TNF-α impairs platelet function by inhibiting autophagy and disrupting metabolism via syntaxin 17 downregulation
Guadalupe Rojas-Sanchez, … , José A. López, Pavel Davizon-Castillo
Guadalupe Rojas-Sanchez, … , José A. López, Pavel Davizon-Castillo
Published June 10, 2025
Citation Information: J Clin Invest. 2025;135(15):e186065. https://doi.org/10.1172/JCI186065.
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Research Article Hematology Metabolism

TNF-α impairs platelet function by inhibiting autophagy and disrupting metabolism via syntaxin 17 downregulation

Abstract

Platelets play a dual role in hemostasis and inflammation-associated thrombosis and hemorrhage. Although the mechanisms linking inflammation to platelet dysfunction remain poorly understood, our previous work demonstrated that TNF-α alters mitochondrial mass, platelet activation, and autophagy-related pathways in megakaryocytes. Here, we hypothesized that TNF-α impairs platelet function by disrupting autophagy, a process critical for mitochondrial health and cellular metabolism. Using human and murine models of TNF-α–driven diseases, including myeloproliferative neoplasms and rheumatoid arthritis, we found that TNF-α downregulates syntaxin 17 (STX17), a key mediator of autophagosome-lysosome fusion. This disruption inhibited autophagy, leading to the accumulation of dysfunctional mitochondria and reduced mitochondrial respiration. These metabolic alterations compromised platelet-driven clot contraction, a process linked to thrombotic and hemorrhagic complications. Our findings reveal a mechanism by which TNF-α disrupts hemostasis through autophagy inhibition, highlighting TNF-α as a critical regulator of platelet metabolism and function. This study provides potentially new insights into inflammation-associated pathologies and suggests autophagy-targeting strategies as potential therapeutic avenues to restore hemostatic balance.

Authors

Guadalupe Rojas-Sanchez, Jorge Calzada-Martinez, Brandon McMahon, Aaron C. Petrey, Gabriela Dveksler, Gerardo P. Espino-Solis, Orlando Esparza, Giovanny Hernandez, Dennis Le, Eric P. Wartchow, Ken Jones, Lucas H. Ting, Catherine Jankowski, Marguerite R. Kelher, Marilyn Manco-Johnson, Marie L. Feser, Kevin D. Deane, Travis Nemkov, Angelo D’Alessandro, Andrew Thorburn, Paola Maycotte, José A. López, Pavel Davizon-Castillo

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Figure 7

In vivo TNF-α blockade preserves STX17 levels, autophagy, mitochondrial respiration, and clot contraction in a mouse model of TNF-α–driven aseptic inflammation.

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In vivo TNF-α blockade preserves STX17 levels, autophagy, mitochondrial ...
(A) Experimental approach. Young (3-month-old) C57BL/6 mice were treated daily with vehicle (0.01% BSA in PBS), TNF-α, or TNF-α plus an anti–TNF-α mAb (every other day) for 15 days (n = 4 each). Platelets were incubated with vehicle (PBS) or CQ (50 μM) for 2 hours to analyze autophagic flux. (B) Immunoblotting of STX17, LC3B-II, and TOM20. (C) Analysis of STX17, (D) LC3B-II, and (E) TOM20 levels. Before-and-after graph, n = 4 each; 2-way ANOVA, Šídák’s test. (F) Quantification of intracellular LC3 by FACS, representative histogram with before-and-after graphs, Veh and TNF-α plus anti–TNF-α mAb n = 4, TNF-α n = 3; 2-way ANOVA, Šídák’s test. (G) The OCR of washed platelets (n = 4) was measured with a Seahorse XF HS Mini Analyzer (mean ± SEM of 3 independent samples). (H) Basal, maximal, and ATP-linked respiration (n = 4), Brown-Forsythe and Welch’s ANOVA tests. (I) Thrombin-induced clot contraction assay using normalized platelet counts, Veh (n = 4), TNF-α (n = 5), and TNF-α plus anti–TNF-α mAb (n = 4); Brown-Forsythe and Welch’s ANOVA test. Box-and-whisker plots (H and I) represent the data distribution.