboratory plasmid 1409 linearizing with the KpnI restriction enzyme. A contaminating band that runs approximately at 130 nucleotides was observed to be an artifact of the reaction. Numerous strategies were attempted to prevent the transcription of this contaminating band, to no success. In vitro transcribed RNA was cleaned using RNeasy spin columns (Qiagen). Then, 1.5 μM of apo SuCas12a2 was incubated with 1 mg of SuCas12a2 pre-CRISPR×3 RNA in 1× 3.1 buffer from New England Biolabs (100 mM NaCl, 50 mM Tris-HCl, 10 mM MgCl2, 100 mg ml−1 BSA pH 7.9) and incubated at 25 °C for various times. The samples were run on a gel (12% polyacrylamide, 8 M, TBE) alongside a ssRNA low range ladder (New England Biolabs) and stained with SYBR gold (Thermo Fisher Scientific).
For processing of a 1× crRNA with WT and crRNA-processing mutants, a synthetic crRNA with a 13 base 5′ unprocessed overhang (smcrRNA; Supplementary Tables 1 and 3) was refolded using a previously outlined protocol60. In a 10 μl reaction, 150 nM of crRNA substrate was combined with 1.5 μM WT, K784A or K785A apo SuCas12a2 protein in NEB 3.1. The reactions were incubated at 37 °C for 1 h. The reactions were quenched with phenol and phenol–chloroform extraction was performed. The results were analysed using 12% urea–PAGE stained with SYBR Gold.
For analysis of targeted cleavage, 10 μl reactions of 250 nM SuCas12a2–crRNA with 100 nM of complementary FAM-labelled synthetic oligonucleotide (that is, ssDNA, dsDNA or RNA) in 1× NEB 3.1 buffer were incubated at 37 °C for 1 h. Reactions were quenched with phenol and then phenol–chloroform extraction was performed. Results were analysed using a previously outlined FDF-PAGE method61 and visualized for fluorescein fluorescence.
For analysis of collateral cleavage, 10 μl reactions of 250 nM SuCas12a2–crRNA, and 250 nM of target (RNA complementary to the crRNA-guide) or non-target (RNA non-complementary to the crRNA-guide) substrate and 100 nM of 5′-FAM labelled collateral substrate (ssDNA, dsDNA, RNA) in 1× NEB 3.1 were incubated at 37 °C for 1 h. Reactions were quenched with phenol and then phenol–chloroform extraction was performed. The results were analysed using 12% urea–PAGE and visualized for fluorescein fluorescence.
For analysis of the flanking-sequence requirements for activation, 10 μl reactions of 250 nM Cas12a2–crRNA, with 300 nM of different target ssRNAs (self (flanked by sequence complementary to the direct repeat of the crRNA), no flanks and flanks containing a 5′-GAAA-3′ PFS on the 3′ side of the protospacer) and 100 nM of collateral 5′-FAM dsDNA in 1× NEB 3.1 buffer were incubated at 37 °C for 1 h. The reactions were quenched with phenol and phenol–chloroform extraction was performed. The results were analysed using 12% urea–PAGE and visualized for fluorescein fluorescence.
For kinetic analysis of collateral cleavage, a single 100 μl reaction containing 100 nM Cas12a2–crRNA, 100 nM of target ssRNA (crRNA complementary) and 100 nM of different 5′-FAM labelled collateral substrates (ssDNA, dsDNA, RNA) in 1× NEB 3.1 buffer was made. Time points were taken at 1, 2, 5, 10, 15, 30, 60, 120 and 180 min by combining 10 μl from the 100 μl reaction with phenol, and then performing phenol–chloroform extraction. The results were analysed using 12% urea–PAGE and visualized for fluorescein fluorescence.
For the plasmid-cleavage assay, a 100 μl reaction containing 14 nM Cas12a2–crRNA, 25 nM target RNA, 7 nM of pUC19 plasmid in 1× NEB 3.1 buffer was incubated at 37 °C. At the indicated time points, 10 μl of the reaction was removed and quenched with phenol and phenol–chloroform extraction was performed. The reactions were visualized on 1% agarose with ethidium bromide.
EnGen LbaCas12a (LbCas12a) was purchased from New England Biolabs (M0653S). Reactions (10 μl) containing 250 nM of LbCas12a and 500 nM of its cognate crRNA in 1× NEB 2.1 buffer were incubated at 37 °C with 200 nM of different target substrates (ssDNA, dsDNA, RNA) and 100 nM of different FAM-labelled collateral substrates (ssDNA, dsDNA, RNA). After 1 h, the reactions were quenched by phenol and phenol–chloroform extraction was performed. The results were analysed using 12% urea–PAGE and visualized for fluorescein fluorescence.
LwCas13a was purchased from MCLAB Molecular Cloning Laboratories (Cas13a-100). Reactions (10 μl) containing 250 nM of LwCas13a and 500 nM of its cognate crRNA in the provided 1× Cas9 buffer (20 mM HEPES (pH 6.5), 5 mM MgCl2, 100 mM NaCl, 100 μM EDTA) were incubated at 37 °C with 200 nM of different target substrates (ssDNA, dsDNA, RNA) and 100 nM of different FAM-labelled collateral substrates (ssDNA, dsDNA, RNA). After 1 h, the reactions were quenched by phenol and phenol–chloroform extraction was performed. The results were analysed using 12% urea–PAGE and visualized for fluorescein fluorescence.
AbCas12g was expressed in E. coli NiCo 21 DE3 using pET28a-mH6-Cas12g1 (Addgene plasmid, 120879) and initially purified as described previously25. The protein was then transferred to low-salt buffer (25 mM HEPES pH 7.8, 50 mM NH4Cl, 2 mM MgCl2, 7 mM BME, 5% glycerol) by buffer-exchange and loaded over heparin followed by elution with a linear NaCl gradient and gel-filtration as described previously62. Purified protein was flash-frozen and stored at −80 °C. The Cas12g1 non-coding plasmid pACYC-Cas12g1 (Addgene plasmid, 120880) was used as a template for PCR amplification of the AbCas12g tracrRNA sequence with Cas12gtracrRNA F and R primers (Supplementary Tables 1 and 3) in 2× Taq Master Mix (New England Biolabs). The non-coding plasmid was removed with DpnI by incubation at 37 °C for 1 h in CutSmart buffer (New England Biolabs). DNA components were cleaned after PCR and DpnI digestion using the E.Z.N.A. Cycle Pure Kit (OMEGA BioTek). The Cas12g tracrRNA was transcribed using the HighScribe T7 Quick High Yield RNA synthesis kit and cleaned using the Monarch RNA cleanup kit (New England Biolabs). Reactions (10 μl) containing 250 nM of Cas12g, 500 nM of the Cas12g crRNA and 1 μΜ of Cas12g tracrRNA in 1× NEB 3.1 buffer were incubated at 37 °C or 50 °C with 200 nM of different target substrates (ssDNA, dsDNA, RNA) and 100 nM of different FAM-labelled collateral substrates (ssDNA, dsDNA, RNA). After 1 h, the reactions were quenched by phenol and phenol–chloroform extraction was performed. The results were analysed using 12% urea–PAGE and visualized for fluorescein fluorescence.
To analyse SuCas12a2 collateral activity, 10 μl reactions containing 250 nM of Cas12a2–crRNA, 200 nM of different target substrates (ssDNA, dsDNA, ssRNA) and 100 nM of different FAM-labelled collateral substrates (ssDNA, dsDNA, RNA) in 1× NEB 3.1 buffer were incubated at 37 °C for 1 h. The reactions were quenched with phenol and phenol–chloroform extraction was performed. The results were analysed using 12% urea–PAGE and visualized for fluorescein.
Cas12a2 (100 nM) was complexed with crRNA (120 nM) in NEB 3.1 buffer (50 mM Tris-HCl pH 7.9, 100 mM NaCl, 10 mM MgCl2, 100 µg ml−1 BSA) before combining with RNase or DNase Alert (200 nM, IDT) and Target RNA to the indicated concentrations in a 384-well plate (Greiner Bio-One, 784077). A background control was prepared with nuclease-free water instead of target RNA. The reactions were monitored for reporter fluorescence (RNase Alert: excitation 485-20/emission 528-20, DNAse Alert: excitation 500-20/emission 560-20) over time at either ambient conditions (room temperature) or 37 °C using the Synergy H4 Hybrid multi-mode microplate reader (BioTek Instruments). The slope of the linear region (between 5 and 30 min) was determined at each concentration of target RNA using GraphPad PRISM. Standard error of the linear fit was used as a proxy for standard deviation, and the limit of detection was calculated as 3 × standard error of the water background as described previously46. The limit of detection was estimated by determining where the plot of V0 (relative fluorescence units (RFU)/s) versus concentration of target RNA crosses the detection threshold.
Plasmid cleavage reactions were prepared by combining 14 nM SuCas12a2 (or mutant) with 14 nM crRNA and 25 mM Target RNA in NEB 3.1 buffer (50 mM Tris-HCl pH 7.9, 100 mM NaCl, 10 mM MgCl2, 100 µg ml−1 BSA). Protein was preheated at 37 °C for 15 min before the addition of 7 nM supercoiled pUC19 plasmid. Samples were removed at the time points 1, 2, 5, 10, 20, 30, 45 and 60 min and quenched in pH 8.0 phenol–chloroform. Quenched reactions were mixed by flicking followed by centrifugation. The samples were loaded onto 1% agarose gels and visualized using ethidium bromide. Gels were imaged using the ChemiDoc MP Image System (Bio-Rad).
The plasmid pSPC421 was collected from TOP10 E. coli cells using the ZymoPURE II Plasmid Midiprep Kit by Zymo Research (D4201), and cleaned using the DNA Clean & Concentrator-5 kit from Zymo Research (D4013). ca33Cas12a2 was expressed from the plasmid pCBS5042 and purified as described above at the Rudolf Virchow Center for Integrative and Translational Bioimaging. ca33Cas12a2 nuclease (100 nM) was incubated with the crRNA (1 µM) in the NEB3.1 buffer for 30 min at room temperature. CAO1 target RNA (1 nM) and pSPC425 (3 µg) were added to the reaction medium for 15 min. For evaluating plasmid nicking, the samples were heated at 80 °C for between 1 and 30 min. The reactions were run on a 0.8% agarose gel. DNA polymerase I (NEB, M0209L) was added to the reaction (0.2 U µl−1) with the Atto421-NT labelling mix (1×) and NT labelling buffer (1×) from the Atto425 NT Labelling Kit (Jena Bioscience, PP-305S-425). The samples were incubated at 15 °C for 90 min in a Bio-Rad thermocycler. The resulting labelled DNA fragments were purified using the Microspin S-400 HR columns (Cytiva, 27514001). Fluorescence measurements (𝛌exc = 436 nm; 𝛌em = 484 nm) were performed on a fluorescence microtitre plate reader (BioTek NeoG2) at 25 °C.
The SuCas12a2 expression plasmid pCBS3568 containing the nuclease- and the crRNA-encoding sequences and the no-crRNA control pCBS3569 were transformed into E. coli BL21(AI) and the transformants were plated on selection pates. The resulting colonies were picked and used to inoculate 2 ml overnight liquid cultures. The next day, the overnight cultures were used to inoculate 25 ml of LB containing chloramphenicol to an OD600 of approximately 0.05. Once the growing cultures reached an OD600 of 0.25 after approximately 40 min, expression of the nuclease and the crRNA were induced with 1 mM IPTG and 0.2% l-arabinose. The induced cultures were collected in the stationary phase by centrifugation at 14,000 rpm at 4 °C for 2 min. The cell pellets were then immediately frozen in liquid N2 and stored at −80 °C until further processing.
Total RNA was purified from cell pellets using the Direct-zol RNA Miniprep Plus (Zymo Research, R2072) according to the manufacturer's instructions. DNA was removed using Turbo DNase (Life Technologies, AM2238). Between the individual processing steps, RNA was purified using the RNA Clean & Concentrator kit (Zymo Research, R1017). Ribosomal RNA was removed from the samples using the RiboMinus Transcriptome Isolation Kit, bacteria (Thermo Fisher Scientific, K155004). 3′-phosphoryl groups were removed from RNA using T4 polynucleotide kinase (New England Biolabs, M0201S). cDNA synthesis and library preparation was performed using the NEBNext Multiplex Small RNA Library Prep Set for Illumina (New England Biolabs, E7330S). Size selection for fragments between 200 bp and 700 bp was performed using the Select-a-Size DNA Clean & Concentrator kit (Zymo Research, D4080). Finally, DNA was purified using AMPure XP beads (Beckman Coulter, A63882) and quantified using the Qubit dsDNA HS assay kit (Thermo Fisher Scientific, Q32851) on DeNovix DS-11 FX (DeNovix).
Library sequencing was performed at the Helmholtz Center for Infectious Research (HZI) GMAK facility in Braunschweig, Germany, using the MiSeq 300 sequencing method (Illumina). The resulting paired-end reads were quality controlled, trimmed and merged using BBTools63 (https://sourceforge.net/projects/bbmap/). Next, the reads were mapped to the crRNA expression site on the plus strand of pCBS273 using Bowtie2 (http://bowtie-bio.sourceforge.net/bowtie2/). The associated raw and processed sequencing data as well the data-processing steps can be found at the NCBI Gene Expression Omnibus (GEO: GSE178531).
Standard plasmid clearance assays were performed in E. coli BL21(AI) containing nuclease- and crRNA-expressing plasmids. Bacterial cultures were grown overnight and used to inoculate fresh LB medium containing chloramphenicol to an OD600 of 0.05–0.1. Subsequently, these cultures were grown until the OD600 reached approximately 0.25, at which time 1 mM IPTG and 0.2% l-arabinose were added for induction. Once the cultures reached an OD600 of 0.6–0.8, the cells were collected and made electrocompetent64. Electrocompetent cells were prepared from four biological replicates. Immediately after, 1 µl of 50 ng μl−1 of the target and non-target plasmid were electroporated into 50 µl of the electrocompetent E. coli cells. To achieve high transformation efficiencies, the used plasmids were purified through ethanol precipitation and quantified using the Qubit dsDNA HS Assay Kit (Thermo Fisher Scientific, Q32851). The electroporated cells were recovered for 1 h at 37 °C with shaking in 500 µl LB containing 1 mM IPTG and 0.2% l-arabinose without antibiotics. Next, the cultures were sequentially diluted to 10−5 in tenfold increments. Then, 5–10 µl of each dilution was spotted onto LB plates containing antibiotics to select the nuclease-crRNA and the target/non-target plasmids. The plates also contained 0.3 mM IPTG and 0.2% l-arabinose. The plates were incubated overnight at 37 °C.
The next day, the colonies were manually counted and the resulting counts were adjusted for the dilution factor. Counts from the highest countable dilution were used to calculate transformation fold reduction as a ratio between the colonies in the non-target condition divided by the colonies in the target condition.
In a modification of the assay used to determine the cell suicide phenotype, the target and the non-target plasmids were transformed into E. coli BL21(AI) first. Next, these cells were made electrocompetent and the nuclease-crRNA plasmids were transformed in last.
When testing Acrs, the Acr plasmid (ampicillin) and the nuclease-crRNA plasmid (chloramphenicol) were co-transformed, followed by electroporation of the target or non-target plasmid (kanamycin).
To investigate the growth of the cultures under nuclease-targeting conditions, the nuclease-crRNA and the target/non-target plasmids were transformed into E. coli BL21(AI). The resulting transformants were recovered in SOC medium and grown overnight with 0.2% glucose to inhibit nuclease and crRNA expression. In the morning, the cells were collected by centrifugation at 5,000g for 2 min. The pellets were resuspended in LB and used to inoculate 200 µl of LB medium on a 96-well plate to a final OD600 of 0.01. Depending on the experiment, the reactions contained different combinations of antibiotics, IPTG and l-arabinose. The plates were incubated in the BioTek Synergy H1 plate reader at 37 °C with vigorous shaking. The OD600 of the cultures was recorded every 3 min. Plasmid clearance assays were performed with the overnight cultures, as described above.
To determine PFS preferences of SuCas12a2, a PFS depletion assay was performed. An oligo library (ODpr23) consisting of 1,024 nucleotide combinations in place of a 5-nucleotide PFS-encoding site was synthesized by Integrated DNA Technologies. Using the ODpr23 oligo pool library in a combination with primer ODpr24, targeting plasmid pCBS276 was PCR-amplified using Q5 polymerase (New England Biolabs, M0543). The PCR products were gel-purified using the Zymoclean Gel DNA Recovery Kit (Zymo Research, D4007) and ligated using the KLD reaction mix (New England Biolabs, M0554). The ligated plasmids were purified using ethanol precipitation and electroporated into E. coli TOP10. A total of ten electroporation reactions were performed. After recovery of the electroporated cells in SOC medium, the individual reactions were combined to inoculate 90 ml of LB medium containing kanamycin. A total of 10 µl from each electroporation reaction was plated on selective LB medium to estimate the total number of transformed bacteria. With the colony counts, we estimated that the total number of transformed cells exceeded the number of unique PAM sequences in the library (1,024) by approximately 2,300-fold. Plasmid library DNA was purified from the combined overnight culture using the ZymoPURE II Plasmid Midiprep Kit (Zymo Research, D4201) and additionally cleaned by ethanol precipitation. Next, the plasmid library was verified by Sanger sequencing.
The PAM plasmid library was transformed into electrocompetent E. coli BL21(AI) containing either the SuCas12a2 nuclease-expressing plasmid pCBS273 or an empty plasmid control pCBS3569. The electrocompetent cells were prepared as described above. Approximately 600 ng of the plasmid DNA was electroporated into 50 µl volume of the competent cells. The transformed bacteria were recovered in 500 µl of SOC medium for 1 h at 37 °C and were used to inoculate 50 ml LB with 1 mM IPTG and 0.2% l-arabinose in the presence of kanamycin and chloramphenicol. The cultures were grown for 13 h before the cells were collected by centrifugation at 4,000g for 15 min and the plasmid DNA extracted using ZymoPURE II Plasmid Midiprep Kit (Zymo Research, D4201). After recovery, bacteria were also plated on LB plates containing kanamycin and chloramphenicol without the inducers. These plates were used to estimate the total number of cells transformed with the plasmid library. The total number of transformed cells estimated based on the colony counts exceeded the number of unique PAM sequences in the library by approximately 1,700-fold for the cells containing the SuCas12a2–crRNA plasmid (pCBS273) compared to 11,900-fold in the no-crRNA control (pCBS3569).
The region of the plasmid DNA containing the target site including the PFS-encoding sequence was PCR-amplified using the primers ODpr55 and ODpr56. The PCR reactions were purified using AMPure XP beads (Beckman Coulter, A63882). The purified PCR products were indexed using the primers ODpr58, ODpr60, ODpr59 and ODpr61. The indexed PCR products were purified using the AMPure XP beads, quantified using the Qubit assay (Thermo Fisher Scientific, Q32851) and sent for sequencing at the HZI GMAK facility using the MiSeq PE300 Illumina sequencing method.
Analysis of the PFS-encoding sequence depletion data as well as the creation of the PFS wheels were performed as described previously65. PFS consensus motifs were defined manually. The raw and the processed sequencing data as well as the data-processing steps can be found at the NCBI GEO (GSE178530). Individual PFS sequences were validated using plasmid-clearance assays as described above.
For in vitro assays to test Acr sensitivity of Cas12a nucleases, plasmids encoding Cas12a nuclease were pre-expressed together with a plasmid encoding either a target or non-target crRNA in 9 µl of MyTXTL master mix (Arbor Biosciences) at a final concentration of 4 nM for each plasmid in a total volume of 12 µl. Acrs were pre-expressed separately, at a concentration of 4 nM in a total volume of 12 µl. As the Acrs are encoded on linear DNA fragments, GamS at a final concentration of 2 µM was added to prevent DNA degradation. All pre-expressions were performed at 29 °C for 16 h. The subsequent cleavage assay was performed by adding 1 µl of each pre-expression reaction to 9 µl of fresh myTXTL mix. pCBS420 plasmid constitutively expressing deGFP protein was used as a reporter at a final concentration of 1 nM. For quantification, four 3 µl replicates per reaction were transferred onto a 96-well V-bottom plate (Corning Costar 3357). The reactions were prepared using the Echo 525 Liquid Handler (Beckman Coulter). Fluorescence was measured on the BioTek Synergy H1 plate reader (excitation, 485/20; emission, 528/20). Time-course measurements were run for 16 h at 29 °C, with 3 min intervals between the measurements.
All fold-repression values for plasmid reporter constructs represent the ratio of deGFP concentrations after 16 h of reaction for the non-target over the target crRNA. For the experiments measuring the inhibitory activity of Acrs, inhibition was calculated from end-point expression values after 16 h of expression according to the following formula66: percentage inhibition of nuclease activity = 100 × (RFUt,Acr/RFUnt,Acr − RFUt,-/RFUnt,-)/(1 − RFUt,-/RFUnt,-), where the inhibition of nuclease activity (%) is defined by the ratio of fluorescence between GFP targeting (t) and non-targeting (nt) Cas nucleases in the presence (Acr) and absence (-) of Acrs.
To measure the RecA-dependent SOS response, the nuclease-crRNA, the target/non-target plasmids (pCBS276/pCBS3578, kanamycin) and the reporter PrecA-gfp/no-gfp (pCBS3611/pCBS3616, ampicillin) plasmids were transformed into E. coli BL21(AI) sequentially. The plasmids pCBS273 and pCBS3588 (chloramphenicol) were used to express SuCas12a2 and LbCas12a nucleases, respectively. When measuring the RecA-dependent SOS response in the presence of LsCas13a, the nuclease expression plasmid pCBS361 (chloramphenicol) was used. The target/non-target plasmids pCBS2004/pCBS612 (ampicillin) and PrecA-gfp/no-gfp plasmids pCBS2000/pCBS2002 (kanamycin) were used. First, the cells were grown in LB medium with 0.2% glucose to inhibit the expression of the nucleases and the crRNA. The bacteria were collected from the overnight cultures (15 ml) by centrifugation at 5,000g for 2 min and resuspended in fresh LB. Next, 200 µl of fresh LB medium was inoculated onto 96-well plates with the resuspended bacteria from the overnight cultures. These cultures were grown in the presence of either chloramphenicol, kanamycin and ampicillin, chloramphenicol and ampicillin, or no antibiotics. For the induction of nuclease and crRNA expression 1 mM of IPTG and 0.2% l-arabinose were added.
The cultures were grown at 37 °C with vigorous shaking. OD600 and fluorescence measurements (excitation: 485/20, emission: 528/20) were collected every 5 min on the BioTek Synergy H1 plate reader. Four biological replicates were measured per experimental condition.
To determine whether a change in fluorescence occurred as a result of nuclease targeting, first the background fluorescence collected for the cultures with the PrecA-no-gfp plasmid (pCBS3616/pCBS2002) was subtracted from the values obtained for the cultures with the GFP-expressing plasmids for each time point (pCBS3611/pCBS2000). Next, the fluorescence values were divided by the OD600 values from the corresponding target and the non-target cultures. Statistical significance was determined using Welch's t-test with unequal variance.
In parallel we performed a plasmid-clearance assay with the washed overnight cultures (Supplementary Fig. 9b), as described above. For the lowest plated dilution, cultures at an OD600 of around 0.1 were used.
For the flow cytometry measurements, E. coli BL21(AI) cells were sequentially electroporated with the nuclease-encoding and target/non-target plasmids. The SuCas12a2- and LbCas12a-expressing plasmids pCBS273 and pCBS3588 were used, respectively. Target plasmid pCBS273 and non-target plasmid pCBS3578 were used. For the experiments involving LsCas13a, nuclease-expression plasmid pCBS361 was used in combination with the target plasmid pCBS2004 and non-target plasmid pCBS612. After plasmid transformation, the E. coli bacteria were recovered in SOC medium and grown overnight in LB with chloramphenicol, kanamycin and 0.2% glucose. Next, the cells were collected at 5,000g for 2 min and resuspended in fresh LB. The resuspended bacteria were used to inoculate 15 ml cultures to an OD600 of about 0.01. These cultures were grown at 37 °C with 220 rpm shaking for 6 h without antibiotics with 1 mM IPTG and 0.2% l-arabinose. Every 2 h the OD600 of the cultures was measured and 500 µl samples were collected and centrifuged for 3 min at 5,000g. The cell pellets were then resuspended in 1× PBS containing 2 µg ml−1 DAPI (Thermo Fisher Scientific, 62248). The resuspended cells were stained for 10 min in the dark, after which 10 µl was transferred into 240 µl of 1× PBS on a 96-well plate. DAPI fluorescence was measured using the Cytoflow Novocyte Quanteon flow cytometer as emission in the Pacific Blue spectrum (455 nm). Data regarding the forward scatter (FSC) and the side scatter were also collected.
The resulting data were analysed in Python. First, clusters of bacteria exhibiting distinct FSC and Pacific Blue signals were identified using density-based spatial clustering of applications with noise (DBSCAN; https://scikit-learn.org/stable/modules/generated/sklearn.cluster.DBSCAN.html). Next, the ratios of the Pacific Blue to the FSC signal for each data point and the percentage of the data points within each cluster were parsed from the clustering data. The resulting values were plotted in the form of balloon plots. A total of 60,000 events per sample were analysed.
Dead and viable bacteria were estimated using the LIVE/DEAD BacLight Bacterial Viability and Counting Kit (Molecular Probes, L34856). The measurements were performed using the Cytoflow Novocyte Quanteon flow cytometer. E. coli BL21(AI) bacteria were transformed with nuclease, crRNA, and either target or non-target expression plasmids. For expressing SuCas12a2 and LbCas12a with a target guide, the plasmids pCBS273 and pCBS3588 were used, respectively. Target expression plasmid pCBS2004 and non-target expression plasmid pCBS612 were used. For expressing LsCas13a with target and non-target guides, plasmids pCBS273 and pCBS3578 were used, respectively. Cultures containing combinations of nuclease–guide and target plasmids were grown for approximately 16 h with 0.2% glucose inhibitor in four biological replicates. Next, 1 ml of each culture was collected by centrifugation at 5,000g for 3 min. The resulting pellet was resuspended in 1 ml of fresh LB medium. A total of 60 µl of this suspension was used to inoculate 20 ml of LB. Three cultures were grown for 2 h at 37 °C with constant shaking at 220 rpm. The expression of the nucleases and the guides was induced with 0.2% arabinose and 0.01 mM IPTG. After 4 h, the OD600 of the cultures was measured. A volume of the cultures corresponding to an OD600 of 1.0 was collected and processed as described in the kit manual. In brief, samples of the bacterial culture were centrifuged at 10,000g for 3 min to pellet the cells. The supernatant was removed and the pellet was resuspended in 1 ml of 0.85% NaCl. As a control for the dead cells, spectate pellet was first resuspended in 300 μl 0.85% NaCl and then 700 μl 70% isopropyl alcohol (dead-cell suspension). The samples were incubated at room temperature for 60 min, with mixing every 15 min. Next, the samples were centrifuged at 10,000g for 3 min and washed in 1 ml 0.85% NaCl, followed by another centrifugation. Finally, the samples were resuspended in 0.5 ml of 0.85% NaCl. One millilitre of the master mix for staining the cells contained 977 µl of 0.85% NaCl, 1.5 µl of component A (3.34 mM SYTO 9 nucleic acid stain), 1.5 µl of component B (30 mM propidium iodide (PI)), 10 µl of component C (beads) and 10 µl of the sample. These reactions were incubated for 15 min at room temperature protected from light. Fluorescence was collected in the green (fluorescein for SYTO 9) and red (Texas Red for PI) channels. The dead cells in each sample were gated on the basis of the dead-cell suspension control treated with isopropyl alcohol. The percentage of dead cells stained with PI was calculated from the total number of events without the beads. A total of 50,000 events were counted per sample.
Samples corresponding to 1 ml of culture at an OD600 of 0.4 grown for dead/live staining, as described above, were collected and centrifuged at 10,000g for 3 min. The resulting pellets were frozen in liquid nitrogen and stored −80 °C until further processing. Total RNA was extracted using 1.5 ml of Trizol and 1.5 ml of ethanol with the Direct-zol RNA Miniprep kit (R2051, Zymo), according to the manufacturer's instructions. The RNA was further purified using the RNA Clean & Concentrator-5 kit (R1013, Zymo). A total of 0.5 µg of RNA from each sample in 5 µl was combined with 2.5 µl of RNA loading dye, heated to 70 °C for 10 min and subsequently chilled on ice for 2 min. The RNA High-Range ladder that was used was also heat-treated. The denatured samples (5 µl) and the leader (3 µl) were loaded onto a 1% TBE gel. The gel was run for 40 min at 120 V. Next, the gel was stained for 30 min in ethidium bromide, washed for 10 ml and imaged. Gel images were analysed using GelAnalyzer v.19.1 (www.gelanalyzer.com).
For confocal microscopy, the cells were grown as described above for flow cytometry. At 2 h intervals, 500 µl of each culture was collected and centrifuged at 5,000g for 3 min. Next, the bacteria were diluted to approximately the same cell density and stained with 2 µg ml−1 of FM4-64 dye (Thermo Fisher Scientific, T13320) and 1 µg ml−1 of DAPI (Thermo Fisher Scientific, 62248). Imagining was performed on the Leica DMi6000B TCS-SP5 II Inverted Confocal Microscope at ×1,000 magnification.
Further information on research design is available in the Nature Portfolio Reporting Summary linked to this article.
The NGS data from the PAM depletion assay and crRNA sequencing data were deposited at the NCBI GEO under accession code GSE178536. All other data supporting the findings in the Article and the Supplementary Information are available from the corresponding authors on reasonable request.
Lopatina, A., Tal, N. & Sorek, R. Abortive infection: bacterial suicide as an antiviral immune strategy. Annu. Rev. Virol. 7, 371–384 (2020).
Article CAS Google Scholar
Koonin, E. V. & Krupovic, M. Origin of programmed cell death from antiviral defense? Proc. Natl Acad. Sci. USA 116, 16167–16169 (2019).
Article ADS CAS Google Scholar
Meeske, A. J., Nakandakari-Higa, S. & Marraffini, L. A. Cas13-induced cellular dormancy prevents the rise of CRISPR-resistant bacteriophage. Nature 570, 241–245 (2019).
Article ADS CAS Google Scholar
Rostøl, J. T. & Marraffini, L. A. Non-specific degradation of transcripts promotes plasmid clearance during type III-A CRISPR–Cas immunity. Nat. Microbiol. 4, 656–662 (2019).
Article Google Scholar
Rostøl, J. T. et al. The Card1 nuclease provides defence during type III CRISPR immunity. Nature 590, 624–629 (2021).
Article ADS Google Scholar
VanderWal, A. R., Park, J.-U., Polevoda, B., Kellogg, E. H. & O’Connell, M. R. CRISPR-Csx28 forms a Cas13b-activated membrane pore required for robust CRISPR-Cas adaptive immunity. Preprint at bioRxiv https://doi.org/10.1101/2021.11.02.466367 (2021).
Gootenberg, J. S. et al. Nucleic acid detection with CRISPR-Cas13a/C2c2. Science 356, 438–442 (2017).
Article ADS CAS Google Scholar
Abudayyeh, O. O. et al. C2c2 is a single-component programmable RNA-guided RNA-targeting CRISPR effector. Science 353, aaf5573 (2016).
Article Google Scholar
Kazlauskiene, M., Kostiuk, G., Venclovas, Č., Tamulaitis, G. & Siksnys, V. A cyclic oligonucleotide signaling pathway in type III CRISPR-Cas systems. Science 357, 605–609 (2017).
Article ADS CAS Google Scholar
Niewoehner, O. et al. Type III CRISPR–Cas systems produce cyclic oligoadenylate second messengers. Nature 548, 543–548 (2017).
Article ADS CAS Google Scholar
Makarova, K. S., Anantharaman, V., Grishin, N. V., Koonin, E. V. & Aravind, L. CARF and WYL domains: ligand-binding regulators of prokaryotic defense systems. Front. Genet. 5, 102 (2014).
Article Google Scholar
Lau, R. K. et al. Structure and mechanism of a cyclic trinucleotide-activated bacterial endonuclease mediating bacteriophage immunity. Mol. Cell 77, 723–733 (2020).
Article CAS Google Scholar
Grüschow, S., Adamson, C. S. & White, M. F. Specificity and sensitivity of an RNA targeting type III CRISPR complex coupled with a NucC endonuclease effector. Nucleic Acids Res. 49, 13122–13134 (2021).
Article Google Scholar
Chen, J. S. et al. CRISPR-Cas12a target binding unleashes indiscriminate single-stranded DNase activity. Science 360, 436–439 (2018).
Article ADS CAS Google Scholar
Marino, N. D., Pinilla-Redondo, R. & Bondy-Denomy, J. CRISPR-Cas12a targeting of ssDNA plays no detectable role in immunity. Nucleic Acids Res. 50, 6414–6422 (2022).
Article CAS Google Scholar
Zetsche, B. et al. Cpf1 is a single RNA-guided endonuclease of a class 2 CRISPR-Cas system. Cell 163, 759–771 (2015).
Article CAS Google Scholar
Jinek, M. et al. A programmable dual-RNA–guided DNA endonuclease in adaptive bacterial immunity. Science 337, 816–821 (2012).
Article ADS CAS Google Scholar
Makarova, K. S., Wolf, Y. I. & Koonin, E. V. Classification and nomenclature of CRISPR-Cas systems: where from here? CRISPR J. 1, 325–336 (2018).
Article Google Scholar
Bravo, J. P. K. et al. RNA targeting unleashes indiscriminate nuclease activity of CRISPR–Cas12a2. Nature https://doi.org/10.1038/s41586-022-05560-w (2022).
Fonfara, I., Richter, H., Bratovič, M., Le Rhun, A. & Charpentier, E. The CRISPR-associated DNA-cleaving enzyme Cpf1 also processes precursor CRISPR RNA. Nature 532, 517–521 (2016).
Article ADS CAS Google Scholar
Deltcheva, E. et al. CRISPR RNA maturation by trans-encoded small RNA and host factor RNase III. Nature 471, 602–607 (2011).
Article ADS CAS Google Scholar
Swarts, D. C., van der Oost, J. & Jinek, M. Structural basis for guide RNA processing and seed-dependent DNA targeting by CRISPR-Cas12a. Mol. Cell 66, 221–233 (2017).
Article CAS Google Scholar
East-Seletsky, A. et al. Two distinct RNase activities of CRISPR-C2c2 enable guide-RNA processing and RNA detection. Nature 538, 270–273 (2016).
Article ADS CAS Google Scholar
Marshall, R. et al. Rapid and scalable characterization of CRISPR technologies using an E. coli cell-free transcription-translation system. Mol. Cell 69, 146–157 (2018).
Article CAS Google Scholar
Yan, W. X. et al. Functionally diverse type V CRISPR-Cas systems. Science 363, 88–91 (2019).
Article ADS CAS Google Scholar
Murugan, K., Seetharam, A. S., Severin, A. J. & Sashital, D. G. CRISPR-Cas12a has widespread off-target and dsDNA-nicking effects. J. Biol. Chem. 295, 5538–5553 (2020).
Article CAS Google Scholar
Collias, D. & Beisel, C. L. CRISPR technologies and the search for the PAM-free nuclease. Nat. Commun. 12, 555 (2021).
Article ADS CAS Google Scholar
Elmore, J. R. et al. Bipartite recognition of target RNAs activates DNA cleavage by the Type III-B CRISPR-Cas system. Genes Dev. 30, 447–459 (2016).
Article CAS Google Scholar
Kazlauskiene, M., Tamulaitis, G., Kostiuk, G., Venclovas, Č. & Siksnys, V. Spatiotemporal control of type III-A CRISPR-Cas immunity: coupling DNA degradation with the target RNA recognition. Mol. Cell 62, 295–306 (2016).
Article CAS Google Scholar
Liu, T. Y., Iavarone, A. T. & Doudna, J. A. RNA and DNA targeting by a reconstituted Thermus thermophilus type III-A CRISPR-Cas system. PLoS ONE 12, e0170552 (2017).
Article Google Scholar
Han, W. et al. A type III-B CRISPR-Cas effector complex mediating massive target DNA destruction. Nucleic Acids Res. 45, 1983–1993 (2017).
CAS Google Scholar
Wang, B. et al. Structural basis for self-cleavage prevention by tag:anti-tag pairing complementarity in type VI Cas13 CRISPR systems. Mol. Cell 81, 1100–1115 (2021).
Article CAS Google Scholar
Marraffini, L. A. & Sontheimer, E. J. Self versus non-self discrimination during CRISPR RNA-directed immunity. Nature 463, 568–571 (2010).
Article ADS CAS Google Scholar
Wiedenheft, B. et al. RNA-guided complex from a bacterial immune system enhances target recognition through seed sequence interactions. Proc. Natl Acad. Sci. USA 108, 10092–10097 (2011).
Article ADS CAS Google Scholar
Semenova, E. et al. Interference by clustered regularly interspaced short palindromic repeat (CRISPR) RNA is governed by a seed sequence. Proc. Natl Acad. Sci. USA 108, 10098–10103 (2011).
Article ADS CAS Google Scholar
Watters, K. E., Fellmann, C., Bai, H. B., Ren, S. M. & Doudna, J. A. Systematic discovery of natural CRISPR-Cas12a inhibitors. Science 362, 236–239 (2018).
Article ADS CAS Google Scholar
Knott, G. J. et al. Broad-spectrum enzymatic inhibition of CRISPR-Cas12a. Nat. Struct. Mol. Biol. 26, 315–321 (2019).
Article CAS Google Scholar
Marino, N. D. et al. Discovery of widespread type I and type V CRISPR-Cas inhibitors. Science 362, 240–242 (2018).
Article ADS CAS Google Scholar
Dong, L. et al. An anti-CRISPR protein disables type V Cas12a by acetylation. Nat. Struct. Mol. Biol. 26, 308–314 (2019).
Article CAS Google Scholar
Little, J. W. & Mount, D. W. The SOS regulatory system of Escherichia coli. Cell 29, 11–22 (1982).
Article CAS Google Scholar
Janion, C. Some aspects of the SOS response system-a critical survey. Acta Biochim. Pol. 48, 599–610 (2001).
Article CAS Google Scholar
Chen, Z., Lu, M., Zou, D. & Wang, H. An E. coli SOS-EGFP biosensor for fast and sensitive detection of DNA damaging agents. J. Environ. Sci. 24, 541–549 (2012).
Article CAS Google Scholar
Vercoe, R. B. et al. Cytotoxic chromosomal targeting by CRISPR/Cas systems can reshape bacterial genomes and expel or remodel pathogenicity islands. PLoS Genet. 9, e1003454 (2013).
Article CAS Google Scholar
Cui, L. & Bikard, D. Consequences of Cas9 cleavage in the chromosome of Escherichia coli. Nucleic Acids Res. 44, 4243–4251 (2016).
Article CAS Google Scholar
Caliando, B. J. & Voigt, C. A. Targeted DNA degradation using a CRISPR device stably carried in the host genome. Nat. Commun. 6, 6989 (2015).
Article ADS CAS Google Scholar
Huyke, D. A. et al. Enzyme kinetics and detector sensitivity determine limits of detection of amplification-free CRISPR-Cas12 and CRISPR-Cas13 diagnostics. Anal. Chem. 94, 9826–9834 (2022).
Article CAS Google Scholar
Rigby, P. W., Dieckmann, M., Rhodes, C. & Berg, P. Labeling deoxyribonucleic acid to high specific activity in vitro by nick translation with DNA polymerase I. J. Mol. Biol. 113, 237–251 (1977).
Article CAS Google Scholar
Nemudraia, A. et al. Sequence-specific capture and concentration of viral RNA by type III CRISPR system enhances diagnostic. Preprint at Research Square https://doi.org/10.21203/rs.3.rs-1466718/v1 (2022).
Leenay, R. T. & Beisel, C. L. Deciphering, communicating, and engineering the CRISPR PAM. J. Mol. Biol. 429, 177–191 (2017).
Article CAS Google Scholar
Silas, S. et al. Type III CRISPR-Cas systems can provide redundancy to counteract viral escape from type I systems. eLife 6, e27601 (2017).
Article Google Scholar
Estrella, M. A., Kuo, F.-T. & Bailey, S. RNA-activated DNA cleavage by the type III-B CRISPR-Cas effector complex. Genes Dev. 30, 460–470 (2016).
Article CAS Google Scholar
Liu, L. et al. The molecular architecture for RNA-guided RNA cleavage by Cas13a. Cell 170, 714–726 (2017).
Article CAS Google Scholar
Katoh, K. & Standley, D. M. MAFFT multiple sequence alignment software version 7: improvements in performance and usability. Mol. Biol. Evol. 30, 772–780 (2013).
Article CAS Google Scholar
Steenwyk, J. L., Buida, T. J. 3rd, Li, Y., Shen, X.-X. & Rokas, A. ClipKIT: a multiple sequence alignment trimming software for accurate phylogenomic inference. PLoS Biol. 18, e3001007 (2020).
Article CAS Google Scholar
Kozlov, A. M., Darriba, D., Flouri, T., Morel, B. & Stamatakis, A. RAxML-NG: a fast, scalable and user-friendly tool for maximum likelihood phylogenetic inference. Bioinformatics 35, 4453–4455 (2019).
Article CAS Google Scholar
Kelley, L. A., Mezulis, S., Yates, C. M., Wass, M. N. & Sternberg, M. J. E. The Phyre2 web portal for protein modeling, prediction and analysis. Nat. Protoc. 10, 845–858 (2015).
Article CAS Google Scholar
Söding, J., Biegert, A. & Lupas, A. N. The HHpred interactive server for protein homology detection and structure prediction. Nucleic Acids Res. 33, W244–W248 (2005).
Article Google Scholar
Guzman, L. M., Belin, D., Carson, M. J. & Beckwith, J. Tight regulation, modulation, and high-level expression by vectors containing the arabinose PBAD promoter. J. Bacteriol. 177, 4121–4130 (1995).
Article CAS Google Scholar
Studier, F. W. Protein production by auto-induction in high density shaking cultures. Protein Expr. Purif. 41, 207–234 (2005).
Article CAS Google Scholar
Lapinaite, A. et al. DNA capture by a CRISPR-Cas9-guided adenine base editor. Science 369, 566–571 (2020).
Article ADS CAS Google Scholar
Harris, C. J., Molnar, A., Müller, S. Y. & Baulcombe, D. C. FDF-PAGE: a powerful technique revealing previously undetected small RNAs sequestered by complementary transcripts. Nucleic Acids Res. 43, 7590–7599 (2015).
Article CAS Google Scholar
Li, Z., Zhang, H., Xiao, R., Han, R. & Chang, L. Cryo-EM structure of the RNA-guided ribonuclease Cas12g. Nat. Chem. Biol. 17, 387–393 (2021).
Article CAS Google Scholar
Bushnell, B., Rood, J. & Singer, E. BBMerge—accurate paired shotgun read merging via overlap. PLoS ONE 12, e0185056 (2017).
Article Google Scholar
Green, M. R. & Sambrook, J. Molecular Cloning: A Laboratory Manual (Cold Spring Harbor Laboratory Press, 2012).
Leenay, R. T. et al. Identifying and visualizing functional PAM diversity across CRISPR-Cas systems. Mol. Cell 62, 137–147 (2016).
Article CAS Google Scholar
Wandera, K. G. et al. An enhanced assay to characterize anti-CRISPR proteins using a cell-free transcription-translation system. Methods 172, 42–50 (2020).
Article CAS Google Scholar
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We thank K. Makarova for guidance on naming Cas12a2 and for feedback on phylogenetic analyses; L. Fläxl for assistance with transcription–translation; L. Ostertag for assistance with nick translation; F. Ttofali for assistance with plasmid cloning and testing; D. Collias for suggestions around nicking translation; and A. Pawluk and A. Özcan for feedback on the manuscript. The plasmids pET28a-mH6-Cas12g1 (Addgene plasmid, 120879) and pACYC-Cas12g1 (Addgene plasmid, 120880) were gifts from Arbor Biosciences. Plasmid pC001 was a gift from F. Zhang (Addgene plasmid, 79150). This work was supported by an ERC Consolidator grant (865973 to C.L.B.), the DARPA Safe Genes program (HR0011-17-2-0042 to C.L.B.), the National Institutes of Health (R35GM138080 to R.N.J.), the Netherlands Organization for Scientific Research (NWO) through a Rubicon Grant (project 019.193EN.032, to I.M.), and the Federal Agency for Disruptive Innovation (to C.L.B.). The views, opinions and/or findings expressed should not be interpreted as representing the official views or policies of the Department of Defense or the US Government.
Open access funding provided by Helmholtz-Zentrum für Infektionsforschung GmbH (HZI).
Benjamin N. Gray
Present address: Syngenta, Research Triangle Park, NC, USA
Helmholtz Institute for RNA-based Infection Research, Helmholtz Centre for Infection Research, Würzburg, Germany
Oleg Dmytrenko, Elena Vialetto, Ioannis Mougiakos, Katharina G. Wandera, Johannes Weber, Thomas Gaudin & Chase L. Beisel
Benson Hill, St Louis, MO, USA
Gina C. Neumann, Benjamin N. Gray & Matthew B. Begemann
Department of Chemistry and Biochemistry, Utah State University, Logan, UT, USA
Thomson Hallmark, Dylan J. Keiser, Valerie M. Crowley, Hannah Domgaard, Josie Metcalf & Ryan N. Jackson
Medical Faculty, University of Würzburg, Würzburg, Germany
Chase L. Beisel
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Conceptualization: O.D., G.C.N., R.N.J. and C.L.B. Methodology: O.D., G.C.N., V.M.C., J.M., H.D., T.H. and D.J.K. Bioinformatic discovery of Cas12a2 orthologues: B.N.G. and O.D. First observation of bacterial abortive infection: G.C.N. Phylogenetic analysis: O.D. Discovery of RNA targeting: O.D., D.J.K., R.N.J. and C.L.B. Experimentation in E. coli: O.D., G.C.N., V.M.C., E.V., I.M. and J.W. Experimentation in transcription–translation: K.G.W., J.W. and O.D. Experimentation in vitro: V.M.C., D.J.K., H.D, T.H. and J.M. Nick-translation diagnostic: T.G. Writing—original draft: O.D., V.M.C., R.N.J. and C.L.B. Writing—review and editing: all of the authors. Visualization: O.D., D.J.K., T.H., H.D., R.N.J. and C.L.B. Supervision: M.B.B., R.N.J. and C.L.B. Funding acquisition: R.N.J. and C.L.B.
Correspondence to Matthew B. Begemann, Ryan N. Jackson or Chase L. Beisel.
Benson Hill has one granted patent (US 9,896,696) and has filed additional patent applications. G.C.N. and M.B.B. are employees of Benson Hill. O.D., R.N.J. and C.L.B. have filed provisional patent applications on the related concepts, with one granted patent (US 9,896,696). C.L.B. is a co-founder of Locus Biosciences and is a scientific advisory board member of Benson Hill. The other authors declare no competing interests.
Nature thanks Raymond Staals and the other, anonymous, reviewer(s) for their contribution to the peer review of this work. Peer reviewer reports are available.
Publisher's note Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
The phylogenetic tree generated using amino acid sequences is the annotated version of Fig. 1a. The shaded regions designate Cas12a2 (red), Cas12a (blue), and Cas12b (grey) orthologues. The blue and red filled circles indicate systems that contain both Cas12a2 and Cas12a. Transfer bootstrap expectation (TBE) values are shown at the nodes.
a, Different guide:target pairs tested under antibiotic selection of the nuclease and target plasmids or only the nuclease plasmid. b, Reduction in plasmid transformation by Cas12a2 orthologues tested under antibiotic selection of the nuclease and target plasmids. c, Effect of swapping direct repeats associated with SuCas12a2 and Cas12a nucleases on plasmid transformation. The indicated nuclease, repeat-encoding crRNA, and target were subjected to the traditional (left) and modified (right) plasmid interference assay in E. coli. d, Diagram of the target and non-target plasmids used in the plasmid clearance assay shown in e. e, Impact of a promoter and a terminator upstream of the target site on plasmid clearance by SuCas12s2 and LbCas12a. f, Diagram of the cell-free TXTL reactions used to evaluate the impact of target expression on Cas12a2 collateral silencing shown in g. g, The effect of collateral silencing by SuCas12a2 in TXTL as a function of having a promoter, no promoter, or terminator upstream of the target expression site. Scatter plots represent averages of 4 technical replicates ± s.d. Unless stated otherwise, values are means ± s.d. of at least 3 independent experiments started from separate colonies. ns: p > 0.05, *: p < 0.05, **: p < 0.005 calculated with one-tailed Welch's t-test.
a, Diagram of the predicted secondary structure of the SuCas12a2 direct repeat. Cleavage sites of SuCas12a2 and Cas12a are indicated. b, Sequencing coverage of the cDNA mapped to the crRNA locus in E. coli BL21(AI) expressing SuCas12a2. Coverage for all of the quality-filtered reads above 10 nts as well as reads between 10 and 55 nts mapped to the plus strand are shown. c, In vitro processing of a 56-nt pre-crRNA incubated for 60 min in the presence of apo-SuCas12a2 or two mutants predicted to disrupt crRNA processing. d, In vitro SuCas12a2-mediated cleavage of a pre-crRNA containing three direct repeats and three spacers (3× crRNA). Reactions containing apo-SuCas12a2 are indicated. Time points after mixing the cleavage reaction with apo-SuCas12a2 are indicated. The estimated sizes of the pre-crRNA and crRNAs after cleavage are indicated on the left. The last two lanes contain RNA extracted from SuCas12a2 co-expressed with a CRISPR array. The difference in size between the major crRNA band in the in vitro assay (~ 67 nt) and the crRNA extracted from SuCas12a2 bound to E. coli-expressed crRNA (~42) may be due to further trimming by 3′ exonucleases in the cell. For gel source data, see Supplementary Fig. 1.
a, Non-specific collateral activities of SuCas12a2, LbCas12a, LwaCas13a, and AbCas12g towards FAM-labelled non-target ssDNA, dsDNA, and RNA in the presence of target ssDNA, dsDNA, and RNA. All cleavage reactions were conducted at 37 °C unless specified otherwise. AbCas12g was triggered by RNA and ssDNA and exhibited preferential collateral cleavage of RNA over ssDNA but no discernable cleavage of dsDNA. b, SuCas12a2-mediated cleavage over time of FAM-labelled RNA (top), ssDNA (middle), and dsDNA (bottom) non-target substrates. These substrates are cleaved by SuCas12a2 through its non-specific collateral activity. c, Electromobility shift assay indicating SuCas12a2 and LbCas13a mostly do not indiscriminately degrade dsRNA. Uncleaved substrates and cleaved products are indicated. d, Impact of mutating conserved cysteines within the predicted Zinc finger domain of SuCas12a2 on RNA-triggered collateral activity. The mutated cysteines within SuCas12a2 are C1170S, C1173S, C1188S and C1191S. e, Electromobility shift assays of supercoiled pUC19 plasmid with SuCas12a2:crRNA and different RNA sequences over time. RNA sequences include: Non-self target (complementary to gRNA with 3′ GAAAG PFS), Target complement (complement of non-self target), Non-target (RNA sequence used in trans-cleavage assays), No PFS (RNA that only contains compliment to gRNA no 3′ PFS), Self-PFS (complementary to gRNA with 3′ AUCUA PFS). RNA sequences can be found in Supplementary Table 1. SuCas12a2(E1063A) with the non-self target is included as a negative control. NN: no-nuclease control. For gel source data, see Supplementary Fig. 1.
a, Sequencing coverage of the PFS libraries from the target and the control E. coli cultures. Data from two biological replicates are shown. b, Correlation between the depletion scores obtained from the two replicate libraries. c, The complex PFS profile recognized by SuCas12a2. See ref. 65 for more information on interpreting PAM wheels. Given the complexity of the PFS profile, four different PAM wheels are shown based on each nucleotide at the −1 PFS position. d, Validation of selected PFS sequences identified in the PFS screen with SuCas12a2 using the plasmid clearance assay. Values are means ± s.d. of ≥ 3 independent experiments started from separate colonies. ns: p > 0.05, *: p < 0.05, **: p < 0.005 calculated with one-tailed Welch's t-test.
a, Impact of guide length on plasmid clearance. The guide sequence is depicted with blue letters. The standard crRNA guide length based on crRNA processing (Extended Data Fig. 3) is 24 nts. b, Reduction in plasmid transformation by SuCas12a2 and LbCas12a in the presence of a shared PAM/PFS, Cas12a2-specific PFS, and mismatches to the target under target plasmid and nuclease plasmid or nuclease plasmid-only selection. Values are means ± s.d. of at least 3 independent experiments started from separate colonies. ns: p > 0.05, *: p < 0.05, **: p < 0.005 calculated with one-tailed Welch's t-test.
a, 1% agarose gel resolving total RNA extracted from E. coli BL21(AI) expressing SuCas12a2, LbCas12a and LsCas13a under target (T) and non-target (NT) conditions. Expression of the nucleases and crRNA was induced with 10 nM IPTG and 0.2% arabinose for 2 h. Individual wells for each condition represent biological replicates. Nucleotide sizes are based on a resolved RNA ladder. sRNA pool: RNA pool comprising tRNAs and other small RNAs. b, Quantification of band intensities across the 4 independent experimental replicates started from separate colonies. Significance was calculated using two-tailed Welch's t-test (ns: p > 0.05, *: p < 0.05, **: p < 0.005).
The cultures were collected 4 h after inoculation and induction of nuclease and crRNA. Prior to the analysis, the cells were stained with DAPI. The subpopulation with low DAPI and high forward scatter reflects elongated cells with reduced DNA content. Contour plots are representative of 4 independent experiments.
Extensive filamentation can be observed with the bacteria containing the target-expression plasmid and expressing SuCas12a2 and target crRNA 2 h and 4 h after induction. Within each overlaid image, fluorescent DNA (DAPI) staining is shown in blue and membrane (FM4–64) staining is shown in red. Paired images are representative of 2 independent experiments.
a, Progress curve for target RNA-activated cleavage of RNA beacon by SuCas12a2 at 37 °C. b, Limit of detection of SuCas12a2 using an RNA beacon as determined using the velocity method46. Velocities were obtained by regression analysis of the linear regions of the progress curves. The velocity method was used to determine all reported limits of detection. c, Progress curve for target RNA-activated cleavage of ssDNA beacon by Cas12a2 at ambient temperature (RT). Error bars in a and c represent the mean and standard deviation of three independent measurements. Error bars in b represent the standard error for the linear fit of three independent measurements. d, Overview of detection assay based on plasmid nicking and nick translation. e, Resolved plasmid substrate incubated with the ca33Cas12a2-gRNA RNP (100 nM) and the indicated RNA (1 nM). The incubation time before initiating nick translation is indicated for each experimental condition. The first lane (Plasmid only) represents the plasmid incubated without an RNP. Non-target RNA1: COA1 gRNA and SARS-CoV-2 RNA. Non-target-RNA2: SARS-CoV-2 gRNA and COA1 RNA. f, Fluorescence measurements following nick translation with the different reactions from e. Fluorescence values were normalized to that of the plasmid-only control. For the positive control, the plasmid was subjected to a mix of DNase I and DNA polymerase I. Values are means ± s.d. of 3 independent experiments. Significance was calculated using two-tailed Welch's t-test compared to a value of 1 (ns: p > 0.05, *: p < 0.05, **: p < 0.005). For gel source data, see Supplementary Fig. 1.
Gel source data.
Supplementary Figs. 2–9 and the legend for Supplementary Fig. 1.
Supplementary Tables 1–5.
Fasta file listing Cas12a2, Cas12a and Cas12b amino acid sequences.
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Dmytrenko, O., Neumann, G.C., Hallmark, T. et al. Cas12a2 elicits abortive infection through RNA-triggered destruction of dsDNA. Nature 613, 588–594 (2023). https://doi.org/10.1038/s41586-022-05559-3
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Received: 13 June 2022
Accepted: 11 November 2022
Published: 04 January 2023
Issue Date: 19 January 2023
DOI: https://doi.org/10.1038/s41586-022-05559-3
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