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Molecular control of PDPNhi macrophage subset induction by ADAP as a host defense in sepsis
Pengchao Zhang, Xinning Wang, Xiaodong Yang, Hebin Liu
Pengchao Zhang, Xinning Wang, Xiaodong Yang, Hebin Liu
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Research Article Immunology Inflammation

Molecular control of PDPNhi macrophage subset induction by ADAP as a host defense in sepsis

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Abstract

Induction of podoplanin (PDPN) expression is a critical response of macrophages to LPS stimulation or bacterial infection in sepsis, but how this key process of TLR4-stimulated PDPN upregulation is regulated and the effect of PDPN expression on macrophage function remain elusive. Here, we determined how this process is regulated in vitro and in vivo. PDPN failed to be upregulated in TLR4-stimulated macrophages deficient in adhesion and degranulation-promoting adapter protein (ADAP), which could be rescued by the reconstitution of ADAP. A distinct PDPNhi peritoneal macrophage (PM) subset, which exhibited an M2-like phenotype and enhanced phagocytic activity, was generated in WT but not in ADAP-deficient septic mice. The blockade of PDPNhi PMs mimicked the effect of ADAP deficiency, which exacerbated sepsis. Mechanistically, Bruton’s tyrosine kinase–mediated (BTK-mediated) tyrosine phosphorylation of ADAP at Y571 worked together with mTOR to converge on STAT3 activation for the transactivation of the PDPN promoter. Moreover, agonist activation of STAT3 profoundly potentiated the PDPNhi PM subset generation and alleviated sepsis severity in mice. Together, our findings reveal a mechanism whereby ADAP resets macrophage function by controlling the TLR4-induced upregulation of PDPN as a host innate immune defense during sepsis.

Authors

Pengchao Zhang, Xinning Wang, Xiaodong Yang, Hebin Liu

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Figure 5

The PDPNhi PM subset exhibits a phenotype closely akin to M2 macrophages accompanied by enhanced phagocytic activity, and provides enhanced protection against sepsis.

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The PDPNhi PM subset exhibits a phenotype closely akin to M2 macrophages...
(A) RNA-Seq analysis of CD11b+F4/80+PDPNhi and CD11b+F4/80+PDPNlo PMs sorted from WT mice 18 hours after E. coli injection (2 × 107 CFU, i.p.), showing the numbers of upregulated and downregulated DEGs (log2[fold change] ≤ −1/ ≥ 1, 5% FDR). (B) Top 10 KEGG pathways identified from DEGs in A by KEGG enrichment analysis. (C) Heatmaps showing the DEGs of the chemokine-related genes in CD11b+F4/80+PDPNhi PMs, compared with CD11b+F4/80+PDPNlo, grouped by hierarchical clustering analysis of the RNA-Seq data. (D and E) qPCR analysis of M2-related chemokine DEGs (D) and polarization markers (E) in PDPNhi versus PDPNlo PMs from WT septic mice (n = 4 each, unpaired t test). Relative mRNA levels were normalized to Hprt. (F) Flow cytometric analysis of E. coli–GFP uptake by CD11b+F4/80+PDPNlo and CD11b+F4/80+PDPNhi PMs in LPS-treated septic WT mice. GFP fluorescence (mean fluorescence intensity) was compared (n = 3 each, unpaired t test). (G) GSEA histogram for the “phagosome” gene set in PDPNhi versus PDPNlo PMs. The normalized enrichment score (NES) and FDR q value are indicated. (H) The mRNA levels of Cd36 and Marco in PDPNhi and PDPNlo PMs from WT septic mice were determined using qPCR (n = 4 each, unpaired t test). Relative mRNA levels were normalized to Hprt. (I) Kaplan-Meier survival analysis of WT and Adap–/– mice injected with anti-PDPN blocking antibodies (100 μg/mouse, i.v.) 2 hours after E. coli infection (2 × 107 CFU, i.p.) (WT E. coli, n = 15; Adap–/– E. coli, n = 10; WT E. coli–anti-PDPN, n = 16; Adap–/– E. coli–anti-PDPN, n = 11). Log-rank test was used to compare survival curve.

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