Skip to main content

Thank you for visiting You are using a browser version with limited support for CSS. To obtain the best experience, we recommend you use a more up to date browser (or turn off compatibility mode in Internet Explorer). In the meantime, to ensure continued support, we are displaying the site without styles and JavaScript.

Efficient base editing for multiple genes and loci in pigs using base editors


Cytosine base editors (CBEs) enable programmable C-to-T conversion without DNA double-stranded breaks and homology-directed repair in a variety of organisms, which exhibit great potential for agricultural and biomedical applications. However, all reported cases only involved C-to-T substitution at a single targeted genomic site. Whether C-to-T substitution is effective in multiple sites/loci has not been verified in large animals. Here, by using pigs, an important animal for agriculture and biomedicine, as the subjective animal, we showed that CBEs could efficiently induce C-to-T conversions at multiple sites/loci with the combination of three genes, including DMD, TYR, and LMNA, or RAG1, RAG2, and IL2RG, simultaneously, at the embryonic and cellular levels. CBEs also could disrupt genes (pol gene of porcine endogenous retrovirus) with dozens of copies by introducing multiple premature stop codons. With the CBEs, pigs carrying single gene or multiple gene point mutations were generated through embryo injection or nuclear transfer approach.


Precise point mutation in the genome of an organism has great potential for agricultural and biomedical applications. Traditional methods precisely introduce or correct genetic point mutations by CRISPR-Cas9 and CRISPR-Cpf1 through the homology-directed repair (HDR) pathway requiring DNA double-strand breaks (DSBs) and exogenous donor DNA templates1,2,3,4. However, DSBs could create large deletion, complex genomic rearrangement, and targeted chromosome elimination when targeting several genomic loci simultaneously5,6,7, which might lead to excessive DNA damage and cell death. In addition, HDR occurs infrequently (typically ~0.1–5%)8, especially in non-dividing cells, thus impeding the use of HDR for precise genome editing in many species.

The newly developed base editors (BEs)8,9,10 efficiently enable precise and highly predictable nucleotide substitutions (C-to-T or A-to-G conversion) at targeted genomic loci, independent of DSBs and donor templates. Thus, these BEs have great potential applications for both agriculture and biomedicine. To date, cytosine base editors (CBEs) have been successfully applied in plants (such as Arabidopsis, rice, wheat, and maize)11,12, mammals (such as mice13,14,15,16, rats17, and rabbits18), and human cells19,20,21 and embryos22,23,24. Many traits in agriculture are caused by multiple SNPs, and many genetic diseases in biomedicine arise from point mutations in multiple sites. Therefore, base editing of a genome in multiple sites is necessary to achieve favorable traits in agriculture, to establish human disease animal models, and to treat human hereditary diseases. However, all the reported cases only involved C-to-T substitution at a single targeted genomic site by using a single sgRNA. Whether C-to-T substitution is effective in base gene editing for multiple sites of a genome of large animals has not been verified.

In this study, we test the multiplexed base editing efficiency of BE3 (rAPOBEC1-XTEN-nCas9-UGI) and hA3A-BE3 (hAPOBEC3A-XTEN-nCas9-UGI) in pig, which is an important animal for both agriculture and biomedicine. We first confirm that the BE3 system was able to generate multiplexed base editing efficiently in embryonic and cellular levels. We also realize multiple copy base editing with a single sgRNA for porcine endogenous retrovirus (PERV) in porcine embryos and fibroblasts. Furthermore, with the CBE system, we achieve gene editing in pigs with single gene point mutation as well as multiple gene point mutations through either embryo injection or somatic cell nuclear transfer (SCNT) approach.


Efficient base editing for multiple sites in porcine embryos

To confirm whether base editing for multiple sites can be achieved by BE3 in the genome of porcine embryos (Fig. 1a), we selected six porcine genes, namely, DMD, TYR, LMNA, RAG1, RAG2, and IL2RG, which encode dystrophin, tyrosinase, lamin A/C, RAG1 protein, RAG2 protein, and IL-2 receptor gamma chain, respectively, as the target sites (Fig. 1b). Premature stop codons (Q493STOP and Q28STOP) would be generated by a single C-to-T conversion at the target sites in DMD and TYR, which are expected to result in Duchenne muscular dystrophy (DMD) and albinism, respectively. For LMNA, C-to-T conversion (a synonymous mutation, G608G) at the target site would create a cryptic splice donor site that produces a truncated splicing mutant of lamin A/C protein, termed “progerin”, resulting in Hutchinson-Gilford Progeria Syndrome (HGPS)25. For RAG1, RAG2, and IL2RG, premature stop codons are expected to be generated due to C-to-T conversion. Mutations in RAG1 or RAG2 would result in the complete absence of B and T cells26, and IL2RG mutations lead to the absence or profound depletion of T and natural killer (NK) cells without affecting the number of B cells27. RAG1-, RAG2-, and IL2RG-deficient pigs would lack B cells, T cells, and NK cells (B/T/NK cells). In vitro transcribed DTL (DMD-sgRNA, TYR-sgRNA, and LMNA-sgRNA) or R12I (RAG1-sgRNA, RAG2-sgRNA, and IL2RG-sgRNA) with BE3 mRNAs (150 ng/μL) were co-injected together into 100 porcine parthenogenetically activated (PA) oocytes, which were conveniently available by in vitro matured oocytes derived from the ovary of slaughtered pigs. The injected PA embryos were cultured for 6 days post-parthenogenetic activation until blastocyst formation. The blastocyst rate of embryos injected with BE3 mRNA and DTL or R12I was 24% (24/100) and 25% (25/100) (Fig. 1e), respectively, which is consistent with the blastocyst rate of the embryos injected with water (24%, 24/100), indicating that BE3 and sgRNAs did not affect the early development of porcine embryo. A single blastocyst was lysed individually for genotyping by Sanger sequencing. Targeted point mutations were observed in 18 out of 24 (75%) embryos for DTL and 14 out of 22 (63.6%) embryos for R12I at target sites. Of these screened blastocysts, 12 for DTL (50%, 12/24) and 8 for R12I (36.4%, 8/22) were identified to have C-to-T mutations in three genes (Fig. 1c–e; Supplementary Fig. 1), four for DTL (16.7%, 4/24), and five for R12I (22.7%, 5/22) showed double-gene base editing (one for DMD and TYR, three for DMD and LMNA, one for RAG1 and RAG2, two for RAG1 and IL2RG, and two for RAG2 and IL2RG), two for DTL (8.3%, 2/24) and one for R12I (4.5%, 1/22) showed single-gene base editing (one for TYR, one for LMNA, and one for IL2RG) (Fig. 1e). In addition to the specific conversion of C-to-T mutation, a few C-to-A substitutions were also found at expected positions of TYR-sgRNA (Fig. 1c; Supplementary Fig. 1a). In some embryos, C-to-T conversions occurred not only at positions 4–8 but also at position 13 for TYR-sgRNA, position 11 for LMNA-sgRNA, position 9 for RAG1-sgRNA, position 3 for RAG2-sgRNA, and positions 3, 9, and 10 for IL2RG-sgRNA, which would lead to the corresponding amino acid changes (S30L, S610F, S62F, S2L, V154V, L156L, and Q157STOP, respectively) (Fig. 1c, d; Supplementary Fig. 1a, b).

Fig. 1

The BE3 system can simultaneously induce C-to-T base editing at multiple genes/loci of porcine embryos. a Schematic of BE3-mediated C-to-T base editing. b Target-site sequences of DMD-, TYR-, LMNA-, RAG1-, RAG2-, IL2RG-, and pol-sgRNA. Target sequence (black), protospacer adjacent motif (PAM) region (green), target sites (red), and mutant amino acid (underlined). WT wild-type. c Sanger sequencing results of embryo-4# and 11# injected with DMD-sgRNA, TYR-sgRNA, and LMNA-sgRNA. The red box shows the successful C-to-T substitutions at target sites. d Sanger sequencing results of embryo-3# and 17# injected with RAG1-sgRNA, RAG2-sgRNA, and IL2RG-sgRNA. e Summary of multiple sites base editing by BE3 in porcine embryos. f Schematic of the PERV gene structure. One sgRNA targeting the catalytic region of the PERV pol gene was designed. The codon to be modified is underlined. The targeting sequence is in red and the PAM region is in green. g Representative sequence chromatogram of the target site of the pol gene from injected embryos 6#. Red box shows the successful C-to-T substitutions at target sites. h Nucleotide substitution frequencies mediated by BE3 and pol-sgRNA were measured in the injected embryos 6# by targeted deep sequencing

Recently, a new member of CBEs, hA3A-BE3, has been harnessed for base editing the genomes of mammalian cells and plants with improved efficiency and specificity28,29,30. We also tested multiple base editing capacity of hA3A-BE3 in pig embryos. As in BE3, DTL and R12I were used to evaluate the hA3A-BE3 system in porcine embryos. As shown in Supplementary Fig. 2a–e, 50% embryos for DTL (5/10) and 41.7% embryos for R12I (5/12) harbored C-to-T mutations at target sites of all three genes, which were comparable with those of the BE3 system (50% for DTL and 36.4% for R12I).

Some genes, such as pol gene of porcine endogenous retrovirus, which is a critical safety concern for xenotransplantation of pig organ to human, have multiple copies in the genome31. Induction of stop codons by BE3 could impede virus replication, possibly providing a new strategy to reduce PERV transmission. A sgRNA targeting the highly conserved catalytic center of the pol gene on PERVs was designed (Fig. 1f). Similarly, in vitro transcribed BE3 mRNA and pol-sgRNA were co-injected into the 100 PA embryos. At 6 days after in vitro culture, 20 blastocysts were harvested and genotyped by Sanger sequencing. As shown in Fig. 1g, h, and Supplementary Fig. 3a, b, all embryos harbored C-to-T conversions specifically at position 4 at frequencies ranging from 29.5% to 78.9%. Consequently, Q148STOP amino acid conversions occurred over all embryos. In addition, C-to-G conversion at position 4 was found in all embryos, with efficiencies ranging from 11.8% to 46.8% (Supplementary Fig. 3a, b). These results demonstrated that BE3 can simultaneously mediate the C-to-T conversion of several genes or a single gene with multiple copies with high efficiency in porcine embryos.

Base editing at multiple loci in porcine somatic cells

We next investigated whether BE3 could generate C-to-T conversions in multiple genes or multicopy genes simultaneously in porcine somatic cells. Six sgRNA candidates targeting exons of porcine DMD, TYR, LMNA, RAG1, RAG2, and IL2RG genes were synthesized and cloned into the BbsI-digested U6-sgRNA cloning vector (Fig. 1b). The mixed sgRNAs DTL (DMD-, TYR-, and LMNA-sgRNA) or R12I (RAG1-, RAG2-, and IL2RG-sgRNA) were co-transfected with BE3-expressing vectors into the porcine fetal fibroblasts (PFFs), which were then cultured in 10-cm dishes at a seeding density of 5 cells/cm2 to form single-cell colonies. After 10–14 days of G418 selection, single-cell colonies were obtained and genotyped by Sanger sequencing. Sequencing results are summarized in Supplementary Data 1 and 2. For DTL, 26 single-cell colonies (25.2%, 26/103) showed C-to-T substitution of all three genes (Fig. 2a; Supplementary Fig. 4a), 18 (17.5%, 18/103, three for DMD and TYR, six for TYR and LMNA, and nine for DMD and LMNA) showed double-gene base editing, and 12 (seven for DMD, three for TYR, and two2 for LMNA) showed single-gene base editing (Fig. 2c). For R12I, three single-cell colonies (1.5%, 3/204) with C-to-T substitution of all three genes (Fig. 2b; Supplementary Fig. 4b), 18 (8.8%, 18/204, 15 for RAG1 and RAG2, 1 for RAG1 and IL2RG, and 2 for RAG2 and IL2RG) with double-gene base editing, and 56 (12 for RAG1 and 44 for RAG2) with single-gene base editing were identified (Fig. 2c). Specific C-to-T substitutions occurred within the canonical BE3 editing window (positions 4–8) as expected. As shown in Fig. 2b and Supplementary Fig. 4b, unwanted C-to-T substitutions at position 3 for RAG2-sgRNA and positions 3, 9, and 10 for IL2RG-sgRNA were observed, leading to the corresponding amino acid changes (S2L, V154V, L156L, and Q157STOP, respectively). Furthermore, unwanted C-to-A substitutions at position 8 for RAG2-sgRNA were observed in cell colony R12I-C22, resulting in an aminoacid change (Q4K). Thus, BE3 can efficiently induce C-to-T substitution in three different genes of porcine somatic cells in one step. We also tested the multiple base editing capacity of hA3A-BE3 in porcine cell level. As in BE3, DTL and R12I were used for evaluation of hA3A-BE3 in porcine fibroblasts. Base editing at target sites of all three genes occurred in the genomes of 55% single-cell colonies for DTL (11/20) and 40% for R12I (8/40), which was higher than BE3-mediated multiplex base editing (25.2% for DTL and 1.5% for R12I) (Supplementary Fig. 5a–e).

Fig. 2

BE3-mediated base editing for multiple genes/loci in porcine somatic cells. a, b Sanger sequencing chromatograms of selected single-cell colonies. The codon in the red box indicate expected substitutions at target sites. c Summary of base editing in porcine fibroblasts. d Sanger sequencing results of selected single-cell colonies in the pol gene. e, f Summary of the targeted deep sequencing of on-target site for the pol gene (cell colonies 30# and 87#)

The BE3- and pol-sgRNA-expressing vectors were co-transfected into Bama-PFFs to induce the same premature stop codon into multiple copies of pol gene. Previous reports identified 25 copies of functional PERVs in the Bama-mini pigs32. In this study, we analyzed 155 single-cell-derived colonies by PCR and Sanger sequencing to confirm the C-to-T conversion. Sequencing results showed that 59 colonies (38.1%, 59/155) were confirmed to have C-to-T base editing at position 4 of pol-sgRNA. The copy number of PERV in 40 colonies (25.8%, 40/155) was reduced by more than half (Supplementary Fig. 6c). The 30# and 87# cell colonies (Supplementary Fig. 6a) were further subjected to high-throughput deep sequencing, and the frequencies of base substitutions were calculated. The C-to-T conversions occurred on 84.9% of targeted Colonies for 30# colony and 84.0% for 87# colony (Fig. 2d–f; Supplementary Fig. 6b), indicating that the copy number of PERV reduced by around 85% in both cell colonies. In addition, C-to-G substitutions were observed in 30# and 87# colonies with efficiencies of 2.0% and 2.4%, respectively (Fig. 2d–f; Supplementary Fig. 6b).

Generation of LMNA G608G pig via zygote injection

Although single-cell colonies harboring desired LMNAG608G mutation were effectively obtained (41.7%, 43/103) when using BE3 and LMNA-sgRNA (Fig. 2c), these colonies exhibited premature senescence phenotypes and were unsuitable for use as nuclear donor for SCNT (Supplementary Fig. 7). Therefore, we investigated whether the LMNAG608G mutation pig model could be generated by using embryo injection of base editors. In vitro-transcribed BE3 mRNA and LMNA-sgRNA were co-injected into the cytoplasm of one-cell stage zygotes from four Large White sows. Forty-six injected porcine zygotes were then transferred into two surrogate Large White sows. A total of nine piglets (five male and four female, one stillborn and eight liveborn) were born at term from one pregnant surrogate (Fig. 3a, b). Genotype analysis showed that eight piglets (88.9%, 8/9) harbored C-to-T mutation (Fig. 3c, d; Supplementary Fig. 8). For 357-2, 357-3, 357-4, and 357-7 (44.4%, 4/9), undesired indels (1 bp or 12 bp deletion) were also found at target sites with the efficiency of 44%, 15%, 3%, and 28%, respectively (Fig. 3c; Supplementary Fig. 8). Targeted deep sequencing results showed that 13%-100% site-specific C-to-T mutations were achieved at LMNA c.1824C site for piglet 357-1, 357-2, 357-3, 357-5, 357-6, 357-7, 357-8, and 357-9 (Fig. 3c–e). Notably, piglet 357-8 harbored homozygous c.1824C-to-T mutations, but unfortunately died within 2 days (Fig. 3c–e). The heart, liver, spleen, lung, and kidney of piglet 357-8 were collected, and Sanger sequencing results showed that homozygous c.1824C-to- T mutations were observed in all these tissues (Supplementary Fig. 9). These results showed that pig models carrying C-to-T substitutions can be generated efficiently by direct injection of zygotes with BE3 system.

Fig. 3

Generation of LMNAG608G pig via direct zygote injection. a Summary of generation of LMNAG608G mutant pigs by using direct zygote injection of the BE3 system. b Representative photograph of newborn LMNAG608G piglets. c Summary of genotypes of nine newborn piglets from targeted deep sequencing. C-to-T substitutions and indels are shown in red. d Sanger sequencing chromatograms of WT, 357-5, and 357-8 piglets. The red arrow indicates the target sites with C-to-T conversions. e The efficiencies of C-to-T and non C-to-T substitutions in all Cs in LMNA-sgRNA were detected by targeted deep sequencing. f The expression of WT and truncated LMNA was detected by RT-PCR. Truncated LMNA mRNA is translated to progerin, which can result in HGPS. g Sanger sequencing chromatograms of RT-PCR products of WT and LMNAG608G piglets. h Western blot was used to detect the expression of lamin A/C and progerin protein in the heart, liver, spleen, lung, kidney, and ear tissues of WT and 357-8 piglets. Source data are provided as a Source Data file

Examining the potential off-target (POT) effects is important to evaluate a new genome-editing tool. We computationally predicted POT sites using Cas-OFFinder ( Sanger sequencing analysis of seven POT sites showed that one off-target mutation (OT3) was found in eight (88.9%, 8/9) base-edited piglets (Supplementary Fig. 10), which are consistent with recent reports showing that CBEs can induce genome-wide off-target mutations in mammals34 and plants35.

To test whether LMNAG608G mutation could cause aberrant mRNA splicing, total RNAs from the ear tissues were extracted. RT-PCR and Sanger sequencing analysis showed that ear tissues from all LMNAG608G piglets expressed a smaller mRNA with a 150-nucleotide deletion (Fig. 3f, g). Western blot analysis of the heart, liver, spleen, lung, and kidney tissues of piglet 357-8 demonstrated the presence of progerin, a truncated splicing mutant of lamin A, in the tissues of LMNAG608G mutation piglets but not in wild-type (WT) tissues (Fig. 3h). These results demonstrated that LMNAG608G mutation piglets, consistent with human HGPS patients, can express progerin mRNA and protein.

Generation of base editing pigs via SCNT

DMD heterozygous female pig could grow normally. Mating DMD−/+ female pigs with DMD+/Y could generate DMD knockout pig model with symptoms of patients1. For this purpose, seven cell colonies (DMD-C3, 17, 36, 59, 67, 87, and 92) with C-to-T conversion in one allele and wild-type or 18 -bp deletion in the other allele were selected as nuclear donors for SCNT (Supplementary Fig. 11). A total of 400 cloned embryos were constructed and surgically transferred into two surrogates (T62-1, 51-1), and one surrogate (T62-1) was pregnant (Fig. 4a). After ~114 days of gestation, one live piglet (T62-1-1) was born (Fig. 4b). We amplified the DMD-sgRNA-targeted site from the genomic DNA of a newborn piglet by PCR, and then obtained Sanger-sequenced PCR products. Sequencing results showed that the cloned piglet harbored a C-to-T mutation in one allele and 18 -bp deletion in the other allele (Fig. 4c; Supplementary Fig. 12a, b). The cloned piglet grew healthy, and is more than 1-year old now.

Fig. 4

Base editing pigs were generated by SCNT. a Summary of SCNT results for generation of DMD mutant and RAG1, RAG2, and IL2RG mutant cloned pigs. b Image of DMD heterozygous female pigs produced in this study. c Genotype of DMD heterozygous female piglets. d Representative images of five cloned piglets with C-to-T conversions in RAG1, RAG2, and IL2RG genes. e Sanger sequencing chromatograms of DNA from wild-type and five cloned piglets. The red arrow indicates the substituted nucleotides

Four single-cell colonies (R12I-C22, C29, C56, and C108) with RAG1, RAG2, and IL2RG mutations were selected for SCNT to confirm whether live pigs could be achieved through multiple base editing (Fig. 2b; Supplementary Fig. 4b). A total of 1338 reconstructed embryos were transferred into six surrogate pigs (A624, A625, A630, A631, A632, and A633). Of these surrogate animals, two became pregnant (A632, A633), yielding two males (A632-1 and A632-2) and three females (A632-3, A633-1, and A633-2) piglets that were naturally delivered after 114 days of gestation (Fig. 4a, d). Genotype analysis showed that A632-1 contained CAA > TAA mutations in both alleles of the RAG1 gene, CAG > TAG mutation in one allele and CAG > AAG mutation in the other allele of the RAG2 gene, and CAG > TAG in both alleles of the IL2RG gene, which is consistent with the genotype of R12I-C22 cell colony. For A632-2 piglets, a premature stop codon was generated in one allele of the RAG1 gene, while complete CAG > TAG conversions were achieved for the RAG2 and IL2RG genes. This genotype was the same as that in R12I-C108 cell colony. The genotype of A633-1 and A633-2 piglets was CAG > TAG mutation in only one allele of RAG2 and IL2RG genes, and no mutation was found for the RAG1 gene. These two piglets originated from the SCNT of R12I-C59 cell colony. For A632-3, only a premature stop codon was achieved in one allele of the IL2RG gene, corresponding to the genotype of donor R12I-C29 cell colony (Fig. 4e; Supplementary Fig. 13).

We identified 21, 7, 8, and 10 POT sites with 2–3 nucleotide mismatches for DMD-sgRNA, RAG1-sgRNA, RAG2-sgRNA, and IL2RG-sgRNA, respectively. Sanger sequencing analysis of all PCR products indicated that no base substitution was detected at any of these POT sites of all cloned piglets (Supplementary Figs 14,  15a–c).

All cloned RAG1, RAG2, and IL2RG mutated piglets were raised in the conventional housing environment and piglets with immunodeficiency presented health issues. Consequently, piglets carrying homozygous RAG1, RAG2, or IL2RG mutations (A632-2, A632-1), which looked normal and strong upon birth, died 12 and 49 days after birth, respectively, due to infection in the lung (Fig. 5a; Supplementary Fig. 16). Cloned piglets carrying heterozygous RAG2 and IL2RG mutations also died 41 and 75 days after birth due to the same reason. By contrast, piglets with only IL2RG heterozygous mutations (A632-3) grew normally and survived until they reached sexual maturity. Dead RAG1, RAG2, and IL2RG mutated piglets and killed age-matched WT piglets were autopsied immediately. The results showed that mutated piglets had undetectable or severely hypoplastic thymuses compared with age-matched wild-type piglets (Fig. 5b). Moreover, the spleens of the A632-1, A632-2, A633-1, and A633-2 piglets were smaller and thinner than those of the WT piglets (Fig. 5c). The thymuses and spleens were fixed and then subjected to hematoxylin–eosin (H&E) staining. In the thymuses of mutated piglets, the thymic lobules were atrophied and very few medulla-like areas were detected, whereas thymic lobules were clearly found in age-matched WT piglets (Fig. 5d). The white pulp was almost undetectable and showed hypoplastic lymphoid aggregations in the spleens of the mutated piglets, but not in the spleens of the WT piglets (Fig. 5e).

Fig. 5

Phenotype of RAG1, RAG2, and IL2RG mutant piglets. a Survival curve for the five cloned piglets. b, c The hymus (b) and spleen (c) of piglets with base editing at RAG1, RAG2, and IL2RG genes were evidently smaller than those of age-matched WT piglets. d, e H&E staining results of the thymus (d) and spleen (e) of A632-2 and age-matched WT piglets. Scale bar, 20 μm

We detected whether RAG1/2 and ILR2G knockout pigs lack mature B, T, and NK lymphocytes. Cells from the peripheral blood, spleen, and bone marrow were collected. Quantitative RT-PCR (qRT-PCR) analysis showed that IL2RG, T-cell surface markers CD4 and CD8, and B-cell surface marker CD19 were drastically reduced in the peripheral blood of two IL2RG−/Y (A632-1 and A632-2) and two IL2RG+/− (A633-1 and A633-2) piglets, but no expression changes were found in the A632-3 piglet (Fig. 6a). This result may be caused by the X chromosome inactivation of the IL2RG gene in female mammals. Sanger sequencing of the RT-PCR products of IL2RG showed that only mutant IL2RG was expressed in the A633-1 and A633-2 piglets, which caused spleen and thymus hypoplasia and immunodeficiency (Supplementary Fig. 17). The collected peripheral blood cells were then subjected to flow-cytometric analysis. After staining with CD3 antibodies, almost no CD3+ populations were detected in the peripheral blood of A632-1, A632-2, A633-1, and A633-2 (2.97%, 1.17%, 3.53, and 2.75%, respectively), confirming the lack of mature T cells (Fig. 6b). However, 31.2% and 55.9% CD3+ cells were harbored in the corresponding WT and A6332-3 piglets. Furthermore, IgM expression was detected to determine the status of B cells by FACS. IgM+ cells were almost undetectable in the PB of A632-1, A633-1, and A633-2 (0, 0.13%, and 0.01%, respectively), whereas the ratios of 8.32% and 3.30% were observed in the WT and A632-3 counterparts, respectively (Fig. 6c). After staining with CD3 and CD8 antibodies, we almost failed to detect CD3+CD8+ cells in A632-1, A632-2, A633-1, and A633-2 (0.95%, 0.50%, 0.34%, and 0.63%, respectively), but the ratios of 2.39% and 7.67% were found in WT and A632-3 piglets, respectively. These results indicated the absence of NK cells in our obtained immunodeficient piglets (Fig. 6d).

Fig. 6

Immunocytes and V(D)J rearrangement analysis of RAG1, RAG2, and IL2RG mutant piglets. a qRT-PCR analysis of IL2RG, CD4, CD8, and CD19 expression in peripheral blood of RAG1, RAG2, and IL2RG mutant piglets. bd FACS analysis of mature B (b), T (c), NK (d) cells from the peripheral blood. Cells were stained with antibodies of anti-CD3, IgM CD8 to detect mature B (b), T (c), and NK (d) cells. e, f TCR-β gene rearrangement analysis in the peripheral blood and thymus. g, h, and i IgH gene rearrangement analysis in the peripheral blood (g), spleen (h), and bone marrow (i). Source data are provided as a Source Data file

V(D)J rearrangement is the unique mechanism of genetic recombination that occurs only in developing lymphocytes during the early stages of T- and B-cell maturation. We further analyzed whether or not V(D)J rearrangements of TCR and BCR had been blocked by the disruption of RAG1 and RAG2 genes. V(D)J rearrangements in the T-cell receptor β chain (TCRβ) locus were detected in the thymus and PB by PCR. PCR results showed no rearrangements at the TCRβ locus in the thymus and PB of the RAG1−/− (A632-1) and RAG2−/− (A632-2) piglets (Fig. 6e, f). For BCR, we selected the IgH locus to detect V(D)J rearrangements in the spleen, peripheral blood, and bone marrow. Similarly, the V(D)J rearrangements of the IgH locus were not detected in the RAG1/2 knockout pigs, By contrast, V(D)J rearrangements at the TCRβ and IgH loci were observed in the WT control and A632-2 piglet (Fig. 6g–i). For the A633-1 and A633-2 piglets, V(D)J rearrangements dramatically decreased and became almost undetectable in the thymus, which may be caused by abnormal lymphocyte development due to IL2RG mutation.


BE3-mediated C-to-T substitution in the codons of open-reading frames can potentially cause amino acid substitutions (missense mutations), aberrant splicing or conversion of CAA, CAG, CGA, and TGG codons into stop codons (nonsense mutations)36,37. Induction of stop codons, the most frequent events resulting from C-to-T substitutions, as well as aberrant splicing, can induce degradation of mRNA transcripts by nonsense-mediated decay or the synthesis of truncated proteins, thus enabling gene disruption. In this work, among the seven genes tested, six genes, namely, DMD, TYR, RAG1, RAG2, IL2RG, and pol, could be induced a premature stop codon. By contrast, induction of an aberrant splicing mutation was the better choice for the other gene (LMNA).

Gene editing in animals could be realized d by co-injection of Cas9 mRNA and sgRNA into one-cell stage embryos. Therefore, we first tested efficiency of the BE3 system and hA3A-BE3 system for multiple base editing in embryo level. A combination of three functionally unrelated genes (DMD, TYR, and LMNA), and a combination of three immune-related genes (RAG1, RAG2, and IL2RG) were used for the respective experiments. Our results showed that, in embryo level, both BE3 system and hA3A-BE3 system were able to generate multiple base editing with high efficiency. Approximately 40–50% embryos contained C-to-T conversions in three genes simultaneously. The other blastocysts could contain cells with one or two gene mutations in some embryos. C-to-T conversions occurred not only at positions 4–8 but also at other positions, such as 9, 10, 11, and 13, which would lead to unwanted corresponding amino acid changes. In addition to the specific conversion of C-to-T mutation, undesired mutations such as C-to-A substitutions (TYR-sgRNA) and indels (1 -bp or 12 -bp deletion for LMNA gene, and 18 -bp deletion for DMD gene) were also found at expected positions. These unwanted mutations had been also reported in other organisms and probably were caused by deamination and subsequent base-excision repair during the C-to-T conversion21.

When using embryo injection to generate gene editing animals, the event of C-to-T conversion may happen in a cell of two or more cell-stage embryos. Thus, many of the resulting founder animals were chimeric ones mixed with mutant and non-mutant tissues, or mixed with homozygous cells and heterozygous cells. To acquire the animals with a pure pattern of mutation, one or two more rounds of further breeding have to be employed for selection among the offspring, which is expensive and time consuming. For multiple base editing, occurrence of the undesired mutations in founders would increase the complexity of the chimeric issues. Therefore, embryo injection is unsuitable for generating multiple-base editing large animals, such as pigs, with long gestation term and sex maturation time. However, when generating a single-base editing animal, for some genes, for instance, (e.g., LMNA gene, an aging-related gene, with special functions), embryo injection could be a better choice. Mutations of LMNA gene could cause premature aging syndromes. When we putatively established porcine fibroblast line-harboring LMNAG608G mutation, the cells also exhibited premature senescence phenotypes in vitro, and were unsuitable for use as nuclear donors for SCNT. Therefore, we applied embryo injection of base editors to establish a LMNAG608G mutation pig model. HGPS pig models carrying a c.1824C-to-T point mutation were successfully generated via zygotes injection, indicating that pig models carrying C-to-T substitutions can be generated by direct zygote injection of BE3, thus providing an appropriate model for preclinical study of aging.

Gene targeting of large animals can be achieved through combination of gene targeting of somatic cells with somatic cell nuclear transfer1,2,38. In vitro screening of gene-edited fibroblasts with desired mutations prior to SCNT could circumvent several problems, such as chimerism and unwanted mutations, which are commonly found in embryo injection approach. In the proposed approach, given that the pig cloning technology has been well established, the most elusive issue for the generation of gene editing animal is to create mutant cells that can be used as donor nuclei. Therefore, we tested the multiple base editing efficiency of BE3 and hA3A-BE3 in porcine somatic cells. Our results showed that, both BE3 and hA3A-BE3 could be applied for efficient base editing in three genes simultaneously. Unlike that in embryo level, in which hA3A-BE3 and BE3 had similar efficiency, the efficiency of hA3A-BE3-mediated multiplex base editing was higher than that of BE3 in porcine cell level. Although as in the embryo level, BE3 and hA3A-BE3 systems could also result in cells with one or two gene mutations and unwanted mutations, such as undesired non-C-to-T substitutions and indels in some cell colonies. The cell lines with desired mutations can then be selected by genotyping to obtain cloned pigs with favorable phenotypes. The effectiveness of this approach was validated by the generation of pigs with point mutations in one and three genes. We first made a DMD pig model with C-to-T conversion of a single gene (DMD gene) through the BE3 system combining with SCNT approach. DMD is an X-linked recessive hereditary disease, and the average life expectancy of patients with this disorder is 26 years old39. Previously reported DMD−/− or DMD−/Y pigs made by deletion of a fragment through the CRISPR-Cpf1 system could not survive beyond 3 months1. Thus, we chose female cell colonies with DMD−/+ mutation of C-to-T conversion to generate DMD heterozygous female pigs, which could survive more than 1 year and could be used to mate with DMD+/Y pigs to achieve many F1 pig models with DMD phenotypes for biomedicine study. The application of the BE3 system in generation of multiple base editing animal was validated by choosing the mutant cells with C-to-T conversions of three functionally related genes RAG1, RAG2, and IL2RG for SCNT. We successfully achieved immunodeficient pigs lacking B cells, T cells, and NK cells, which are consistent with the SCID pigs made by deletion of fragments with other gene editing technologies40,41,42.

The risk of cross-species transmission of PERVs has impeded the clinical application of xenotransplantation from pig human. Previously, PERVs are inactivated in a porcine primary cell line by using CRISPR-Cas931,32. Here, we proved that induction of stop codons can also disrupt genes with dozens of copies of pol gene on PERVs in the porcine genome. CRISPR-Cas9-mediated DSBs are deleterious for cell growth. To support clonal expansion of 100% PERV-inactivated cells, p53 inhibitor is added to mitigate the stress from multiplex DNA damage during multiplexable genome engineering. By using the BE3 system, instead of DSBs, stop codons were generated, thereby avoiding DNA damage and maintaining normal growth of mutant cells, thus, potentially facilitating disruption genes with multiple copies. In this study, we found that the copy number of pol gene could be substantially reduced in both embryonic and cellular levels. Deep-sequencing results showed that about 85% copies of pol genes were converted from C to T, indicating that CBE could be used to generate PERV-inactivated pigs.

Off-targeting issue has been a safety concern for gene editing. Recent reports showed that BE3, but not ABE, could induce genome-wide de novo single-nucleotide variants (SNVs) in mice34 and rice35. We only detected one off-target mutation (OT3 for LMNA-sgRNA) of 53 POTs (7 for LMNA-sgRNA, 21 for DMD-sgRNA, 7 for RAG1-sgRNA, 8 for RAG2-sgRNA, and 10 for IL2RG-sgRNA) with PCR followed by Sanger sequencing. The status of genome-wide C-to-T type of SNVs beyond POTs of base-edited pigs achieved in this reports was not verified by whole-genome sequencing. Given that most of the survived base-edited pigs are growing normally, we speculate that the de novo SNVs may not cause fatal phenotypes.

In summary, the CBE system (BE3 and hA3A-BE3) can be used to generate multiplex point mutations efficiently at the cellular and embryonic levels simultaneously. Single and multiple gene point mutations could be introduced into large animals, such as pigs, through embryo injection or nuclear transfer approach. The application of the CBE system should promote the generation of animal models harboring various point mutations or for gene therapy of genetic diseases with multiplex point mutations.



Bama miniature pigs and Large White pigs were maintained at the large animal facility of Guangzhou Institute of Biomedicine and Health, Chinese Academy of Sciences. The protocols for the use of pigs were approved by the Institutional Animal Care and Use Committees at Guangzhou Institute of Biomedicine and Health Chinese Academy of Sciences (Animal Welfare Assurance #A5748-01).

Vector construction

BE3 fragments were synthesized by Guangzhou IGE Biotechnology Ltd. The fragments were then cloned into the pCS2 vector with the SP6 promoter and into the pCDNA3.1 ( + ) vector with the CMV promoter. The obtained vectors were named as pCS2-BE3 and pCDNA3.1-BE3. pCMV-hA3A-BE3 vector (#113410) and U6-sgRNA cloning vector (#48962) were purchased from Addgene. pCS2-hA3A-BE3 vector was constructed by ligating linearized pCS2 vector and hA3A-BE3 fragment. DMD-sgRNA, TYR-sgRNA, LMNA-sgRNA, pol-sgRNA, RAG1-sgRNA, RAG2-sgRNA, and IL2RG-sgRNA were designed following the G-N19-NGG rule. Two complementary oligonucleotides of sgRNAs were synthesized and then annealed to double-stranded DNAs. The annealed products were then cloned into the BbsI-digested U6-sgRNA cloning vector and obtained sgRNA-expressing plasmid. The primers used above are listed in Supplementary Data 3.

Production of mRNA and sgRNA

The pCS2-BE3 and pCS2-hA3A-BE3 vectors were linearized by the restriction endonuclease Not I, which were used as the BE3 and hA3A-BE3 mRNA template. The BE3 and hA3A-BE3 mRNAs were synthesized using mMESSAGE mMACHINE™ SP6 Transcription Kit (Thermo Fisher Scientific, AM1340) and purified with RNeasy MiniElute Cleanup kit (Qiagen) in accordance with the manufacturer’s instructions. Templates for sgRNA in vitro transcription were amplified from the constructed U6-sgRNA cloning vectors and then transcribed using HiScribe™ T7 Quick High Yield RNA Synthesis Kit (New England Biolabs). The in vitro-transcribed sgRNAs were purified with miRNeasy Mini Kit (Qiagen) following the manufacturer’s instructions. The primers used for amplifying sgRNAs are listed in Supplementary Data 3.

Pig embryo injection

For pigs, zygotes from Large White pigs were collected after insemination and transferred into manipulation medium. Given that the porcine oocytes are easily available from a local slaughterhouse, in vitro-activated porcine parthenogenetic embryos were used to evaluate the editing efficiency and viability of pig embryos after injection RNA of the CBE system. Porcine oocyte collection, in vitro maturation, and parthenogenetic activation were conducted as reported in our previous studies43,44. In brief, a mixture of BE3 or hA3A-BE3 mRNAs (150 ng/μL) and sgRNAs (50 ng/μL for each sgRNA) was microinjected into the cytoplasm of one-cell stage porcine zygotes and porcine PA embryos. After 6-day in vitro culture, blastocysts of pigs were collected for genotyping by PCR and Sanger sequencing.

PFFs culture and transfection

PFFs were isolated from 35-day-old fetuses of Bama miniature pigs. After removing heads, tails, limbs and viscera, the remaining fetuses were digested by 0.5 mg/mL collagenase IV for 2.5 h at 38 ℃. Isolated PFFs were cultured in the PFF culture medium (Dulbecco’s modified Eagle’s medium (DMEM, HyClone) supplemented with 15% fetal bovine serum (FBS, Gibco), 1% nonessential amino acids (NEAA, Gibco), 2 mM GlutaMAX (Gibco), 1 mM sodium pyruvate (Gibco), and 2% penicillin–streptomycin (HyClone)) for 12 h and then frozen in cell freezing medium (90% FBS and 10% dimethyl sulfoxide).

A day before transfection, PFFs were thawed and cultured in 10 -cm dishes to subconfluence. Then, ~1 × 106 PFFs were electroporated with pCDNA3.1-BE3 or pCMV-hA3A-BE3 (10 μg), and sgRNA-expressing vectors (3 μg of each sgRNA) at 1350 V, 30 ms, 1 pulse using the NeonTM transfection system (Life technology). The electroporated cells were recovered for 24 h, and then divided into 20 10 -cm culture dishes. After 10-day G418 selection, individual cell colonies were selected and cultured in 24-well plates. When the confluence reached 90%, the cell colonies were sub-cultured in 12-well plates, and 20% of each cell colony was collected and lysed individually in 10 μL of lysis buffer (0.45% NP-40 plus 0.6% Proteinase K) for 60 min at 56 ℃, and then for 10 min at 95 ℃. The lysate was then used as a template for PCR. The corresponding primers are listed in Supplementary Data 3. The PCR products were further sequenced to identify point mutations. Some PCR products were subjected to sub-clone into the pMD18-T vector (Takara) and then sequenced to determine the exact point mutation patterns and mutation efficiency. Cell colonies with expected mutations were expanded and then cryopreserved in cell freezing medium (90% FBS and 10% dimethyl sulfoxide) for future use.

SCNT and production of mutant pigs

Before SCNT, the cryopreserved cell colonies were thawed and cultured in a 24-well plate. Porcine oocyte collection, in vitro maturation, and SCNT were performed as our previous reports43,44. Briefly, the selected cumulus oocyte complexes were cultured in maturation medium for 42–44 h at 39 ℃ in an incubator containing 5% CO2. Matured oocytes were then enucleated and donor cells were injected into the perivitelline space of the oocytes. After injection, fusion and activation were performed using an electro-fusion instrument in accordance with the manufacturer’s instructions. The reconstructed embryos were then cultured overnight and surgically transferred to the oviducts of the surrogates. After 114 days of gestation, the cloned piglets were delivered through natural birth.

Genomic DNA extraction and genotyping

Genomic DNAs were extracted from the ear tissues of the newborn animals by using TIANamp Genomic DNA Kit (TIANGEN) and then subjected to targeted Sanger sequencing and deep sequencing. The primers used for animal genotyping were the same as those used for cell- and embryo-level genotyping.

H&E staining

The thymus and spleen tissues obtained from WT and RAG1, RAG2, and IL2RG mutant pigs were fixed in 4% paraformaldehyde for 2 days. The fixed tissues were embedded in paraffin wax and cross-sectioned at 3 μM using a vibratome for H&E staining. The slides were deparaffinized with xylene and subsequently rehydrated with 100%, 90%, 80%, 70%, and 50% alcohol, followed by H2O. Finally, the rehydrated slides were stained with H&E and viewed under a fluorescence inversion microscope.

RT-PCR and qRT-PCR analysis

The total RNAs were extracted from the ear tissues of WT and LMNAG608G piglets, and the thymus and spleens of WT and RAG1, RAG2, and IL2RG mutant piglets by using TRIzol Reagent (Life technologies) in accordance with the supplier’s manual. The total RNAs (5 μg) were used to synthesize cDNAs by using ReverTra Ace (Toyobo) and oligo-dT (Takara). For RAG1, RAG2, and IL2RG mutant piglets, transcript levels of CD4, CD8, CD19, and IL2RG were evaluated by qRT-PCR using the CFX96 real-time system (BIO-RAD) with SYBR Green Supermix (172-5274, BIO-RAD). For LMNAG608G piglets, RT-PCR was performed to detect the expression of progerin. The primers used for RT-PCR and qRT-PCR are listed in Supplementary Data 3.

Flow-cytometry analysis

Peripheral blood mononuclear cells were isolated from whole blood of RAG1, RAG2, and IL2RG mutant piglets and age-matched control piglets. Red blood cells were eliminated by using ACK lysis buffer (Leagene). To identify porcine CD3+ T, IgM+ B, and CD3-CD8+ NK cells, we used mouse anti-pig CD3 (BD, 561476, 1:200), CD8 (BD, 559584, 1:200), and goat anti-pig IgM (AbD, AAI39F, 1:200). Samples were analyzed using an Accuri C6 flow cytometer (Accuri Cytometers, Ann Arbor, MI).

PCR analysis to identify V(D)J recombination

DNA samples were extracted from the peripheral blood, spleen, thymus and born marrow of RAG1, RAG2, and IL2RG mutant piglets and age-matched control piglets. The primers for identifying V(D)J recombination are shown in Supplementary Data 3. TCR-β recombination and IgH genes were analyzed by PCR using 2 × SuperStar PCR Mix (GenStar). We used the D1J1-F, D1J1-R, FR1, and JF primers to identify the rearranged of TCR-β and IgH. The thermal cycler parameters were as follows: 95 ℃ for 5 min; 35 cycles of 98 ℃ for 15 s, 68 ℃ for 30 s, and 72 ℃ for 2 min; and a final step at 72 ℃ for 5 min.

Off-target analysis

The POT sites for each sgRNA were predicted to analyze site-specific edits by the BE3 system according to an online design tool ( allowing for un-gapped alignment with up to three mismatches in the sgRNA target sequence. All POTs were amplified by PCR and then subjected to Sanger sequencing to confirm the off-target effects, respectively. The primers for amplifying the off-target sites are listed in Supplementary Data 3.

Reporting summary

Further information on research design is available in the Nature Research Reporting Summary linked to this article.

Data availability

Previously constructed plasmids are available from Addgene under ID numbers 113410 and 48962. All deep-sequencing data from this study has been deposited at NCBI Sequence Read Archive (SRA) under accession numbers SRR8776264, SRR8776265, and SRR8776266. The source data underlying Figs 3f, 3h, and 6a, 6e–i are provided as a Source Data file. All relevant data supporting the findings of this study are represented within the article or available from the corresponding authors upon reasonable request.


  1. 1.

    Wu, H. et al. Engineering CRISPR-Cpf1 with tRNA promotes genome editing capability in mammalian systems. Cell Mol. Life Sci.: CMLS, (2018).

    CAS  Article  Google Scholar 

  2. 2.

    Yang, Y. et al. Genetically humanized pigs exclusively expressing human insulin are generated through custom endonuclease-mediated seamless engineering. J. Mol. Cell Biol. 8, 174–177 (2016).

    Article  Google Scholar 

  3. 3.

    Yang, L. et al. Optimization of scarless human stem cell genome editing. Nucleic Acids Res 41, 9049–9061 (2013).

    CAS  Article  Google Scholar 

  4. 4.

    Yin, H. et al. Genome editing with Cas9 in adult mice corrects a disease mutation and phenotype. Nat. Biotechnol. 32, 551–553 (2014).

    CAS  Article  Google Scholar 

  5. 5.

    Ihry, R. J. et al. p53 inhibits CRISPR-Cas9 engineering in human pluripotent stem cells. Nat. Med. 24, 939–946 (2018).

    CAS  Article  Google Scholar 

  6. 6.

    Haapaniemi, E., Botla, S., Persson, J., Schmierer, B. & Taipale, J. CRISPR-Cas9 genome editing induces a p53-mediated DNA damage response. Nature Med., (2018).

    CAS  Article  Google Scholar 

  7. 7.

    Kosicki, M., Tomberg, K. & Bradley, A. Repair of double-strand breaks induced by CRISPR-Cas9 leads to large deletions and complex rearrangements. Nat Biotechnol., (2018).

    CAS  Article  Google Scholar 

  8. 8.

    Komor, A. C., Kim, Y. B., Packer, M. S., Zuris, J. A. & Liu, D. R. Programmable editing of a target base in genomic DNA without double-stranded DNA cleavage. Nature 533, 420–+ (2016).

    ADS  CAS  Article  Google Scholar 

  9. 9.

    Nishida, K. et al. Targeted nucleotide editing using hybrid prokaryotic and vertebrate adaptive immune systems. Science 353, 8 (2016).

    Article  Google Scholar 

  10. 10.

    Gaudelli, N. M. et al. Programmable base editing of A.T to G.C in genomic DNA without DNA cleavage. Nature 551, 464–+ (2017).

    ADS  CAS  Article  Google Scholar 

  11. 11.

    Lu, Y. M. & Zhu, J. K. Precise editing of a target base in the rice genome using a modified CRISPR-Cas9 system. Mol. Plant. 10, 523–525 (2017).

    CAS  Article  Google Scholar 

  12. 12.

    Zong, Y. et al. Precise base editing in rice, wheat and maize with a Cas9-cytidine deaminase fusion. Nat. Biotechnol. 35, 438–+ (2017).

    CAS  Article  Google Scholar 

  13. 13.

    Kim, K. et al. Highly efficient RNA-guided base editing in mouse embryos. Nat. Biotechnol. 35, 435–+ (2017).

    CAS  Article  Google Scholar 

  14. 14.

    Liang, P. P. et al. Effective gene editing by high-fidelity base editor 2 in mouse zygotes. Protein Cell 8, 601–611 (2017).

    CAS  Article  Google Scholar 

  15. 15.

    Liu, Z. et al. Efficient generation of mouse models of human diseases via ABE- and BE-mediated base editing. Nat. Commun. 9, 8 (2018).

    ADS  Article  Google Scholar 

  16. 16.

    Sasaguri, H. et al. Introduction of pathogenic mutations into the mouse Psen1 gene by Base Editor and Target-AID. Nat. Commun. 9, 2892 (2018).

    ADS  Article  Google Scholar 

  17. 17.

    Ma, Y. et al. Highly efficient and precise base editing by engineered dCas9-guide tRNA adenosine deaminase in rats. Cell Discov. 4, 39 (2018).

    Article  Google Scholar 

  18. 18.

    Liu, Z. et al. Highly efficient RNA-guided base editing in rabbit. Nat. Commun. 9, 2717 (2018).

    ADS  Article  Google Scholar 

  19. 19.

    Kim, D. et al. Genome-wide target specificities of CRISPR RNA-guided programmable deaminases. Nat. Biotechnol. 35, 475–+ (2017).

    CAS  Article  Google Scholar 

  20. 20.

    Kim, Y. B. et al. Increasing the genome-targeting scope and precision of base editing with engineered Cas9-cytidine deaminase fusions. Nat. Biotechnol. 35, 371–+ (2017).

    CAS  Article  Google Scholar 

  21. 21.

    Komor, A. C. et al. Improved base excision repair inhibition and bacteriophage Mu Gam protein yields C:G-to-T: A base editors with higher efficiency and product purity. Sci. Adv. 3, 9 (2017).

    Article  Google Scholar 

  22. 22.

    Li, G. L. et al. Highly efficient and precise base editing in discarded human tripronuclear embryos. Protein Cell 8, 776–779 (2017).

    CAS  Article  Google Scholar 

  23. 23.

    Liang, P. P. et al. Correction of beta-thalassemia mutant by base editor in human embryos. Protein Cell 8, 811–822 (2017).

    CAS  Article  Google Scholar 

  24. 24.

    Zhou, C. Y. et al. Highly efficient base editing in human tripronuclear zygotes. Protein Cell 8, 772–775 (2017).

    CAS  Article  Google Scholar 

  25. 25.

    Merideth, M. A. et al. Phenotype and course of Hutchinson-Gilford progeria syndrome. N. Engl. J. Med. 358, 592–604 (2008).

    CAS  Article  Google Scholar 

  26. 26.

    Schwarz, K. et al. RAG mutations in human B cell-negative SCID. Science 274, 97–99 (1996).

    ADS  CAS  Article  Google Scholar 

  27. 27.

    Noguchi, M. et al. Interleukin-2 receptor gamma chain mutation results in x-linked severe combined immunodeficiency in humans. Cell 73, 147–157 (1993).

    CAS  Article  Google Scholar 

  28. 28.

    Gehrke, J. M. et al. An APOBEC3A-Cas9 base editor with minimized bystander and off-target activities. Nat. Biotechnol. 36, 977–+ (2018).

    CAS  Article  Google Scholar 

  29. 29.

    Zong, Y. et al. Efficient C-to-T base editing in plants using a fusion of nCas9 and human APOBEC3A. Nat. Biotechnol. 36, 950–+ (2018).

    CAS  Article  Google Scholar 

  30. 30.

    Wang, X. et al. Efficient base editing in methylated regions with a human APOBEC3A-Cas9 fusion. Nat. Biotechnol. 36, 946–+, (2018).

    CAS  Article  PubMed  Google Scholar 

  31. 31.

    Yang, L. H. et al. Genome-wide inactivation of porcine endogenous retroviruses (PERVs). Science 350, 1101–1104 (2015).

    ADS  CAS  Article  Google Scholar 

  32. 32.

    Niu, D. et al. Inactivation of porcine endogenous retrovirus in pigs using CRISPR-Cas9. Science 357, 1303–1307 (2017).

    ADS  CAS  Article  Google Scholar 

  33. 33.

    Bae, S., Park, J. & Kim, J. S. Cas-OFFinder: a fast and versatile algorithm that searches for potential off-target sites of Cas9 RNA-guided endonucleases. Bioinformatics 30, 1473–1475 (2014).

    CAS  Article  Google Scholar 

  34. 34.

    Zuo, E. W. et al. Cytosine base editor generates substantial off-target single-nucleotide variants in mouse embryos. Science 364, 289–+ (2019).

    ADS  CAS  PubMed  Google Scholar 

  35. 35.

    Jin, S. et al. Cytosine, but not adenine, base editors induce genome-wide off-target mutations in rice. Science 364, 292–+ (2019).

    ADS  CAS  PubMed  Google Scholar 

  36. 36.

    Billon, P. et al. CRISPR-mediated base editing enables efficient disruption of eukaryotic genes through induction of stop codons. Mol. Cell 67, 1068–+ (2017).

    CAS  Article  Google Scholar 

  37. 37.

    Kuscu, C. et al. CRISPR-STOP: gene silencing through base-editing-induced nonsense mutations. Nat. Methods 14, 710–+ (2017).

    CAS  Article  Google Scholar 

  38. 38.

    Wang, K. P. et al. Cre-dependent Cas9-expressing pigs enable efficient in vivo genome editing. Genome Res. 27, 2061–2071 (2017).

    CAS  Article  Google Scholar 

  39. 39.

    Hoffman, E. P., Brown, R. H. & Kunkel, L. M. Dystrophin - the protein product of the duchenne muscular-dystrophy locus. Cell 51, 919–928 (1987).

    CAS  Article  Google Scholar 

  40. 40.

    Huang, J. et al. RAG1/2 knockout pigs with severe combined immunodeficiency. J. Immunol. 193, 1496–1503 (2014).

    CAS  Article  Google Scholar 

  41. 41.

    Suzuki, S. et al. Il2rg gene-targeted severe combined immunodeficiency pigs. Cell Stem Cell 10, 753–758 (2012).

    CAS  Article  Google Scholar 

  42. 42.

    Lei, S. H. et al. Increased and prolonged human norovirus infection in RAG2/IL2RG deficient gnotobiotic pigs with severe combined immunodeficiency. Sci. Rep. 6, 12 (2016).

    Article  Google Scholar 

  43. 43.

    Lai, L. X. et al. Production of alpha-1,3-galactosyltransferase knockout pigs by nuclear transfer coning. Science 295, 1089–1092 (2002).

    ADS  CAS  Article  Google Scholar 

  44. 44.

    Yang, D. S. et al. Expression of Huntington’s disease protein results in apoptotic neurons in the brains of cloned transgenic pigs. Hum. Mol. Genet. 19, 3983–3994 (2010).

    CAS  Article  Google Scholar 

Download references


This work was financially supported from the Strategic Priority Research Program of the Chinese Academy of Sciences (XDA16030503, XDA16030501), the National Key Research and Development Program of China Stem Cell and Translational Research (2017YFA0105103), Key Research & Development Program of Guangzhou Regenerative Medicine and Health Guangdong Laboratory (2018GZR110104004), the National Natural Science Foundation of China (81702115, 81672317, 31871292), the Youth Innovation Promotion Association of the Chinese Academy of Sciences (2019347), Science and Technology Planning Project of Guangdong Province, China (2014B020225003, 2016A030313169, 2017B030314056, 2017A050501059), the Bureau of Science and Technology of Guangzhou Municipality (201704030034), and the Science and Technology Planning Project of Jiangmen (2017TD02).

Author information




L.L. and K.W. designed the study. J.X., W.G., N.L., and Q.L. performed experiments and analyzed the data. W.G., F.C., Z.O., Q.Z., C.L., and N.F. performed SCNT and porcine embryos injection. Y.Z. and Z.L. performed embryos transfer experiments and provided animal (pig) care. S.G. performed bioinformatics analysis. X.Y., X.H., H.W., Q.J., H.S., Y.L., T.L., and L.Q. provided technical assistance. X.L. provided valuable comments. K.W. and L.L. supervised the project and wrote the paper.

Corresponding authors

Correspondence to Kepin Wang or Liangxue Lai.

Ethics declarations

Competing interests

The authors declare no competing interests.

Additional information

Peer review information: Nature Communications thanks Bhanu Telugu and 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.

Supplementary information

Source Data

Rights and permissions

Open Access This article is licensed under a Creative Commons Attribution 4.0 International License, which permits use, sharing, adaptation, distribution and reproduction in any medium or format, as long as you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons license, and indicate if changes were made. The images or other third party material in this article are included in the article’s Creative Commons license, unless indicated otherwise in a credit line to the material. If material is not included in the article’s Creative Commons license and your intended use is not permitted by statutory regulation or exceeds the permitted use, you will need to obtain permission directly from the copyright holder. To view a copy of this license, visit

Reprints and Permissions

About this article

Verify currency and authenticity via CrossMark

Cite this article

Xie, J., Ge, W., Li, N. et al. Efficient base editing for multiple genes and loci in pigs using base editors. Nat Commun 10, 2852 (2019).

Download citation


By submitting a comment you agree to abide by our Terms and Community Guidelines. If you find something abusive or that does not comply with our terms or guidelines please flag it as inappropriate.


Quick links

Nature Briefing

Sign up for the Nature Briefing newsletter — what matters in science, free to your inbox daily.

Get the most important science stories of the day, free in your inbox. Sign up for Nature Briefing