Selective autophagy can be mediated via receptor molecules that link specific cargoes to the autophagosomal membranes decorated by ubiquitin-like microtubule-associated protein light chain 3 (LC3) modifiers. Although several autophagy receptors have been identified, little is known about mechanisms controlling their functions in vivo. In this work, we found that phosphorylation of an autophagy receptor, optineurin, promoted selective autophagy of ubiquitincoated cytosolic Salmonella enterica. The protein kinase TANK binding kinase 1 (TBK1) phosphorylated optineurin on serine-177, enhancing LC3 binding affinity and autophagic clearance of cytosolic Salmonella. Conversely, ubiquitin-or LC3-binding optineurin mutants and silencing of optineurin or TBK1 impaired Salmonella autophagy, resulting in increased intracellular bacterial proliferation. We propose that phosphorylation of autophagy receptors might be a general mechanism for regulation of cargo-selective autophagy.Macroautophagy (hereafter referred to as autophagy) is an evolutionarily conserved catabolic process by which cells deliver bulk cytosolic components for degradation to the lysosome (1-4). Selectivity in cargo targeting is mediated via autophagy receptors that simultaneously bind cargoes and autophagy modifiers, autophagy-related protein 8 (ATG8)/ microtubule-associated protein light chain 3 (LC3)/γ-aminobutyric acid receptor-associated protein (GABARAP) proteins, which are conjugated to the autophagosomal membranes (5, 6). The regulatory mechanisms controlling the spatiotemporal dynamics of the autophagy receptor-target interaction in cells remain unclear (7). Multiple autophagy receptors have been identified with the yeast two-hybrid system (8, 9), which included an N-terminal fragment of optineurin (OPTN), a ubiquitin-binding protein also known as NF-κB essential modulator-related protein ( Fig. 1, A and B). The specific interactions between OPTN and LC3/GABARAP proteins were verified by pull-down assays in mammalian cells, directed yeast two-hybrid transformations, and in vitro using purified proteins ( Fig. 1C and fig. S1, A and B) (10). OPTN bound to ubiquitin chains and autophagy modifiers ATG8/LC3/GABARAP proteins but not to mono-ubiquitin or other ubiquitin-like proteins ( Fig. 1C and fig. S1C). Deletion mapping of the N-terminal region of OPTN identified an LC3 interacting motif (LIR), a linear tetrapeptide sequence present in known autophagy receptors that binds directly to LC3/GABARAP modifiers (9, 11, 12). The LIR was located between the coiled-coil domains of OPTN encompassing amino acids 169 to 209 (Fig. 1A) and was essential for in vitro and in vivo binding between OPTN and LC3/ GABARAP (Fig. 1, B and C, and figs. S1A and S2A). Single point mutations at either OPTN Phe 178 →Ala 178 (F178A) or I181A (13), corresponding to the WxxL of p62, were sufficient to abrogate the interaction with LC3/GABARAP proteins, whereas these mutants were still able to bind to linear ubiquitin chains fused to glutathione S-transferase (GST-4xUb) (...
More than 70 years ago, Hobby 1 and Bigger 2 observed that antibiotics that are considered bactericidal and kill bacteria in fact fail to sterilize cultures. Bigger realized that the small number of bacteria that manage to survive intensive antibiotic treatments are a distinct subpopulation of bacteria that he named 'persisters'. Fuelled in part by increasing concerns about antibiotic resistance but also by technological advances in single-cell analyses, the past 15 years have witnessed a great deal of research on antibiotic persistence by investigators with different backgrounds and perspectives. As the number of scientists that tackle the puzzles and challenges of antibiotic persistence from many different angles has profoundly increased, it is now time to agree on the basic definition of persistence and its distinction from the other mechanisms by which bacteria survive exposure to bactericidal antibiotic treatments 3. Several approaches have independently emerged to define and measure persistence. Research groups following seemingly similar procedures may reach different results, and careful examination of the experimental procedures often reveals that results of different groups cannot be compared. During the European Molecular Biology Organization (EMBO) Workshop 'Bacterial Persistence and Antimicrobial Therapy' (10-14 June 2018) in Ascona, Switzerland, which brought together 121 investigators involved in antibiotic persistence research from 21 countries, a discussion panel laid the main themes for a Consensus Statement on the definition and detection procedure of antibiotic persistence detailed below. In light of the potential role that antibiotic persistence can have in antibiotic treatment regimens, it is our hope that clarification and standardization of experimental procedures will facilitate the translation of basic science research into practical guidelines. Defining the persistence phenomena We adopt here a phenomenological definition of antibiotic persistence that is based on a small set of observations that can be made from experiments performed in vitro and that does not assume a specific mechanism. We focus on the differences and similarities between antibiotic persistence and other processes enabling bacteria to survive exposure to antibiotic treatments that could kill them, such as resistance, tolerance and heteroresistance. We identify different types of persistence that should be measured differently to obtain meaningful results; therefore, the definition of these types goes beyond semantics. For the more mathematically oriented readers, we provide a mathematical definition of the
Lipopolysaccharide from Gram-negative bacteria is sensed in the host cell cytoplasm by a non-canonical inflammasome pathway that ultimately results in caspase-11 activation and cell death. In mouse macrophages, activation of this pathway requires the production of type-I interferons, indicating that interferon-induced genes have a critical role in initiating this pathway. Here we report that a cluster of small interferon-inducible GTPases, the so-called guanylate-binding proteins, is required for the full activity of the non-canonical caspase-11 inflammasome during infections with vacuolar Gram-negative bacteria. We show that guanylate-binding proteins are recruited to intracellular bacterial pathogens and are necessary to induce the lysis of the pathogen-containing vacuole. Lysis of the vacuole releases bacteria into the cytosol, thus allowing the detection of their lipopolysaccharide by a yet unknown lipopolysaccharide sensor. Moreover, recognition of the lysed vacuole by the danger sensor galectin-8 initiates the uptake of bacteria into autophagosomes, which results in a reduction of caspase-11 activation. These results indicate that host-mediated lysis of pathogen-containing vacuoles is an essential immune function and is necessary for efficient recognition of pathogens by inflammasome complexes in the cytosol.
Antibiotic therapy often fails to eliminate a fraction of transiently refractory bacteria, causing relapses and chronic infections. Multiple mechanisms can induce such persisters with high antimicrobial tolerance in vitro, but their in vivo relevance remains unclear. Using a fluorescent growth rate reporter, we detected extensive phenotypic variation of Salmonella in host tissues. This included slow-growing subsets as well as well-nourished fast-growing subsets driving disease progression. Monitoring of Salmonella growth and survival during chemotherapy revealed that antibiotic killing correlated with single-cell division rates. Nondividing Salmonella survived best but were rare, limiting their impact. Instead, most survivors originated from abundant moderately growing, partially tolerant Salmonella. These data demonstrate that host tissues diversify pathogen physiology, with major consequences for disease progression and control.
New antibiotics are urgently needed to control infectious diseases. Metabolic enzymes could represent attractive targets for such antibiotics, but in vivo target validation is largely lacking. Here we have obtained in vivo information about over 700 Salmonella enterica enzymes from network analysis of mutant phenotypes, genome comparisons and Salmonella proteomes from infected mice. Over 400 of these enzymes are non-essential for Salmonella virulence, reflecting extensive metabolic redundancies and access to surprisingly diverse host nutrients. The essential enzymes identified were almost exclusively associated with a small subgroup of pathways, enabling us to perform a nearly exhaustive screen. Sixty-four enzymes identified as essential in Salmonella are conserved in other important human pathogens, but almost all belong to metabolic pathways that are inhibited by current antibiotics or that have previously been considered for antimicrobial development. Our comprehensive in vivo analysis thus suggests a shortage of new metabolic targets for broad-spectrum antibiotics, and draws attention to some previously known but unexploited targets.
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