Inhibition of Mast Cell Degranulation by Novel Small Molecule MRGPRX2 Antagonists.

BACKGROUND: Mas-related G-protein coupled receptor X2 (MRGPRX2) is a promiscuous receptor on mast cells that mediates IgE-independent degranulation and has been implicated in multiple mast cell-mediated disorders, including chronic urticaria, atopic dermatitis, and pain disorders. Although it is a promising therapeutic target, few potent, selective, small molecule antagonists have been identified, and functional effects of human MRGPRX2 inhibition have not been evaluated in vivo. OBJECTIVE: We identified and characterized novel, potent, and selective orally active small molecule MRGPRX2 antagonists for potential treatment of mast cell-mediated disease. METHODS: Antagonists were identified using multiple functional assays in cell lines overexpressing human MRGPRX2, LAD2 mast cells, human peripheral stem cell-derived mast cells, and isolated skin mast cells. Skin mast cell degranulation was evaluated in Mrgprb2em(-/-) knockout (KO) and Mrgprb2em(MRGPRX2) transgenic human MRGPRX2 knock-in (KI) mice by assessment of agonist-induced skin vascular permeability. Ex vivo skin mast cell degranulation and associated histamine release was evaluated by microdialysis of human skin tissue samples. RESULTS: MRGPRX2 antagonists potently inhibited agonist-induced MRGPRX2 activation and mast cell degranulation in all mast cell types tested, in an IgE-independent manner. Orally administered MRGPRX2 antagonists also inhibited agonist-induced degranulation and resulting vascular permeability in MRGPRX2 KI mice. In addition, antagonist treatment dose dependently inhibited agonist-induced degranulation in ex vivo human skin. CONCLUSION: MRGPRX2 small molecule antagonists potently inhibited agonist-induced mast cell degranulation in vitro and in vivo as well as ex vivo in human skin, supporting potential therapeutic utility as a novel treatment for multiple human diseases involving clinically relevant mast cell activation.

Long-term Maintenance of Sterility Following Skin Transplantation in Germ-free Mice.

BACKGROUND: There is considerable interest in investigating the role of the microbiota in various diseases, including transplant rejection. Germ-free (GF) and gnotobiotic mice are powerful models for this line of investigation, but performing surgery within the confines of a sterile housing isolator is exceptionally challenging. Development of rigorous protocols to be able to remove axenic mice from their sterile isolator for surgical intervention in a Class II biological safety cabinet (BSC) without compromising sterility would give many investigators access to this model and broaden possible studies. However, it is assumed that GF animals will most often become colonized with environmental microbiota upon leaving the isolator. In this study, we tested whether applying sterile techniques for animal transport out of the isolator and skin transplantation in a Class II BSC could maintain animal sterility. METHODS: Quantitative polymerase chain reaction (qPCR) of the bacterial 16S ribosomal RNA gene, and cultures in various aerobic and anaerobic conditions were used to probe for bacterial contamination before and after transplantation. RESULTS: Out of 28 surgeries performed, only 3 mice acquired bacterial contamination coincident with a transient shutdown of the ventilation system in the BSC. CONCLUSION: Our results indicate that skin transplantation can be successfully performed in GF mice using sterile conditions for transport and surgery in a Class II BSC, but requires continuous positive airflow. Our approach paves the way to investigating the role of the microbiota in modulating immune responses to skin allografts as a first model of solid organ transplantation in GF mice.

Control of hematopoietic stem cell quiescence by the E3 ubiquitin ligase Fbw7.

Ubiquitination is a posttranslational mechanism that controls diverse cellular processes. We focus here on the ubiquitin ligase Fbw7, a recently identified hematopoietic tumor suppressor that can target for degradation several important oncogenes, including Notch1, c-Myc, and cyclin E. We have generated conditional Fbw7 knockout animals and inactivated the gene in hematopoietic stem cells (HSCs), progenitors, and their differentiated progeny. Deletion of Fbw7 specifically and rapidly affects hematopoiesis in a cell-autonomous manner. Fbw7(-/-) HSCs show defective maintenance of quiescence, leading to impaired self-renewal and a severe loss of competitive repopulating capacity. Furthermore, Fbw7(-/-) progenitors are unable to colonize the thymus, leading to a profound depletion of T cell progenitors. Deletion of Fbw7 in bone marrow (BM) stem cells and progenitors leads to the stabilization of c-Myc, a transcription factor previously implicated in HSC self-renewal. On the other hand, neither Notch1 nor cyclin E is visibly stabilized in the BM of Fbw7-deficient mice. Gene expression studies of Fbw7(-/-) HSCs and hematopoietic progenitors indicate that Fbw7 regulates, through the regulation of HSC cycle entry, the transcriptional "signature" that is associated with the quiescent, self-renewing HSC phenotype.