Direction of leukocyte polarization and migration by the phosphoinositide-transfer protein TIPE2.

The polarization of leukocytes toward chemoattractants is essential for the directed migration (chemotaxis) of leukocytes. How leukocytes acquire polarity after encountering chemical gradients is not well understood. We found here that leukocyte polarity was generated by TIPE2 (TNFAIP8L2), a transfer protein for phosphoinositide second messengers. TIPE2 functioned as a local enhancer of phosphoinositide-dependent signaling and cytoskeleton remodeling, which promoted leading-edge formation. Conversely, TIPE2 acted as an inhibitor of the GTPase Rac, which promoted trailing-edge polarization. Consequently, TIPE2-deficient leukocytes were defective in polarization and chemotaxis, and TIPE2-deficient mice were resistant to leukocyte-mediated neural inflammation. Thus, the leukocyte polarizer is a dual-role phosphoinositide-transfer protein and represents a potential therapeutic target for the treatment of inflammatory diseases.

TIPE3 is the transfer protein of lipid second messengers that promote cancer.

More than half of human cancers have aberrantly upregulated phosphoinositide signals; yet how phospholipid signals are controlled during tumorigenesis is not fully understood. We report here that TIPE3 (TNFAIP8L3) is the transfer protein of phosphoinositide second messengers that promote cancer. High-resolution crystal structure of TIPE3 shows a large hydrophobic cavity that is occupied by a phospholipid-like molecule. TIPE3 preferentially captures and shuttles two lipid second messengers, i.e., phosphatidylinositol 4,5-bisphosphate and phosphatidylinositol 3,4,5-trisphosphate, and increases their levels in the plasma membrane. Notably, human cancers have markedly upregulated TIPE3 expression. Knocking out TIPE3 diminishes tumorigenesis, whereas enforced TIPE3 expression enhances it in vivo. Thus, the function and metabolism of phosphoinositide second messengers are controlled by a specific transfer protein during tumorigenesis.

FCRL6 receptor: expression and associated proteins.

FCRL6 receptor is a more recently identified representative of the FCRL family. We generated a panel of mouse mAbs to baculovirus-derived recombinant FCRL6 protein. The clone 7B2 was found to specifically recognize a 63kDa protein expressed preferentially on the surface of CD8 T and CD56 NK cells in human peripheral blood and spleen. The clone 7B2 reacts with FCRL6 in Western blotting, FACS, and immunohistochemistry. In the T cell lineage, FCRL6 functions in antigen-experienced cells. Mitogenic stimulation of PB leukocytes in vitro resulted in an abrogation of the FCRL6 gene expression. We found a significant decrease in the FCRL6 gene expression in peripheral T cells of patients with certain autoimmune and blood diseases, and its upregulation at the late stages of HIV infection. Study of the FCRL6 association with signaling molecules showed its ability to recruit SHP-1, SHP-2, SHIP-1, and SHIP-2 phosphatases, and also adaptor protein Grb2 through phosphorylated cytoplasmic tyrosines. The current results demonstrate inhibitory potential of FCRL6 and suggest its possible involvement in modulation of CTL effector functions in various immune disorders.

Species-specific evolution of the FcR family in endothermic vertebrates.

In primates and rodents, the extended FcR family is comprised of three subsets: classical FcRs, structurally diverse cell surface receptors currently designated FCRL1-FCRL6, and intracellular proteins FCRLA and FCRLB. Using bioinformatic analysis, we revealed the FcR-like genes of the same three subsets in the genome of dog, another representative of placental mammals, and in the genome of short-tailed opossum, a representative of marsupials. In contrast, a single FcR-like gene was found in the current version of the chicken genome. This in silico finding was confirmed by the gene cloning and subsequent Southern blot hybridization. The chicken FCRL gene encodes a cell surface receptor with the extracellular region composed of four Ig-like domains of the D1-, D2-, D3-, and D4-subtypes. The gene is expressed in lymphoid and non-lymphoid tissues. Phylogenetic analysis of the mammalian and chicken genes suggested that classical FcRs, FCRLA, and FCRLB emerged after the mammalian-avian split but before the eutherian-marsupial radiation. The data obtained show that the repertoire of the classical FcRs and surface FcR-like proteins in mammalian species was shaped by an extensive recombination process, which resulted in domain shuffling and species-specific gain and loss of distinct exons or entire genes.