Abstract
Guide RNAs offer programmability for CRISPR-Cas9 genome editing but also add challenges for delivery. Chemical modification, which has been key to the success of oligonucleotide therapeutics, can enhance the stability, distribution, cellular uptake, and safety of nucleic acids. Previously, we engineered heavily and fully modified SpyCas9 crRNA and tracrRNA, which showed enhanced stability and retained activity when delivered to cultured cells in the form of the ribonucleoprotein complex. In this study, we report that a short, fully stabilized oligonucleotide (a “protecting oligo”), which can be displaced by tracrRNA annealing, can significantly enhance the potency and stability of a heavily modified crRNA. Furthermore, protecting oligos allow various bioconjugates to be appended, thereby improving cellular uptake and biodistribution of crRNA in vivo. Finally, we achieved in vivo genome editing in adult mouse liver and central nervous system via co-delivery of unformulated, chemically modified crRNAs with protecting oligos and AAV vectors that express tracrRNA and either SpyCas9 or a base editor derivative. Our proof-of-concept establishment of AAV/crRNA co-delivery offers a route towards transient editing activity, target multiplexing, guide redosing, and vector inactivation.
Introduction
Rapidly evolving CRISPR-Cas genome editing tools have revolutionized biomedical research, and promise new routes to therapeutics. Currently, most of the widely applied genome editing tools are based on a Cas9 protein from Streptococcus pyogenes (SpyCas9) (1–3). The natural effector complex consists of SpyCas9 bound to a CRISPR RNA (crRNA) and a trans-activating crRNA (tracrRNA) (4–7). The guide sequence within the crRNA can direct the effector complex to a desired genomic locus followed by a specific protospacer adjacent motif (PAM), and the Cas9 nuclease can generate a double-strand DNA (dsDNA) break. When applied to genome editing in eukaryotic cells, non-homologous-end-joining (NHEJ) can induce indels that result in gene disruption, while homology-directed repair (HDR) can generate precise edits (2). HDR-independent precision genome editing tools have also been developed by fusing functional domains to Cas9 nickase (nCas9) mutants. For example, base editors consist of nucleobase deaminase enzymes fused to nCas9 and can generate single-base changes within the targeted genomic locus without requiring dsDNA breaks (8–12). More recently, prime editors were developed by fusing engineered reverse transcriptase (RT) to nCas9, which offers even more versatility and can make virtually any substitution, small insertion, and deletion within the genome (3, 13–15).
The programmability and versatility of CRISPR genome editing tools derive from their RNA-guided nature. However, an RNA guide also adds challenges for in vivo delivery. Unmodified single-stranded RNAs (ssRNA) are extremely vulnerable to nuclease degradation and are rapidly degraded in cells and biological fluids such as serum (16, 17). Chemical modification, which has been key to the success of oligonucleotide therapeutics, can enhance the stability, distribution, cellular uptake, and safety of nucleic acids (16–27). Indeed, most of the clinically advanced and FDA-approved antisense oligonucleotides (ASOs) and short interfering RNAs (siRNAs) are fully chemically modified and stabilized for delivery without lipid nanoparticle (LNP) formulation (16, 17, 28–33). Complete chemical modification enables efficient delivery and robust in vivo efficacy in multiple tissues including the liver as well as the central nervous system (CNS) (16, 18, 34, 35). Likewise, we reasoned that extensive chemical modification of CRISPR guide RNAs could facilitate delivery in vivo and potentially achieve self-delivery without LNPs. For example, self-delivering crRNAs could be administered with an effector (and a tracrRNA, if needed) expressed from a viral vector such as adeno-associated virus (AAV), which is FDA-approved and has been shown to efficiently deliver genome editing agents in a wide range of tissues including liver and CNS (15, 36–39). Separating guide delivery from effector-encoding viral vectors has the potential to limit off-target editing (because the co-delivered guide is only transiently present rather than continuously produced), facilitate multiplexed targeting, increase spatiotemporal control over editing events, enable guide RNA redosing (if needed), and provide a route to inactivate the AAV vector once the desired editing is achieved (25).
Previously, using SpyCas9, we have engineered heavily and fully chemically modified crRNAs and tracrRNAs that exhibit increased stability while retaining editing activity when delivered to cultured cells as a ribonucleoprotein (RNP) complex (23). In this study, we designed fully chemically stabilized protecting oligos (P.O.s) that significantly enhanced the stability and potency of a heavily modified crRNA. Furthermore, when linked with bioconjugates, the P.O.s can boost cellular uptake of the crRNA, acting as a delivery agent without interfering with Cas9 activity. Moreover, we show that the chemically modified crRNAs coupled with P.O.s can generate editing by passive, LNP-independent uptake in cultured cells that stably express effector protein and tracrRNA. Finally, we show that unformulated, chemically modified crRNAs co-delivered with tracrRNA- and effector-expressing AAV vectors support genome editing in vivo in adult mice.
Materials and Methods
Molecular cloning.
The U1a-SpyCas9-miniU6-tracrRNA lentivector used for generating the stable HEK293T-SpyCas9-tracrRNA-TLR-MCV1 reporter cell line shown in Figure 1a was cloned by Gibson assembly. The Addgene plasmid #52962 was digested with NotI and BamH1 restriction enzymes, and the lentivector backbone was Gibson-assembled with a miniU6-tracrRNA gene block and U1a-SpyCas9 amplified by PCR from Addgene plasmid #121507. Similarly, the dGFP reporter plasmid was cloned into a lentivector for generating the HEK29T-SpyCas9-ABE-tracrRNA-dGFP reporter cell line shown in Figure 1a. First, the Addgene plasmid #52962 was digested with NotI and BamH1 restriction enzymes. Then, the dGFP reporter plasmid was digested with EcoRI and MluI restriction enzymes, followed by Gibson assembly with bridging double-strand DNA (dsDNA) containing homology sequences. A PiggyBac transposon plasmid (Addgene plasmid #159095) was used to integrate the SpyCas9-ABE-tracrRNA expression gene in the HEK293T-SpyCas9-ABE-tracrRNA-dGFP reporter and Hepa1–6-SpyCas9-ABE-tracrRNA stable cell lines shown in Figure 1a. Addgene plasmid #159095 was digested with SalI and EcoRV, and the backbone was Gibson-assembled with the CMV enhancer and CbH promoter, SpyCas9-ABE8e, U6-tracrRNA, and hPGK-PuroR. The plasmid for packaging AAV to express tracrRNA (Figure 4, 5) was cloned by swapping the sgRNA with tracrRNA in Addgene Plasmid #121508 by overlapping PCR, and removing the EGFP-expression cassette by SpeI and XbaI restriction enzyme digestion, followed by Gibson assembly using a bridging dsDNA. The plasmid for packaging AAV to express SpyCas9 was Addgene Plasmid #121507. Plasmids for packaging AAV to express intein-split SpyCas9-ABE8e and tracrRNA (Figure 5) were generated by swapping the sgRNA with tracrRNA sequence using overlapping PCR and restriction cloning. Sequences of original plasmids described in this paper can be found in the Supplementary note and will be deposited to Addgene.
Stable cell lines.
The SpyCas9-tracrRNA transgene in the HEK293T-SpyCas9-tracrRNA-TLR-MCV1 reporter cell line, and the dGFP reporter transgene in the HEK293T-SpyCas9-ABE-tracrRNA-dGFP reporter cell line, were integrated into the genome of HEK293T-TLR-MCV1 reporter cells(40) and HEK293T cells, respectively, by lentiviral transduction. HEK293-F cells (ThermoFisher R79007) were transfected with the transfer plasmid and the packaging plasmids (Addgene plasmids #12263 and #8454) using TransIT-LT1 transfection reagent (Mirus MIR 2304). Two days later, the media containing lentivirus was collected and filtered through a 0.45 μm filter (Cytiva 6780–25040) to remove cell debris. HEK293T-TLR-MCV1 cells were transduced with lentivirus encoding SpyCas9-tracrRNA, and the HEK293T cells were transduced with lentivirus encoding the dGFP reporter in the presence of 8 μg/ml polybrene (Millipore Sigma TR-1003-G). Three days after transduction, the media was removed, and fresh media containing 5 μg/ml Blasticidin (Gibco R21001) was added to both cell lines. Ten days post-selection, cells were collected, and single-cell clones were established by serial dilution in 96-well plates. The SpyCas9-ABE-tracRNA transgene was integrated by PiggyBac transposon into the HEK293T-dGFP reporter cell line to generate HEK293T-SpyCas9-tracrRNA-dGFP reporter cell line, or into Hepa1–6 cell line to generate Hepa1–6-SpyCas9-ABE-tracrRNA stable cell line. Briefly, the SpyCas9-ABE-tracrRNA PiggyBac transposon plasmid and PiggyBac transposase expression plasmid (System Biosciences PB210PA-1) were mixed in a 2:1 molar ratio and transfected into the HEK293T-dGFP reporter cell line using Lipofectamine 3000 (ThermoFisher L3000015), or electroporated into Hepa1–6 cells using a Neon Transfection System 10 μl kit (ThermoFisher MPK 1096) with the following electroporation parameters: pulse voltage (1230 v), pulse width (20 ms), pulse number (3). Four days after transfection or electroporation, fresh media containing 2.5 μg/ml Puromycin (ThermoFisher A1113802) was added to both cell lines. Seven days post-selection, cells were collected, and single-cell clones were established by serial dilution in 96-well plates.
Cell culture.
HEK293T reporter cell lines and the Hepa1–6 stable cell line were cultured in Dulbecco’s Modified Eagle Media (DMEM, Genesee Scientific 25–500) supplemented with 10% Fetal Bovine Serum (FBS, Gibco 26140079). All cells were incubated in a 37 °C incubator with 5% CO2.
Oligonucleotide Synthesis.
Oligonucleotides were synthesized by phosphoramidite solid-phase synthesis on a Dr. Oligo 48 (Biolytic, Fremont, CA). All phosphoramidites with standard protecting groups were purchased from ChemGenes (Wilmington, MA). Phosphoramidites were prepared at 0.1 M in anhydrous acetonitrile (ACN), except for 2’-O-methyl-uridine dissolved in anhydrous ACN containing 15% dimethylformamide. 5-(Benzylthio)-1H-tetrazole (BTT) was used as the activator at 0.25 M, and the coupling time for all phosphoramidites was 4 minutes. Detritylations were performed using 3% trichloroacetic acid in dichloromethane. Capping reagents used were CAP A (20% n-methylimidazole in ACN) and CAP B (20% acetic anhydride and 30% 2,6-lutidine in ACN). Reagents for capping and detritylation were purchased from American International Chemical LLC (AIC), Westborough, MA. Phosphite oxidation to convert to phosphate was performed with 0.05 M iodine in pyridine-H2O (9:1, v/v) (AIC) or phosphorothioate with a solution of 0.1 M of 3 [(dimethylaminomethylene)amino]-3H-1,2,4-dithiazole-5-thione (DDTT) in pyridine (ChemGenes) for 4 minutes. Unconjugated oligonucleotides were synthesized on 500 Å long-chain alkyl amine (LCAA) controlled pore glass (CPG) functionalized with Unylinker terminus (ChemGenes). Cholesterol-conjugated oligonucleotides were synthesized on a 500Å LCAA-CPG support, where the cholesterol moiety is bound through a tetra-ethyleneglycol (TEG) linker (Chemgenes, Wilmington, MA). GalNAc conjugated oligonucleotides were grown on a 500Å LCAA-CPG where the trivalent GalNAc cluster was linked to the oligonucleotide through an aminopropanediol linker. TEG was used as the proximal spacers for each of the GalNac units. DHA-conjugated oligonucleotides were synthesized on a 500Å LCAA-CPG where the DHA is bound to the oligonucleotide via a C7-linker. Both GalNAc and DHA CPGs were purchased from Hongene Biotech, Union City, CA.
Deprotection and Purification of Oligonucleotides.
Synthesis columns containing oligonucleotides were treated previously with 10% diethylamine (Fisher) in ACN on the synthesizer. Oligonucleotides were cleaved and base-protecting groups were removed with a solution of 1:1 40% methylamine in water/30% ammonium hydroxide for 2 hours at room temperature. Cleaved and deprotected oligos were fully dried under a vacuum. Oligonucleotides containing 2’TBDMS protecting groups were dissolved in 115 μL DMSO (Sigma-Aldrich) at 65 °C. Triethylamine 60 μL (Sigma-Aldrich) followed by triethylamine-trihydrofluoride 75 μL (Sigma-Aldrich) was added, and the whole solution was incubated for 2.5 hours at 65°C. Deprotected oligonucleotides were cooled and precipitated in a solution of 0.1 M sodium acetate in isopropanol (Sigma Aldrich). After centrifugation, the supernatants were discarded, and the pellets were dried under a vacuum. Dried oligonucleotides were dissolved in 400 μL RNase-free water and desalted using Amicon Ultra 0.5 mL 3K filter tubes (Millipore, Billerica, MA USA), followed by three RNase-free water wash rounds for 15 min at 14000 × g. Finally, desalted oligonucleotides were extracted and diluted in RNase-free water.
Quantification and LC-MS Analysis of Oligonucleotides.
Absorbances at 260 nm were obtained using a Nanodrop 1000 series. Extinction coefficients were calculated for each sequence, and concentrations were determined following the Beer-Lambert equation. The identities of oligonucleotides were verified by LC-MS analysis on an Agilent 6530 accurate mass Q-TOF using the following conditions: buffer A: 100 mM 1,1,1,3,3,3-hexafluoroisopropanol (HFIP) and 9 mM triethylamine (TEA) in LC-MS grade water; buffer B:100 mM HFIP and 9 mM TEA in LC-MS grade methanol; column, Agilent AdvanceBio oligonucleotides C18; linear gradient 5–100% B in 5 minutes was used for all oligonucleotides; temperature, 60 °C; flow rate, 0.85 ml/min. LC peaks were monitored at 260 nm. MS parameters: Source, electrospray ionization; ion polarity, negative mode; range, 100–3,200 m/z; scan rate, 2 spectra/s; capillary voltage, 4,000; fragmentor, 200 V; gas temp, 325 °C.
Buffer exchange of oligonucleotide for in cellulo and in vivo study.
Oligonucleotides were first concentrated using Ultra Centrifugal 3K Filter Unit (Amicon UFC500396), then washed three times with 1M Sodium Acetate solution (Sigma 711096) and three times with phosphate buffered saline (PBS), pH 7.4 (Gibco 10010–023). Finally, the oligonucleotides were eluted in PBS, pH 7.4 (Gibco 10010–023), and absorbances at 260 nm were obtained using Nanodrop 1000 to determine the concentrations for in cellulo and in vivo study.
CrRNA/protecting oligo (P.O.) annealing and electroporation.
Each crRNA was mixed with P.O. at a 1:1 ratio, heated to 95 °C for 5 minutes, then gradually cooled to 15 °C (−0.1 °C per second, with the temperature held for 30 seconds every 10 °C). Electroporation of crRNA was performed using a Neon Transfection System 10 μl kit (ThermoFisher MPK 1096), with the following parameters: HEK293T cells, pulse voltage (1150 v), pulse width (20 ms), pulse number (2); Hepa1–6 cells, pulse voltage (1230 v), pulse width (20 ms), pulse number (3). Cells were cultured for 48 hours before being quantified by flow cytometry.
Free uptake of crRNA.
HEK293T-SpyCas9-ABE-tracrRNA-dGFP reporter cells were seeded at 25% confluency in a 48-well cell culture plate (ThermoFisher 150687) and cultured in DMEM + 10% FBS for 24 hours. Fresh culture media containing DMEM + 3% FBS and various concentrations of crRNA were mixed with the cells by gently pipetting up and down and incubated for an additional 72 hours before being quantified by flow cytometry.
Fluorescent reporter assay.
Cells were trypsinized, harvested into microcentrifuge tubes and centrifuged at 300 × g for 3 mins. Supernatant was removed and the cell pellet was resuspended into 1 x PBS and transferred into flow cytometry tubes. MACSQuant VYB was used for quantification of the percentage of fluorescent-positive cells, and 10,000 events were counted for FACS analysis. Data was analyzed using Flowjo v10. A representative gating strategy can be found in Supplementary Figure 1.
crRNA stability assay.
The crRNAs with or without P.O. were diluted in PBS, pH 7.4 and 10% FBS (ThermoFisher A3160501) and incubated at 37 °C for 0, 1, 4, 24 hours in a thermocycler. At each time point, samples were taken and mixed with an equal volume of 2x RNA gel loading dye (ThermoFisher R0641) and heated to 75 °C for 10 minutes to denature. The digested RNA was further resolved by 10% urea polyacrylamide gel electrophoresis (PAGE) followed by SYBR Gold (Invitrogen S11494) staining.
AAV production.
AAV vector packaging was done at the Viral Vector Core of the Horae Gene Therapy Center at the UMass Chan Medical School as previously described (41). Constructs were packaged in AAV9 capsids, and viral titers were determined by digital droplet PCR and gel electrophoresis, followed by silver staining.
Stereotactic intrastriatal (IS) injection.
All animal study protocols were approved by the Institutional Animal Care and Use Committee (IACUC) at UMass Chan Medical School. The Cas9+/+ mice that constitutively express Cas9 was generated by crossing a male mouse of Jackson Lab #027632 with a Cre-expressing female mouse (JAX #008454). The Cas9/mTmG mice were generated by crossing the Cas9+/+ mice and the mTmG+/+ mice (JAX #007676). For IS injection, 10 – 13 week-old mice were weighed and anesthetized by intraperitoneal injection of a 0.1 mg/kg Fentanyl, 5 mg/kg Midazolam, and 0.25 mg/kg Dexmedetomidine mixture. A total dose of 5 × 1010 vg of AAV in 3 μl was administered via unilateral intrastriatal injection (3 μl on the right side) performed as previously described at the following coordinates from bregma: +1.0 mm anterior-posterior (AP), ±2.0 mm mediolateral, and −3.0 mm dorsoventral (35, 42). Once the injection was completed, mice were intraperitoneally injected with 0.5 mg/kg Flumazenil and 5.0 mg/kg Atipamezole, and subcutaneously injected with 0.3 mg/kg Buprenorphine. Two weeks later, the same IS injection was performed to deliver 3 nmol crRNA in 3 μl volume into the AAV-injected site. Mice were euthanized 2 weeks after the second injection.
Retro-orbital (RO) injection.
The FahPM/PM mice were kept on water supplemented with 10 mg/L 2-(2-nitro-4-trifluoromethylbenzoyl)-1,3-cyclohexanedione (NTBC; Sigma, PHR1731–1G). Mice with more than 20% weight loss were humanely euthanized according to IACUC guidelines. For RO injection, six-week-old female mice were anesthetized by placement inside an approved induction chamber and introduction of Isoflurane at a flow rate of 2–3% and oxygen at 1.5 liters per minute. A total dose of 2 × 1012 vg of AAV (1 × 1012 vg of each AAV) in 200 μl was injected into the retro-orbital sinus of the mice. Animals were observed for signs of pain or distress and returned to a clean cage when able to remain sternal. Five weeks later, the same RO injections were performed to deliver GalNac-crRNA. When multiple injections of retro-orbital injection were performed, the injection site was alternated between the two eyes.
Genomic DNA extraction from cultured cells and mouse tissues.
For cultured cells, genomic DNAs were extracted 48 hours after electroporation. Briefly, cell culture media were aspirated, and cells were lysed using QuickExtract DNA Extraction Solution (Lucigen) following the manufacturer’s protocols. For mouse tissues, biopsies from each of the five liver lobes were collected into individual tubes. Tissues were homogenized, and genomic DNA was extracted using GenElute Mammalian Genomic DNA Miniprep Kit (Millipore Sigma G1N350).
Immunohistochemistry (IHC).
A floating section IHC staining protocol (43) was used in Figure 4c. Briefly, mice were perfused with PBS and brains were harvested and fixed with 10% neutral buffered formalin (ThermoFisher 5735) for 20 hours. Coronal brain sections (40 μm) were obtained using a vibratome (SCHOTT KL 1500). Brain sections were permeabilized by incubating in PBS, pH 7.4 with 0.3 % Triton X-100 (Sigma T8787), and blocked with 3% hydrogen peroxide (Sigma 216763). The sections were then incubated with blocking solution [1.5% normal goat serum (Vector Laboratories S-1000) + 0.3 % Triton X-100 in PBS, pH 7.4] for 3 hours at room temperature (RT) followed by incubating with a rabbit anti-EGFP antibody (ThermoFisher G10362, 1:1000 dilution) at 4 °C overnight. After washing with PBS, the sections were incubated with a secondary antibody (Vector Laboratories BA-1000) for 10 minutes at RT, then with ABC reagent (Vector Laboratories PK-6100) for 30 minutes at RT. To detect EGFP-positive signals, the sections were stained with 1x DAB (ThermoFisher 34065) for 2 minutes at RT. Finally, the sections were mounted on slides with PBS and 0.5% gelatin (Sigma G1890) in 30% ethanol and dried overnight before imaging.
IHC staining shown in Figure 5h used formalin-fixed, paraffin-embedded sections. Briefly, mice were euthanized by CO2 asphyxiation, and livers were fixed with 10% neutral buffered formalin (Epredia 5735), embedded with paraffin, and sectioned at 10 μm. For IHC, liver sections were dewaxed, rehydrated, and stained using an anti-FAH antibody (Abcam ab83770) at 1:400 dilution as described previously (42, 44).
ImageJ analysis on IHC images.
The percentage of EGFP-positive cells was quantified using the ImageJ color deconvolution 2 plugin. A 1 mm2 region around the injection site was selected for quantification. Colors were deconvoluted using “H DAB”, and the number of nuclei was counted by inverting the nuclei image color, applying median blur (3), and find maxima (30). The number of EGFP-positive cells was counted by inverting the DAB image color, applying Gaussian blur (2), setting the threshold to remove the background counting, and applying watershed, followed by analyzing particles (200 - infinity). The percentage of EGFP-positive cells = (number of DAB-positive cells/number of nuclei) × 100%.
Fluorescent imaging.
Mouse brains IS-injected with Cy3-labeled crRNAs were perfused with PBS, fixed with 10% neutral buffered formalin for 20 hours, paraffin-embedded, and sectioned to 10 μm. Before imaging, the brain sections were deparaffinized by incubating in xylene for 10 minutes, and mounted with DAPI mounting media (Invitrogen P36962). Images were taken under a Leica fluorescent microscope. The same laser intensity and exposure settings were applied to all images for comparisons between groups.
Targeted amplicon deep sequencing and data analysis.
Genomic DNA was PCR-amplified using Q5 High-Fidelity 2x Master Mix (NEB M0492) for 20 cycles. For barcoding PCR, 1 μl of the unpurified PCR product was used as a template and amplified for 20 cycles. The barcoded PCR products were further pooled and gel-extracted using Zymo gel extraction kit and DNA clean & concentrator (Zymo research 11–301, 11–303) and quantified by Qubit 1× dsDNA HS assay kits (ThermoFisher Q32851). Sequencing of the pooled amplicons was performed using an Illumina MiniSeq system (300-cycles, FC-420–1004) following the manufacturer’s protocol. The raw MiniSeq output was de-multiplexed using bcl2fastq2 (Illumina, version 2.20.0) with the flag --barcode-mismatches 0. To align the generated fastq files and to quantify editing efficiency, CRISPResso2(45) (version 2.0.40) was used in batch mode with base editor output and the following flags: -w 10, -q 30, -plot_window_size 20, -min_frequency_alleles_around_cut_to_plot 0.1. Indel frequency = (insertions reads + deletions reads)/all aligned reads × 100%. Base editing frequency = A-to-G reads/all aligned reads × 100%.
Statistical analysis
The statistical analysis was performed in Prism software using either one-way ANOVA with Dunnett correction for multiple comparisons, or two-way ANOVA with Sidak correction for multiple comparisons.
Results
Activities and stabilities of previously engineered chemically modified crRNAs
Previously, we developed chemically modified crRNAs that support SpyCas9 activity in cell culture via RNP delivery (23). These crRNAs were heavily or fully modified on the sugar-phosphate backbone with various chemical modifications to enhance stability while retaining significant activity. First, to quickly screen the activity of these crRNAs in a context that mimics viral co-delivery (delivering naked crRNA with virus-expressed effector protein and tracrRNA), we established two stable human HEK293T cell lines that express an effector protein, the tracrRNA and a fluorescent reporter gene (Figure 1a) from integrated vectors. In the first case, we generated a clonal line stably expressing SpyCas9 nuclease, tracrRNA, and a traffic light reporter (TLR-MCV1) (40, 46). This reporter consists of a disrupted GFP followed by an out-of-frame mCherry; a double-strand DNA break in the broken GFP region generates a frameshift and places mCherry in-frame, leading to red fluorescence (Figure 1a, top; Supplemental Figure 1a). A distinct clonal cell line stably expresses SpyCas9-ABE8e (11), tracrRNA, and a dead_GFP (dGFP) reporter (in which a G-to-A nonsense mutation in the GFP coding sequence prevents GFP expression). Adenine base editing that reverses the point mutation activates GFP expression (Figure 1a, middle; Supplemental Figure 1b). We also engineered a third clonal line, derived from mouse Hepa1–6 cells, that stably expresses SpyCas9-ABE8e and tracrRNA (Figure 1a, bottom) without a reporter, to facilitate tests at endogenous sites in the mouse genome. In all three cases, the activity of each crRNA chemical modification pattern can be assessed by electroporating the crRNA into the stable cell lines and measuring either reporter activation by Fluorescence Activated Cell Sorting (FACS) analysis, or endogenous target editing by amplicon deep sequencing.
We chose to test a series of the chemical modification patterns of the previously engineered crRNAs that showed robust activity when delivered in the form of the RNP complex (Figure 1b) (manuscript in preparation) (47). We synthesized crRNAs with these chemical modification patterns and spacer sequences targeting either the fluorescent reporter gene or endogenous mouse genomic loci. By electroporating the crRNAs into the stable cell lines, we found that the heavily modified C20 showed consistently high activity at all the target sites tested (Figure 1c–1g) and significantly improved activity compared to the minimally modified C0 (Figure 1c). However, all other heavily and fully modified crRNAs tested showed reduced activity compared with C20, with both SpyCas9 nuclease and SpyCas9-ABE8e, and the activity was inconsistent between different target sites (Figure 1c–1g).
Naked crRNA delivered without lipid formulation needs to be stable enough to survive harsh environments in vivo. As an initial test of the stabilities of the differently modified crRNAs, we incubated the naked crRNAs shown in Figure 1b in non-heat-inactivated fetal bovine serum (FBS) at 37°C. We found that only the fully modified crRNAs (i.e., those without any ribose moieties) resisted ribonuclease degradation and remained stable throughout the 24 hours of incubation (Figure 1h). The superior activity but poor stability of C20, together with the opposite trend for C21, C40 and C45, indicate that stability/efficacy trade-offs still exist among these previously engineered crRNAs.
Protecting oligonucleotides can enhance the potency and stability of heavily modified crRNAs
While continuing the development of crRNA chemical configurations that combine high potency and stability on their own, we explored an alternative strategy to enhance the C20 crRNA’s stability while retaining its consistently high activity across sites (Figure 1c–1g). The C20 modification pattern includes six riboses, though each ribose also includes a 3’-phosphorothioate for partial stabilization (Figure 1b). To further enhance the stability of C20, we designed a series of fully 2’-O-Me modified oligos, which we termed “protecting oligos” (P.O.s), with a sequence complementary to the ribose-containing region of C20. This idea was inspired by the design of DNA/RNA heteroduplex oligonucleotides (HDOs) (48, 49) and by the well-established observation that double-stranded RNAs are more resistant to nuclease degradation than single-stranded RNAs (50–52). Because the P.O. leaves the fully chemically stabilized 3’ portion of the repeat region available for annealing, we hypothesized that it could be displaced by strand invasion of the tracrRNA after its initial annealing to the unprotected crRNA bases, thereby allowing the formation of the active crRNA/tracrRNA complex (Figure 2a, 2b) (5).
By annealing the P.O. to C20 and electroporating the duplex into the stable cell lines, we found that the duplexes exhibited significantly enhanced potency compared to C20 alone at all target sites tested (Figure 2c–2f). Furthermore, when incubating the duplex with non-heat-inactivated FBS at 37°C, we found that P.O.s greatly improved C20 stability. Furthermore, P.O.s with lengths equal to or longer than 14 nucleotides (nt) can protect the majority of C20 from degradation throughout the 24 hours of incubation (Figure 2g). The high efficacy of the C20/P.O. complex further implies that the stability conferred by duplex formation does not prevent productive tracrRNA annealing, as we hypothesized.
We then further explored the mechanisms of P.O. activity. We compared the activities of C20 with P.O.s of different lengths or that anneal to different regions of C20 (Supplemental Figure 2a). We found that P.O.s as short as 10 nt (PO1) enhanced C20 potency, although to a lesser extent than the 14 nt P.O. (PO7), possibly because the lower melting temperature limited the degree of C20 protection, as indicated in Figure 2g. Conversely, we found that longer P.O.s (up to 22 nt for PO16) reduced C20 potency, possibly due to the strong binding affinity that inhibited initial tracrRNA annealing, P.O. displacement, or both. Furthermore, the positions where the P.O. binds are also important (Supplemental Figure 2a). A 16 nt P.O. (B10) that leaves no toe-hold for initial tracrRNA annealing also leads to reduced activity, consistent with our hypothesis that the P.O. needs to be displaced by tracrRNA before C20 can become active (Supplemental Figure 2a). Finally, we showed that the P.O. neither inhibited nor enhanced the potency of a fully modified and stabilized crRNA (C40), implying that the potency increase conferred by the P.O. resulted from C20 stabilization (Supplemental Figure 2b).
Protecting oligonucleotides support editing by passive uptake and provide sites for chemical conjugates that enhance in vivo distribution
Electroporation bypasses normal steps of cellular uptake and directly introduces the crRNA into the cellular interior (53), enabling functional assessments of editing but providing no information on natural cellular uptake, endosomal escape, or nuclear trafficking. In contrast, it is well established that naked, chemically modified siRNAs and ASOs can be delivered into cultured cells through passive uptake and induce specific mRNA knockdown (18, 54–56). We hypothesized that C20/P.O. complexes can similarly enter cells via passive uptake, enabling endosome escape and nuclear trafficking to form an effector complex and support editing. To test this, we added naked C20, with or without PO7, directly into the cell culture medium of the stable cell line expressing SpyCas9-ABE8e, tracrRNA, and the dGFP reporter (Figure 3a). Three days later, we analyzed the editing efficiency by FACS. We found that the unformulated C20/PO7 complex can be delivered via passive uptake in these cells and guide SpyCas9 editing activity (Figure 3b).
A significant advance in the field of oligonucleotide therapeutics has been the development of oligo bioconjugation (29, 57–61), in which oligos are appended with lipids (60–68), vitamins (69, 70), peptides (71), receptor ligands (58, 59, 72), aptamers (73), or antibodies (74, 75). Depending on the target cell type, these modifications can promote bioavailability, cellular uptake, tissue specificity, and safety of the in vivo delivered oligonucleotides through various mechanisms such as 1) penetrating the cell by natural transport mechanisms, 2) specifically binding to a cell surface receptor, or 3) interacting non-specifically with the cell membrane (29). For example, the most clinically advanced bioconjugate, N-acetylgalactosamine (GalNac), is a ligand for the asialoglycoprotein receptor (ASGPR), which is highly expressed on the membranes of hepatocytes (58, 59, 72). Conjugating GalNac to therapeutic siRNAs has yielded significant improvements in its pharmacological properties (32). Furthermore, conjugation with lipids such as cholesterol or long-chain fatty acids can broaden therapeutic distribution by facilitating plasma membrane association, binding circulating plasma lipoproteins, promoting uptake by interactions with lipoprotein receptors, or combinations thereof (60). More recently, docosanoic acid (DCA) (63) and docosahexaenoic acid (DHA) (62) have been used to improve biodistribution in extrahepatic tissues such as the muscle and brain.
Despite these advances with ASOs and siRNAs, lipid conjugates such as cholesterol cannot be assumed to be compatible with crRNA and Cas9 activity. Our previous study showed that adding a cholesterol conjugate to crRNA significantly reduced both the in vitro and the in cellulo activity of the RNP complex (23). The reduced efficiency may be caused by either the strong hydrophobicity or the steric hindrance of the cholesterol conjugate, perhaps affecting guide loading, protein function, or both. A potential advantage of the P.O. approach is that it can provide additional “handles” for conjugates, without the conjugates being present in the final, functional RNP complex. To test this idea, we compared the effects of hydrophobic conjugates on editing efficiency when tethered to C20 or to the P.O.. Through electroporation, we observed that while C20 with cholesterol conjugation showed significantly reduced editing efficiency, cholesterol conjugation to the P.O. did not interfere with editing (Figure 3c).
To directly examine the effects of P.O. hydrophobic conjugation on C20 tissue distribution in vivo, we delivered Cy3-labeled C20 with and without cholesterol- or DHA-conjugated P.O.s in adult mouse brains by intrastriatal (IS) injection. As expected, we found that compared to unconjugated P.O.s, both cholesterol- and DHA-conjugated P.O.s significantly enhanced the in vivo distribution of C20 (Figure 3d). These data suggest that the P.O. facilitates various types of conjugation and can be used as a delivery vehicle to enhance the biodistribution of crRNA without interfering with Cas9 activity.
In vivo genome editing in adult mouse CNS by co-delivery of AAV and self-delivering crRNA
Encouraged by these results, we tested whether the unformulated C20/P.O. complex can support genome editing by AAV co-delivery in vivo. We chose to test this in a double transgenic reporter mouse model, Cas9/mTmG+/+. This mouse model was generated by crossing the homozygous Cas9+/+ mice with the homozygous mTmG+/+ reporter mice (76). The Cas9+/+ mouse model constitutively expresses SpyCas9, and the only component requiring AAV delivery is the tracrRNA. The mTmG+/+ reporter consists of loxP sites on either side of a membrane-targeted tdTomato (mT) cassette, which constitutively expresses red fluorescence, and a downstream membrane-targeted EGFP (mG) that cannot be expressed until the mT cassette is deleted (Figure 4a). First, we injected a self-complementary (sc) AAV9 that expresses tracrRNA into adult Cas9/mTmG+/+ mouse brain by IS injection. Two weeks later, we performed IS injection again to deliver a naked C20 that targets the two loxP sites to generate a segmental deletion of the mT cassette and allow mG expression. We then detected EGFP expression by performing Immunohistochemistry (IHC) on formalin-fixed mouse brain sections using anti-EGFP antibodies (Figure 4a).
Recent studies on siRNAs showed that compared to cholesterol, conjugation of the less hydrophobic DHA allows broader distribution in the CNS and supports more robust silencing (62). Additionally, using a d(TT)-PO-C7 cleavable linker between siRNA and lipid conjugates has been shown to significantly improve silencing efficacy without altering tissue accumulation (20, 63). This is potentially because the cleavable linker has limited stability in vivo, allowing initial tissue distribution while being quickly cleaved after cellular uptake to release the siRNA (preventing oligo attachment to the endosomal membrane or other disruptions to intracellular trafficking). By IHC staining using an anti-EGFP antibody, we found that C20 without P.O. did not generate any editing in the brain (Figure 4b, 4c). At the same time, we only observed a few EGFP-positive cells around the injection site with C20 and P.O. with no conjugation. In contrast, C20 with P.O. having either a DHA or cholesterol conjugate (with either cleavable or stable linker) generated more efficient editing with broader distribution (Figure 4b, 4c), consistent with the in vivo distribution results shown in Figure 3d. When quantifying the percentage of EGFP-positive cells within 1 mm2 around the site of injection, we found that DHA conjugation performed better than cholesterol conjugation, and having a cleavable linker further improves the editing efficiency (Figure 4d).
In vivo genome editing in adult mouse liver by co-delivery of AAV-expressed effector and tracrRNA and GalNac-conjugated, self-delivering crRNA
Next, we tested whether we could achieve in vivo genome editing through systemic delivery of C20/P.O. complex co-delivered with AAV-expressed effector protein and the tracrRNA, initially in hepatocytes due to the advanced state of GalNac conjugates in clinical applications of oligonucleotides (58, 59, 72, 77). Here, we chose two established mouse targets to test the efficacy of our co-delivery approach: the Pcsk9 gene in wild-type B6 mice (Supplementary Figure 3), and the Fah gene that is mutated in a mouse model of hereditary tyrosinemia type 1 (HT1).
For Pcsk9 editing in adult B6 mice, we tested C20 with either a 14 nt or a 16 nt P.O. having a trivalent GalNac conjugate (Figure 5a) (72). We also included a non-targeting C20 crRNA as well as PBS as negative controls. First, we injected adult mice with AAV to express either SpyCas9-ABE8e and tracrRNA (Figure 5b), or SpyCas9 nuclease and tracrRNA (Figure 5c) through retro-orbital (RO) injection, and then allowed five weeks for effector protein expression. We then injected C20 with and without GalNac-conjugated P.O. via a single RO injection at 80 mg/kg. The editing efficiency was assessed by extracting genomic DNA from mouse liver and performing targeted amplicon deep sequencing. We found low yet significant editing at the target genomic locus by C20 with both lengths of P.O.s, while no editing was observed for the non-targeting control C20-injected mice (Figure 5b–5c).
Next, we tested whether our co-delivery approach can generate therapeutic-relevant editing by testing in the mouse model of HT1. The HT1 mouse model used in this study is the FahPM/PM mouse, which possesses a G-to-A point mutation in the last nucleotide of exon 8 of the Fah gene, which encodes fumarylacetoacetate hydrolase (78, 79). This point mutation generates exon 8 skipping and causes FAH deficiency (Figure 5d). Because FAH catalyzes one step of the tyrosine catabolic pathway, FAH deficiency leads to accumulation of toxic fumarylacetoacetate and succinyl acetoacetate, causing damage in multiple organs (78). The FahPM/PM mouse can be treated with 2-(2-nitro-4-trifluoromethylbenzoyl)-1,3-cyclohexanedione (NTBC), an inhibitor of an enzyme upstream within the tyrosine degradation pathway to prevent toxin accumulation (79). Without such treatment, the mice rapidly lose weight and die. Previously, studies showed that the point mutation in the FahPM/PM mouse could be corrected by SpyCas9-ABE delivered by lipid nanoparticles carrying mRNA and sgRNA, or by plasmid hydrodynamic tail-vein injection (44, 80).
We first injected AAV9 to express SpyCas9-ABE8e and tracrRNA by RO injection, using split inteins to reconstitute the effector as described (81–83). After five weeks, we performed RO injections of C20 with a previously validated spacer sequence targeting the point mutation in the FahPM/PM mouse (44, 80), with either a 14 nt or a 16 nt trivalent GalNac-conjugated P.O., at a single 80 mg/kg dose. The mice were kept on NTBC for two weeks to maintain body weight and allow time for editing to occur. We then sacrificed three mice from each group and extracted liver genomic DNA to measure the editing efficiency by targeted amplicon deep sequencing, as well as detecting FAH-positive hepatocytes via IHC staining using anti-FAH antibodies. For the remaining mouse from each group, we cycled NTBC off and on (7–10 days off followed by 2 days on) for three months to allow FAH-positive hepatocytes to expand, and we monitored body weight to assess functional rescue (Figure 5e).
Before NTBC withdrawal, we observed low yet significant on-target editing in the groups that were co-delivered with both AAV9 vectors and the C20/P.O. guides (Figure 5f). After NTBC withdrawal, the PBS-injected mouse rapidly lost body weight and was humanely sacrificed after the body weight dropped below 80%. The mice treated with AAV9-expressed SpyCas9-ABE8e and tracrRNA and C20/P.O. duplexes gradually gained body weight over time (Figure 5g). The mice were then sacrificed after three months of NTBC cycling, and IHC staining was performed on liver sections using anti-FAH antibodies. We observed the expansion of FAH-positive hepatocytes in the liver tissue treated via AAV9/guide co-delivery (Figure 5h). These data provide an initial indication that systemic delivery of C20 and GalNac-conjugated P.O.s, with AAV-expressed effector protein and tracrRNA, can achieve in vivo genome editing in the liver and provide therapeutic benefits.
The initial editing efficiency we achieved in the liver, though significant, was low. We then sought to improve the efficiency by optimizing the dosing regimen. The ASGPR, which is expressed on the surface of hepatocytes and is responsible for the uptake of GalNac-conjugated oligos (58, 59, 72), has a cell surface recycling time of 10–15 minutes (77, 84, 85). Data from previous studies also showed that due to ASGPR saturation, hepatocytes can only take up limited amounts of GalNac-conjugated molecules after bolus intravenous injection (86). Our initial study injected a single dose of C20 with GalNac-conjugated P.O. at 80 mg/kg, far exceeding the import capacity of available ASGPR (86). We reasoned that instead of a single large dose, dividing the oligos into three consecutive daily RO injections each with one-third of the previous dose (26 mg/kg) may deliver more oligos into the hepatocyte, thus boosting the editing efficiency.
To test this idea, we first RO-injected AAV9 to express SpyCas9-ABE8e and tracrRNA in the B6 mice. Then, after five weeks, we performed three consecutive daily RO injections of C20 targeting the Pcsk9 gene complexed with a 14 nt GalNac-conjugated P.O. at 26 mg/kg. We then harvested the mouse liver genomic DNA and performed targeted amplicon deep sequencing to measure the editing efficiency (Figure 6a). We found that compared to a single dose of 80 mg/kg oligo, three consecutive daily doses at 26 mg/kg significantly improved the editing efficiency (Figure 6b). In addition, we did not observe any sign of toxicity in the liver by redosing, and the oligo-treated mice were in good health, similar to the PBS-injected mice. These data indicate that repeat crRNA dosing is possible and can be well-tolerated, and that further optimization of the dosing regimen promises to provide additional improvements in editing efficiency.
Discussion
Our results serve as a proof-of-concept study for using P.O. to enhance stability, potency, and cellular uptake of crRNAs to achieve self-delivery in vivo. The self-delivering crRNAs can be applied for viral vector co-delivery, potentially allowing multiplexed targeting, especially in tissues that are hard to access (such as the CNS). Tailored co-delivery of the protected crRNA into specific tissues may also provide spatiotemporal control of editing events, reduce off-target effects in unintended organs, and perhaps enable AAV vector inactivation in the future through the co-delivery of vector-targeting guides (Supplementary Figure 4) (25).
Although editing efficiencies initially achievable by this approach are still low, our work comprises (to our knowledge) the first description of in vivo genome editing via self-delivering crRNA. Importantly, our study also shows that knowledge acquired from the rapidly evolving oligonucleotide therapeutic fields (16, 17, 57, 65, 87) can be readily applied to improve the distribution and efficiency of self-delivering crRNA in vivo. Future optimization of P.O.s, including but not limited to additional types of chemical modification, conjugates that allow enhanced or directed cellular uptake and improved pharmacokinetic profiles, and linkers between the P.O. and its conjugates may further enhance potency. Multiple potential directions can be explored that build on these initial proof-of-principle studies. For example, 2’-F residues have been shown to shift the subcellular localization of oligos from the cytoplasm to the nucleus (88), where Cas9 and tracrRNA are localized. Replacing 2’-O-Me residues at specific positions within the crRNA or the P.O. with 2’-F may increase effector complex concentration, thus enhancing editing efficiency. Different conjugates can also be applied such as myristic acid (61, 66) and α-tocopherol (69, 70), which were recently shown to provide improved distribution and efficiency properties to ASOs and siRNAs. Additionally, a recent study with siRNAs indicates that a high-affinity universal oligonucleotide anchor with a high-molecular-weight conjugate can reduce the renal clearance of siRNA and enhance blood and tissue retention (89). This approach may also be combined with the P.O. strategy to further enhance potency. Moreover, future studies focusing on optimizing AAV capsids (90, 91), routes of administration (77, 85, 86, 92–96), and dosing regimens for co-delivered AAV vectors and crRNAs promise to further enhance distribution, uptake, safety, and editing efficiency.
Because P.O.s do not interfere with Cas9 activity and tolerate a wide range of bioconjugates, it serves as a delivery vehicle that will be also valuable for delivering fully modified and stabilized crRNA in vivo. Furthermore, P.O.s offer opportunities to improve pharmacokinetic and pharmacodynamic behaviors for in vivo-delivered, chemically modified crRNA. Our current design of the C20/P.O. complex (a 36 nt crRNA duplexed with a 14 to 16 nt P.O.) mimics asymmetric siRNA designs (a 19 to 21 nt guide strand duplexed with an 11 to 15 nt passenger strand) (16). The single-stranded PS-tails resemble ASO features that serve to enhance cellular uptake. At the same time, the double-stranded region adopts a helical conformation that is relatively consistent across distinct guide sequences, likely facilitating consistency in pharmacokinetic properties. Our P.O. strategy can also be applied to crRNAs with other chemical modification patterns, or to crRNAs for other Cas9 homologs. Finally, the crRNA/P.O. delivery strategy could be extended to transgenic animals or plants that can express the effector and tracrRNA without viral vector co-delivery, advancing genome editing approaches in model organisms and potentially crops or livestock. We anticipate that our study will provide a foundation on which more potent self-delivering crRNA compounds can be engineered for improving the safety and efficacy of in vivo CRISPR genome editing via AAV co-delivery.
Supplementary Material
Acknowledgments
We thank Nadia Amrani for helpful advice on modified crRNAs, Yueying Cao for FahPM/PM mouse colony maintenance, Julia Alterman for helpful discussion, and Socheata Ly for advice on ImageJ analysis. We also thank the UMCMS Viral Vector Core for AAV packaging services, the UMCMS Morphology Core for tissue sectioning and IHC staining, and the UMCMS Flow Cytometry Core for FACS support. We are grateful to all members of the Watts, Khvorova, Wolfe, Gao, Liu, and Sontheimer labs for their valuable discussions, advice, and helpful feedback.
Funding
This work was supported by the National Institutes of Health (NIH) Common Fund Program, Somatic Cell Genome Editing, through an award administered by the National Center for Advancing Translational Sciences (NCATS) [UH3 TR002668 to E.J.S., A.K., J.K.W. and S.A.W.]; an award administered by the National Institute for Allergies and Infectious Diseases (NIAID) [U01 AI142756 to D.R.L.]; a SCGE Collaborative Opportunity Fund award to D.R.L., E.J.S., A.K., J.K.W. and S.A.W.; NIH grants UG3AI150551, R35GM118062, and RM1HG009490, and HHMI. This work was also supported by NIH grant S10 OD028576 to the UMass Chan Flow Cytometry Core, S10 OD020012 to the UMass Chan Nucleic Acid Chemistry Center, and a K99 award [HL163805 to G.A.N.].
Footnotes
Declaration of Competing Interests
E.J.S., J.K.W, A.K., S.A.W., and H.Z. are co-inventors on patent filings related to this work. G.G. is a scientific co-founder, scientific advisor, and equity holder of Voyager Therapeutics, Adrenas Therapeutics, and Aspa Therapeutics. E.J.S. is a co-founder, scientific advisor, and equity holder of Intellia Therapeutics, and a member of the Scientific Advisory Board (S.A.B.) of Tessera Therapeutics. A.K. is a member of the S.A.B. of Prime Medicine. D.R.L is a consultant and equity owner of Prime Medicine, Beam Therapeutics, Pairwise Plants, Nvelop Therapeutics, and Chroma Medicine, companies that use or deliver genome editing or epigenome-modulating agents. S.A.W. is a consultant for Chroma Medicine and serves on the S.A.B. for Graphite Bio.
Data availability
Illumina amplicon deep sequencing data is available at the NCBI Sequencing Read Archive (SRA) database under BioProject ID PRJNA939727. Plasmids first described in this paper will be deposited to Addgene for distribution. All other data are available upon reasonable request.
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Associated Data
This section collects any data citations, data availability statements, or supplementary materials included in this article.
Supplementary Materials
Data Availability Statement
Illumina amplicon deep sequencing data is available at the NCBI Sequencing Read Archive (SRA) database under BioProject ID PRJNA939727. Plasmids first described in this paper will be deposited to Addgene for distribution. All other data are available upon reasonable request.