This application proposes to establish a fourth Mutant Mouse Regional Resource Center (MMRRC) repository at The Jackson Laboratory (JAX). For over 60 years mutant mice, with phenotypes mimicking human diseases, have played a critical role in understanding the genetics underlying mammalian biology and human genetic disorders. The advent of transgenic and gene targeting technologies, coupled with large scale mutagenesis and gene trap programs has led to a virtual explosion in the production and use of mutant and genetically engineered mice. These valuable resources can only be fully exploited if they are archived, managed, and made accessible to the scientific community by centralized repositories. The Jackson Laboratory's experience and capacity as a repository, the quality of its existing programs, its management systems, and its reputation for research excellence all demonstrate that JAX will be a strong addition to the MMRRC network. In this application, we propose to establish a JAX MMRRC that would: 1) acquire mutant strains;2) import and archive mutant strains;3) distribute strains as cryopreserved material, mice recovered from cryopreserved material, ES cell lines, or live mice;4) implement a state-of-the-art quality control program;5) provide customer support and technical service;6) promote MMRRC strains;7) have an interactive Repository management plan;8) establish the bioinformatics infrastructure to operate and to interact with other MMRRC repositories, and 9) conduct research to add utility to JAX MMRRC strains by developing pluripotent stem cell resources from valuable Repository disease models using both standard derivation techniques and IPS technology. The JAX MMRRC will be fully functional upon funding and will offer experience and capacity to the existing MMRRC program.
The JAX Mutant Mouse Regional Resource Center (MMRRC) repository proposed in this project will provide access to mouse models for human disorders and for basic biomedical research to understand biological systems affected by human diseases. With a sequenced genome and increasingly sophisticated stem cell technologies to manipulate it, the mouse remains the most powerful model organism for biomedical research. Genetically engineered mouse models with homologous human genes are critical for translational and pre-clinical research. They enable scientists to understand the causes and pathologies of human diseases so that prevention strategies or therapeutics for these diseases can be developed. In addition, therapies or drugs can be tested on mouse models prior to human trials to assess efficacy and safety.
|Lilue, Jingtao; Doran, Anthony G; Fiddes, Ian T et al. (2018) Sixteen diverse laboratory mouse reference genomes define strain-specific haplotypes and novel functional loci. Nat Genet 50:1574-1583|
|Montonye, Dan R; Ericsson, Aaron C; Busi, Susheel B et al. (2018) Acclimation and Institutionalization of the Mouse Microbiota Following Transportation. Front Microbiol 9:1085|
|Racine, Jeremy J; Stewart, Isabel; Ratiu, Jeremy et al. (2018) Improved Murine MHC-Deficient HLA Transgenic NOD Mouse Models for Type 1 Diabetes Therapy Development. Diabetes 67:923-935|
|Lutz, Cathleen (2017) A license to cure? Lab Anim (NY) 46:162-163|
|Peterson, Kevin A; Beane, Glen L; Goodwin, Leslie O et al. (2017) CRISPRtools: a flexible computational platform for performing CRISPR/Cas9 experiments in the mouse. Mamm Genome 28:283-290|
|Willmann, Raffaella; Gordish-Dressman, Heather; Meinen, Sarina et al. (2017) Improving Reproducibility of Phenotypic Assessments in the DyW Mouse Model of Laminin-?2 Related Congenital Muscular Dystrophy. J Neuromuscul Dis 4:115-126|
|Liu, Edison T; Bolcun-Filas, Ewelina; Grass, David S et al. (2017) Of mice and CRISPR: The post-CRISPR future of the mouse as a model system for the human condition. EMBO Rep 18:187-193|
|Manolio, Teri A; Fowler, Douglas M; Starita, Lea M et al. (2017) Bedside Back to Bench: Building Bridges between Basic and Clinical Genomic Research. Cell 169:6-12|
|Lloyd, Kent; Franklin, Craig; Lutz, Cat et al. (2015) Reproducibility: use mouse biobanks or lose them. Nature 522:151-3|
|Srivastava, Anuj; Philip, Vivek M; Greenstein, Ian et al. (2014) Discovery of transgene insertion sites by high throughput sequencing of mate pair libraries. BMC Genomics 15:367|
Showing the most recent 10 out of 13 publications