Phosphorylation of TMEM55B by Erk/MAPK regulates lysosomal positioning.

TMEM55B is first identified as phosphatidylinositol-4,5-P24-phosphatases (PtdIns-4,5-P24-phosphatases) that catalyse dephosphorylation of PtdIns-4,5-P2 to PtdIns-5-P. We demonstrate for the first time that TMEM55B is phosphorylated by Erk/MAPK and that this mechanism participates in regulation of lysosomal clustering. Exposure of RAW264.7 macrophages to various stimuli induces phosphorylation of TMEM55B on Ser76 and Ser169, sites corresponding to consensus sequences (PX(S/T)P) for phosphorylation by MAPK. Of these stimuli, Toll-like receptor ligands most strongly induce TMEM55B phosphorylation, and this is blocked by the MEK1/2 inhibitor U0126. However, phosphorylation does not impact intrinsic phosphatase activity of TMEM55B. TMEM55B has recently been implicated in starvation induced lysosomal translocation. Amino acid starvation induces perinuclear lamp1 clustering in RAW264.7 macrophages, which was attenuated by shRNA-mediated knock-down or CRISPR/Cas9-mediated knock-out of TMEM55B. Cells exposed to U0126 also exhibit attenuated lamp1 clustering. Overexpression of TMEM55B but not TMEM55A notably enhances lamp1 clustering, with TMEM55B mutants (lacking phosphorylation sites or mimicking the phosphorylated state) exhibiting lower and higher efficacies (respectively) than wild-type TMEM55B. Collectively, results suggest that phosphorylation of TMEM55B by Erk/MAPK impacts lysosomal dynamics.

PIKfyve accelerates phagosome acidification through activation of TRPML1 while arrests aberrant vacuolation independent of the Ca2+ channel.

PIKfyve phosphorylates PtdIns(3)P to PtdIns(3, 5)P2. One of the best characterized effector downstream of PtdIns(3, 5)P2 is a lysosomal Ca2+ channel, TRPML1. Although it has been reported that TRPML1 is involved in phagosome-lysosome fusion, the relevance of the Ca2+ channel in phagosome acidification has been denied. In this article, however, we demonstrated that the phagosome acidification was dependent on TRPML1. Based on the classical idea that Fluorescein isothiocyanate (FITC)-fluorescence is highly sensitive to acidic pH, we could estimate the phagosome acidification by time laps imaging. FITC-zymosan fluorescence that was engulfed by macrophages, decreased immediately after the uptake while the extinction of FITC-zymosan fluorescence was delayed in PIKfyve-deficient cells. The acidification arrest was completely rescued in the presence of Ca2+ ionophore A23187. Cells treated with a PIKfyve inhibitor, apilimod, also showed delayed phagosome acidification but were rescued by the overexpression of TRPML1. Additionally, TRPML1 agonist, ML-SA1 was effective to acidify the phagosome in PIKfyve-deficient cells. Another phenotype observed in PIKfyve-deficient cells is vacuole formation. Unexpectedly, enlarged vacuole formation in PIKfyve-deficient cells was not rescued by Ca2+ or over expression of TRPML1. It is likely that the acidification and vacuolation arrest is bifurcating downstream of PIKfyve.