This technology includes a conventional knockout mice: beta- 1,4-N-acetylgalactosaminyl transferase 1 (GM2 Synthase) KO; B4galntltm1Rlp for the study of glycosphingolipid storage disorders. The glycosphingolipid (GSL) storage diseases are caused by genetic disruption in the lysosomal degradation pathway of GSLs, and include Tay-Sachs disease, Sandhoff's disease, Gaucher's disease, Fabry's disease, Krabbe's disease, and several others. In most of these diseases, GSLs accumulate to massive levels in cells, particularly in neurons, causing neurodegeneration and a shortened life span.

This technology includes A1AR-selective agonists which are full or partial agonists of the A1AR and are being considered for treatment of various conditions: seizures, stroke, diabetes, pain, cardio-protection and arrhythmias. A1AR agonists are highly neuroprotective in ischemic and epileptic models. A1AR agonists are also being explored for antidepressant, antianxiety, and other neuropsychiatric effects, due to their presynaptic action to decrease the release of excitatory amino acids in the brain.

This technology includes a mouse model for studying SiP1 receptor signaling for development of therapeutics for a variety of conditions. The S1P1 receptor locus of the mouse has been modified by gene targeting to encode a fusion of the S1P1 receptor and the tetracycline-controlled activator protein (tTA) connected by a Tobacco Etch Virus (TEV) cleavage sequence, internal ribosome initiation sequence (IRES), followed by a beta-arrestin-Tobacco Etch Virus (TEV) protease fusion protein. When activated, the modified S1P1 receptor binds the beta-arrestin-TEV protease fusion, which cleaves the tTA.

This technology includes a transgenic mouse model which can be used to study perinatal oocyte dynamics. In the first two days after birth, the number of primordial ovarian follicles and their germ cells undergo a major decrease. The mechanism for this decrease was studied. Ablation of FIGLA (Factor in the germline, alpha), a basic helix-loop-transcription factor, results in massive perinatal oocyte loss. A transgenic mouse line was established, Figla-EGFP /Cre, in which EGFP and Cre recombinase are expressed just before birth in germ cells.

This technology includes lentivirus vectors to be used to treat sickle cell disease and beta thalassemia. (i) Lin28A or Lin28B vectors designed for erythroid-specific expression using EKLF1, SPTA1, or similar erythroid-specific regulatory elements will be used to transduce hematopoietic stem cells isolated from humans with sickle cell disease or beta-thalassemia syndromes.

This technology includes identification of the wild mouse microbiome as a method to increase resistance to lethal viral infection. We establish that the gut microbiome of barrier-raised C57BL/6 mice is dysbiotic compared to that of their outbred, wild-living progenitors, Mus musculus domesticus. We find that the multigenerational offspring of pregnant germfree C57BL/6 mice reconstituted with the gut microbiome of wild mice exhibit a less inflammatory response and increased survival following influenza A virus infection.

This technology includes transgenic mice in which designer rat M3 muscarinic receptor mutants were expressed only in islet 13-cells (directed by rat insulin promoter II), were unable to bind acetylcholine (the endogenous ligand) but could be selectively activated by an otherwise pharmacologically inert compound (clozapine-N-oxide (CNO)). The R-q receptor contained a Y148C point mutation, which enabled CNO to selectively activate G proteins of the Gq/11 family. The R-5 receptor contained an A238G mutation, which enabled CNO to selectively activate G proteins of the G5 family.

This technology includes a Drosophila mutant strain that can be used as an in vivo model for diseases of the oral cavity and digestive tract (Sjogren's syndrome, colitis, colon cancer, inflammatory bowel disease), where the mucous membrane is disrupted or non-functional. This mutant lacks a mucous membrane and displays epithelial cell damage, uncontrolled cell proliferation and the up-regulation of conserved signaling pathways (JAK/STAT).

This technology includes a novel AAV isolate (AAV44.9) to be used as gene therapy for the inner ear for the treatment of deafness. The ability of AAV vectors to transduce dividing and non-dividing cells, establish long-term transgene expression, and the lack of pathogenicity has made them attractive for use in gene therapy applications. Vectors based on new AAV isolates may have different host range and different immunological properties, thus allowing for more efficient transduction in certain cell types.