The aim of the study was to establish Ace2 (angiotensin-converting enzyme 2) knockout mouse model with CRISPR/Cas9 gene targeting technology. A vector targeting Ace2 gene knockout was constructed with the primers of single-guide RNA (gRNA), and then transcribed gRNA/Cas9 mRNA was micro-injected into the mouse zygote. The deletion of exons 3 to 18 of Ace2 gene in mice was detected and identified by PCR and gene sequencing. The Ace2 gene knock-out mice were bred and copulated. Ace2 protein and mRNA expression were detected by Western blot and qRT-PCR in F3 progeny knock-out male mice. The gRNA expression vector was successfully constructed and transcribed in vitro, and active gRNA and Cas9 mRNA were injected directly into zygote. The deletion of exons 3 to 18 of Ace2 gene in six positive founder mice as the F0 generation were confirmed by PCR and gene sequencing. Six founder mice were mated with wild-type mice, then achieved F1 generation were mated and produced F2 generation. The female positive mouse of F2 was selected to mate with wild-type mice and produce Ace2 mice of F3 generation. Ace2 mRNA and protein were not detected in tissues of these Ace2 mice. In conclusion, a mouse model with Ace2 deficiency has been successfully established with CRISPR/Cas9 technique, which shall lay a foundation for future investigation of Ace2.
Animals ; CRISPR-Cas Systems ; Female ; Gene Knockout Techniques ; Gene Targeting ; Male ; Mice ; Mice, Knockout ; RNA, Guide ; genetics

The establishment and development of gene knockout mice have provided powerful support for the study of gene function and the treatment of human diseases. Gene targeting and gene trap are two techniques for generating gene knockout mice from embryonic stem cells. Gene targeting replaces endogenous knockout gene by homologous recombination. There are two ways to knock out target genes: promoter trap and polyA trap. In recent years, many new gene knockout techniques have been developed, including Cre/loxP system, CRISP/Cas9 system, latest ZFN technology and TALEN technology. This article focuses on the several new knockout mouse techniques.
Animals ; Disease Models, Animal ; Embryonic Stem Cells ; Gene Knockout Techniques ; trends ; Gene Targeting ; trends ; Homologous Recombination ; Humans ; Mice ; Mice, Knockout

The objective of this study was to compare the effects between knocking-out Sam68 gene by homologous recombination method and silencing the gene by siRNA silencing technique in DT40 cell line. Gene targeting technique was used to isolate Sam68 gene-deleted chicken DT40 cells. Meanwhile, Sam68 gene silencing cells was obtained by using stable expression of siRNA plasmid pSilencer-Sam68. Then, the function of these two cell lines were analyzed by comparing with wild-type DT40 cell line. The results showed that the growth retardation in Sam68 gene knocked-out cell line was observed due to elongation of the G2/M phase, but which could not be found in Sam68 gene silencing cell line. It is concluded that in accordance with study of protein function in living cells, use of gene knockout technique for cell line can provide the experimental results more real than those resulting from gene silence technique.
Animals ; Cell Line, Tumor ; Chickens ; Gene Expression Regulation, Neoplastic ; Gene Knockout Techniques ; Gene Silencing ; Gene Targeting ; Plasmids ; RNA, Small Interfering ; genetics ; Transfection

S100 calcium binding protein A9 (S100A9) is involved in a variety of biological processes such as inflammation and tumor cell migration and invasion regulation. The purpose of this study was to construct S100A9 gene-edited mice by using CRISPR/Cas9 technology, thereby providing an animal model for exploring the biological functions of this gene. According to the S100A9 gene sequence, the single-stranded small guide RNA (sgRNA) targeting exons 2 and 3 was transcribed in vitro, and a mixture of Cas9 mRNA and candidate sgRNA was injected into mouse fertilized eggs by microinjection. Early embryos were obtained and transferred to surrogate mice, and F
Animals ; Bronchoalveolar Lavage Fluid ; CRISPR-Cas Systems/genetics* ; Calgranulin B ; Disease Models, Animal ; Gene Knockout Techniques ; Gene Targeting ; Lung ; Mice ; Mice, Inbred C57BL ; Mice, Knockout ; Ovalbumin ; Phenotype

It is one of the frequently utilized strategies for positive-negative selection to elevate the gene targeting efficiency in somatic cells by enriching targeted colonies. Knocking out prnp in animals by gene targeting can prevent it from expressing Prion protein (Pathogenic protein of transmissible spongiform encephalopathy), which enables it to resist infection of Prion. We constructed a bovine prnp biallelic targeting vector via the positive-negative selection strategy, and transfected the linearized vector into the bovine fetal fibroblasts through electroporation. Then, we selected cells in cell culture medium with G418 under a concentration of 600 microg/mL followed by Ganciclovir (GCV) under a concentration of 200 nmol/mL. In the end, we successfully obtained 176 cell clones. All these clones were identified by means of sequencing, immunofluorescence and western blotting, respectively, confirming that there existed 9 positive cell clones. The results showed that the bovine prnp gene was successfully knocked out. Conclusively, we provide an effective way to knockout bovine prnp gene, which could serve as the basis for producing prion protein gene knockout transgenic cloned cattle.
Animals ; Cattle ; Electroporation ; Encephalopathy, Bovine Spongiform ; genetics ; Fetus ; cytology ; Fibroblasts ; cytology ; metabolism ; Gene Knockout Techniques ; methods ; Gene Targeting ; Genetic Vectors ; genetics ; Prions ; genetics ; Transfection

The effective material basis of traditional Chinese medicine(TCM) is an indispensable part of studies on TCM, and each technology has its advantages and disadvantages. The target constituent knock-out/knock-in technology has attracted much attention since it was proposed because of its unique advantages of regarding the extract of the formula as a whole, which can better reflect the characteristics of multi-component and multi-target integration and regulation of TCM. This method investigated the contribution of target constituent to the overall efficacy of a TCM by analyzing the changes in efficacy of the remaining formula before and after knock-out/knock-in of the target constitution. The application of this model not only facilitates studies of the effective constituents of TCM, but also help to develop the quality control standard of TCM. However, the application of this model is restricted due to the limitation of target constituent separation technology. By reviewing the literatures in recent years, this study summarized the research process and application of this method for a reference.
Animals ; Drugs, Chinese Herbal/pharmacology* ; Gene Knock-In Techniques ; Gene Knockout Techniques ; Medicine, Chinese Traditional ; Quality Control

BACKGROUND: It has been proven that CRISPR/Cas9 (Clustered Regularly Interspaced Short Palindromic Repeats/CRISPR-associated 9) system was the modern gene-editing technology through the constitutive expression of nucleases Cas9 in the mammalian, which binds to the specific site in the genome mediated by single-guide RNA (sgRNA) at desired genomic loci. The aim of this study is that the animal model of EZH2 gene knockout was constructed using CRISPR/Cas9 technology. METHODS: In this study, we designed two single-guide RNAs targeting the Exon3 and Exon4 of EZH2 gene. Then, their gene-targeting efficiency were detected by SURVEYOR assay. The lentivirus was perfused into the lungs of mice by using a bronchial tube and detected by immunohistochemistry and qRT-PCR. RESULTS: The experimental results of NIH-3T3 cells verify that the designed sgEZH2 can efficiently effect the cleavage of target DNA by Cas9 in vitro. The immunohistochemistry and qRT-PCR results showed that the EZH2 expression in experimental group was significantly decreased in the mouse lung tissue. CONCLUSIONS The study successfully designed two sgRNA which can play a knock-out EZH2 function. An EZH2 knockout animal model was successfully constructed by CRISPR/Cas9 system, and it will be an effective animal model for studying the functions and mechanisms of EZH2.
Animals ; CRISPR-Cas Systems ; Enhancer of Zeste Homolog 2 Protein ; genetics ; metabolism ; Female ; Gene Knockout Techniques ; Gene Targeting ; Humans ; Lung Neoplasms ; genetics ; metabolism ; Male ; Mice ; Mice, Inbred C57BL ; Mice, Knockout ; RNA, Guide

Gene knockout by ZFNs (zinc-finger nucleases) is efficient and specific, and successfully applied in more than 10 organisms. Currently, it is unclear whether this technology can be used for knocking-out enhanced green fluorescent protein (EGFP) gene in transgenic goats. Here we constructed and used ZFN-coding plasmids to produce genetic knockouts in the cells of cloned fetus produced from donor cells by microinjection of EGFP gene. Following introduced plasmids into caprine primary cultured fetus fibroblasts by electroporation, targeting of a transgene resulted in sequence mutation. Using the flow cytometric analysis, we confirmed the disappearance of EGFP expression in treated cells. Sequence from PCR products corresponding to targeted site showed that insertion of a G into the exon of EGFP resulted in frame shift mutation. These results suggest that ZFN-mediated gene targeting can apply to caprine fetus fibroblasts, which may open a unique avenue toward the creation of gene knockout goats combining with somatic cell nuclear transfer.
Animals ; Base Sequence ; Cloning, Organism ; Electrophoresis ; Endonucleases ; genetics ; metabolism ; Fetus ; Fibroblasts ; metabolism ; Gene Knockout Techniques ; Gene Targeting ; methods ; Goats ; Green Fluorescent Proteins ; genetics ; Molecular Sequence Data ; Mutation ; Zinc Fingers

In producing transgenic livestock, selectable marker genes (SMGs) are usually used to screen transgenic cells from numerous normal cells. That results in SMGs integrating into the genome and transmitting to offspring. In fact, SMGs could dramatically affect gene regulation at integration sites and also make the safety evaluation of transgenic animals complicated. In order to determine the deletion time and methods in the process of producing transgenic goats, the feasibility of deleting SMGs was explored by Cre/LoxP before or after somatic cell cloning. In addition, we compared the efficiency of protein transduction with plasmids co-transduction. We could delete 43.9% SMGs after screening out the transgenic cell clones, but these cells could not be applied to somatic cells cloning because of serious aging after two gene modifications. The SMG-free cells suitable for nuclear transfer were accessible by using the cells of transgenic goats, but this approach was more time consuming. Finally, we found that the Cre plasmid could delete SMGs with an efficiency of 7.81%, but about 30% in SMG-free cells had sequences of Cre plasmid. Compared with Cre plasmid, the integration of new exogenous gene could be avoided by TAT-CRE protein transduction, and the deletion rate of TAT-CRE transduction was between 43.9 and 72.8%. Therefore, TAT-Cre transduction could be an effective method for deleting selectable marker genes.
Animals ; Animals, Genetically Modified ; genetics ; Cloning, Organism ; veterinary ; Gene Knockout Techniques ; Gene Targeting ; methods ; Genes, Reporter ; Genetic Engineering ; Genetic Vectors ; genetics ; Goats ; genetics ; Integrases ; chemistry ; metabolism ; Recombination, Genetic ; Transgenes ; genetics

Homologous recombination is an important technique that is used to modify mammalian genome. Here, we constructed an efficient common gene targeting vector based on the plasmid pBS246. The vector consisted two positive selection markers, neomycin resistance gene (neo) and enhanced green fluorescent protein gene (EGFP) flanked by locus of X-over P1 (LoxP) sites. Two synthesized multiple cloning sequences MCS-1 and MCS-2 that contain several "8 bp cutter" enzyme sites were placed in outside of LoxP sites. Additionally, a negative selection marker HSV-tk (herpes simplex virus thymidine kinase) gene was located adjacent to MCS-1 site. The constructed vector was named pGT-V1, and its functions were characterized in C2C12 cells. The vector had the following unique features: 1) EGFP was used to monitor instantly the transfection rate that was essential for increasing the efficiency of gene knockout (KO); 2) The EGFP marker located between two LoxP sites was able to be removed from KO positive cells to avoid the potential damage of selection markers to the recipient cells. The process could be monitored visually and the positive cells without selecting markers (the loss of green fluorescent cells) could be sorted out by either flow cytometry or immunomagnetic beads; 3) "8 bp cutter" restriction sites were embedded in MCS sequences, which then enhanced the versatility of this vector. In summary, the constructed plasmid optimized the vector of gene targeting and provided a new technique means for the transgenic animal research.
Animals ; Base Sequence ; Cloning, Molecular ; Drug Resistance ; genetics ; Gene Knockout Techniques ; Gene Targeting ; methods ; Genetic Vectors ; genetics ; Green Fluorescent Proteins ; genetics ; Homologous Recombination ; Mice ; Molecular Sequence Data ; Neomycin ; pharmacology