Genetic mutation of Tas2r104/Tas2r105/Tas2r114 cluster leads to a loss of taste perception to denatonium benzoate and cucurbitacin B.

BACKGROUND: Bitter taste receptors (Tas2rs) are generally considered to sense various bitter compounds to escape the intake of toxic substances. Bitter taste receptors have been found to widely express in extraoral tissues and have important physiological functions outside the gustatory system in vivo. METHODS: To investigate the physiological functions of the bitter taste receptor cluster Tas2r106/Tas2r104/Tas2r105/Tas2r114 in lingual and extraoral tissues, multiple Tas2rs mutant mice and Gnat3 were produced using CRISPR/Cas9 gene-editing technique. A mixture containing Cas9 and sgRNA mRNAs for Tas2rs and Gnat3 gene was microinjected into the cytoplasm of the zygotes. Then, T7EN1 assays and sequencing were used to screen genetic mutation at the target sites in founder mice. Quantitative real-time polymerase chain reaction (qRT-PCR) and immunostaining were used to study the expression level of taste signaling cascade and bitter taste receptor in taste buds. Perception to taste substance was also studied using two-bottle preference tests. RESULTS: We successfully produced several Tas2rs and Gnat3 mutant mice using the CRISPR/Cas9 technique. Immunostaining results showed that the expression of GNAT3 and PLCB2 was not altered in Tas2rs mutant mice. But qRT-PCR results revealed the changed expression profile of mTas2rs gene in taste buds of these mutant mice. With two-bottle preference tests, these mutant mice eliminate responses to cycloheximide due to genetic mutation of Tas2r105. In addition, these mutant mice showed a loss of taste perception to quinine dihydrochloride, denatonium benzoate, and cucurbitacin B (CuB). Gnat3-mediated taste receptor and its signal pathway contribute to CuB perception. CONCLUSIONS: These findings implied that these mutant mice would be a valuable means to understand the biological functions of TAS2Rs in extraoral tissues and investigate bitter compound-induced responses mediated by these TAS2Rs in many extraoral tissues.

Development of a humanized HLA-A30 transgenic mouse model.

BACKGROUND: There are remarkable genetic differences between animal major histocompatibility complex (MHC) systems and the human leukocyte antigen (HLA) system. HLA transgenic humanized mouse model systems offer a much better method to study the HLA-A-related principal mechanisms for vaccine development and HLA-A-restricted responses against infection in human. METHODS: A recombinant gene encoding the chimeric HLA-A30 monochain was constructed. This HHD molecule contains the following: α1-α2 domains of HLA-A30, α3 and cytoplasmic domains of H-2Db , linked at its N-terminus to the C-terminus of human ß2m by a 15-amino-acid peptide linker. The recombinant gene encoding the chimeric HLA-A30 monochain cassette was introduced into bacterial artificial chromosome (BAC) CH502-67J3 containing the HLA-A01 gene locus by Red-mediated homologous recombination. Modified BAC CH502-67J3 was microinjected into the pronuclei of wild-type mouse oocytes. This humanized mouse model was further used to assess the immune responses against influenza A virus (H1N1) pdm09 clinically isolated from human patients. Immune cell population, cytokine production, and histopathology in the lung were analyzed. RESULTS: We describe a novel human ß2m-HLA-A30 (α1α2)-H-2Db (α3 transmembrane cytoplasmic) (HHD) monochain transgenic mouse strain, which contains the intact HLA-A01 gene locus including 49 kb 5'-UTR and 74 kb 3'-UTR of HLA-A01*01. Five transgenic lines integrated into the large genomic region of HLA-A gene locus were obtained, and the robust expression of exogenous transgene was detected in various tissues from A30-18# and A30-19# lines encompassing the intact flanking sequences. Flow cytometry revealed that the introduction of a large genomic region in HLA-A gene locus can influence the immune cell constitution in humanized mice. Pdm09 infection caused a similar immune response among HLA-A30 Tg humanized mice and wild-type mice, and induced the rapid increase of cytokines, including IFN-γ, TNF-α, and IL-6, in both HLA-A30 humanized Tg mice and wild-type mice. The expression of HLA-A30 transgene was dramatically promoted in tissues from A30-9# line at 3 days post-infection (dpi). CONCLUSIONS: We established a promising preclinical research animal model of HLA-A30 Tg humanized mouse, which could accelerate the identification of novel HLA-A30-restricted epitopes and vaccine development, and support the study of HLA-A-restricted responses against infection in humans.

Generation and expression analysis of BAC humanized mice carrying HLA-DP401 haplotype.

Background: Human leukocyte antigen (HLA)-DP is much less studied than other HLA class II antigens, that is, HLA-DR and HLA-DQ, etc. However, the accumulating data have suggested the important roles of DP-restricted responses in the context of cancer, allergy, and infectious disease. Lack of animal models expressing these genes as authentic cis-haplotypes blocks our understanding for the role of HLA-DP haplotypes in immunity. Methods: To explore the potential cis-acting control elements involved in the transcriptional regulation of the HLA-DPA1/DPB1 gene, we performed the expression analysis using bacterial artificial chromosome (BAC)-based transgenic humanized mice in the C57BL/6 background, which carried the entire HLA-DP401 gene locus. We further developed a mouse model of Staphylococcus aureus pneumonia in HLA-DP401 humanized transgenic mice, and performed the analysis on the expression pattern of HLA-DP401 and immunological responses in the model. Results: In this study, we screened and identified a BAC clone spanning the entire HLA-DP gene locus. DNA from this clone was analyzed for integrity by pulsed-field gel electrophoresis and then microinjected into fertilized mouse oocytes to produce transgenic founder animals. Nine sets of PCR primers for regional markers with an average distance of 15 kb between each primer were used to confirm the integrity of the transgene in the five transgenic lines carrying the HLA-DPA1/DPB1 gene. Transgene copy numbers were determined by real-time PCR analysis. HLA-DP401 gene expression was analyzed at the mRNA and protein level. Although infection with S aureus Newman did not alter the percentage of immune cells in the spleen and thymus from the HLA-DP401-H2-Aß1 humanized mice. Increased expression of HLA-DP401 was observed in the thymus of the humanized mice infected by S aureus. Conclusions: We generated several BAC transgenic mice, and analyzed the expression of HLA-DPA1/DPB1 in those mice. A model of Saureus-induced pneumonia in the HLA-DP401-H2-Aß1-/- humanized mice was further developed, and S aureus infection upregulated the HLA-DP401 expression in thymus of those humanized mice. These findings demonstrate the potential of those HLA-DPA1/DPB1 transgenic humanized mice for developing animal models of infectious diseases and MHC-associated immunological diseases.

Ablation of NTPDase2+ cells inhibits the formation of filiform papillae in tongue tip.

BACKGROUND: Lingual epithelia in the tongue tip are among the most rapidly regenerating tissues, but the mechanism of cell genesis in this tissue is still unknown. Previous study has suggested the existence of multiple stem cell pools in lingual epithelia and papillae. Like K14+ and Sox2+ cells, NTPDase2+ cells have characteristics of stem cells. METHODS: We employed a system using doxycycline to conditionally ablate NTPDase2+ cells in lingual epithelia and papillae by regulated expression of the diphtheria toxin A (DTA) gene. Transgenic lines, which expressed the rtTA gene in NTPDase2+ cells, were produced by pronuclear injection of zygotes from C57BL/6 mice using the BAC clone RP23-47P18. The NTPDase2-rtTA transgenic mice were crossed with the TetO-DTA transgenic animals. The double transgenic mice were treated with doxycycline. Doxycycline (Dox) was diluted in 5% sucrose in water to a final concentration of 0.3-0.5 mg/mL and supplied as drinking water. RESULTS: After 15 days of Dox induction, the expression of NTPDase2, Sox2 and K14 was ablated from lingual epithelia. DTA expression in NTPDase2+ cells did not inhibit the turnover of GNAT3+ or PLCß2+ cells in taste buds, nor the expression of S100ß beneath lingual epithelia and papillae. After 35 days ablation of NTPDase2+ cells, the basic structure of lingual epithelia and papillae remained intact. However, the ratio of cell to total tissue area was decreased in lingual epithelia and circumvallate (CV) papillae. DTA expression also inhibited the regeneration of filiform papillae on the dorsal surface of the tongue tip. CONCLUSIONS: These studies provide important insights into the understanding of dynamic equilibrium among the multiple stem cell populations present in the lingual epithelia and papillae.