SemOpenAlex |

SemOpenAlex

Matches in SemOpenAlex for { <https://semopenalex.org/work/W2904701752> ?p ?o ?g. }

Showing items 1 to 100 of ±148 with 100 items per page.

W2904701752 abstract "Background: The pathophysiology of non-alcoholic steatohepatitis involves hepatocyte lipotoxicity due to excess saturated free fatty acids and concomitant proinflammatory macrophage effector responses. These include the infiltration of macrophages into hepatic cords in response to incompletely understood stimuli. Stressed hepatocytes release an increased number of extracellular vesicles (EVs), which are known to participate in intercellular signaling and coordination of the behavior of immune cell populations via their cargo. We hypothesized that hepatocyte-derived lipotoxic EVs that are enriched in sphingosine 1-phosphate (S1P) are effectors of macrophage infiltration in the hepatic microenvironment. Methods: Lipotoxic EVs were isolated from palmitate treated immortalized mouse hepatocytes and characterized by nanoparticle tracking analysis. Lipotoxic EV sphingolipids were quantified using tandem mass spectrometry. Wildtype and S1P1 receptor knockout bone marrow-derived macrophages were exposed to lipotoxic EV gradients in a microfluidic gradient generator. Macrophage migration toward EV gradients was captured by time-lapse microscopy and analyzed to determine directional migration. Fluorescence-activated cell sorting along with quantitative PCR and immunohistochemistry were utilized to characterize the cell surface expression of S1P1 receptor on intrahepatic leukocytes and hepatic expression of S1P1 receptor, respectively. Results: Palmitate treatment induced the release of EVs. These EVs were enriched in S1P. Palmitate-induced S1P enriched EVs were chemoattractive to macrophages. EV S1P enrichment depended on the activity of sphingosine kinases 1 and 2, such that, pharmacological inhibition of sphingosine kinases 1 and 2 resulted in a significant reduction in EV S1P cargo without affecting the number of EVs released. When exposed to EVs derived from cells treated with palmitate in the presence of a pharmacologic inhibitor of sphingosine kinases 1 and 2, macrophages displayed diminished chemotactic behavior. To determine receptor-ligand specificity, we tested the migration responses of macrophages genetically deleted in the S1P1 receptor toward lipotoxic EVs. S1P1 receptor knockout macrophages displayed a marked reduction in their chemotactic responses toward lipotoxic palmitate-induced EVs. Conclusions:Palmitate-induced lipotoxic EVs are enriched in S1P through sphingosine kinases 1 and 2. S1P-enriched EVs activate persistent and directional macrophage chemotaxis mediated by the S1P1 receptor, a potential signaling axis for macrophage infiltration during hepatic lipotoxicity, and a potential therapeutic target for non-alcoholic steatohepatitis." @default.
W2904701752 created "2018-12-22" @default.
W2904701752 creator A5000258536 @default.
W2904701752 creator A5002077162 @default.
W2904701752 creator A5015961302 @default.
W2904701752 creator A5045769998 @default.
W2904701752 creator A5057268832 @default.
W2904701752 creator A5090345895 @default.
W2904701752 date "2018-12-19" @default.
W2904701752 modified "2023-10-12" @default.
W2904701752 title "Hepatocyte-Derived Lipotoxic Extracellular Vesicle Sphingosine 1-Phosphate Induces Macrophage Chemotaxis" @default.
W2904701752 cites W1256777839 @default.
W2904701752 cites W1549006420 @default.
W2904701752 cites W1856151485 @default.
W2904701752 cites W1966452335 @default.
W2904701752 cites W1968393209 @default.
W2904701752 cites W1971411560 @default.
W2904701752 cites W1978878949 @default.
W2904701752 cites W1979620916 @default.
W2904701752 cites W1986132627 @default.
W2904701752 cites W1989607865 @default.
W2904701752 cites W1989908272 @default.
W2904701752 cites W1996283676 @default.
W2904701752 cites W1997486939 @default.
W2904701752 cites W2004933414 @default.
W2904701752 cites W2022770236 @default.
W2904701752 cites W2033112925 @default.
W2904701752 cites W2034188379 @default.
W2904701752 cites W2035030361 @default.
W2904701752 cites W2036409124 @default.
W2904701752 cites W2044544386 @default.
W2904701752 cites W2055096275 @default.
W2904701752 cites W2056211342 @default.
W2904701752 cites W2056818014 @default.
W2904701752 cites W2057491043 @default.
W2904701752 cites W2062279417 @default.
W2904701752 cites W2066453798 @default.
W2904701752 cites W2067038570 @default.
W2904701752 cites W2113047132 @default.
W2904701752 cites W2116896168 @default.
W2904701752 cites W2121354606 @default.
W2904701752 cites W2127740643 @default.
W2904701752 cites W2129125398 @default.
W2904701752 cites W2137631404 @default.
W2904701752 cites W2143068056 @default.
W2904701752 cites W2151293178 @default.
W2904701752 cites W2157586986 @default.
W2904701752 cites W2161510975 @default.
W2904701752 cites W2168359048 @default.
W2904701752 cites W2169598496 @default.
W2904701752 cites W2207469885 @default.
W2904701752 cites W2283843704 @default.
W2904701752 cites W2298753429 @default.
W2904701752 cites W2321179708 @default.
W2904701752 cites W2520827869 @default.
W2904701752 cites W2562831699 @default.
W2904701752 cites W2562988756 @default.
W2904701752 cites W2588587410 @default.
W2904701752 cites W2625667927 @default.
W2904701752 cites W2746863374 @default.
W2904701752 cites W2752884184 @default.
W2904701752 cites W2760098333 @default.
W2904701752 cites W2767674693 @default.
W2904701752 cites W2771958146 @default.
W2904701752 cites W2784023715 @default.
W2904701752 cites W2784619339 @default.
W2904701752 cites W2791013485 @default.
W2904701752 cites W2792614876 @default.
W2904701752 cites W2792704999 @default.
W2904701752 cites W2808583077 @default.
W2904701752 cites W2888186473 @default.
W2904701752 cites W584440894 @default.
W2904701752 doi "https://doi.org/10.3389/fimmu.2018.02980" @default.
W2904701752 hasPubMedCentralId "https://www.ncbi.nlm.nih.gov/pmc/articles/6305739" @default.
W2904701752 hasPubMedId "https://pubmed.ncbi.nlm.nih.gov/30619336" @default.
W2904701752 hasPublicationYear "2018" @default.
W2904701752 type Work @default.
W2904701752 sameAs 2904701752 @default.
W2904701752 citedByCount "59" @default.
W2904701752 countsByYear W29047017522019 @default.
W2904701752 countsByYear W29047017522020 @default.
W2904701752 countsByYear W29047017522021 @default.
W2904701752 countsByYear W29047017522022 @default.
W2904701752 countsByYear W29047017522023 @default.
W2904701752 crossrefType "journal-article" @default.
W2904701752 hasAuthorship W2904701752A5000258536 @default.
W2904701752 hasAuthorship W2904701752A5002077162 @default.
W2904701752 hasAuthorship W2904701752A5015961302 @default.
W2904701752 hasAuthorship W2904701752A5045769998 @default.
W2904701752 hasAuthorship W2904701752A5057268832 @default.
W2904701752 hasAuthorship W2904701752A5090345895 @default.
W2904701752 hasBestOaLocation W29047017521 @default.
W2904701752 hasConcept C134018914 @default.
W2904701752 hasConcept C170493617 @default.
W2904701752 hasConcept C185592680 @default.
W2904701752 hasConcept C202751555 @default.
W2904701752 hasConcept C2776200302 @default.
W2904701752 hasConcept C2776596873 @default.
W2904701752 hasConcept C2777391703 @default.
W2904701752 hasConcept C2777700496 @default.