Deficits in receptor-mediated endocytosis and recycling in cells from mice with Gpr107 locus disruption.

GPR107 is a type III integral membrane protein that was initially predicted to be a member of the family of G-protein-coupled receptors. This report shows that deletion of Gpr107 leads to an embryonic lethal phenotype that is characterized by a reduction in cubilin transcript abundance and a decrease in the representation of multiple genes implicated in the cubilin-megalin endocytic receptor complex (megalin is also known as LRP2). Gpr107-null fibroblast cells exhibit reduced transferrin internalization, decreased uptake of low-density lipoprotein (LDL) receptor-related protein-1 (LRP1) cargo and resistance to toxins. Colocalization studies and proteomic analyses suggest that GPR107 associates with clathrin and the retromer protein VPS35 and that GPR107 might be responsible for the return of receptors to the plasma membrane from endocytic compartments. The highly selective deficits observed in Gpr107-null cells indicate that GPR107 interacts directly or indirectly with a limited subset of surface receptors.

Deletion of the murine cytochrome P450 Cyp2j locus by fused BAC-mediated recombination identifies a role for Cyp2j in the pulmonary vascular response to hypoxia.

Epoxyeicosatrienoic acids (EETs) confer vasoactive and cardioprotective functions. Genetic analysis of the contributions of these short-lived mediators to pathophysiology has been confounded to date by the allelic expansion in rodents of the portion of the genome syntenic to human CYP2J2, a gene encoding one of the principle cytochrome P450 epoxygenases responsible for the formation of EETs in humans. Mice have eight potentially functional genes that could direct the synthesis of epoxygenases with properties similar to those of CYP2J2. As an initial step towards understanding the role of the murine Cyp2j locus, we have created mice bearing a 626-kb deletion spanning the entire region syntenic to CYP2J2, using a combination of homologous and site-directed recombination strategies. A mouse strain in which the locus deletion was complemented by transgenic delivery of BAC sequences encoding human CYP2J2 was also created. Systemic and pulmonary hemodynamic measurements did not differ in wild-type, null, and complemented mice at baseline. However, hypoxic pulmonary vasoconstriction (HPV) during left mainstem bronchus occlusion was impaired and associated with reduced systemic oxygenation in null mice, but not in null mice bearing the human transgene. Administration of an epoxygenase inhibitor to wild-type mice also impaired HPV. These findings demonstrate that Cyp2j gene products regulate the pulmonary vascular response to hypoxia.

GPR108, an NF-κB activator suppressed by TIRAP, negatively regulates TLR-triggered immune responses.

Higher vertebrates have evolved innate and adaptive immune systems to defend against foreign substances and pathogens. Sophisticated regulatory circuits are needed to avoid inappropriate immune responses and inflammation. GPR108 is a seven-transmembrane family protein that activates NF-κB strongly when overexpressed. Surprisingly, its action in a physiological context is that of an antagonist of Toll-like receptor (TLR)-mediated signaling. Cells from Gpr108-null mice exhibit enhanced cytokine secretion and NF-κB and IRF3 signaling, whereas Gpr108-null macrophages reconstituted with GPR108 exhibit blunted signaling. Co-expression of TLRs and GPR108 reduces NF-κB and IFNß promoter activation compared to expression of either TLRs or GPR108 alone. Upon TLR stimulation GPR108 abundance increases and the protein engages TLRs and their partners to reduce MyD88 expression and interfere with its binding to TLR4 through blocking MyD88 ubiquitination. In turn GPR108 is antagonized by TIRAP, an adaptor protein for TLR and MyD88. The interrelationships between GPR108 and innate immune signaling components are multifactorial and point to a membrane-associated signaling structure of significant complexity.