Neutrophils insert elastase into hepatocytes to regulate calcium signaling in alcohol-associated hepatitis
Noriyoshi Ogino, … , Barbara E. Ehrlich, Michael H. Nathanson
Noriyoshi Ogino, … , Barbara E. Ehrlich, Michael H. Nathanson
Published June 25, 2024
Citation Information: J Clin Invest. 2024;134(16):e171691. https://doi.org/10.1172/JCI171691.
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Research Article Hepatology

Neutrophils insert elastase into hepatocytes to regulate calcium signaling in alcohol-associated hepatitis

Abstract

Neutrophil infiltration occurs in a variety of liver diseases, but it is unclear how neutrophils and hepatocytes interact. Neutrophils generally use granule proteases to digest phagocytosed bacteria and foreign substances or neutralize them in neutrophil extracellular traps. In certain pathological states, granule proteases play a destructive role against the host as well. More recently, nondestructive actions of neutrophil granule proteins have been reported, such as modulation of tissue remodeling and metabolism. Here, we report a completely different mechanism by which neutrophils act nondestructively, by inserting granules directly into hepatocytes. Specifically, elastase-containing granules were transferred to hepatocytes where elastase selectively degraded intracellular calcium channels to reduce cell proliferation without cytotoxicity. In response, hepatocytes increased expression of Serpin E2 and A3, which inhibited elastase activity. Elastase insertion was seen in patient specimens of alcohol-associated hepatitis, and the relationship between elastase-mediated ITPR2 degradation and reduced cell proliferation was confirmed in mouse models. Moreover, neutrophils from patients with alcohol-associated hepatitis were more prone to degranulation and more potent in reducing calcium channel expression than neutrophils from healthy individuals. This nondestructive and reversible action on hepatocytes defines a previously unrecognized role for neutrophils in the transient regulation of epithelial calcium signaling mechanisms.

Authors

Noriyoshi Ogino, M. Fatima Leite, Mateus T. Guerra, Emma Kruglov, Hiromitsu Asashima, David A. Hafler, Takeshi Ito, João P. Pereira, Brandon J. Peiffer, Zhaoli Sun, Barbara E. Ehrlich, Michael H. Nathanson

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Figure 2

The decrease in ITPR2 in HepG2 cells induced by neutrophils is rapid and reversible.

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The decrease in ITPR2 in HepG2 cells induced by neutrophils is rapid and...
(A) Representative immunoblots and (B) quantitation of ITPR2 levels in HepG2 cells cocultured with neutrophils show that loss of ITPR2 persists for up to 20 hours in the continued presence of neutrophils. (C and D) RT-qPCR shows that ITPR2 mRNA levels in HepG2 cells are increased after 1 hour and decreased after 20 hours of coculture with neutrophils. (E) Representative immunoblots and (F) quantitation show that ITPR2 levels begin to recover after neutrophils are removed. ITPR2 levels were measured in HepG2 cells cocultured with neutrophils for 20 hours, and then cells were washed to remove neutrophils and cultured for 2 more hours and collected (after neutrophil removal). Comparisons were relative to HepG2 cells cultured alone for 22 hours or cocultured with neutrophils. (G) Ca2+ signals in HepG2 cells progressively recover after neutrophils are removed. AUC of Fluo-4 fluorescence after stimulation with ATP (20 μM) was measured at 3 time points: after coculture with neutrophils for 1 hour (1 h, followed by complete removal of neutrophils for 1 hour [2 h] or 19 hours [20 h]). Data represent 5–7 coverslips each, with cell numbers n = 286, 208, 112. (H) Representative immunoblots and (I) quantitation shows that loss of ITPR2 in HepG2 cells is not blocked by treatment with MG132 (proteasome inhibitor, 50 μM), bafilomycin A1 (Baf, autophagy inhibitor, 50 nM), or Ac-Leu-Leu-Nle-aldehyde (ALLN, calpain inhibitor, 50 μM) for 1 hour, followed by coculture with neutrophils for 1 hour. Data are expressed as mean ± SD, n = 3–8. NS, not significant. *P < 0.05; **P < 0.01; ***P < 0.001; ****P < 0.0001 by unpaired, 2-tailed Student’s t test (BD and F) or 1-way ANOVA with Tukey’s multiple-comparison test (G and I).