SBIR-STTR Award

The cost of drug development has skyrocketed to an estimated $2.6B for every FDA approved drug primarily due to failures from lack of efficacy or safety, suggesting that our current preclinical validation process has been insufficient in predicting therapeutic potential and toxicity in humans. Animal models are the gold standard for dissecting disease mechanisms and evaluating novel drug targets in vivo; however, the cost and long lead time to develop them has prevented their routine use in the drug discovery process. With the recent developments in CRISPR/Cas9 genome editing, and advances in RNA interference technologies, we now have the ability to rapidly develop animal models with precise genomic modifications, and human-like disease pathologies. We have shown that RNAi serves as a fast alterative to gene deletion and can also be used within genetically engineered mouse models to assess the therapeutic potential and predict toxicities of novel gene targets. The goal of this proposal is to expand our capabilities beyond mice and develop a platform for rapid and cost-effective production of RNAi rats in as little as 4 months. Despite the utility of mouse models, for many scientists, the rat still remains the preferred rodent due to their larger size for surgical manipulation, repeat blood sampling, and their cognitive and physiological characteristics that more closely resemble humans than their mouse counterparts. For neurobiology, cardiobiology, immunology and toxicology, they are still the dominant rodent model in research. Nearly 20% of our current client base has inquired about rat models over the last 5 years, noting that most toxicology studies of their compounds are still done in rats prior to Phase I. We believe that rats will gain popularity once again as the premier rodent model in drug discovery and we intend to be at the forefront of this shifting paradigm. CRISPR/Cas9 genome editing now provides a path for manipulating the rat genome; however, current approaches enable the derivation of permanent gene knockout alleles, but do not allow temporal and reversible gene regulation. Our goal is to draw from our vast experience of mouse model creation and exploit the efficiency of CRISPR-based targeting to develop RNAi rat models that enable inducible and reversible gene silencing to simulate therapeutic regimes. These RNAi rat models will transform the preclinical validation process with assessment of potential drug response and resistance mechanisms in vivo, ultimately guiding the development of safer and more effective drugs.

Project Terms:
Advanced Development; Alleles; Animal Model; base; Blood specimen; Characteristics; Client; Clinical Trials; Clustered Regularly Interspaced Short Palindromic Repeats; Cognitive; cost; cost effective; Coupled; CRISPR/Cas technology; Custom; Data; Derivation procedure; Development; Disease; Drug Costs; drug development; drug discovery; Drug usage; Embryo; embryo cell; Engineering; experience; Failure; FDA approved; Foundations; Future; Gene Deletion; gene discovery; Gene Expression; Gene Expression Regulation; Gene Silencing; Gene Targeting; Generations; Genes; Genetic Engineering; Genetically Engineered Mouse; Genome; genome editing; Genome engineering; Genomics; Goals; Gold; Harvest; Homing; Human; human disease; Immunology; in vivo; inducible gene expression; inhibitor/antagonist; Injections; Intervention; Knock-in; knockout animal; knockout gene; large scale production; Lead; Mediating; model development; Modeling; Modification; mouse model; Mus; Neurobiology; new therapeutic target; novel; Operative Surgical Procedures; Organism; Pathology; Pharmaceutical Preparations; Phase; Physiological; pre-clinical; Preclinical Testing; prevent; Procedures; Process; Production; promoter; rat genome; Rat Strains; Rattus; Reporter; Research; Research Personnel; resistance mechanism; Resort; response; RNA Interference; Rodent; Rodent Model; Safety; Scientist; Site; Small Business Innovation Research Grant; small hairpin RNA; System; Technology; Testing; Tetanus Helper Peptide; Therapeutic; Therapeutic Intervention; Therapeutic Studies; Time; tool; Toxic effect; Toxicology; Trans-Activators; Transgenic Organisms; Translating; Validation;

The cost of drug development has skyrocketed to an estimated $2.6B for every FDA approved drug primarily due to failures from lack of efficacy or safety, suggesting that our current preclinical validation process has been insufficient in predicting therapeutic potential and toxicity in humans. Animal models are the gold standard for dissecting disease mechanisms and evaluating novel drug targets in vivo; however, the cost and long lead time to develop them has prevented their routine use in the drug discovery process. With the recent developments in CRISPR/Cas9 genome editing, and advances in RNA interference technologies, we now have the ability to rapidly develop animal models with precise genomic modifications and human-like disease pathologies. We have shown that RNAi serves as a fast alternative to gene deletion and can also be used within genetically engineered mouse models to assess the therapeutic potential and predict toxicities of novel gene targets. The goal of this proposal is to expand our capabilities beyond mice and develop a platform for rapid and cost-effective production of RNAi rats in as little as 4 months. Despite the utility of mouse models, for many scientists, the rat still remains the preferred rodent due to their larger size for surgical manipulation, repeat blood sampling, and their cognitive and physiological characteristics that more closely resemble humans than their mouse counterparts. For neurobiology, cardiobiology, immunology and toxicology, they are still the dominant rodent model in research. Nearly 30% of our current client base has inquired about rat models over the last 5 years, noting that most toxicology studies of their compounds are still done in rats prior to Phase I clinical trials. We know rats will gain popularity once again as the premier rodent model in drug discovery, as we have already been contracted a large pharmaceutical company for an initial pilot program for these models. We intend to be at the forefront of this shifting paradigm back to the rat model. Using novel in situ delivery methods of CRISPR/Cas9 reagents, we will now be able to manipulate the rat genome in a rapid and cost-efficient manner and systematically generate RNAi rat models that allow for temporal and reversible gene regulation to simulate therapeutic regimes. These RNAi rat models will transform the preclinical validation process with assessment of potential drug response and resistance mechanisms in vivo, ultimately guiding the development of safer and more effective drugs.

Public Health Relevance Statement:
Narrative The goal of this project is to develop a powerful and highly efficient platform for generating RNAi rat models with reversible gene silencing capabilities in as little as 4 months using CRISPR-mediated genome engineering. For many scientists, the rat still remains the preferred rodent due to their larger size and cognitive and physiological characteristics that more closely resemble humans than their mouse counterparts; however current approaches of genome manipulation in rats allow for only permanent gene knockout. Through temporal and reversible gene regulation, these RNAi rat models will transform the preclinical validation process with in vivo assessment of potential drug response, ultimately guiding the development of safer and more effective drugs.

Project Terms:
Adopted; Advanced Development; Animal Model; Back; base; Biological Models; Blood specimen; Carcinogenicity Tests; Cessation of life; Characteristics; Client; Clustered Regularly Interspaced Short Palindromic Repeats; Cognitive; Contracts; cost; cost effective; cost efficient; CRISPR/Cas technology; Custom; Development; Disease; Drug Costs; drug development; drug discovery; Drug usage; Embryo; Embryology; experience; Failure; FDA approved; Female; Foundations; Funding; Future; Gene Deletion; gene discovery; Gene Expression; Gene Expression Regulation; Gene Silencing; Gene Targeting; Generations; Genes; Genetic Engineering; Genetically Engineered Mouse; Genome; genome editing; Genome engineering; Genomics; Goals; Gold; Hand; Homing; Human; human disease; Immunology; In Situ; in vivo; Investments; knockout animal; knockout gene; Laboratories; Lead; Libraries; Mammalian Oviducts; Marketing; Mediating; Methods; Modeling; Modification; mouse model; Mus; Neurobiology; new therapeutic target; novel; nucleic acid delivery; operation; Operative Surgical Procedures; Pathology; Pharmaceutical Preparations; Pharmacologic Substance; Phase; Phase I Clinical Trials; Physiological; pre-clinical; Preclinical Testing; prevent; Procedures; Process; Production; programs; promoter; Protocols documentation; rat genome; Rattus; Reagent; Reporter; Research; Research Personnel; resistance mechanism; Resort; response; Rivers; RNA Interference; Rodent; Rodent Model; Safety; Scientist; Services; Site; Small Business Innovation Research Grant; small hairpin RNA; Surveys; System; Technology; Technology Transfer; Therapeutic; Therapeutic Intervention; Therapeutic Studies; Time; tool; Toxic effect; Toxicity Tests; Toxicology; Translating; Validation; Work