SBIR-STTR Award

The laboratory rat is the preferred rodent model in pre-clinical drug studies and encompasses the bulk of accumulated knowledge in drug development. Their larger size facilitates procedures otherwise difficult in mice, including studies using instrumentation, blood sampling, and surgeries. Although rats are more suitable than mice for pharmacological, toxicological, physiological, and many biological assays, the absence of genetic engineering technologies suitable for use in the rat has made the mouse the preeminent rodent model. However, the recent emergence of new and more precise gene targeting techniques for the rat has resulted in significant growth in the production of genetically modified rats, which will undoubtedly expand at an exponential rate. A limiting factor in the adoption of genetically modified rats as the rodent model of choice has been the expensive, inefficient, and labor intensive manipulations required for their production, resulting in costs as high as $50,000 to $100,000 per genetically modified rat line. Consequently, it is essential to develop more viable technologies for rat genome engineering that result in more accurate, efficient, and cost-effective production of genetically modified rats. Transposagen Biopharmaceuticals, Inc. is the worldwide leader in the generation of genetically modified rat models and is uniquely positioned to facilitate advancements in this field. Precision BioSciences develops custom genome engineering enzymes based on engineered homing endonucleases. This research proposal is a collaborative effort to merge the two technologies and test the feasibility of using engineered homing endonucleases as an extremely specific and efficient method to produce genetically modified rats. In Phase I we will attempt to knockout the rat Rag1 gene in spermatagonial stem cells (SSCs) using a Rag1-specific endonuclease. These modified cells will then be used to generate knockout Rag1 mutant rats. For comparison, we will attempt to achieve the same result using conventional gene targeting methods in SSCs. The incorporation of an engineered endonuclease in SSCs should greatly streamlines the knockout rat production process, Transposagen Biopharmaceuticals and Precision BioSciences will collaborate in a large-scale Phase II project to generate precisely engineered high-value rat models. Success in this project will significantly reduce the cost of transgenic rat production and give academic and industry investigators greater access to improved rodent models.

Public Health Relevance:
The laboratory rat has been a valuable animal model for biomedical research due to its similarity to human physiology. However, the ease and lower costs associated with generating mutations in mice has lead to a greater reliance on genetically engineered mouse models despite the inability of many of these models to mimic human diseases. We outline a novel strategy that integrates our expertise in spermatogonial stem cells (SSCs) with a site-specific enzyme technology to increase efficiency of mutagenesis. We aim to establish an innovative transgenic rat service that will provide clients with a lower cost and more efficient alternative to the current genetically modified rat technology. Thus, if feasibility is demonstrated, this project would benefit many goals of public health by making the production of mutations in the rat that model human diseases readily accessible to the research community.

Thesaurus Terms:
Adoption;Agreement;Animal Model;Animal Models And Related Studies;Assay;Bioassay;Biologic Assays;Biologic Products;Biological Agent;Biological Assay;Biological Products;Biomedical Research;Blood Sample;Blood Specimen;Cell Isolation;Cell Line;Cell Segregation;Cell Separation;Cell Separation Technology;Cellline;Cells;Client;Clone Cells;Common Rat Strains;Communities;Corynebacterium Diphtheriae Toxin;Custom;Dna;Dna Double Strand Break;Dna Recombination;Dna Recombination (Naturally Occurring);Deletion Mutation;Deoxyribonucleic Acid;Diphtheria Toxin;Drugs;Embryo;Embryonic;Engineering;Enzymes;Event;Feasibility Studies;Female;Frame Shift Mutation;Frameshift Mutation;Frequencies (Time Pattern);Frequency;G 418 Sulfate;G-418;G418;Gene Targeting;Generalized Growth;Generations;Genes;Genetic;Genetic Alteration;Genetic Change;Genetic Engineering;Genetic Engineering Biotechnology;Genetic Engineering Molecular Biology;Genetic Recombination;Genetic Defect;Genetically Engineered Mouse;Genetics-Mutagenesis;Genome Engineering;Genomics;Goals;Growth;Homing;Hour;Human;In Vitro;Industry;Investigators;Knock-Out;Knockout;Knowledge;Laboratory Animals;Laboratory Rat;Lead;Libraries;Licensing;Man (Taxonomy);Measures;Mediating;Medication;Methods;Mice;Mice Mammals;Microinjections;Modeling;Modern Man;Murine;Mus;Mutagenesis;Mutagenesis Molecular Biology;Mutation;Neomycin;O-2-Amino-2,7-Dideoxy-D-Glycero-Alpha-D-Gluco-Heptopyranosyl-(1-4)-O-(3-Deoxy-4-C-Methyl-3-(Methylamino)-Beta-L-Arabinopyranosyl-(1-6))-D-Streptamine;Operative Procedures;Operative Surgical Procedures;Pb Element;Pharmaceutic Preparations;Pharmaceutical Preparations;Phase;Physiologic;Physiological;Physiology;Plasmids;Polymerase;Position;Positioning Attribute;Procedures;Process;Production;Progenitor Cells;Public Health;Rag-1 Genes;Rag1 Gene;Rag1;Rag1 Mouse;Rat;Rat Cell Line;Rats Mammals;Rattus;Reading Frame Shift Mutation;Recombinant Dna Technology;Recombination;Recombination-Activating Genes-1;Reliance;Research;Research Personnel;Research Proposals;Researchers;Resistance;Rodent Model;Services;Site;Stem Cells;Sterility;Strains Cell Lines;Study Models;Surgical;Surgical Interventions;Surgical Procedure;Techniques;Technology;Testicles;Testing;Testis;Tissue Growth;Transfection;Transgenic Organisms;Transmission;Transplantation;Validation;Antibiotic G 418;Arm;Base;Biopharmaceutical;Biotherapeutic Agent;Cell Sorting;Cost;Cost Effective;Cost-Effective;Cultured Cell Line;Drug Development;Drug/Agent;Endonuclease;Genome Mutation;Heavy Metal Pb;Heavy Metal Lead;Hepatoma Cell;Homologous Recombination;Human Disease;Improved;Innovate;Innovation;Innovative;Instrumentation;Male;Model Organism;Mouse Model;Mutant;New Approaches;New Technology;Novel;Novel Approaches;Novel Strategies;Novel Strategy;Novel Technologies;Ontogeny;Pre-Clinical;Preclinical;Public Health Medicine (Field);Pup;Rat Genome;Resistant;Sterile;Success;Surgery;Transgenic;Transmission Process;Transplant;Vector

The laboratory rat is a preferred rodent model in pre-clinical drug studies. Their larger size facilitates procedures otherwise difficult in mice, includng studies using instrumentation, blood sampling, and surgeries, and allows for ten times the amount of tissue collection. Although rats are often more suitable than mice for pharmacological, toxicological, physiological, and many other biological assays, the ease of genetic engineering technologies has made the mouse the preeminent rodent model. However, the recent emergence of new and more precise gene targeting techniques for the rat has resulted in significant growth in the production of genetically-modified rats. In Phase I, we demonstrated the feasibility of combining custom site-specific Xanthomonas TAL Nuclease (XTNTM) [a.k.a. TALEN] technology with spermatogonial stem cells (SSCs) for rapid, cost-effective and precise genome engineering in the rat. Indeed, the Phase I studies enabled Transposagen to launch custom XTNTM and knockout rat production services in 2012, and we have successfully created and delivered custom knockout rats to both industry and academic investigators. In work outside the Phase I project, we paired XTN TALEN technology with piggyBacTM technology to create the Footprint-FreeTM Gene Editing System, the only commercially available system that can engineer as little as a single nucleotide without leaving unwanted mutations and allowing for selection of rare events. For Phase II studies, we propose to use SSC- and Footprint-FreeTM Gene Editing technology to create a suite of rats that would express a specific human CP2D6* allele in the absence of the homologous rat Cyp2d genes (i.e., humanized CYP2D6 rat models). Humans carry a single, but highly polymorphic, p450 CYP2D6 gene. CYP2D6 metabolizes nearly 25% of current drugs and is represented by over 70 variants in the population, which possess a wide range of enzyme activities. As a consequence, adverse drug effects, or lack of drug effect, depend on the specific allele(s) an individual is carrying. Humanized CYP2D6 animal models would be of great value for drug testing. To accomplish this task, we will optimize strategies to simultaneously delete a ~60 kb segment of the rat genome that contains the 5-gene Cyp2d cluster and knock-in a specific human CYP2D6* allele so that it would be placed under transcriptional control of the rat Cyp2d2 promoter to ensure a physiological pattern of expression. Not only would the humanized rat be useful for assessing the consequences of CYP2D6*-specific metabolites in the whole animal, but hepatocytes isolated from these animals would provide a reliable and consistent source of CYP2D6* hepatocytes for in vitro drug metabolism testing. More generally, successful optimization of Footprint-FreeTM Gene Editing protocols for the creation of large-scale humanizing knock-in mutations would enable, for the first time, the possibility of sophisticated and cost-effective genome engineering in many mammalian organisms.

Public Health Relevance Statement:


Public Health Relevance:
The laboratory rat has been a valuable animal model for biomedical research due to its similarity to human physiology. Pharmaceutical companies currently rely primarily on animal or transformed cell models for pre- clinical metabolism and toxicity testing during drug discovery. Thus, there is a compelling need for animal models that are more predictive for ADME properties in humans. However, the ease and lower costs associated with generating mutations in mice has lead to a greater reliance on genetically engineered mouse models despite the inability of many of these models to mimic human pathways. We outline a strategy that integrates our expertise in spermatogonial stem cells (SSCs) with a site-specific enzyme technology to create knockout and humanized rat models for drug discovery applications. Thus, this project would benefit many goals of public health by making the production of mutations in the rat that better model human physiology readily accessible to the research community.

Project Terms:
Adverse drug effect; Alleles; Animal Model; Animals; arm; base; Biological Assay; Biomedical Research; Blood specimen; Cell Line; Cell model; cell transformation; Cells; Cleaved cell; Communities; Complex; cost; cost effective; Coupled; Custom; CYP2D6 gene; design; Detection; drug discovery; drug metabolism; drug testing; endonuclease; Engineering; Ensure; enzyme activity; enzyme model; Enzymes; Event; Excision; Gene Family; Gene Targeting; Genes; Genetic Engineering; Genetically Engineered Mouse; Genome engineering; Goals; Growth; Hepatocyte; homologous recombination; Housing; Human; In Vitro; Individual; Industry; instrumentation; interest; Knock-in Mouse; Knock-out; knockout gene; Laboratory Rat; Lead; Left; Link; male; member; Metabolism; Methods; Modeling; mouse model; Multigene Family; Mus; Mutation; Nonhomologous DNA End Joining; novel; nuclease; Nucleotides; Operative Surgical Procedures; Organism; Pathway interactions; Pattern; Pharmaceutical Preparations; Pharmacologic Substance; Phase; phase 1 study; phase 2 study; Physiological; Physiology; Population; pre-clinical; predictive modeling; Procedures; Production; Promotor (Genetics); Property; Protocols documentation; public health medicine (field); public health relevance; rat genome; Rattus; Reliance; Research; Research Personnel; Rodent Model; Services; Shipping; Ships; Site; Source; stem; Stem cells; System; Techniques; Technology; Testing; Time; Tissue Banks; Toxic effect; Toxicity Tests; Transcriptional Regulation; Transplantation; Transposase; United States National Institutes of Health; Variant; vector; Work; Xanthomonas