JPWO2015155904A1 - Gene knockout pig - Google Patents

Abstract

The inventors have developed a method for efficiently modifying genes in pigs by eliminating the shortcomings of the prior art, and enabling breeding of gene knockout pigs that are lethal before reaching the breeding age. It was an issue. The present invention uses a mRNA encoding a Zinc finger nuclease specific for a gene of interest to cleave the gene of interest to produce a gene knockout pig cell, take out the cell nucleus, and enucleate unfertilized eggs After transplantation, they were transferred to the surrogate mother's uterus to produce gene knockout pig individuals. Gene knockout pigs produced in this way are fatal that cannot reach the breeding age like the XSCID pigs of the examples, but gene knockout pigs that can be reproduced by blastocyst complementation technology using normal embryos. He also showed that it could be created.

Description

  Pigs, when viewed genetically, have anatomical characteristics, physiological characteristics, and hematology, even though the genetic distance to humans is greater than the genetic distance between mice and humans. The characteristic features are more similar to human than mouse. Therefore, it has attracted interest as a large experimental animal that can provide highly valuable and extrapolable information to humans.

  To date, porcine models for various human diseases such as cystic fibrosis, diabetes, Alzheimer's disease, and retinitis pigmentosa have been created. Furthermore, research on the use of genetically modified pigs as organ / tissue donors for xenotransplantation into humans is ongoing (Non-patent Document 1, Non-patent Document 2, Non-patent Document). 3).

Endogenous gene knockout (KO) is a useful tool for analyzing gene function and creating animal models that mimic human disease. So far, various gene knockout mice have been created using embryonic stem cells (ES cells) genetically modified by homologous recombination. In the case of pigs, since reliable ES cells have not been established and ES cells cannot be used, gene knockout cells are obtained using homologous recombination technology using somatic cells, which are used as nuclear donors. It has been used as a cell in combination with somatic cell nuclear transfer (SCNT) technology to produce gene knockout pigs. However, since the efficiency of homologous recombination is low for cultured mammalian cells (frequency, 10 ^-6 to 10 ^-8 ), it takes a lot of time to actually obtain the individual, and this inefficiency The production of knockout pigs has been hampered by sex and complexity (Non-Patent Document 4 to Non-Patent Document 6), and the production of knockout pigs via homologous recombination techniques is still limited.

  One new technique is to knock out endogenous genes using Zinc finger nuclease (ZFN), which eliminates the inefficiency and complexity of homologous recombination in mammals This is expected (Non-Patent Document 7). Genetically engineered ZFN is an artificial restriction enzyme containing a Zinc finger DNA-binding domain and a DNA cleavage domain (Non-Patent Document 8). We have previously described that gene knockout in porcine primary fetal fibroblasts in vitro is possible using ZFN (9) and has been genetically modified by ZFN. For the first time, it has been shown that somatic cells can produce gene knockout pigs after somatic cell nuclear transfer (SCNT) (Non-patent Documents 10 to 13). In these studies, plasmid DNA encoding ZFN was introduced into somatic cells or nuclear donor cells for somatic cell nuclear transfer (SCNT).

  However, plasmid DNA can be randomly integrated into the genome of the cell, which can cause disruption of the endogenous gene and constitutive expression of ZFN. In the production of knockout pigs using conventional Zinc finger nucleases, plasmid DNA is used for the expression of Zinc finger nucleases. In the method using plasmid DNA, there is a concern that a foreign gene is inserted into the genome of an animal individual, which means that there is a risk of destroying the original gene of the animal.

Dai Y, et al. (2002) Nat Biotechnol 20: 251-255. Lai L, et al. (2002) Science 295: 1089-1092. Elliott RB, et al. (2007) Xenotransplantation 14: 157-161. Porter AC, and Itzhaki JE (1993) Eur J Biochem 218: 273-281. Brown JP, et al. (1997) Science 277: 831-834. van Nierop GP, et al. (2009) Nucleic Acids Res 37: 5725-5736. Geurts AM, et al. (2009) Science 325: 433. Kim YG, et al. (1996) Proc Natl Acad Sci U S A 93: 1156--1160. Watanabe M, et al. (2010) Biochem Biophys Res Commun 402: 14-18. Whyte JJ, et al. (2011) Mol Reprod Dev 78: 2. Hauschild J, et al. (2011) Proc Natl Acad Sci U S A 108: 12013-12017. Li P, et al. (2012) J Surg Res 181: e39-45. Yang D, et al. (2011) Cell Res 21: 979-982.

  The inventors of the present invention have sought to develop a method that can eliminate the above-mentioned drawbacks in the case of performing gene knockout using plasmid DNA, and that enables efficient genetic modification in pigs. Therefore, the research group takes advantage of the fact that mRNA is not normally integrated into the genome, and by combining it with Zinc finger nuclease-encoding mRNA and somatic cell nuclear transfer technology, safe knockout without risk of damaging gene functions other than the intended purpose. Tried to produce pigs.

  The present invention uses mRNA encoding ZFN composed of a Zinc finger domain designed to specifically target a gene targeted for knockout and a nuclease for cleaving the target DNA. Then, after cutting the target gene and causing a partial defect, gene knockout porcine cells are created by using the DNA repair mechanism of the living body to connect the cut genes, and the cells are used A gene knockout pig individual was created.

  As a specific example of the present invention, 12 bases designed to target the sequence of exon 1 in the porcine interleukin-2 receptor γ gene (IL2RG gene, a causative gene of severe combined immunodeficiency) A ZFN having four Zinc finger domains to be recognized was constructed, and a porcine IL2RG gene knockout cell was produced using the ZFN, and a porcine IL2RG gene knockout pig was produced using the ZFN. The IL2RG gene knockout pig produced in this way cannot survive until the breeding age because of its immunodeficiency, but it is viable by reviving the thymus by blastocyst complementation technology. That is, it was also shown that IL2RG knockout pigs (male) can be produced.

  In the case of the homologous recombination method or the ZFN plasmid DNA method known as a gene knockout method, there is a risk that the targeting vector is incorporated into an unintended site in the genome, but according to the method of the present invention, By using mRNA encoding ZFN, gene knockout cells can be generated without inserting foreign DNA into the genome, and a highly safe gene knockout method has been successfully developed. In addition, in the method of the present invention, gene knockout cells can be produced in a relatively short period of time, and therefore the time required to produce a gene knockout animal can be greatly shortened.

  In addition, the X chromosome-linked severe combined immunodeficiency (XSCID) pig produced as a specific embodiment is a natural killer (NK) that plays an important role in immune functions against tumor cells and transplanted cells in addition to T cells. Although cells are deficient, B cells are present. B cells are present in porcine XSCID as in human XSCID, but mouse X-SCID has no B cells. Therefore, animal models that better reflect humans in X-SCID are pigs, not mice. Moreover, since XSCID pigs are similar in size to humans and physiologically very similar to humans, they are cancer models, stem cell transplant research, drug discovery research as various human disease models. In addition to becoming a model animal widely used for such purposes, it can be used as a base animal for the production of artificial organs.

FIG. 1 summarizes the characteristics of the gene knockout technique. FIG. 2 is a diagram showing the design of ZFN targeting the porcine IL2RG gene and the generation of nuclear donor cells. FIG. 3 is a diagram showing the production of IL2RG knockout pigs and the results of genetic and protein analysis of the produced pigs. FIG. 4 shows the results of histological confirmation of the IL2RG knockout pig phenotype. FIG. 5 shows the results of flow cytometry analysis of mononuclear cells in IL2RG knockout pigs. FIG. 6 is a diagram showing production of chimeric individuals between IL2RG knockout pigs and wild type (WT) pigs by scutellum method complementation, and changes in body weight after birth.

In the first aspect, the present invention provides a method for producing a cell in which a gene of interest is knocked out (KO), including the following method:
Introducing an mRNA encoding a Zinc finger nuclease (ZFN) protein comprising a Zinc finger domain and a nuclease targeting a target gene sequence into a cell;
Producing a ZFN protein that targets a target gene in a cell;
Cleaving and removing the DNA sequence of the target gene in the genome by the action of the ZFN protein;
The process of reconnecting the cleaved genome parts by the intracellular DNA damage repair mechanism.

  In the prior art, as a method for producing a cell in which a target gene is knocked out, a method by homologous recombination, a gene knockout method by zinc finger nuclease using plasmid DNA, and the like have been known.

  In the method of gene knockout by homologous recombination, it is essential to introduce a foreign gene into the nucleotide sequence of the target gene using a targeting vector in order to eliminate the gene function of the target gene, but this is not intended in the genome. There was a risk of incorporating the targeting vector into the site. In addition, the efficiency of homologous recombination itself is very low, and it takes a long time to obtain the target gene knockout cell.

  As a method for eliminating such drawbacks, a method using a ZFN protein targeting the nucleotide sequence of a target gene has been developed. In this method, plasmid DNA encoding a ZFN protein is incorporated into a cell, a ZFN protein targeting the nucleotide sequence of the target gene is expressed in the cell, the target gene is cleaved, and knocked out. However, in this method, the gene knockout efficiency is increased, and as a result, the time taken to obtain the target cell can be greatly shortened. However, in this method, plasmid DNA encoding the target ZFN protein is also used. There was a risk that a foreign gene (such as a ZFN gene) derived from a plasmid vector would be incorporated at an unintended site in the genome (see FIG. 1).

  In the present invention, an mRNA encoding a ZFN protein containing a Zinc finger domain and a nuclease targeting a target gene sequence is used for the purpose of eliminating the disadvantages associated with the conventional gene knockout technology. It was decided to. Specifically, mRNA encoding a ZFN protein containing a Zinc finger domain and a nuclease targeting the target gene sequence is introduced into the cell, and the target ZFN protein is obtained using an intracellular protein translation system. A cell in which the target gene has been deleted by cutting and removing the DNA sequence of the target gene in the genome by the action of the ZFN protein and reconnecting the cut portions of the genome with the intracellular DNA damage repair mechanism Can be manufactured.

  An advantage of using mRNA encoding ZFN is that ZFN expression is transient. This can greatly reduce the possibility of non-target mutations. Non-targeted mutations were a potential limiting element of ZFN technology, but the introduction of mRNA encoding ZFN could immediately induce ZFN translation in the cytoplasm without the risk of genomic mutation. This could reduce the possibility of mutations or destruction of endogenous genes in the nucleus. In this method, since mRNA is introduced into the cell, DNA encoding the ZFN protein that targets the target gene sequence (foreign DNA) does not exist in the cell. As a result, the foreign gene There is no danger of exogenous DNA containing the DNA being integrated into the genome, and the problems of the prior art can be solved.

  So far, a method of gene knockout by directly injecting mRNA encoding ZFN into a fertilized egg has been reported in rodents (Mashimo T, et al. (2010) PLoS One 5: e8870; Carbery ID, et al. (2010) Genetics 186: 451-459 .; Cui X, et al. (2011) Nat Biotechnol 29: 64-67). However, in pigs, since a method for gene transfer into fertilized eggs has not been established, the production of knockout pigs using mRNA encoding ZFN has not yet been reported. Therefore, in a preferred embodiment, the present invention produces a cell in which a gene of interest is knocked out in a porcine cell.

  The ZFN protein used in the present invention is characterized by containing a Zinc finger domain in the protein. A Zinc finger is a protein having DNA binding properties, and one Zinc finger domain can recognize and bind to three nucleotides. In the art, the composition of Zinc finger proteins is already known for each of any three nucleotide combinations. Therefore, by combining the amino acid sequence of this Zinc finger protein based on the known knowledge about the relationship with the target nucleotide, it is possible to modify the target nucleotide sequence to be recognized. A ZFN protein can comprise a plurality of, for example, 3-10, preferably 3-6, Zinc finger domains. As described above, since one Zinc finger domain can recognize and bind to 3 nucleotides, for example, when it contains 3 Zinc finger domains, it recognizes 9 nucleotides and 6 Zinc fingers. If it contains a domain, it can recognize 18 nucleotides.

  The ZFN protein used in the present invention is also characterized by including a nuclease domain in the protein. As such a nuclease, it is generally used as a sequence-independent DNA cleavage domain derived from the type II restriction enzyme FokI. However, other nucleases such as Sts I can be used. it can.

  An mRNA encoding a ZFN protein having such a structure is introduced into a cell, and a target ZFN protein is produced using an intracellular protein translation system. In the cell, this ZFN protein specifically binds to the target DNA sequence of the target gene through the Zinc finger domain, and cleaves a specific part of the target gene through the nuclease domain. The cleaved DNA is repaired by homologous recombination or non-homologous end ligation by a DNA repair mechanism inherent in the cell. As a result, a part of the target gene is deleted, and as a result, the target gene functions Cells in a deleted state, that is, cells in which the target gene is knocked out can be produced.

  Since the target nucleotide sequence can be freely defined by appropriately modifying the amino acid sequence of the Zinc finger domain of the ZFN protein, the target gene (target nucleotide) to be targeted is not limited at all.

In the present invention, in the second aspect, there is provided a method for producing a gene knockout animal using, as a nuclear donor, a cell in which a target gene produced by the production method of the first aspect is knocked out. Specifically, a method for producing a gene knockout animal comprising the following steps is provided:
Producing a cell in which the gene of interest produced by the production method of the first aspect is knocked out;
Thereafter, a step of removing the nucleus from the produced cell in which the target gene is knocked out, and somatic cell nuclear transfer into an enucleated unfertilized egg cell;
A process of embryo transfer by transferring an early embryo produced by somatic cell nuclear transfer into the uterus of a surrogate mother.

  In the method for producing a gene knockout animal according to the second aspect of the present invention, the cells produced in the first aspect are used as nuclear donors, and the obtained nuclei are transplanted into enucleated unfertilized egg cells by somatic cell nuclear transfer technology. It is characterized by that. This is a method for producing an individual (a cloned animal) by transferring an early embryo derived from a nuclear-implanted unfertilized egg cell produced by this method to a surrogate mother's uterus and causing embryo development in the uterus.

  Somatic cell nuclear transfer technology, also called somatic cell cloning, creates an early embryo by transplanting (fusion) the somatic cell nucleus into an unfertilized egg excluding the nucleus, and the produced early embryo is used as a surrogate mother's uterus. This is a method of creating an individual (clone). Since the embryo has a nucleus derived from somatic cells, the embryo that develops is characterized by having the same genetic information as the nucleus of the original somatic cell. And since the cell which knocked out the target gene in the 1st aspect of this invention can be proliferated, it can replicate the same nucleus. Therefore, in the method of the second aspect of the present invention, by using the cell prepared in the first aspect as a nuclear donor, a cloned animal having the same gene configuration in which the target gene is knocked out can be produced. .

  As a third aspect of the present invention, using the method for producing a cell in which the target gene is knocked out in the first aspect and the method for producing a gene knockout animal in the second aspect, the interleukin-2 receptor γ ( IL2RG) gene was selected as the target gene, and an attempt was made to create a knockout animal of the interleukin-2 receptor γ gene (IL2RG gene) in pigs.

  The IL2RG gene selected as the target gene in this embodiment is a gene that is on the X-chromosome of male cells and encodes a common γ chain (γc). When the IL2 receptor γc chain does not function, the action of interleukin is not transmitted. Moreover, the IL2 receptor γc chain receptor is widely used by six types of interleukins: interleukin-2 (IL-2), IL-4, IL-7, IL-9, IL-15, and IL-21. Therefore, it is known that all these interleukin signals are not transmitted into the cell, resulting in severe immunodeficiency. In humans and mice, mutations in this gene are known to cause X chromosome-linked severe combined immunodeficiency (XSCID), which is characterized by a severe loss of cellular and humoral immunity (XSCID) ( Noguchi M, et al. (1993) Cell 73: 147-157; Buckley RH (2004) Annu Rev Immunol 22: 625-655).

  In the case of a knockout animal that produces immunodeficiency based on a mutation in the IL2RG gene produced in a mouse, although the pathological condition is similar to that of human XSCID, the life of the mouse itself is short-lived. There was a disadvantage that it was not suitable for creating a disease model mouse. Therefore, in this technical field, there has been a demand for the development of animals that have a long survival period and can be models for human diseases.

  In the present invention, IL2RG gene knockout porcine cells are produced according to the first aspect of the present invention using pig as a material and mRNA encoding ZFN targeting IL2RG gene, and then the second of the present invention. According to the embodiment, IL2RG gene knockout pig nuclei were used as nuclear donors, and somatic cell nuclei were transplanted into porcine enucleated unfertilized eggs to produce IL2RG gene knockout pigs.

  Confirmation of the lymphocyte phenotype of this knockout pig showed that T cells and NK cells were almost disappeared in the male pig, and from this phenotype, the generated knockout pig developed the XSCID phenotype Showed that it can. According to previous knowledge, in human XSCID patients, the number of T cells and NK cells is significantly decreased, but the number of B cells is still normal and sometimes increased, but XSCID In mice and XSCID rats, a significant decrease in the number of T cells and B cells has been reported. From this, it was known that the phenotype of the rodent XSCID model does not necessarily mimic the symptoms of human XSCID. On the other hand, the IL2RG knockout pig produced in the present invention is deficient in T cells and NK cells, and it was shown that the number of B cells is normal. Such a phenotype is considered to be a model that accurately mimics human XSCID.

  When a knockout animal is produced by this method, gene knockout cells can be produced by mRNA encoding ZFN without performing antibiotic selection. In fact, a sufficient number of nuclear donor cells for somatic cell nuclear transfer (SCNT) were obtained in a very short period (approximately 3 weeks). Furthermore, IL2RG-knockout cells produced by mRNA encoding ZFN in the present invention can be cloned in full term without rejuvenation of nuclear donor cells and without subsequent recloning. It became possible to produce fetuses. In the conventional homologous recombination method, an average period of 12 to 18 months is required until a knockout animal is obtained. However, in the method of the present invention, as a result, it is necessary to establish a knockout cell. Even if we consider about 114 days (less than 4 months) of the pregnancy period of pigs, including the period of gestation, we will produce cloned fetuses within 6 months, with a period of about 1/2 to 1/3. I was able to. This significant reduction in time is very useful in producing knockout pigs.

  In the second aspect of the present invention, since knockout embryos are produced by somatic cell transplantation, all the cells of the born pig contain the knockout of the target gene, and the gene knockout is inevitably performed. It is also transmitted to germline cells (germ cells such as egg cells or spermatogonia). The gene knockout pig of IL2RG gene produced as an example in the present invention has the property of XSCID and develops symptoms only in males.

  Since XSCID animals develop symptoms only in males as described above, no symptoms develop in females that retain the heterozygous IL2RG gene knockout. Therefore, once a gene knockout animal has been created, the maintenance of the knockout should be carried out with heterozygous female animals, and by mating, half of the males that are born theoretically become XSCID, producing XSCID animals. be able to.

  However, a simpler approach is to use blastocyst complementation technology (Matsunari et al., PNAS, 4557-4562, 2013; Nakano et al. PLoS One, e61900, 2013) even for male individuals presenting with XSCID. To produce male individuals that can survive (ie, can reproduce) even if the IL2RG gene is knocked out.

Gene knockout male animals by blastocyst complementation technology by injection method (Matsunari et al., PNAS, 4557-4562, 2013)
A step of producing a cell in which a target gene is knocked out by a method such as any of the methods described in the present specification;
Thereafter, a nucleus is taken out from the cell in which the produced target gene is knocked out, and a somatic cell nucleus is transplanted into an enucleated unfertilized egg cell to produce a host embryo;
Removing a nucleus from a cell of a healthy animal and transplanting a somatic cell nucleus into an enucleated unfertilized egg cell to produce a donor embryo;
Injecting cells from the donor embryo up to the morula stage into the host embryo until the morula stage;
Embryo transfer of the embryo of the host embryo into which the embryo derived from the donor embryo has been injected into the surrogate mother's womb, and embryo development; Process;
Can be produced by a method for producing a reproductive gene knockout male animal.

On the other hand, the gene knockout male animal by the scutellum method complementation technique by the aggregation method (Nakano et al. PLoS One, e61900, 2013)
A step of producing a cell in which a target gene is knocked out by a method such as any of the methods described in the present specification;
Thereafter, a nucleus is taken out from the cell in which the produced target gene is knocked out, and a somatic cell nucleus is transplanted into an enucleated unfertilized egg cell to produce a host embryo;
Removing a nucleus from a cell of a healthy animal and transplanting a somatic cell nucleus into an enucleated unfertilized egg cell to produce a donor embryo;
Dispersing the cells of the host embryo and donor embryo up to the morula stage and mixing the donor embryo-derived cells and the host embryo-derived cells to produce aggregated embryos;
After the blastocyst is formed from the aggregated embryo, the blastocyst is transferred into the surrogate mother's womb and embryonic development is performed; and a chimeric male individual capable of forming a sperm in which the target gene is knocked out is selected. The step of:
Can be produced by a method for producing a reproductive gene knockout animal.

By either method, the breedable gene knockout animal produced is
A chimera of a cell derived from a host embryo in which the target gene is knocked out and a cell derived from a host embryo of a healthy animal;
• Germline cells are derived from the host embryo;
-Functional deficiency caused by knockout of target gene is complemented by cells derived from healthy animals;
It has the characteristic called.

  In the present invention, gene knockout male animals in various animals can be produced by such a method. Examples of various animals include pigs, monkeys, rats, mice, cows and sheep.

  By creating a breeding male individual (X * Y and XY chimera), it is possible to create a heterozygous female individual (XX *) with a heterozygous IL2RG gene by crossing with a healthy female individual (XX) (Table) 1 (A)). IL2RG gene heterozygous female individuals (XX *) are crossed with fertile IL2RG gene-deficient male individuals (X * Y and XY chimeras) to obtain IL2RG gene homozygous female individuals (X * X *, XSCID). Present) and IL2RG gene hetero-deficient male individuals (presenting X * Y, XSCID) (Table 1 (B)). By storing the sperm of a male individual capable of breeding, XSCID pigs can be bred more efficiently using healthy female individuals.

  In addition, by using somatic cells of individuals having the genotypes shown in Table 1, live offspring animals can be generated after somatic cell nuclear transfer (SCNT). In the present invention, the inventors have found that the endogenous gene in porcine primary culture cells can be knocked out using mRNA encoding Zinc finger nuclease (ZFN). Thereby, somatic cell cloning enables efficient production of gene knockout pigs.

  All animal experiments related to the present invention were approved by the Institutional Animal Care and Use Committee of Meiji University (IACUC10-0004). All chemicals were purchased from Sigma-Aldrich Chemical Co. (MO, USA) unless otherwise stated.

Example 1 Design of Zinc Finger Nuclease (ZFN) In this example, a Zinc finger nuclease (ZFN) that can be used for gene knockout (KO) in porcine cells was designed.

  A custom-made ZFN plasmid for the porcine IL2RG gene was obtained from Toolgen Inc. The design and effectiveness of these ZFNs was done by Toolgen Inc. (Seoul, South Korea). Like human, mouse, and rat IL2RG, porcine IL2RG is found on the X chromosome and is composed of eight exons. In this study, we constructed a ZFN targeting exon 1 of porcine IL2RG. Each constructed ZFN had four Zinc finger domains that recognize 12 bases (FIG. 2A). In FIG. 2A, the coding region and the untranslated region are shown in gray and white boxes, respectively. ZFN consists of a nuclease domain (Fok I) and a DNA binding domain (Zinc finger protein), and the recognition sequence of the Zinc finger protein is underlined. This ZFN pair (right and left) each contains four Zinc finger proteins and recognizes a 24 bp target sequence together in both the right and left ZFNs (FIG. 2A).

  For the production of mRNA encoding ZFN, each of the ZFN plasmids was digested with the restriction enzyme Xho I. The linearized plasmid was then purified using phenol / chloroform to produce a high quality DNA template for in vitro transcription. Capped ZFN mRNA was generated from linear DNA templates via in vitro transcription using MessageMAX T7 ARCA-capped message transcription kit (Cambio, Cambridge, UK). A poly (A) tail was then added to each mRNA by polyadenylation using a poly (A) polymerase tailing kit (Cambio). The mRNA encoding poly (A) -tailed ZFN is then used on a spin column using MEGAclear kit (Life Technologies, CA, USA) and finally to 400 ng / μl RNase-free water Purified by resuspension.

Example 2 Preparation of IL2RG Gene Knockout Cells In this example, porcine IL2RG knockout cells were prepared using the ZFN mRNA prepared in Example 1 according to the flowchart shown in FIG. 2B.

A primary culture of porcine fetal fibroblasts (male) was used as a precursor strain for producing IL2RG gene knockout cells. Fibroblasts and their derivatives (knockout cells) are seeded onto type I collagen-coated dishes or plates (Asahi Glass, Tokyo, Japan) and 15% FBS (Nichirei Bioscience, Tokyo, Japan) and 1 × antibiotics The cells were cultured at 37 ° C. in a humid atmosphere containing 5% CO ₂ in MEMα (Life Technologies) to which the substance solution (Life Technologies) was added.

Fetal fibroblasts are cultured to 70-90% confluence, washed twice using D-PBS (−) (Life Technologies), and treated with 0.05% trypsin-EDTA (Life Technologies). The cells were isolated and collected. The cells (4 × 10 ⁵ ) are then resuspended, 40 μl R buffer (supplied as part of Neon Transfection System, Life Technologies), and 2 μl mRNA solution encoding ZFN (400 ng / μl) Added. Cells were then electroporated under the following conditions: pulse voltage, 1,100 V; pulse width, 30 ms; and number of pulses, 1 (program # 6). After electroporation, the cells were cultured in the above-mentioned culture medium without antibiotics for 24 hours and then in culture medium with antibiotics at 32 ° C. for 3 days (transient cold shock).

  No visible morphological abnormalities were detected in fetal fibroblasts after introduction of mRNA and after transient cooling shock treatment. After transient cold shock treatment, cells are cultured for recovery at 37 ° C until confluence, followed by limiting dilution, and 192 single cell-derived clones in 5 96-well plates Got. On day 12 after limiting dilution, relatively high confluent (> 50%) cells in each well were selected and aliquoted and used for further culture and mutational analysis. On the other hand, after limiting dilution, cells at low confluence (about 50%) were not used for further experiments.

  Of the 192 single cell-derived cell lines obtained, one cell line with ZFN-inducible mutation was established (1/192, 0.5%), and this cell line (# 98, Fig. 2B) Used as nuclear donor for cell nuclear transfer (SCNT). From the DNA sequence analysis based on comparison to the start codon region of wild type IL2RG (SEQ ID NO: 1), these cells can be replaced with 3-bp substitutions and the major transcription start and start codon (ATG) of porcine IL2RG. It was also shown to have a spanning 86-bp deletion (FIG. 2C, SEQ ID NO: 2), indicating that this mutation disrupts IL2RG function. In FIG. 2C, the upper sequence and the lower sequence indicate the WT sequence of IL2RG and the sequence of clone # 98, respectively. Deletion mutations and nucleotide substitutions in clone # 98 are indicated by hyphens and black squares, respectively. The initiation codon for IL2RG is indicated by a dotted box. The ZFN binding site and the ZFN cleavage site are indicated by double underline and box, respectively. The major transcription start site is indicated by ◯. A sufficient number of knockout cells were prepared for somatic cell nuclear transfer (SCNT) by culturing for 3 weeks.

Example 3 Production of IL2RG Knockout Clone Pig In this example, a porcine IL2RG knockout cell produced in Example 2 was used as a nuclear donor cell to produce a pig knockout cloned fetus and the pig knockout cloned fetus. We analyzed ZFN-induced mutations in.

  Somatic cell nuclear transfer (SCNT) was performed as follows. In vitro matured oocytes containing the first polar body were treated with 10 mM HEPES, 0.3% (w) in the presence of 0.1 μg / ml demecorsin, 5 μg / ml cytochalasin B (CB), and 10% FBS. / v) In a Tyrode lactose medium containing polyvinylpyrrolidone (PVP), the polar body and the surrounding cytoplasm were enucleated by gentle aspiration using a tip beveled pipette.

After cell cycle synchronization by serum starvation for 2 days, fibroblasts (clone # 98) were used as nuclear donors. Single donor cells were inserted into the clonal space of enucleated oocytes. The donor cell-oocyte complex is placed in a 280 mM mannitol (Nacalai Tesque, Kyoto, Japan) (pH 7.2) solution containing 0.15 mM MgSO ₄ , 0.01% (w / v) PVA, and 0.5 mM HEPES. And held between two electrode needles. Somatic cells by applying a single direct current (DC) pulse (273 V / mm, 20 μs) and 4 V pre-pulse and post-pulse-alternating current (AC) fields at 1 MHz for 5 seconds Membrane fusion was induced using a hybridizer (LF201; NEPA GENE, Chiba, Japan).

  The developmental potential of somatic cell nuclear transfer (SCNT) embryos reconstituted with IL2RG knockout cells was examined in vitro. Of the 403 somatic cell nuclear transfer (SCNT) embryos created in the two replicate experiments, 237 (58.8%) developed in blastocysts (Table 2). This blastocyst formation rate was reported in our previous study (Matsunari H, et al. (2012) In: Miyagawa S, editor, Xenotransplantation. Rijeka, Croatia: InTech. Pp. 37-54). The blastocyst formation rate was comparable.

Next, the reconstructed embryo was cultured in PZM5 medium supplemented with 4 mg / ml BSA for 1 to 1.5 hours, and then electrically activated. For induction of electrical activation, reconstituted embryos were treated with _{2 of} fusion chamber slides filled with an activation solution consisting of 280 mM mannitol, 0.05 mM CaCl ₂ , 0.1 mM MgSO ₄ , and 0.01% (w / v) PVA. Placed between two wire electrodes (1.0 mm distance). A single 150 V / mm DC pulse was applied for 100 μs using a pulse generator device (Multiporator; Eppendorf, Hamburg, Germany).

After activation, reconstituted embryos were transferred into PZM5 supplemented with 5 μg / ml CB and 500 nM Scriptaid for 3 hours. Embryos were transferred into PZM5 supplemented with 500 nM Scriptaid and cultured for an additional 12-14 hours. After incubation, embryos were further cultured in PZM5 and the dishes were maintained at 38.5 ° C. in a humidified atmosphere of 5% CO ₂ and 90% N ₂ . Beyond the morula stage, embryos were cultured in PZM5 supplemented with 10% FBS.

  Next, 199 blastocysts (FIG. 3A) obtained by somatic cell nuclear transfer (SCNT) were mixed with immature female pigs (Large White / Landrace × Duroc), body weights of 100 to 105 kg, and somatic cell nuclei. Used as recipients of transplanted (SCNT) embryos to become pregnant. For two recipient female pigs, the estrus phase was induced by a single intramuscular injection of 1,000 IU eCG (ASKA Pharmaceutical Co., Ltd., Tokyo, Japan). 66 hours after eCG injection, 1,500 IU hCG (Kyoritsu Seiyaku Corporation, Tokyo, Japan) was injected intramuscularly to induce ovulation and synchronize the estrus (P177 and P178; Table 2). Somatic cell nuclear transfer (SCNT) embryos cultured for 5-6 days were surgically transferred into recipient oviducts approximately 146 hours after hCG injection.

  Pregnancy was confirmed on day 39 of gestation for both female pigs. Opportunistic infections after the birth of XSCID animals are inevitable in conventional rearing environments. Thus, four male IL2RG knockout cloned fetuses born at term were obtained by cesarean section from one recipient female pig (P177) on day 113 of gestation (FIG. 3B). The weight and length of the 4 piglets ranged from 0.56 to 1.16 kg and from 22 to 28 cm, respectively. Another recipient female pig (P178) aborted on the 46th day of pregnancy.

Example 4 Analysis of IL2RG Knockout Clone Pigs In this example, the results of analysis on the macroscopic or microscopic properties of IL2RG knockout clone pigs produced in Example 3 are shown.

(4-1) Gene analysis First, it was examined by PCR genotyping and DNA sequence analysis whether IL2RG knockout clone pigs were produced as genetically aimed. The target region of IL2RG-ZFN is defined as MightyAmp DNA polymerase (Takara Bio, Shiga, Japan) and the corresponding primer (5'-ATAGTGGTGT CAGTGTGATT GAGC (SEQ ID NO: 3) and 5'-TACGAACTGA CTTATGACTT ACC (SEQ ID NO: 4 )) And amplified by direct PCR from cell clones.

  Next, nested PCR using PrimeSTAR HS DNA polymerase (Takara Bio) and appropriate primers (5'-ATACCCAGCT TTCGTCTCTG C (SEQ ID NO: 5) and 5'-TTCCAGAATT CTATACGACC (SEQ ID NO: 6)) Went. Next, the PCR fragment containing the ZFN target region was sequenced using sequencing primer 5'-AGCCTGTGTC ATAGCATAC (SEQ ID NO: 7), BigDye Terminator Cycle sequencing kit, and ABI PRISM 3100 Genetic Analyzer (Life Technologies) Examined. For analysis of mutations in cloned fetuses, DNeasy Tissue and Blood Kit (QIAGEN, Hilden, Germany) was used to extract genomic DNA from fetal tail biopsies, followed by PCR genotyping and DNA sequencing as described above. Went as it did. All new sequence data have been registered in DDBJ / EMBL / GenBank (AB846644-AB846648).

  The results of PCR genotyping for the 4 cloned pigs obtained (FIG. 3C; M: DNA marker) and the results of DNA sequence analysis of IL2RG in the cloned pig are shown (FIG. 3D), respectively. PCR genotyping and DNA sequencing of four cloned pigs revealed that all four pigs had the same mutations as nuclear donor cells (3-bp substitution and 86-bp deletion; FIGS. 3C and 3D) It was shown to have In FIG. 3D, the arrow and box indicate the same mutation as that of the nuclear donor cell (clone # 98).

(4-2) Protein analysis Next, it was examined by Western blot analysis whether IL2RG knockout clone pigs were produced as intended from the viewpoint of gene expression. After sacrifice of IL2RG knockout pigs and age-matched WT pigs, the excised spleens were homogenized in RIPA buffer (Thermo Scientific, MA, USA) containing protease inhibitor cocktail (Nacalai Tesque) and centrifuged And the supernatant was collected. The protein concentration of the samples was quantified using a DC protein assay (Bio-Rad, CA, USA) based on the Raleigh method. Approximately 40 μg of protein from the spleen extract was subjected to 10% SDS-PAGE and transferred to Hybond-P PVDF membrane (GE Healthcare Bio-Sciences, NJ, USA) by electroblotting.

  The membrane was blocked with Blocking One (Nacalai Tesque) for 30 minutes at room temperature. After blocking, incubated with anti-IL2RG antibody (1: 200 dilution; Santa Cruz Biotechnology, CA, USA) for 1 hour at room temperature and HRP-conjugated anti-rabbit IgG antibody (1: 5,000 dilution; Santa Cruz) Biotechnology) was incubated for 1 hour at room temperature. Blots were developed using ECL Western Blotting Detection Reagents (GE Healthcare Bio-Sciences). The signal was detected and imaged using the ImageQuant LAS-4000 system (GE Healthcare Bio-Sciences). Β-actin was used as an electrophoresis control.

  FIG. 3E shows the results of Western blotting of IL2RG protein in the spleen of IL2RG knockout pigs (FIG. 3E; M: protein standard marker). This Western blot analysis further showed that all four pigs lacked the IL2RG protein (FIG. 3E).

(4-3) Histological analysis
IL2RG knockout pigs and age-matched WT pigs were sacrificed and subjected to global anatomical analysis. The gross analysis showed that all four IL2RG knockout pigs were completely deficient in the thymus (FIGS. 4A, 4B). In FIG. 4A, white arrowheads indicate normal thymus in WT pigs.

  The spleen removed from the sacrificed animal is then fixed in 10% neutral buffered formalin solution (Wako Pure Chemical Industries, Osaka, Japan), embedded in paraffin, sectioned, and standard Staining with hematoxylin-eosin in a typical manner.

Microscopic images of the histological analysis of the spleen are shown in FIGS. 4C and 4D. In these figures, histological analysis of spleens of WT and IL2RG knockout pigs was performed. The white pulp of the spleen is indicated by a dotted white circle (Bar = 100 μm). Wild-type (WT) pigs clearly showed the presence of lymphocytes in the white pulp of peripheral lymphoid sheath tissue (PALS) (FIG. 4C), whereas IL2RG knockout pigs showed very little or no PALS The absence of lymphocytes was shown (Figure 4D). Embryonic blood production in the red pulp was strong in both WT and IL2RG knockout pigs (data not shown). Lymphocyte population counts in the peripheral blood (PB) of WT and IL2RG knockout pigs, as mean ± SD values for 4 pigs, 15.7 ± 2.2 × 10 ² / μl in WT pigs and IL2RG knockout pigs, respectively 6.5 ± 3.0 × 10 ² / μl, which indicates that the number of lymphocytes was significantly reduced in IL2RG knockout pigs, the value for WT pigs and the value for IL2RG knockout pigs (n = 4) It shows that there is a statistically significant difference (* P <0.01; FIG. 4E).

(4-4) Cytological analysis Furthermore, the cell composition of peripheral blood mononuclear cells was analyzed using flow cytometry analysis.

Peripheral blood mononuclear cells were collected from whole blood and spleen of IL2RG knockout pigs using erythrocyte lysis solution Pharmlyse (Becton Dickinson, BD, NJ, USA) and 1 × 10 ⁶ cells were Mouse anti-porcine CD3e (Abcam, Cambridge, UK), CD4a antibody (BD), CD8a antibody (BD), CD16 antibody (AbDSerotec, NC, USA), CD45RA antibody (AbDSerotec), and monocyte and granulocyte antibody (M / G, Abcam) for 30 minutes at room temperature.

  Following incubation, the cell suspension was washed and resuspended in PBS (−) supplemented with 1% FBS (w / v). Cell populations isolated from peripheral blood and spleen of IL2RG-knockout pigs were evaluated using a FACSCalibur flow cytometer (BD) equipped with a 488-nm argon laser. Cell debris and aggregates were removed using bivariate forward scatter / side scatter (FSC / SSC) parameters.

In all analyses, de facto lymphocyte populations were removed and 1 × 10 ⁴ events that passed the gate per sample were acquired and analyzed using CELLQuest Pro software (BD).

  Flow cytometric analysis of T cells, B cells, and NK cells in peripheral blood of IL2RG knockout pigs is shown in FIG. 5A. The results showed that the number of CD3 + T cells (0.3% ± 0.1%) in IL2RG knockout pigs was significantly lower than in WT pigs (74.0% ± 10.2%) (P <0.0001) (Figure 5A).

  Furthermore, IL2RG knockout pigs were also found to be deficient in CD3 + CD4 + T cells and CD3 + CD8 + T cells. The B cell population (CD3- and CD45RA +) in IL2RG knockout pigs was observed to be similar to the B cell population in WT pigs, but the number of NK cells (monocyte / granulocyte-, CD3-, and CD16 +) ) Was significantly reduced in IL2RG knockout pigs compared to WT pigs (IL2RG knockout, 0.9% ± 0.2% vs. WT, 8.1 ± 4.5%; P = 0.004).

  As seen in peripheral blood, the number of splenic T cells (IL2RG knockout, 0.2% ± 0.1% vs. WT, 28.1% ± 10.9%; P <0.0001) and the number of NK cells (IL2RG knockout, 0.8% ± 0.3) % Vs. WT, 3.9% ± 0.8%; P = 0.0001) was significantly reduced in IL2RG knockout pigs (FIG. 5B). Thus, in IL2RG knockout pigs, almost complete loss of T cells and NK cells was seen, a decrease similar to that in human XSCID patients.

  Dot plots show CD3, CD4, and CD8 cells for boundaries of T cell subpopulations, and CD3, CD45RA, and CD16 for differentiation of T, B, and NK cell subpopulations in peripheral blood Cells (in the non-myeloid fraction, ie monocytes / granulocytes (M / G) -negative) are shown respectively. (FIG. 5B) Population of T cells (CD3 +) and NK cells (M / G−, CD3-, CD16 +) among mononuclear cells in the spleen of IL2RG knockout pigs. Data show the mean ± SD values of 4 obtained pigs.

Example 5: Blastocyst complementation for the production of fertile IL2RG knockout pigs (male) (1)
In this example, the breeding possibility of the knockout pig produced in Example 3 was examined.

  The IL2RG knockout pig (male) produced in Example 3 exhibits an immunodeficiency phenotype as shown in Example 4. Therefore, after delivery, the child died due to factors such as opportunistic infection, and cannot be used for breeding in normal environment breeding. Therefore, using the blastocyst complementation method that has already been proved in pigs (Matsunari et al., PNAS, 4557-4562, 2013; Nakano et al. PLoS One, e61900, 2013), the expression of IL2RG knockout pigs An attempt was made to create a IL2RG knockout pig that complements the mold and can be bred.

  A blastocyst complementation treatment was performed on a cloned embryo derived from IL2RG knockout cells (this was used as a host embryo) using a cloned embryo (this was used as a donor embryo) prepared from healthy pig cells. Chimera embryos for blastocyst complementation are basically prepared by injection method by Matsunari et al. (PNAS, 4557-4562, 2013) and aggregation method by Nakano et al. (Nakano et al. PLoS One, e61900 , 2013). In all cases, humanized Kusabira-Orange (huKO) fluorescent protein was expressed in donor embryo cells.

In the injection method, donor embryos (huKO-labeled) are produced by introducing nuclei removed from healthy female pig cells into enucleated unfertilized eggs by somatic cell nuclear transfer technology, and this nuclear transfer embryo (donor embryo, On day 4, morula stage, cells were dispersed with 0.1 mM EDTA-2Na (Ca ²⁺ / Mg ²⁺ -free PBS, 0.01% polyvinyl alcohol added), and the transparent body was digested with a 0.25% pronase solution. The blastomere from the donor embryo was obtained from the embryo by gentle pipetting using a glass capillary. The host embryo was produced by using the cells of IL2RG knockout pig (male) produced in Example 3 as a nuclear source and introducing the nucleus into an enucleated unfertilized egg by somatic cell nuclear transfer technology. About 10 donors (blastomeres) were injected into the center of the host embryo by micromanipulation. Injected embryos were cultured for 48 hours in vitro to obtain chimeric blastocysts in which host cells and donor cells were mixed.

  On the other hand, in the agglutination method, both donor embryos and host embryos were prepared as Day 4 (morula embryo stage) nuclear transfer embryos, each of which was dispersed with EDTA-2Na, and the zona pellucida was digested by pronase treatment. The blastomeres were separated by gentle pipetting using a glass capillary. Aggregated embryos were prepared by putting blastomeres for one embryo into microwells for both donor embryo-derived cells and host embryo-derived cells. The aggregated embryos were then cultured for 24 hours and developed into blastocysts.

  As a result of transplanting 124 chimeric blastocysts developed at the blastocyst stage into the uterus of two recipient females, two became pregnant and delivered. A total of 6 pups were obtained, and one dead pup was chimera by gene analysis using PCR method and fluorescence observation. As a result of autopsy of this chimeric individual, it was confirmed that the thymus was normally formed. This result indicates that the thymus, which is dysplastic in IL2RG knockout pigs, has been restored by blastocyst complementation. In addition, abnormalities in organs and reproductive organs were not observed. From the above, the individual obtained this time was stillbirth, but if it can survive, it can be considered that it can grow into a male having normal breeding ability. Although this example is stillbirth data, it proves in principle the thymic resurrection (blastocyst complementation) and indicates the possibility of producing a reproductive IL2RG knockout pig (male).

Example 6: Blastocyst complementation for the production of fertile IL2RG knockout pigs (male) (2)
In this example, following the blastocyst complementation using a pig chimeric embryo expressing the humanized Kusabira-Orange (huKO) fluorescent protein shown in Example 5, the breeding of the knockout pig produced in Example 3 was performed. Further studies were made on the possibilities.

  Specifically, Example 5 except that clone embryos (donors, females) prepared from wild-type pig cells with black hair color were used for clone embryos (host, male) derived from IL2RG knockout cells. This was performed according to the blastocyst complementation injection method described in.

  The chimera determination was different from the chimera determination by fluorescent protein in Example 5, and the experiment was designed so that the chimera can be determined by sex and hair color after birth by using a donor whose hair color is black.

  62 chimeric blastocysts (124 total) developed in the blastocyst stage were transplanted into the uterus of two recipient female pigs (M107 and M108 individuals). As a result, one female pig (M107 individuals) became pregnant and delivered. From this female pig, a total of 6 pups (all males are male) are obtained, of which the sex and coat color (the brown color of the wild-type pig and the brown color of the knockout pig are brown, 2 out of 6 litters are chimeric individuals (M107-1 individuals, M107-3 individuals) based on the determination of the hair color to be a mixture of hair and black hair) and gene analysis using PCR. It became clear that. These animals are male (i.e., derived from a host embryo derived from IL2RG knockout cells) in terms of reproductive organs, and because they grow smoothly, immune organs such as the thymus are normal (i.e., derived from healthy pigs). Is guessed. This revealed that these chimeric offspring were SCID pigs that could reproduce. These two chimera pups are growing steadily while gaining weight up to 1.5 months, even after the weaning period, and are alive after 2.5 months.

  In contrast, four of the six that were non-chimeric (SCID pigs) all died at 0-12 days after birth.

  As shown in this example, it was shown that under normal breeding conditions, SCID pigs die soon after birth. On the other hand, in the case of a chimeric offspring, the body weight increases steadily (see FIG. 6), and it survives even after 2.5 months from birth.

  Such a litter derived from a chimeric embryo is still alive and growing, and therefore cannot be subjected to autopsy, so it cannot be actually confirmed whether or not the thymus is present. However, blood can be collected from these individuals to confirm the structure of immune system cells in peripheral blood. As a result, it was shown that T cells and NK cells are almost absent in IL2RG knockout pigs (SCID), while T cells and NK cells are present in SCID chimeric embryo-derived offspring (see Table 4).

  These results show that these individuals grew smoothly and that blastocyst complementation was successful, and that it was possible to produce reproductive IL2RG knockout pig (male) individuals It was.

  In the case of the homologous recombination method or the ZFN plasmid DNA method known as a gene knockout method, there is a risk that the targeting vector is incorporated into an unintended site in the genome, but according to the method of the present invention, By using mRNA encoding ZFN, gene knockout cells can be generated without inserting foreign DNA into the genome, and a highly safe gene knockout method has been successfully developed. In addition, in the method of the present invention, gene knockout cells can be produced in a relatively short period of time, and therefore the time required to produce a gene knockout animal can be greatly shortened.

  In addition to T cells and B cells, XSCID pigs created as a specific embodiment lack natural killer (NK) cells that have an important role in immune functions against tumor cells and transplanted cells. Since pigs are similar in size to humans and physiologically very similar to humans, they are widely used in various cancer models such as cancer research, stem cell transplant research, and drug discovery research. In addition to becoming a model animal to be used, it can be used as a base animal for the production of artificial organs.

Claims (16)

Introducing an mRNA encoding a Zinc finger nuclease (ZFN) protein comprising a Zinc finger domain and a nuclease targeting a target gene sequence into a cell;
Producing a ZFN protein that targets a target gene in a cell;
Cleaving and removing the DNA sequence of the target gene in the genome by the action of the ZFN protein;
Rejoining the cleaved genome by an intracellular DNA damage repair mechanism;
A method for producing a cell in which a gene of interest is knocked out.   2. The production method according to claim 1, wherein the cells are porcine cells.   The production method according to claim 1 or 2, wherein the ZFN protein comprises a plurality of Zinc finger domains.   The production method according to any one of claims 1 to 3, wherein the nuclease contained in the ZFN protein is FokI or StsI.   The production method according to any one of claims 1 to 4, wherein the target gene is an interleukin-2 receptor γ gene (IL2RG gene). A step of producing a cell in which a target gene is knocked out by the method according to any one of claims 1 to 5;
Thereafter, a step of removing the nucleus from the produced cell in which the target gene is knocked out, and somatic cell nuclear transfer into an enucleated unfertilized egg cell;
A step of embryo transfer by transferring an early embryo produced by somatic cell nuclear transfer into the uterus of a surrogate mother;
A method for producing a gene knockout animal, comprising: A step of producing a cell in which a target gene is knocked out by the method according to any one of claims 1 to 5;
Thereafter, a nucleus is taken out from the cell in which the produced target gene is knocked out, and a somatic cell nucleus is transplanted into an enucleated unfertilized egg cell to produce a host embryo;
Removing nuclei from healthy pig cells and transplanting somatic cell nuclei into enucleated unfertilized egg cells to produce donor embryos;
Injecting cells from the donor embryo up to the morula stage into the host embryo until the morula stage;
Embryo transfer of the embryo of the host embryo into which the embryo derived from the donor embryo has been injected into the surrogate mother's womb, and embryo development; and selecting a chimeric male individual capable of forming a sperm in which the target gene has been knocked out Process;
A method for producing a reproductive gene knockout male animal, comprising: A step of producing a cell in which a target gene is knocked out by the method according to any one of claims 1 to 5;
Thereafter, a nucleus is taken out from the cell in which the produced target gene is knocked out, and a somatic cell nucleus is transplanted into an enucleated unfertilized egg cell to produce a host embryo;
Removing nuclei from healthy pig cells and transplanting somatic cell nuclei into enucleated unfertilized egg cells to produce donor embryos;
Dispersing the cells of the host embryo and donor embryo up to the morula stage and mixing the donor embryo-derived cells and the host embryo-derived cells to produce aggregated embryos;
After the blastocyst is formed from the aggregated embryo, the blastocyst is transferred into the surrogate mother's womb and embryonic development is performed; The step of:
A method for producing a reproductive gene knockout male animal, comprising: The method for producing a gene knockout animal according to any one of claims 6 to 8, wherein the target gene is an IL2RG gene.   A gene knockout animal in which a part or all of the coding region of the IL2RG gene is deleted and the function of the IL2RG gene is lost.   The gene knockout animal according to claim 8, which causes X-linked severe combined immunodeficiency (XSCID).   The gene knockout animal according to claim 10 or 11, wherein the animal is selected from pigs, monkeys, rats, mice, cows, and sheep.   13. The gene knockout animal according to claim 12, wherein the animal is a pig.   The gene knockout animal according to any one of claims 10 to 13, wherein a foreign gene is not introduced into the genome into a gene other than the IL2RG gene.   The gene knockout animal according to any one of claims 10 to 14, which is produced by the method according to any one of claims 6 to 9. The gene knockout animal according to any one of claims 10 to 15, which is a reproductive male pig whose thymus is revived.