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1. Legionella pneumophila targets autophagosomes and promotes host autophagy during late infection

   https://doi.org/10.1101/2021.07.08.451723  

   Noll, Rebecca R; Pike, Colleen M; Lehman, Stephanie S; Williamson, Chad D; Neunuebel, M Ramona (July 2021, bioRxiv)

   Abstract Autophagy is a fundamental eukaryotic process that mediates clearance of unwanted molecules and facilitates nutrient release. The bacterial pathogenLegionella pneumophilaestablishes an intracellular niche within phagocytes by manipulating host cellular processes, such as autophagy. Effector proteins translocated byL. pneumophila’s Dot/Icm type IV secretion system have been shown to suppress autophagy. However evidence suggests that overall inhibition of autophagy may be detrimental to the bacterium. As autophagy contributes to cellular homeostasis and nutrient acquisition,L. pneumophilamay translocate effectors that promote autophagy for these benefits. Here, we show that effector protein Lpg2411 binds phosphatidylinositol-3-phosphate lipids and preferentially binds autophagosomes. Translocated Lpg2411 accumulates late during infection and co-localizes with the autophagy receptor p62 and ubiquitin. Furthermore, autophagy is inhibited to a greater extent in host cells infected with a mutant strain lacking Lpg2411 compared to those infected with wild-typeL. pneumophila,indicating that Lpg2411 stimulates autophagy to support the bacterium’s intracellular lifestyle. SummaryLegionella pneumophilatranslocates several effector proteins that inhibit autophagic processes. In this study, we find that the effector protein Lpg2411 targets autophagosomes during late stages of infection and promotes autophagy. 

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2. Modulation of host cell signaling pathways in response to Coxiella burnetii infection

   Brewer, Melissa; Rayburn, Theresa; Alkhateib, Paris; Ferguson, Bryce; Lind, Benjamin; Pankey, Aaron; Hise, Kincade; Jones, Shandra; Wu, Ning (September 2024, Journal of Biotech Research)

   Coxiella burnetii is an obligate intracellular bacterium that lives in a modified lysosome termed the Coxiella containing vacuole (CCV). C. burnetii is the causative agent of the zoonotic illness Q Fever, which primarily infects ruminant livestock and can spread to humans via inhalation. Acute Q fever is characterized by a flu like illness, while chronic disease is associated with more severe symptoms including endocarditis and chronic fatigue syndrome. C. burnetii has a biphasic life cycle consisting of a small cell variant (SCV) and large cell variant (LCV). The SCV is environmentally stable and can cause infection via inhalation of 1 - 10 infectious particles. Once taken up by the host cell, C. burnetii must manipulate the signaling pathways of the host cell to form the CCV where it switches to the LCV, the metabolic and replicative form of the bacterium. It primarily accomplishes this goal by utilizing a Type IV B Secretion System (T4BSS), which is unique to C. burnetii and Legionella pneumophila. The T4BSS, along with some other secretion mechanisms, secretes effector proteins into the host cell. These proteins then interfere with or modulate the host cell to recruit vacuoles, evade detection by the immune system, and prevent the host cell from initiating apoptosis. After about 6 days, the LCV will convert to SCV and then initiate host cell lysis to spread infection. This review looked at many eukaryotic cells signaling pathways and the interactions between C. burnetii and host proteins. These interactions are responsible for the modulation of host cell pathways necessary for CCV formation and C. burnetii survival. Understanding these interactions better will help with future treatments for C. burnetii infection. Further discoveries in these interactions are crucial for the future of C. burnetii research. 

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3. Synergy between microwave radiation and silver for inactivation of Legionella pneumophila

   Saleh, N. B.; Ayres, C.; Lawler, D. F.; Kirisits, M. J. (July 2020, 1st Virtual Canadian Symposium on Water Quality Research)

   Legionella pneumophila is an opportunistic human pathogen that can cause a severe and deadly form of pneumonia called Legionnaires’ disease. Over the past decade, the number of reported cases of Legionnaires’ disease has quadrupled in the U.S., with 8,000-18,000 hospitalizations per year at a yearly incidence rate of 1.7/100,000. Within the water sector, this public health risk is exacerbated by the proliferation of L. pneumophila in complex biological matrices such as biofilms and within free-living amoebae. Traditional disinfection technologies fail to effectively mitigate this emerging pathogen issue, necessitating development of point-of-use (POU) technologies with high inactivation efficacy. We aim to harness microwave (MW) radiation and take advantage of its synergy with ion-mediated toxicity to effectively inactivate L. pneumophila. In this study, planktonic L. pneumophila cells have been exposed to ionic and nano-particulate silver. While neither treatment alone is effective over a short exposure period, a combined treatment of silver with MW radiation successfully achieves 3-4 log removal within 6 min of irradiation, as shown in Figure 1. Enhanced toxicity was observed when L. pneumophila was pre-exposed to either treatment (i.e., MW heating or silver exposure) prior to exposure to the other; these results suggest that silver ion transport within the cells is facilitated by heat treatment. Data presented here serve as the proof-of-concept toward the development of a L pneumophila inactivation device that harnesses MW radiation and can potentially mitigate this public health risk, even if the cells are protected by amoebae or biofilms. 

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4. Effects of Copper on Legionella pneumophila Revealed via Viability Assays and Proteomics

   https://doi.org/10.3390/pathogens13070563  

   Song, Yang; Mena-Aguilar, Didier; Brown, Connor L; Rhoads, William J; Helm, Richard F; Pruden, Amy; Edwards, Marc A (July 2024, Pathogens)

   Cu is an antimicrobial that is commonly applied to premise (i.e., building) plumbing systems for Legionella control, but the precise mechanisms of inactivation are not well defined. Here, we applied a suite of viability assays and mass spectrometry-based proteomics to assess the mechanistic effects of Cu on L. pneumophila. Although a five- to six-log reduction in culturability was observed with 5 mg/L Cu2+ exposure, cell membrane integrity only indicated a <50% reduction. Whole-cell proteomic analysis revealed that AhpD, a protein related to oxidative stress, was elevated in Cu-exposed Legionella relative to culturable cells. Other proteins related to cell membrane synthesis and motility were also higher for the Cu-exposed cells relative to controls without Cu. While the proteins related to primary metabolism decreased for the Cu-exposed cells, no significant differences in the abundance of proteins related to virulence or infectivity were found, which was consistent with the ability of VBNC cells to cause infections. Whereas the cell-membrane integrity assay provided an upper-bound measurement of viability, an amoebae co-culture assay provided a lower-bound limit. The findings have important implications for assessing Legionella risk following its exposure to copper in engineered water systems. 

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5. Molecular basis of product recognition during PIP5K-mediated production of PI(4,5)P2 with positive feedback

   https://doi.org/10.1016/j.jbc.2024.107631  

   Duewell, Benjamin R; Faris, Katherine A; Hansen, Scott D (September 2024, Journal of Biological Chemistry)

   Cole, Phillip A (Ed.)

   The ability for cells to localize and activate peripheral membrane-binding proteins is critical for signal transduction. Ubiquitously important in these signaling processes are phosphatidylinositol phosphate (PIP) lipids, which are dynamically phosphorylated by PIP lipid kinases on intracellular membranes. Functioning primarily at the plasma membrane, phosphatidylinositol-4-phosphate 5-kinases (PIP5K) catalyzes the phosphorylation of PI(4)P to generate most of the PI(4,5)P2 lipids found in eukaryotic plasma membranes. Recently, we determined that PIP5K displays a positive feedback loop based on membrane-mediated dimerization and cooperative binding to its product, PI(4,5)P2. Here, we examine how two motifs contribute to PI(4,5)P2 recognition to control membrane association and catalysis of PIP5K. Using a combination of single molecule TIRF microscopy and kinetic analysis of PI(4)P lipid phosphorylation, we map the sequence of steps that allow PIP5K to cooperatively engage PI(4,5)P2. We find that the specificity loop regulates the rate of PIP5K membrane association and helps orient the kinase to more effectively bind PI(4,5)P2 lipids. After correctly orienting on the membrane, PIP5K transitions to binding PI(4,5)P2 lipids near the active site through a motif previously referred to as the substrate or PIP-binding motif (PIPBM). The PIPBM has broad specificity for anionic lipids and serves a role in regulating membrane association in vitro and in vivo. Overall, our data supports a two-step membrane-binding model where the specificity loop and PIPBM act in concert to help PIP5K orient and productively engage anionic lipids to drive the positive feedback during PI(4,5)P2 production. 

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