Overview of gene editing technology
Since 2000, we have established a reliable and efficient service platform for genetically engineered mice and we are committed to providing the best-in-class solutions for genetically engineered animal models. To achieve that, we have:
Dedicated project management team
AI-driven automated design platform SmartEddi
Team of highly experienced research staff
The following three types of genetic engineering technologies are used to generate genetically engineered mouse(GEM) models:
Comparison
Embryonic Stem Cell Targeting
In murine embryonic stem cells, the exchange of an endogenous allele of a target gene for a mutated copy via homologous recombination allows the generation of targeted ES cells with defined mutations. Genetically engineered ES cells remain pluripotent and are able to develop into germ cells in the chimeric animals, thereby ensuring the germline transmission and the creation of a genetically modified line. As of today, embryonic stem cells targetng remains the most classic and reliable genetic engineering technology for mouse models.
Currently, SMOC provides mouse ES cells with three types of genetic background: C57BL/6, 129/S6, B6;129.
These mouse ES cells can be used to generate the following types of mouse models:
Gene knockout
Conditional gene knockout
KO first
Gene knock-in
Point mutation
Conditional point mutation
Targeted gene overexpression
Humanization
SMOC will select the most appropriate technology for each project on a case-by-case basis, by taking project duration and technology risk into account.
Workflow of mouse genetic engineering with ES cell targeting
Design and generate homologous recombination vectors
Transfer the homologous recombination vectors into murine ES cells
Screen and validate the positive targeted ESC clones
Microinject positive ESC clones into mouse blastocysts
Transplant the injected mouse blastocysts into the uterus of pseudopregnant female mice
Generate and screen positive chimeric mice F0
Obtain F1 heterozygous mice by mating positive F0 with wild-type mice or FLP mice
CRISPR Gene Editing Technology
Advantages of CRISPR gene editing technology
Faster compared to the traditional method.
Not limited by the availability of mouse genetic strains
More cost efficient
Workflow of mouse genetic engineering with CRISPR/Cas9 technology
Select target site and design sgRNA, design homologous recombination vector (optional)
Prepare sgRNA and Cas9 mRNA, generate homologous recombination vector (optional)
Microinject sgRNA and Cas9 mRNA (and homologous recombination vector (optional)) into mouse fertilized eggs
Transplant fertilized eggs into the oviducts of pseudopregnant female mice
Generate and screen positive chimeric mice F0
Obtain F1 heterozygous mice by mating positive F0 with wild-type mice
Random Transgenes
A pre-designed gene (or genes) are randomly integrated into the mouse genome through pronuclear microinjection to generate transgenic mice. PiggyBac transposon system usually improves the efficiency.
Workflow of mouse genetic engineering via random transgenes
Design and generate transgenic plasmid
Inject linearized transgenic plasmid into mouse fertilized eggs
Transplant fertilized eggs into the oviducts of pseudopregnant female mice
Generate and screen positive chimeric mice F0
Workflow of mouse genetic engineering via piggBac transposon system
Design and generate PiggyBAC transposon plasmid
Inject transposon plasmid and PiggyBAC transposase into mouse fertilized eggs
Transplant fertilized eggs into the oviducts of pseudopregnant female mice
Generate and screen positive chimeric mice F0
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SMOC’s Annual Progress and Advances in Preclinical immuno-Oncology Research: The workshop is designed as a forum for ideas and opinions exchange on how to decrease the rate of clinical failures in oncology and immuno-oncology.
詳細After the base is put into operation, SMOC’s capability to provide genetically modified rat/mouse models and technical services including gene function research and drug development will be greatly enhanced.
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