Here, we present a method to engineer the genome of C. elegans using CRISPR-Cas9 ribonucleoproteins and homology dependent repair templates.
The clustered regularly interspersed palindromic repeats (CRISPR)-CRISPR-associated protein 9 (Cas9) prokaryotic adaptive immune defense system has been co-opted as a powerful tool for precise eukaryotic genome engineering. Here, we present a rapid and simple method using chimeric single guide RNAs (sgRNA) and CRISPR-Cas9 Ribonucleoproteins (RNPs) for the efficient and precise generation of genomic point mutations in C. elegans. We describe a pipeline for sgRNA target selection, homology-directed repair (HDR) template design, CRISPR-Cas9-RNP complexing and delivery, and a genotyping strategy that enables the robust and rapid identification of correctly edited animals. Our approach not only permits the facile generation and identification of desired genomic point mutant animals, but also facilitates the detection of other complex indel alleles in approximately 4 – 5 days with high efficiency and a reduced screening workload.
Recent technological advances have radically transformed and accelerated the ability to precisely engineer genomes. In particular, the CRISPR-Cas9 system, which relies on the RNA-guided endonuclease Cas9 to induce a double strand break (DSB) near the target sequence of interest, has been extensively used to accurately engineer the genome of the majority of model organisms used in biomedical research1,2,3,4. Significantly, the use of CRISPR-Cas9 has unlocked genome editing even in difficult species like C. elegans5. Regardless of species, generating point mutations with the CRISPR-Cas9 based genome editing system relies on three core components: 1) Cas9 endonuclease, 2) a single guide RNA (sgRNA) that directs the Cas9 endonuclease to a target sequence, and 3) a user designed homology-directed repair (HDR) template containing the desired edit(s) of interest2.
There are several methods that can be used to introduce the targeting sgRNA and Cas9 nuclease into cells including plasmid, RNA, and viral-based delivery methods6. Recently, direct delivery of pre-complexed sgRNA-Cas9 Ribonucleoproteins (RNPs) has emerged as a powerful and efficient tool in CRISPR-Cas9-based genome editing7. The direct delivery of pre-complexed CRISPR-Cas9 RNPs has several distinct advantages, namely: 1) RNPs bypass the need for cellular transcription and translation, 2) RNPs are rapidly cleared, which may increase specificity by reducing available time for off-target cleavage, and 3) RNPs contain no foreign DNA/RNA elements which circumvents the introduction of non-native sequences into the host genome through random integration. Together, these attributes likely provide a short-lived burst of on-target CRISPR editing while minimizing off-target effects.
We describe a simple and efficient protocol for introducing site-specific genomic changes in C. elegans. This protocol includes targeting sgRNA and single stranded oligonucleotide (ssODN) HDR template design, sgRNA-Cas9 RNP complexing and delivery, and a genotyping strategy for the unequivocal identification of properly edited animals. Using this strategy, not only can the desired site-specific changes be recovered, but other non-specific indel mutations may also be recovered. Thus, our strategy permits the generation of an allelic series using a single strategy, where both mono-allelic, bi-allelic, and indel mutants can be generated in the F1 generation.
All animal care and experimental procedures followed the guideline from the National Institutes of Health and the Institutional Animal Care and Use Committee (IACUC) at the University of Michigan. Use RNase-free solutions and pipette tips throughout the protocol. Clean the working area, pipettes, tubes, and centrifuge with RNase Decontamination solution following the manufacturer guidelines (see Materials Table).
1. sgRNA Target Selection
2. Homology-directed Repair Template Design
3. Design Genotyping Primers
4. Prepare Injection Mix
5. Injection Protocol
6. Screen P0 Plates and Single mCherry(+) F1s
7. Single Worm PCR and Genotyping
8. Identification and Sequence Verification of Edited Animals
Mutations in human superoxide dismutase 1 (SOD1) account for ~10 – 20% of familial amyotrophic lateral sclerosis, a devastating neurodegenerative disease that invariably leads to paralysis and death17. Human SOD-1 is an evolutionarily conserved protein sharing 55% identity and 70% similarity with the C. elegans SOD-1 protein (Figure 1B). To demonstrate the simplicity, feasibility, and efficiency of the CRISPR-Cas9 RNP-based approach, we targeted the C. elegans sod-1 gene to introduce the disease-associated human G93A variant in the worm genome (Figure 1A).
To engineer the G93A mutation in the C. elegans genome, an sgRNA was chosen whose PAM recognition site sits 3 bp upstream of the G93 codon (Figure 1C). We designed an ssODN HDR repair template containing: 1) nucleotide changes to convert the G93 codon to A93 (GGA GCA), 2) a silent change to the NGG PAM sequence (CGG CAG) to prevent sgRNA-Cas9-mediated cleavage of the HDR template, 3) a silent mutation (CT) that introduces a unique HindIII restriction enzyme site for genotyping, and 4) 50 bp 5' and 3' homology arms (Figure 1C). A PCR primer set (F1-R1) was designed to produce a single 592 bp PCR product in N2 controls (Figure 1A). An injection mix containing the sgRNA, Cas9, ssODN and a fluorescent marker plasmid (pCFJ90) were mixed together, incubated for 10 min at room temperature, and loaded into a microinjection pipette.
Figure 1D depicts the workflow after the injection mix is loaded into an injection micropipette. On Day 0, 10 – 15 P0 animals were injected in one or both gonad arms using the standard microinjection technique18,19. Injected animals recovered for 1 – 2 h and were then individually plated on OP50-seeded NGM plates. After 2 – 3 days, successful P0 injections were identified by those having mCherry(+) F1 progeny. The top three P0 plates (i.e. those having the greatest number of mCherry(+) F1s) were chosen for subsequent analysis. From each of these three plates (P0-8, P0-10, P0-12), 8 mCherry(+) F1s were singled to individual OP50-seeded 35 mm NGM plates for a total of 24 mCherry(+) F1s. After 2 - 3 days of egg-laying (Day 4 – 5), the individual F1s were transferred into PCR tubes containing worm lysis buffer and frozen for 1 h at -80 °C. Subsequently, the F1s were lysed to liberate genomic DNA, and subjected to PCR. The PCR products were then purified and digested with HindIII for 1 h, and run on a 1.5% agarose gel to identify potential edited animals. In correctly edited animals, HindIII digestion cuts the full-length PCR product (592 bp) into two bands of 370 bp and 222 bp. This genotyping strategy unambiguously differentiates between wild-type (592 bp), heterozygote (592, 370, 222 bp) and homozygote (370, 222 bp) animals. Figure 2A illustrates the genotyping results for the 24 mCherry(+) animals.
To demonstrate that the fluorescent mCherry marker enriches for genome modification, we also picked 8 mCherry(-) animals from each of the three P0 plates. Of the 24 mCherry(+) F1s screened (red bar), 10 contained mono-allelic or bi-allelic modification (42%), 10 were wild type (42%), 3 were potential indels (13%), and there was 1 PCR failure (Figure 2A). In contrast, of the 24 mCherry(-) F1s screened, only 1 animal was correctly modified (4%); whereas, 23 were wild type (96%) (Figure 2A). Figure 2B shows the chromatogram from the full-length gel extracted PCR product (F18-6), demonstrating that the precise nucleotide changes designed in the ssODN HDR template were faithfully incorporated into the genome of this homozygous F1 animal. Notably, F1 animals 10-7, 10-8, and 12-3 exhibited unexpected PCR product sizes and restriction digest banding patterns, suggesting these animals may carry complex indel mutations (Figure 2A). Thus, our method is not only capable of generating desired genome modification(s) with ease, efficiency, and fidelity, but also permits the identification and recovery of unique indel alleles that may shed important and unexpected insight into gene function.
Figure 1. CRISPR-Cas9 engineering of the C. eleganssod-1 locus. (A) Schematic illustration depicting the exon-intron structure of the sod-1 locus in C. elegans. The red bar denotes the location of G93 in exon 3. The primer pair set is noted by the red arrows (F1-R1). (B) Sequence alignment of human and C. elegans (worm) SOD-1 proteins. The targeted G93 residue is highlighted in red. (C) Top, a section of genomic DNA surrounding the G93 codon is shown as a reference, and the PAM (green) and sgRNA target (blue) sites are highlighted. Bottom, the single stranded oligonucleotide (ssODN) homology directed repair (HDR) template is shown containing: the codon edit changing G93 to A93, a silent change to the PAM motif to prevent cleavage by the sgRNA-Cas9 complex, a silent change to introduce a unique HindIII restriction enzyme site (yellow box), and flanking 5' and 3' 50 bp homology arms (black bars). All nucleotide changes designed in the ssODN are highlighted red. (D) Schematic illustration of the pipeline for generating and identifying CRISPR-Cas9 RNP-based point mutants. On day 0, inject 10 – 15 P0 animals with injection mix. On day 2 – 3, identify successfully injected P0 animals by those containing fluorescent F1 progeny, and select three P0 plates with the most fluorescent progeny. From each of the three P0 plates, single 8 fluorescent F1 progeny. On day 4 – 5, (a) step 1, individual F1s are picked and placed into PCR tubes containing Lysis Buffer; (b) step 2, after freezing at -80 °C, PCR tubes containing F1 worms are lysed to release genomic DNA, which is used as a PCR template. The PCR products are then cleaned and digested with the unique restriction enzyme; (c) step 3, enzyme digested products are resolved on an agarose gel where wild type (+/+), heterozygous (m/+), and homozygous (m/m) animals can be identified by restriction digest banding patterns. Please click here to view a larger version of this figure.
Figure 2. Genotyping data for sod-1 (G93A) mutants.(A)Gel image of F1 animals that were individually lysed, PCRed and digested with HindIII. For each P0 plate (P0-8, P0-10, P0-12), 8 mCherry(+) and 8 mCherry(-) F1 animals were analyzed. Both mono-allelic (blue numbers) and bi-allelic (red numbers) edited animals were recovered. Size shifted PCR products or unpredicted HindIII digested bands were also recovered that are indicative of indel mutants (yellow numbers). N2 controls are shown as a reference for PCR product sizing and enzyme specificity. (B) Top, codon spacing and amino acid translations are shown above for the wild type (WT) and below for G93A modified strands. The desired edit is highlighted by a red box, and the silent changes that create an in-frame HindIII restriction site are highlighted by a yellow box. All designed nucleotide changes are shown in bold. Bottom, representative chromatogram from homozygous F1 animal 8-6. Please click here to view a larger version of this figure.
Reagent | Volume | Final Concentration |
ddH2O | 6.3 μL | —- |
KCl (4M) | 0.94 μL | 300 mM |
HEPES (0.5M) pH 7.4 | 0.5 μL | 20 mM |
pCFJ90 (25 ng/μL) | 1.25 μL | 2.5 ng/μL |
ssODN (500 ng/μL) | 1.25 μL | 50 ng/μL |
sgRNA (50 μM) | 1.25 μL | 5 μM |
Cas9 (61 μM) | 1.03 μL | 5 μM |
Final Volume | 12.5 μL | —- |
Table 1. CRISPR-Cas9 RNP Injection Mix. All reagents should be re-suspended in nuclease-free ddH2O. RNase free techniques should be used when handling reagents and when making the injection mix.
Reagent | [Final] |
KCl | 50 mM |
Tris-HCl pH 8.3 | 10 mM |
MgCl2 | 2.5 mM |
NP-40 | 0.45% |
Tween-20 | 0.45% |
Proteinase K | 1 mg/mL |
Table 2. Worm Lysis Buffer Recipe. Proteinase K should be added fresh before each use.
Reagent | 1x | 24x |
2X Q5 Mastermix | 12.5 μL | 300 μL |
Primer F1 (10 μM) | 1.25 μL | 30 μL |
Primer R1 (10 μM) | 1.25 μL | 30 μL |
Worm Lysis | 4 μL | —- |
ddH2O | 6 μL | 144 μL |
Final Volume | 25 μL | 504 μL |
Table 3. PCR Mastermix. The PCR mastermix should be mixed well by pipetting until the solution is homogeneous. 21 µL of the PCR mastermix should be added to clean PCR tubes, and then 4 µL of individual worm lysate should be added to properly labeled tubes.
Reagent | 1x | 24x |
10X Enzyme Buffer | 2 μL | 48 μL |
Cleaned PCR Reaction | 10 μL | —- |
ddH2O | 7 μL | 168 μL |
Restriction Enzyme (10 U/μL) | 1 μL | 24 μL |
Final Volume | 20 μL | 240 μL |
Table 4. Restriction Enzyme Mastermix. The restriction enzyme mastermix should be mixed well by pipetting until the solution is homogeneous. 10 µL of the restriction enzyme mastermix should be added to 10 µL of cleaned PCR product
The CRISPR-Cas9 system is a powerful and effective tool for precisely modifying the genome of model organisms. Here, we demonstrate that chimeric sgRNAs20 coupled with ssODN HDR templates enable the highly efficient generation of genomic point mutations in C. elegans. Importantly, we demonstrate that RNP delivery produces high editing efficiency when fluorescence is used as a co-selection marker, highlighting the ease and reliability of the technique.
The majority of CRISPR-Cas9 methods for C. elegans genome engineering rely on specific genetic backgrounds or co-CRISPR strategies1. The co-CRISPR method has proven to be an incredibly useful tool that increases the likelihood of obtaining a successful genome edit. However, co-CRISPR methods require introducing a phenotype-selectable edit at a marker locus that enriches for the genome edit of interest. While powerful, introducing selectable phenotype-bearing mutations may be undesirable if the strain to edit or the desired point mutation of interest itself exhibits phenotypes that might be exacerbated or suppressed by the marker phenotype. Moreover, co-CRISPR strategies necessitate creating an additional double strand break at a marker locus that may contribute to off-target effects. Here, we present a method that uses a transient fluorescent marker that not only serves to identify successfully injected P0 animals, but also enriches for proper genome edits. Our data demonstrate this method significantly enriches for successfully edited animals in comparison to non-fluorescent animals, and provides several distinct advantages: 1) only one targeting site-specific sgRNA is required, 2) a 5-fold reduction in Cas9 and sgRNA concentration, 3) strain- and phenotype-selection independence, and 4) a nominal screening workload (~24 F1s). Robust CRISPR-Cas9 genome editing in the F1 generation was observed using this method. Notably, the PCR-restriction enzyme-based detection strategy described enables the unequivocal detection of mono- and bi-allelic edited animals in the F1 generation. Finally, the genotyping strategy facilitates identification of potential indel mutations, which can be observed as PCR band shifts when compared to N2 controls, that are either not susceptible to restriction digest or yield complex bands when digested.
The advent of next generation sequencing coupled with large scale genomic efforts has accelerated the identification of genomic variants that segregate with disease21. However, functional tests of pathogenicity have not been demonstrated for the majority of variants in cellular and organismal model systems. In this study, we targeted the sod-1 gene in C. elegans to introduce the widely studied ALS-associated SOD-1G93A mutation. To date, this mutation has been modeled and studied in C. elegans and mice primarily using transgenic overexpression. Although overexpression of variants in animal models may recapitulate key cellular, molecular and behavioral aspects of disease, it is increasingly clear that 'dose' is an extenuating factor in determining phenotypes22. For example, high copy number SOD-1G93A mice carrying ~24 copies of the mutant human SOD-1 gene exhibit greatly accelerated disease course compared to SOD-1G93Adl mice, which carry only ~8 – 10 copies23,24. Here, we demonstrate that our CRISPR-Cas9 RNP-based method can be utilized to rapidly generate human variant-associated mutations in the orthologous worm gene without requiring transgenic overexpression, in an effort to more precisely replicate the genetic context of disease. Our method provides a feasible platform to produce and test genomic variants of unknown significance in the context of endogenous regulatory control and expression, which precludes the confines of overexpression. Finally, we have also used this method to tag endogenous genes with fluorescent proteins (i.e. GFP), which will provide an additional tool for visualizing how variants affect protein localization, aggregation, and turnover.
The authors have nothing to disclose.
There are no conflicts of interest related to this report.
CRISPRevolution sgRNA EZ Kit | Synthego Inc. | chimeric sgRNA | |
Nuclease-free TE | Synthego Inc. | provided with the sgRNA kit EZ kit | |
Nuclease-free water | Synthego Inc. | provided with the sgRNA kit EZ kit | |
4 nmole Ultramer DNA Oligo | Integrated DNA Technologies | ssODN HDR template | |
Alt-R S.p. HiFi Cas9 Nuclease 3NLS | Integrated DNA Technologies | 1078728 | Cas9 protein |
pCFJ90 | Addgene | 19327 | Pmyo-2::mCherry Marker Plasmid |
KCl | Sigma | P5405 | |
HEPES | Sigma | H4034 | |
DNA Clean & Concentrator | Zymo Research | D4004 | |
Zymoclean Gel DNA Recovery Kit | Zymo Research | D4002 | |
Q5 Hot Start High-Fidelity 2X Master Mix | New England Biolabs | M0494L | |
Proteinase K | Sigma | P2308 | |
Glass Borosilicate Glass Micropipettes | Sutter Instruments | BF100-78-10 | OD: 1.0mm. ID: 0.78mm |
Trizma Hydrochloride | Sigma | T5941 | |
MgCl2 | Sigma | M2393 | |
NP-40 | Sigma | 74385 | |
Tween-20 | Fisher Scientific | BP337-100 | |
RNaseZap Decontamination Solution | Fisher Scientific | AM9780 |