Appl1 and Appl2 are Expendable for Mouse Development But Are Essential for HGF-Induced Akt Activation and Migration in Mouse Embryonic Fibroblasts.

Although Appl1 and Appl2 have been implicated in multiple cellular activities, we and others have found that Appl1 is dispensable for mouse embryonic development, suggesting that Appl2 can substitute for Appl1 during development. To address this possibility, we generated conditionally targeted Appl2 mice. We found that ubiquitous Appl2 knockout (Appl2-/-) mice, much like Appl1-/- mice, are viable and grow normally to adulthood. Intriguingly, when Appl1-/- mice were crossed with Appl2-/- mice, we found that homozygous Appl1;Appl2 double knockout (DKO) animals are also viable and grossly normal with regard to reproductive potential and postnatal growth. Appl2-null and DKO mice were found to exhibit altered red blood cell physiology, with erythrocytes from these mice generally being larger and having a more irregular shape than erythrocytes from wild type mice. Although Appl1/2 proteins have been previously shown to have a very strong interaction with phosphatidylinositol-3 kinase (Pi3k) in thymic T cells, Pi3k-Akt signaling and cellular differentiation was unaltered in thymocytes from Appl1;Appl2 (DKO) mice. However, Appl1/2-null mouse embryonic fibroblasts exhibited defects in HGF-induced Akt activation, migration, and invasion. Taken together, these data suggest that Appl1 and Appl2 are required for robust HGF cell signaling but are dispensable for embryonic development and reproduction.

Appl1 is dispensable for Akt signaling in vivo and mouse T-cell development.

Appl1 (Adaptor protein containing pleckstrin homology [PH], phosphotyrosine binding [PTB], and Leucine zipper motifs) is an adaptor that participates in cell signaling by interacting with various signaling molecules including Akt, PI3-kinase (PI3K), Rab5, adiponectin receptor, and TrkA. By using RNA knockdown technology, Appl1 has been implicated in zebrafish development and murine glucose metabolism. To investigate the unambiguous role of Appl1 in vivo, we generated a knockout mouse in which exon1 of the Appl1 gene was disrupted using gene trap methodology. Homozygous Appl1 knockout mice with ubiquitous loss of Appl1 protein expression were viable, grossly normal, and born at expected Mendelian ratios. Moreover, activation of Akt and the downstream effecter Gsk3ß was unaffected in vivo. We next performed glucose and insulin tolerance tests and found that glucose metabolism is normal in Appl1-null mice. We also tested the effect of Appl1 loss on Akt signaling in T cells, because we discovered that Appl1 strongly interacts with the p110ß subunit of PI3K in T lymphocytes. However, such interaction was found to be dispensable for Akt signaling in thymic T cells and T-cell development. Moreover, Appl1 loss did not affect DNA synthesis in cultured thymocytes, although loss of Appl1 was associated with a slight increase in ConA-stimulated splenic T-cell viability/proliferation. Collectively, our findings indicate that Appl1 is dispensable for Akt signaling in vivo and T-cell differentiation.

A role for cFLIP in B cell proliferation and stress MAPK regulation.

Fas/Apo-1 signals through the FADD (Fas-associated death domain) adaptor protein, which recruits and activates the apical caspase 8 and leads to apoptosis. Cellular FLIP (cFLIP) is a homolog of caspase 8 and is also capable of binding to FADD. Previous studies suggest that cFLIP could either enhance or inhibit apoptosis and lead to NF-kappaB and Erk1/2 activation. Like FADD or caspase 8 deficiency, a lack of cFLIP disrupts embryogenesis and T cell proliferation. It has been demonstrated that B cells lacking either FADD or caspase 8 were defective in both Fas-induced apoptosis and TLR-induced proliferation, which indicates that these death-inducing proteins have an additional role in regulating innate immunity. To analyze the function of cFLIP in B cells, conditional deletion of cFLIP was induced by using CD19(Cre). The resulting B cell-specific cFLIP-deficient mice were found to have reduced numbers of peripheral B cells that were hypersensitive to Fas-induced apoptosis and impaired in proliferation induced by TLRs and the BCR. Furthermore, there was aberrant expression of costimulatory proteins and activation markers in cFLIP-deficient B cells. Whereas LPS-induced activation of NF-kappaB and Erk1/2 appears to be unaffected, p38 and Jnk were spontaneously activated and hyperinduced in cFLIP-deficient B cells. Therefore, these data revealed novel functions of cFLIP in B cells.