Abolhassani et al. show that CD70 deficiency is a novel cause of combined immunodeficiency and EBV-associated diseases, reminiscent of CD27 deficiency. CD70–CD27 interactions play a nonredundant role regulating humoral- and cell-mediated immunity in humans, especially for control of EBV.
Autophagy is an evolutionarily conserved mechanism for the gross disposal of intracellular proteins in mammalian cells and dysfunction in this pathway has been associated with human disease. Although the serine threonine kinase Akt is suggested to play a role in this process, little is known about the molecular mechanisms by which Akt induces autophagy. Using a yeast two-hybrid screen, Phafin2 (EAPF or PLEKHF2), a lysosomal protein with a unique structure of N-terminal PH (pleckstrin homology) domain and C-terminal FYVE (Fab 1, YOTB, Vac 1, and EEA1) domain was found to interact with Akt. A sucrose gradient fractionation experiment revealed that both Akt and Phafin2 co-existed in the same lysosome enriched fraction after autophagy induction. Confocal microscopic analysis and BiFC analysis demonstrated that both Akt and Phafin2 accumulate in the lysosome after induction of autophagy. BiFC analysis using PtdIns (3)P interaction defective mutant of Phafin2 demonstrated that lysosomal accumulation of the Akt-Phafin2 complex and subsequent induction of autophagy were lysosomal PtdIns (3)P dependent events. Furthermore, in murine macrophages, both Akt and Phafin2 were required for digestion of fluorescent bacteria and/or LPS-induced autophagy. Taken together, these findings establish that lysosomal accumulation of Akt and Phafin2 is a critical step in the induction of autophagy via an interaction with PtdIns (3)P.
Magnesium transporter 1 (MAGT1) critically mediates magnesium homeostasis in eukaryotes and is highly-conserved across different evolutionary branches. In humans, loss-offunction mutations in the MAGT1 gene cause X-linked magnesium deficiency with Epstein-Barr virus (EBV) infection and neoplasia (XMEN), a disease that has a broad range of clinical and immunological consequences. We have previously shown that EBV susceptibility in XMEN is associated with defective expression of the antiviral natural-killer group 2 member D (NKG2D) protein and abnormal Mg 2؉ transport. New evidence suggests that MAGT1 is the human homolog of the yeast OST3/ OST6 proteins that form an integral part of the N-linked glycosylation complex, although the exact contributions of these perturbations in the glycosylation pathway to disease pathogenesis are still unknown. Using MS-based glycoproteomics, along with CRISPR/Cas9-KO cell lines, natural killer cell-killing assays, and RNA-Seq experiments, we now demonstrate that humans lacking functional MAGT1 have a selective deficiency in both immune and nonimmune glycoproteins, and we identified several critical glycosylation defects in important immune-response proteins and in the expression of genes involved in immunity, particularly CD28. We show that MAGT1 function is partly interchangeable with that of the paralog protein tumorsuppressor candidate 3 (TUSC3) but that each protein has a different tissue distribution in humans. We observed that MAGT1dependent glycosylation is sensitive to Mg 2؉ levels and that reduced Mg 2؉ impairs immune-cell function via the loss of specific glycoproteins. Our findings reveal that defects in protein glycosylation and gene expression underlie immune defects in an inherited disease due to MAGT1 deficiency.MAGT1 is an evolutionally conserved Mg 2ϩ -specific ion transport facilitator found in all animals and has been shown to participate in the multienzyme complex responsible for enzymatic coupling of N-glycans onto peptide substrates (1, 2). Null mutations in the MAGT1 gene lead to the rare primary immunodeficiency "X-linked immunodeficiency with Mg 2ϩ defect, Epstein-Barr virus (EBV) 7 infection and neoplasia" (XMEN) disease (3,4). Here, we explore these dual roles by examining cells from both healthy and MAGT1-deficient humans.Mg 2ϩ is the most abundant divalent cation in eukaryotic cells, with intracellular concentrations ranging from 15 to 20 mM depending on the cell type. Most Mg 2ϩ is tightly bound to cellular substituents, especially nucleic acids, nucleoside triphosphates, and enzymes. The unbound intracellular free Mg 2ϩ is estimated to be 0.4 -1.0 mM or ϳ1-5% of the total Mg 2ϩ concentration in the cell (5, 6), and because Mg 2ϩ is the biologically active form of Mg, these intracellular concentra-
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