The Sir2 family of enzymes or sirtuins are known as nicotinamide adenine dinucleotide (NAD)-dependent deacetylases1 and have been implicated in the regulation of transcription, genome stability, metabolism, and lifespan2, 3. However, four of the seven mammalian sirtuins have very weak deacetylase activity in vitro. Here we show that human Sirt6 efficiently removes long chain fatty acyl groups, such as myristoyl, from lysine residues. The crystal structure of Sirt6 reveals a large hydrophobic pocket that can accommodate long chain fatty acyl groups. We demonstrate further that Sirt6 promotes the secretion of tumor necrosis factor α (TNFα) by removing the fatty acyl modification on K19 and K20 of TNFα. Protein lysine fatty acylation has been known to occur in mammalian cells, but the function and regulatory mechanisms of this modification were unknown. Our data suggest that protein lysine fatty acylation is a novel mechanism that regulates protein secretion. The discovery of Sirt6 as an enzyme that controls protein lysine fatty acylation provides new opportunities to investigate the physiological function of the previously ignored protein posttranslational modification.
Identification of immune effectors and the post-translational modifications that control their activity is essential for dissecting mechanisms of immunity. Here we demonstrate that the antiviral activity of interferon-induced transmembrane protein 3 (IFITM3) is post-translationally regulated by S-palmitoylation. Large-scale profiling of palmitoylated proteins in a dendritic cell line using a chemical reporter strategy revealed over 150 lipid-modified proteins with diverse cellular functions, including innate immunity. We discovered that S-palmitoylation of IFITM3 on membrane-proximal cysteines controls its clustering in membrane compartments and its antiviral activity against influenza virus. The sites of S-palmitoylation are highly conserved among the IFITM family of proteins in vertebrates, which suggests that S-palmitoylation of these immune effectors may be an ancient post-translational modification that is crucial for host resistance to viral infections. The S-palmitoylation and clustering of IFITM3 will be important for elucidating its mechanism of action and for the design of antiviral therapeutics.Vertebrates have evolved sophisticated innate and adaptive mechanisms of immunity to combat microbial pathogens 1 . In response, viruses and pathogenic bacteria have acquired virulence factors that subvert or disarm host defenses 1 . For example, cellular membranes provide a simple barrier to infection, but viruses such as influenza virus have evolved specific proteins that fuse with membranes to allow viral replication inside host cells 2 . Alternatively, intracellular bacterial pathogens are taken up by phagocytic cells, but they then remodel cellular membranes to prevent their own degradation inside lysosomal compartments 3 . Cellular membranes are key interfaces for host resistance and prime targets for microbial virulence factors. We therefore performed large-scale profiling of palmitoylated proteins in phagocytic cells to identify membrane-associated proteins that contribute to immunity against microbial pathogens. We found that S-palmitoylation of interferon-induced transmembrane protein 3 (IFITM3) enhances its clustering in membranes * Correspondence and requests for materials should be addressed to H.C.H. hhang@rockefeller.edu. Author contributionsJ.S.Y. conceived the study, designed and performed experiments, interpreted data and co-wrote the manuscript; Y.-Y.Y. and G.C. synthesized reagents for palmitoylome profiling studies; B.M., C.B.L. and T.M.M. provided reagents and expertise on influenza virus infections; H.C.H. conceived the study, designed experiments, interpreted data and co-wrote the manuscript. Competing financial interestsThe authors declare no competing financial interests. Additional information RESULTS Proteomic analysis of palmitoylated proteins in DC2.4 cellsTo identify lipid-modified and membrane-associated proteins that may contribute to immune responses to microbial infections, we performed large-scale profiling of fatty-acylated proteins in the mouse DC line DC2.4 (ref. ...
The glycosylation of serine and threonine residues with a single GlcNAc moiety is a dynamic posttranslational modification of many nuclear and cytoplasmic proteins. We describe a chemical strategy directed toward identifying O-GlcNAc-modified proteins from living cells or proteins modified in vitro. We demonstrate, in vitro, that each enzyme in the hexosamine salvage pathway, and the enzymes that affect this dynamic modification (UDP-GlcNAc:polypeptidtyltransferase and O-GlcNAcase), tolerate analogues of their natural substrates in which the N-acyl side chain has been modified to bear a bio-orthogonal azide moiety. Accordingly, treatment of cells with N-azidoacetylglucosamine results in the metabolic incorporation of the azido sugar into nuclear and cytoplasmic proteins. These O-azidoacetylglucosamine-modified proteins can be covalently derivatized with various biochemical probes at the site of protein glycosylation by using the Staudinger ligation. The approach was validated by metabolic labeling of nuclear pore protein p62, which is known to be posttranslationally modified with O-GlcNAc. This strategy will prove useful for both the identification of O-GlcNAc-modified proteins and the elucidation of the specific residues that bear this saccharide.
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