Here, we present a protocol to genetically modify primary or expanded human natural killer (NK) cells using Cas9 Ribonucleoproteins (Cas9/RNPs). By using this protocol, we generated human NK cells deficient for transforming growth factor–b receptor 2 (TGFBR2) and hypoxanthine phosphoribosyltransferase 1 (HPRT1).
CRISPR/Cas9 technology is accelerating genome engineering in many cell types, but so far, gene delivery and stable gene modification have been challenging in primary NK cells. For example, transgene delivery using lentiviral or retroviral transduction resulted in a limited yield of genetically-engineered NK cells due to substantial procedure-associated NK cell apoptosis. We describe here a DNA-free method for genome editing of human primary and expanded NK cells using Cas9 ribonucleoprotein complexes (Cas9/RNPs). This method allowed efficient knockout of the TGFBR2 and HPRT1 genes in NK cells. RT-PCR data showed a significant decrease in gene expression level, and a cytotoxicity assay of a representative cell product suggested that the RNP-modified NK cells became less sensitive to TGFβ. Genetically modified cells could be expanded post-electroporation by stimulation with irradiated mbIL21-expressing feeder cells.
Cancer immunotherapy has been advanced in recent years. Genetically-modified chimeric antigen receptor (CAR) T cells are an excellent example of engineered immune cells successfully deployed in cancer immunotherapy. These cells were recently approved by the FDA for treatment against CD19 + B cell malignancies, but success has so far been limited to diseases bearing a few targetable antigens, and targeting such limited antigenic repertoires is prone to failure by immune escape. Furthermore, CAR T cells have been focused on the use of autologous T cells because of the risk of graft-versus-host disease caused by allogeneic T cells. In contrast, NK cells are able to kill tumor targets in an antigen-independent manner and do not cause GvHD, which makes them a good candidate for cancer immunotherapy6,7,8,9.
CRISPR/Cas9 technology has been used recently in engineering immune cells, but genetically reprogramming NK cells with plasmids has always been challenging. This has been due to difficulties in transgene delivery in a DNA dependent manner such as lentiviral and retroviral transduction causing substantial procedure-associated NK cell apoptosis and the limited production of genetically engineered NK cells4,9.
Many innate immune cells express high levels of receptors for pathogen-associated molecular patterns such as Retinoic acid-inducible gene I (RIG-I), which enable heightened recognition of foreign DNA. Suppression of these pathways has enabled higher transduction efficiency in NK cells when using DNA-based methods for genetic modification10.
We describe here the method for using a DNA-free genome editing of primary and expanded human NK cells utilizing Cas9 ribonucleoprotein complexes (Cas9/RNPs). Cas9/RNPs is composed of three components, recombinant Cas9 protein complexed with synthetic single-guide RNA comprised of a complexed crRNA and tracerRNA. These Cas9/RNPs are capable of cleaving genomic targets with higher efficiency as compared to foreign DNA-dependent approaches due to their delivery as functional complexes. Additionally, rapid clearance of Cas9/RNPs from the cells may reduce the off-target effects such as induction of apoptosis. Thus, they can be used to generate knock-outs, or knock-ins when combined with DNA for homologous recombination6,7. We showed that electroporation of Cas9/RNPs is an easy and relatively efficient method that overcomes the previous constraints of genetic modification in NK cells.
TGFβ is a major immunosuppressive cytokine, which inhibits the activation and functions of NK cells. It has been suggested that targeting the TGFβ pathway can increase immune cell functions. We targeted the region encoding TGBR2 ectodomain which binds TGFβ11. The representative results show a significant decrease in the level of mRNA expression of this gene and further demonstrate that the modified NK cells become resistant to TGFβ. In addition, the modified cells retain viability and proliferative potential, as they are able to be expanded post-electroporation using irradiated feeder cells. Therefore, the following method is a promising approach to genetically manipulate NK cells for any further clinical or research purposes.
Healthy donor buffy coats were obtained as source material from the Central Ohio Region American Red Cross. This research was determined to be exempt research by the Institutional Review Board of Nationwide Children’s Hospital.
1. Human NK Cell Purification and Expansion
2. gRNA Design and Selection
3. Design Deletion Screening Primers
4. Transduction of Human Primary and Expanded NK Cells
Note: Transduction of Cas9/RNPs elements into NK is done by electroporation using 4D system as follows.
5. Post Transduction
Electroporation Efficiency
To optimize electroporation of Cas9/RNPs, we tested 16 different programs with transduction of GFP non-targeting siRNA and DNA plasmid into NK cells. Flow cytometry assay showed that the EN-138 had the highest percentage of cell viability and transduction efficiency (35% live GFP positive cells) for both particles (Figure 1 & Figure 2). Interestingly, the efficiency of using this program for Cas9/RNPs electroporation was higher as we saw 60% reduction in TGFBR2 mRNA expression level (Figure 5). Additionally, the genetically modified NK cells could be grown and expanded for 30 days and cryopreserved (data not shown).
Mutation assay
Cas9/RNPs containing gRNA2, gRNA1+gRNA2 and gRNA3 had successful TGFBR2 ectodomain gene knockout, but gRNA1 alone did not make any T7E1 detectable indels (Figure 3). Additionally, Figure 4 indicates successfully knockout of Human HPRT1 (hypoxanthine phosphoribosyltransferase 1) in expanded human NK cells using commercially provided gRNAs. According to band densitometry, the proportional indel rates using gRNA1+gRNA2 resulted in 34% band for TGFBR2 modified NK cells, 25% for gRNA3 and 81% for the HPRT gene modified NK cells.
Gene expression level assay
As a representative of our result, Figure 5 shows the effect of Cas9/RNPs (gRNA1+gRNA2) on mRNA production level of TGFBR2 ectodomain, analyzed by RT-PCR. As seen in the graph, the mRNA expression level of the targeted gene significantly decreased.
Cytotoxicity
As seen in Figure 6, after incubating gRNA1+gRNA2, gRNA2 and gRNA3 Cas9/RNPs modified cells with TGFβ1, co-cultured with DAOY cells; the modified cells did not show any significant decrease in their cytotoxicity level in comparison to the control group which had IL-2 in the media overnight. This result demonstrates that the Cas9/RNPs modified cells retain their cytotoxicity function in the presence of TGFβ1 and shows that the modified cells became TGFβ1 resistant.
Figure 1. These figures show the electroporation efficiency of siRNA and plasmid DNA expressing GFP in NK cells using the EN-138 program. As seen here, the NK cell viability is 77.5%, and 35% of live cells were GFP positive. Please click here to view a larger version of this figure.
Figure 2. This figure shows viability and efficiency of another one of the 16 programs (DN-100) tested for electroporation optimization. Please click here to view a larger version of this figure.
Figure 3. Cas9/RNPs-mediated TGFBR2 knockout in expended (a) Primary NK cells (b) measured by T7E1 mutation assay. T7E1 enzyme recognizes and cleaves mismatched DNA. Each small band (blue arrows) represents digested DNA fragments which carry an indel. Please click here to view a larger version of this figure.
Figure 4. Cas9/RNPs – mediated HPRT disruption in expanded NK cells measured by T7E1 mutation assay. Please click here to view a larger version of this figure.
Figure 5. mRNA expression level of TGFBR2 ectodomain in CRISPR modified NK cells introduced by Cas9/RNPs (gRNA1+gRNA2) using RT-PCR. GAPDH was used as an endogenous control gene. The reduction in RNA levels indicates a disruption of TGFBR2 gene (mean ± SEM, P value <0.0001). Please click here to view a larger version of this figure.
Figure 6. a. The cytotoxicity assay using a representative sample of Cas9/RNPs modified (gRNA1+gRNA2, gRNA2, and gRNA3) NK cells shows that overnight incubation of the cells with TGFβ1 does not decrease significantly their ability to lyse DAOY cells. b. When compared with non-modified NK cells, the Cas9/RNP modified NK cells (gRNA2 and gRNA3) are less sensitive to TGFβ1 (mean ± SEM). Please click here to view a larger version of this figure.
gRNA NO. | gRNA sequence | Ordered as synthetic crRNA | |||||
gRNA1 | 5 CCCCTACCATGACTTTATTC 3 | /AltR1/rArGrUrCrArUrGrGrUrArGrGrGrGrArGrCrUrUrGrGrUrUrUrUrArGrArGrCrUrArUrGrCrU/AltR2/ | |||||
gRNA2 | 5 ATTGCACTCATCAGAGCTAC 3 | /AltR1/rArUrUrGrCrArCrUrCrArUrCrArGrArGrCrUrArCrGrUrUrUrUrArGrArGrCrUrArUrGrCrU/AltR2/ | |||||
gRNA3 | 5 AGTCATGGTAGGGGAGCTTG 3 | /AltR1/rArG rUrCrA rUrGrG rUrArGrGrGrG rArGrC rUrUrG rGrUrUrUrUrA rGrArG rCrUrA rUrGrCrU/AltR2/ |
Table 1. Three designed gRNAs to target exon 4 of TGFBR2 ectodomain as synthetic crRNA.
TGFBR 2 ectodomain Primers FWD | 5 GTC TGC TCC AGG TGA TGT TTA T3 |
TGFBR2 ectodomain Primer REV | 5 GGG CCT GAG AAT CTG CAT TTA 3 |
Table 2. Primers used to amplify the TGFBR2 ectodomain gene
Component | Amount (uL) |
200 µM crRNA | 2.2 |
200 µM Tracer RNA | 2.2 |
IDTE Buffer | 5.6 |
Final product | 10 |
Table 3. Form the crRNA:tracerRNA/complex using 200 µM RNAs
Component | Amount (µL) |
PBS | 1 |
crRNA:tracrRNA duplex (from step 4.2) | 2 (200 pmol) |
Alt-R Cas9 endonuclease (61 µM stock) | 2 |
Total volume | 5 ul |
Table 4. For single crRNA:tracrRNA duplex reaction, dilute Cas9 endonuclease to 36 µM.
Component | Amount (µL) |
PBS | 1 |
crRNA:tracrRNA duplex (ex. gRNA1) | 1 (100 pmol) |
crRNA:tracrRNA duplex (ex. gRNA2) | 1 (100 pmol) |
Alt-R Cas9 endonuclease | 2 |
Total volume | 5 µL |
Table 5. For combination transduction of crRNA:tracrRNA duplexes dilute Cas9 endonuclease to 36 µM.
DNA-dependent modification of NK cells has been challenging4,9. We, therefore, introduced directly a synthetically preformed ribonucleoprotein (RNPs) complex and Cas9 protein as purified protein into primary and expanded NK cells8. This method allowed us to eliminate capping, tailing, and other transcriptional and translational processes started by RNA polymerase II, which may cause NK cell apoptosis associated with DNA-dependent transduction methods.
In addition, the method reported here uses purified Cas9 protein complexed as Cas9/RNPs, which are active immediately following electroporation and are degraded quickly, thereby increasing on-target and decreasing off-target effects over current protocols5,6,7,16. Furthermore, optimizing a new electroporation approach to transduce Cas9/RNP with high efficiency is another critical step introduced here, which are applicable to any other genes of interest. This method may be scaled up for modification of larger numbers of NK cells using commercially available larger electroporation cuvettes (data not shown).
In summary, Cas9/RNPs can be used to genetically modify human primary and expanded NK cells for cancer immunotherapy utilizing the above described method. Our results also demonstrated that a successful knockout of the TGFBR2 ectodomain gene leads to these modified NK cells becoming TGFβ1 resistant11.
Combining RNP delivery with a source of template DNA (such as naturally recombinogenic adeno-associated virus (AAV) donor vectors) may enable site-specific gene insertion by homologous recombination3,18,19.
The authors have nothing to disclose.
We acknowledge Brian Tullius for his kind help in editing the manuscript.
RosetteSep™ Human NK Cell Enrichment Cocktail | STEMCELL Technologies | 15065 | The RosetteSep™ Human NK Cell Enrichment Cocktail is designed to isolate NK cells from whole blood by negative selection. |
Ficoll-Paque® PLUS | GE Healthcare – Life Sciences | 17-1440-02 | |
Alt-R® CRISPR-Cas9 tracrRNA | Integrated DNA Technologies | 1072532 | TracrRNA that contains proprietary chemical modifications conferring increased nuclease resistance. Hybridizes to crRNA to activate the Cas9 enzyme |
Alt-R® CRISPR-Cas9 crRNA | Integrated DNA Technologies | Synthetically produced as Alt-R® CRISPR-Cas9 crRNA, based on the sequence of designed gRNA targeting the gene of intrest | |
Alt-R® Genome Editing Detection Kit | Integrated DNA Technologies | 1075931 | Each kit contains T7EI endonuclease, T7EI reaction buffer, and T7EI assay controls. |
Platinum® Taq DNA Polymerase High Fidelity | Invitrogen | 11304-011 | |
4D-Nucleofector™ System | Lonza | AAF-1002B | |
Human recombinant IL-2 Protein | Novartis | 65483-0116-07 | |
P3 Primary Cell 4D-Nucleofector™ X Kit | Lonza | V4XP-3032 | Contains pmaxGFP™ Vector, Nucleofector™ Solution, Supplement, 16-well Nucleocuvette™ Strips |
Non-targeting: Custom siRNA, Standard 0.05 2mol ON-TARGETplus | Dharmacon | CTM-360019 | |
Alt-R® S.p. Cas9 Nuclease 3NLS | Integrated DNA Technologies | 1074181 | Cas9 Nuclease |
DNeasy® Blood & Tissue Handbook | Qiagen | 69504 | |
RNeasy Mini Kit | Qiagen | 74104 | |
Calcein AM | ThermoFisher | C3099 | |
TGFβ | Biolegend | 580706 | |
Alt-R® CRISPR-Cas9 Control Kit, Human | Integrated DNA Technologies | 1072554 | Includes tracrRNA, HPRT positive control crRNA, negative control crRNA#1, HPRT Primer Mix, and Nuclease-Free Duplex Buffer. |
IDTE pH 7.5 (1X TE Solution) | Integrated DNA Technologies | 11-01-02-02 | |
Alt-R® Cas9 Electroporation Enhancer | Integrated DNA Technologies | 1075915 | Cas9 Electroporation Enhancer |