Autophagy defends the mammalian cytosol against bacterial infection.1-3 Efficient pathogen engulfment is mediated by cargo-selecting autophagy adaptors that rely on unidentified pattern-recognition or danger receptors to label invading pathogens as autophagy cargo, typically by poly-ubiquitin coating.4-9 Here we show that galectin-8, a cytosolic lectin, is a danger receptor that restricts Salmonella proliferation. Galectin-8 monitors endo-lysosomal integrity and detects bacterial invasion by binding host glycans exposed on damaged Salmonella-containing vacuoles. By recruiting NDP52 galectin-8 activates anti-bacterial autophagy. Galectin-8-dependent recruitment of NDP52 to Salmonella-containing vesicles is transient and followed by ubiquitin-dependent NDP52 recruitment. Since galectin-8 also detects sterile damage to endosomes or lysosomes, as well as invasion by Listeria or Shigella, we suggest galectin-8 serves as a versatile receptor for vesicle-damaging pathogens. Our results illustrate how cells deploy the danger receptor galectin-8 to combat infection by monitoring endo-lysososomal integrity based on the specific lack of complex carbohydrates in the cytosol.
Cell-autonomous innate immune responses against bacteria attempting to colonize the cytosol of mammalian cells are incompletely understood. Polyubiquitylated proteins can accumulate on the surface of such bacteria, and bacterial growth is restricted by Tank-binding kinase (TBK1). Here we show that NDP52, not previously known to contribute to innate immunity, recognizes ubiquitin-coated Salmonella enterica in human cells and, by binding the adaptor proteins Nap1 and Sintbad, recruits TBK1. Knockdown of NDP52 and TBK1 facilitated bacterial proliferation and increased the number of cells containing ubiquitin-coated salmonella. NDP52 also recruited LC3, an autophagosomal marker, and knockdown of NDP52 impaired autophagy of salmonella. We conclude that human cells utilize the ubiquitin system and NDP52 to activate autophagy against bacteria attempting to colonize their cytosol.
Serovars of Salmonella enterica cause both gastrointestinal and systemic diseases in a broad range of mammalian hosts, including humans. Salmonella virulence depends in part on its pathogenicity island 2 type III secretion system (SPI-2 T3SS), which is required to translocate at least 28 effector proteins from vacuolar-resident bacteria into host cells. Comparative genomic analysis reveals that all serovars encode a subset of "core" effectors, suggesting that they are critical for virulence in different hosts. An additional subset of effectors is found sporadically throughout different serovars, and several inhibit activation of the innate immune system. In this Review, we summarize the biochemical activities, host cell interaction partners, and physiological functions of SPI-2 T3SS effectors in the context of the selective pressures encountered by S. enterica in vivo. We also consider some of the remaining challenges to achieve a unified understanding of how effector activities work together to promote Salmonella virulence.
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