key: cord-0020498-m4avj5ul
authors: Namba, Takahiro; Tsuge, Mitsuru; Yashiro, Masato; Saito, Yukie; Liu, Keyue; Nishibori, Masahiro; Morishima, Tsuneo; Tsukahara, Hirokazu
title: Anti-high mobility group box 1 monoclonal antibody suppressed hyper-permeability and cytokine production in human pulmonary endothelial cells infected with influenza A virus
date: 2021-08-29
journal: Inflamm Res
DOI: 10.1007/s00011-021-01496-5
sha: 3d3e81a53c5bf85165fc99cd5082a32624aa574a
doc_id: 20498
cord_uid: m4avj5ul

OBJECTIVE: High mobility group box-1 (HMGB1) has been reported to be involved in influenza A virus-induced acute respiratory distress syndrome (ARDS). We studied the efficacy of an anti-HMGB1 mAb using an in vitro model of TNF-α stimulation or influenza A virus infection in human pulmonary microvascular endothelial cells (HMVECs). METHODS: Vascular permeability of HMVECs was quantified using the Boyden chamber assay under tumor necrosis factor-α (TNF-α) stimulation or influenza A virus infection in the presence of anti-HMGB1 mAb or control mAb. The intracellular localization of HMGB1 was assessed by immunostaining. Extracellular cytokine concentrations and intracellular viral mRNA expression were quantified by the enzyme-linked immunosorbent assay and quantitative reverse transcription PCR, respectively. RESULTS: Vascular permeability was increased by TNF-α stimulation or influenza A infection; HMVECs became elongated and the intercellular gaps were extended. Anti-HMGB1 mAb suppressed both the increase in permeability and the cell morphology changes. Translocation of HMGB1 to the cytoplasm was observed in the non-infected cells. Although anti-HMGB1 mAb did not suppress viral replication, it did suppress cytokine production in HMVECs. CONCLUSION: Anti-HMGB1 mAb might be an effective therapy for severe influenza ARDS.

Influenza infection is prevalent every year worldwide and its complications, such as influenza pneumonia and acute respiratory distress syndrome (ARDS), impart high mortality rates [1, 2] . Influenza A (H1N1) pdm09 virus infection caused a pandemic in 2009, resulting in 100,000-400,000 deaths worldwide due to severe ARDS [3] . In the pathophysiology of influenza ARDS, direct viral infection and the subsequent hypercytokinemia response, induced by tumor necrosis factor-alpha (TNF-α) or interleukin-6 (IL-6), activate host immunity, damage pulmonary vascular endothelial cells, and increase vascular leakage resulting in pulmonary edema [4] [5] [6] . Damage to the barrier of endothelial cells can lead to leakage by micro-vessels [4] [5] [6] . Here, we aimed to determine how to prevent damages to the endothelial cells to suppress the progression of influenza-associated ARDS.

In the past decade, various treatments have been developed to prevent the severity of influenza pneumonia [2, 7] . One treatment involves anti-influenza drugs that directly decrease the replication of influenza virus [8] . A second treatment involves therapeutic lung protection strategies, such as extracorporeal membrane oxygenation (ECMO), to alleviate lung damage caused by ventilator-induced lung injury [7] . A third treatment involves anti-inflammatory therapy for hypercytokinemia caused by influenza infection [2, 9, 10] . Various immunomodulators have been developed to date, but they have not yet been put into practical use in the treatment of influenza pneumonia [9, 10] . A certain number of patients develop severe progressive ARDS despite the administration of anti-influenza drugs with ECMO treatment, and they exhibit high mortality rates [2, 11, 12] . Therefore, there is a strong need for the development of novel therapeutic immunomodulatory drugs that can be used in combination with anti-influenza drugs.

Relatively high levels of serum high mobility group box-1 (HMGB1) were reported in patients with severe influenza pneumonia [13] as also observed under various inflammatory conditions, such as sepsis [14, 15] and acute lung inflammation [16] . HMGB1 is a damage-associated molecular pattern (DAMP) protein [14, 15, 17] . HMGB1 can promote the production of inflammatory cytokines, such as TNF-α or IL-6, via the receptor for the advanced glycation end product (RAGE) and toll-like receptor 4 (TLR-4) [15, 17] . Several studies show that HMGB1 would function as a major proinflammatory mediator in these inflammatory conditions [14] [15] [16] [17] . Therefore, the possibility of inhibiting the function of HMGB1 has been suggested as a therapeutic intervention [16] . We previously reported that an anti-HMGB1 mAb improved the survival rate and inhibited cytokine/chemokine expression in the lungs of a mouse model of influenza pneumonia [18] . We also reported that the efficacy of the combined therapy of an anti-influenza drug and an anti-HMGB1 antibody improved the survival rate more than that of anti-influenza drug mono-therapy [19] . The cytokine concentration in the blood and alveolar lavage fluid was also decreased by this combined therapy [19] . In these reports, the efficacy of anti-HMGB1 antibody in vivo was clarified; however, it has not yet been verified in human primary lung endothelial cells in vitro.

Therefore, the aim of this study was to assess the efficacy of an anti-HMGB1 mAb on an in vitro model of severe influenza pneumonia. We stimulated human pulmonary vascular endothelial cells (HMVECs) with TNF-α to induce hypercytokinemia or infected them with influenza A virus, in the presence of anti-HMGB1 mAb or control antibody. We evaluated the permeability, the changes in cell morphology and cytokine production of HMVECs.

Primary HMVECs (Lonza, Walkersville, MD, USA) were grown in the medium and growth supplements supplied by the manufacturer (endothelial cell basal medium 2; EGM-2) containing the following: vascular endothelial growth factor, human fibroblast growth factor B, hydrocortisone, human epidermal growth factor, GA-1000, fetal bovine serum, rat insulin-like growth factor 1, and ascorbic acid [20, 21] . The medium was changed every 48 h until confluence was reached. The cells were cultured in 5% CO 2 at 37 °C. All experiments were performed on cells in the 5th-9th passage.

We used influenza A (H3N2) virus (A/Panama/1/68) maintained in Madin-Darby canine kidney (MDCK) cells. The influenza virus was titrated to determine the median tissue culture infectivity dose (TCID 50 ) of MDCK cells in the presence of trypsin. We diluted the influenza virus tenfold in steps, applied to MDCK cell monolayers in triplicate, and evaluated the cytopathic effects 5 days after infection. The viral infection procedure was performed at multiplicities of infection (MOI) 1 in serum-free media with 0.5% bovine serum albumin (BSA).

A Boyden chamber was used for the evaluation of permeability [22, 23] . HMVECs were seeded on 0.4 mm pore size polyethylene terephthalate track-etched transwell membranes (Corning, NY, USA) at a concentration of 1.0 × 10 5 cells/well and cultured to confluency for 3-4 days. After cell confluence was achieved, the culture media in the upper chamber (200 μL) and the lower chamber (700 μL) were replaced with serum-free media with 0.5% BSA containing human recombinant TNF-α (Peprotech Inc., Rocky Hill, NJ, USA) at a concentration of 100 ng/mL for 24 h, or influenza virus at MOI of 1 for 72 h. At this time, the media in the upper and the lower chamber contained either anti-HMGB1 mAb (#10-22, immunoglobulin G2a subclass, 100 μg/mL) or class-matched control mAb (anti-Keyhole Limpet hemocyanin, 100 μg/mL) [24] . These mAbs were provided by Professor Nishibori, Department of Pharmacology, Okayama University Graduate School of Medicine. To measure permeability, 200 μL assay medium containing fluorescein isothiocyanate-labeled dextran (FITC-Dx; MW 70,000) (Invitrogen Corp., Carlsbad, CA, USA) was added to each upper chamber, and 700 μL assay medium was added to each lower chamber. After several hours of incubation, the fluorescence intensity of the lower chamber medium was measured at 485-538 nm.

HMVECs were grown to confluency on collagen I-coated culture slides (AGC TECHNO GLASS Co., Shizuoka, Japan). After the indicated treatment time, cells were washed with phosphate-buffered saline (PBS) and fixed with 4.0% paraformaldehyde for 15 min. After permeabilization with 0.2% Triton X-100 in PBS for 10 min, the cells were washed and probed with the primary antibodies (mouse anti-influenza A nucleoprotein antibody from Abcam, Cambridge, MA, USA; rabbit anti-HMGB1 antibody from Abcam; and rabbit anti-vascular endothelial (VE) cadherin antibody from Abcam) at a 1:200 dilution for 60 min. The coverslips were washed and then incubated with Alexa Fluor 488-conjugated goat anti-rabbit or anti-mouse secondary antibody (1:500 dilution) (Invitrogen Corp., Carlsbad, CA, USA) for 1 h at 20 °C. The nuclei were stained with 4′,6-diamidino-2-phenylindole (DAPI) in a mounting medium (Vectashield; Vector Laboratories Inc., Burlingame, CA, USA). Samples were evaluated under a fluorescence microscope (BZ-9000 generation II; Keyence Co., Osaka, Japan). When measuring the cell morphology, each long axis and short axis of 100 cells/field at 40 × magnification were measured on the VE cadherin-stained images using the BZ image analysis software application. The same measurements were performed on four randomly selected fields of view.

Total RNA was extracted at 6, 12, 18, and 72 h after influenza infection using the RNeasy Mini Kit (Qiagen, Carlsbad, CA, USA) with DNase digestion. cDNA synthesis was carried out using the TaKaRa PrimeScript first-strand cDNA synthesis kit (Takara Bio Inc., Kusatsu, Japan) according to the manufacturer's instructions. qRT-PCR was conducted using PowerUp SYBR Green PCR Master Mix (Applied Biosystems, Foster City, CA, USA). cDNA was denatured at 50 °C for 2 min and 95 °C for 2 min followed by 40 cycles of 95 °C for 15 s and 60 °C for 1 min using the Real-Time PCR system 7500 (Applied Biosystems). Data were analyzed using SDS software v2.1 (Applied Biosystems). Relative gene expression was compared using the comparative CT method. Glyceraldehyde 3-phosphate dehydrogenase (GAPDH) was used to normalize the efficiency of cDNA synthesis. The primer sets used for this study were influenza A M1: forward 5′-AAG ACC AAT CCT GTC ACC TCTGA-3′ and reverse 5′-CAA AGC GTC TAC GCT GCA GTCC-3′; and GAPDH: forward 5′-GTC TCC TCT GAC TTC AAC AGCG-3′ and reverse 5′-ACC ACC CTG TTG CTG TAG CCAA-3′.

Supernatants were collected at different time points after stimulation with TNF-α or infection with influenza A virus. The levels of HMGB1, IL-6, granulocyte colony-stimulating factor (G-CSF), granulocyte-macrophage CSF (GM-CSF), regulated on activation, normal T cell expressed and secreted (RANTES), and interferon-γ inducible protein (IP-10) were measured using commercial ELISA kits (HMGB1: Shinotest, Kanagawa, Japan; IL-6, G-CSF, GM-CSF, RANTES, IP-10: R&D Systems, Minneapolis, MN, USA) according to the manufacturer's instructions.

HMVECs were seeded on 96-well plates. TNF-α stimulation and influenza A (H3N2) infection were performed at the indicated concentrations. Cell viability was then measured using MTT [3-(4,5-dimethyl-2-thiazolyl)-2,5-diphenyltetrazolium bromide] cell count kit (NACALAI TESQUE, INC., Kyoto, Japan) according to the manufacturer's instructions. The absorbance (570 nm) of each sample was measured by a microplate reader, and the measured absorbance was corrected using a background control.

To quantify HMGB1 translocation, the number of HMGB1 cytoplasmic translocations per 100 cells at 40 × magnification was measured in the HMGB1-stained images. The same measurements were performed on four randomly selected fields of view.

All experiments were performed at least three times and all values are expressed as mean ± standard error (SE). Data were analyzed using GraphPad Prism software version 8.0 for Mac (GraphPad Software, San Diego, CA, USA). Differences between groups were examined for statistical significance using one-way analysis of variance with Tukey's multiple comparison test. Statistical significance was inferred for P values < 0.05.

HMVECs were treated with influenza A (H3N2) at MOI = 1. No staining of viral nucleoprotein (NP) was observed in HMVECs without influenza A (H3N2) infection. NP-positive cells were found in approximately 10% of HMVECs infected with influenza A (H3N2) at MOI = 1, whereas NPpositive cells were found in almost all HMVECs infected at MOI = 10 ( Fig. 1a-f ). Viral NP was stained in both the nucleus and the cytoplasm of HMVECs.

HMVECs were stimulated with TNF-α (100 ng/mL) for 0, 12, and 24 h, or infected with influenza A (H3N2) at MOI = 1 for 0, 24, and 48 h. The HMGB1 concentration in the supernatant had significantly increased after 12 h of TNF-α stimulation compared with that at 0 h. Similarly, the HMGB1 concentration in the supernatant had significantly increased after 24 h compared with that at 12 h (Fig. 2a) . The HMGB1 concentration in the supernatant was significantly increased after 24 h of influenza A (H3N2) infection compared with that at 0 h, and at 48 h compared with that at 24 h (Fig. 2b) .

HMVECs were stimulated with TNF-α (100 ng/mL or 10 ng/mL) for 24 h or infected with influenza A (H3N2) virus at an MOI of 0.1 or 1.0 for 72 h. We did not observe any significant difference in cell viability upon TNF-α stimulation as well as in influenza A virus infection (Fig. 3a, b) .

HMVECs were stimulated with TNF-α (100 ng/mL) for 6 h or infected with influenza A (H3N2) at MOI = 1 for 12 h. Cytoplasmic translocation of HMGB1 was observed in a few HMVECs after TNF-α stimulation ( Fig. 4a-d) and influenza A (H3N2) infection. Cytoplasmic translocation of HMGB1 was higher in cells after influenza A (H3N2) infection than that after TNF-α stimulation. In infected cells, HMGB1 remained in the nucleus. Interestingly, the cytoplasmic translocation was observed not in the infected cells but in the surrounding non-infected cells (Fig. 5a-d) . The translocation of HMGB1 was not observed in the absence of TNF-α stimulation or influenza A (H3N2) infection (Figs. 4e-h, 5e-h).

The translocation of HMGB1 was observed in HMVECs either upon TNF-α stimulation or influenza A (H3N2) infection (TNF-α; 1.9 ± 0.39/100 cells, Influenza A infection; 2.78 ± 0.45/100 cells). The HMGB1 translocation was not observed in the absence of TNF-α stimulation or influenza A (H3N2) infection (Fig. 6a, b) . 

The vascular permeability of HMVECs was increased upon TNF-α stimulation (100 μg/mL, for 24 h), but it was significantly suppressed in the presence of anti-HMGB1 mAb (100 ng/mL) (p < 0.05) (Fig. 7a) . The permeability of HMVECs also increased upon influenza A (H3N2) infection (MOI = 1, for 72 h), and it was significantly suppressed in the presence of anti-HMGB1 mAb (p < 0.05) (Fig. 7b) . 

In the absence of any stimulation, HMVECs showed a uniform cobblestone appearance with almost no intercellular spaces (Fig. 8a, d) . Upon TNF-α stimulation (100 μg/mL, for 24 h), HMVECs showed a cell spindle-shape change, which was significantly inhibited in the presence of anti-HMGB1 mAb (p < 0.05) (Fig. 8b, c) . HMVECs also showed a cell spindleshape change after influenza A (H3N2) infection (MOI = 1, for 72 h), which was significantly inhibited in the presence of anti-HMGB1 mAb (p < 0.05) (Fig. 8e, f) .

The levels of IL-6, GM-CSF, G-CSF, IP-10, and RANTES were significantly increased in the supernatants of HMVECs upon TNF-α stimulation (100 μg/mL, for 24 h). The increased levels of IL-6, GM-CSF, and IP-10 were significantly suppressed in the presence of anti-HMGB1 mAb (IL-6, GM-CSF, and IP-10, p < 0.01; G-CSF, p < 0.05) (Fig. 9a-e) . The levels of IL-6, GM-CSF, G-CSF, IP-10, or RANTES significantly increased in the supernatant of HMVECs infected with influenza A (H3N2) (MOI = 1, for 72 h), and the increased (Fig. 9f-j) .

Viral gene expression of the influenza M1 protein was significantly increased at 12 h in a time-dependent manner after influenza A (H3N2) infection at MOI = 1 (p < 0.05). Viral M1 protein gene expression was not suppressed after influenza A (H3N2) infection in the presence of anti-HMGB1 mAb compared with that of the control mAb (Fig. 10 ).

HMVECs. This influenza A virus was able to infect more cells at MOI = 10 compared to MOI = 1, which agrees with previous reports [21, 23] . Both α2-3 sialic acid and α2-6 sialic acid, which are receptors for the influenza virus to enter cells, are known to be expressed on the surfaces of HMVECs [21] , and influenza infection of HMVECs has been observed in several studies [20, 21, 23, 25] . Previous autopsy reports of patients with influenza pneumonia confirmed that the influenza viral protein was located in a small number of pulmonary vascular endothelial cells [26] . We considered that the pathological condition in which a small number of HMVECs are infected with influenza more closely reflects the pathophysiology of severe influenza pneumonia in humans. Therefore, in this study, we infected HMVECs with influenza A at MOI = 1 to enable an analysis of the inter-relationship between influenza A virus-infected cells and uninfected cells.

We confirmed that TNF-α stimulation and influenza A infection induced the release of HMGB1 from HMVECs. We also confirmed that TNF-α stimulation and influenza A infection caused the translocation of HMGB1 protein from the nucleus to the cytoplasm. Interestingly, HMGB1 translocations were found in surrounding uninfected cells. Several previous reports suggest that HMGB1 could be released from various vascular endothelial cells by TNF-α stimulation [27] or by virus infection [28, 29] . Importantly, HMGB1 has been reported to be released from virus-infected cells in previous studies [28, 29] , which is not consistent with our results. Cytoplasmic translocation of HMGB1 in HMVECs has not yet been investigated for influenza infection and this inconsistency might be due to differences in vascular endothelial cell types and virus types used in the studies. Our study results suggest that influenza A infection in a small number of HMVECs stimulates the transmission of a signal that causes cytoplasmic translocation of HMGB1 in surrounding uninfected cells. At the same time, HMGB1 protein was still found in the nucleus of infected cells, so it was considered possible that the increased HMGB1 in the supernatant was released from non-infected cells rather than from infected cells. The cytoplasmic translocation of HMGB1 has been reported to occur because of the activation of several signaling pathways [30] [31] [32] [33] . In this study, we have confirmed that IL-6 and HMGB1 were released into the supernatant when HMVECs were infected with influenza A. IL-6 and HMGB1 are reported to be able to activate endothelial cells through several signaling pathways [34] [35] [36] [37] . Although there have been no reports of IL-6 or HMGB1 causing HMGB1 translocation, we could consider that the activation of HMVECs by IL-6 and HMGB1 led to HMGB1 translocation indirectly. Further studies are needed to understand the mechanism of HMGB1 translocation in certain surrounding cells and not in others.

We confirmed that anti-HMGB1 mAb was able to suppress the increased permeability upon TNF-α stimulation or influenza A infection. We also showed that anti-HMGB1 mAb suppressed the change in cell morphology of HMVECs and the expanded intercellular space upon TNF-α stimulation or influenza A infection. TNF-α stimulation or influenza A virus infection has been reported to increase vascular endothelial cell permeability [23, 25, 38] . High concentrations of HMGB1 have been reported to increase the vascular permeability in pulmonary vascular endothelial cells [39] . The HMGB1 receptors RAGE and TLR4 have already been reported to express abundantly on the surface of HMVECs [34, [40] [41] [42] . Extracellular HMGB1 binds to either RAGE or TLR4 on the surface of vascular endothelial cells and activates them via the p38MAPK pathway [25, 38, 43] . Activation of the p38MAPK pathway in vascular endothelial cells has been reported to increase the expression of F-actin, and to promote phosphorylation of ezrin/radixin/ moesin family proteins, leading to cytoskeletal changes and hyperpermeability [25, 38, 43] . In this study, we observed that HMGB1 was released following TNF-α stimulation or influenza A (H3N2) infection; this could lead to activation of HMVECs through RAGE and TLR4, changing the cytoskeleton to a spindle shape and expanding the intercellular spaces, thereby increasing the vascular permeability. It was considered that the anti-HMGB1 mAb suppressed the activation of HMVECs by neutralizing the released extracellular HMGB1 and inhibited the changes in cell morphology and the increase in permeability.

We confirmed that anti-HMGB1 mAb suppressed the production of cytokines/chemokines such as IL-6, G-CSF, GM-CSF, and IP-10 from HMVECs. Several studies show that TNF-α stimulation or influenza infection induces the secretion of inflammatory cytokines from HMVECs by activating the p38 MAPK and c-Jun N-terminal kinase pathways in endothelial cells [21, 25, 44] . Nuclear factor κB is activated in endothelial cells, which is thought to increase the production of cytokines/chemokines [25, 43, 44] . IL-6 and IP-10 have been histopathologically found in pulmonary bronchial epithelial cells and endothelial cells of patients with severe influenza ARDS [45] . Clinically, high blood concentrations of IL-6, G-CSF, GM-CSF, and IP-10 have been reported to be indicators of the risk of death in patients with severe influenza pneumonia [46, 47] . In particular, vascular endothelial cells express the IL-6 receptor and are directly activated by IL-6 via the Janus kinase-signal transducer and activator of transcription 3 pathway, resulting in the release of HMGB1 [35] [36] [37] . Our study suggests that anti-HMGB1 mAb suppresses the activation of HMVECs and prevents further exacerbation of hyperinflammation by specifically inhibiting extracellular HMGB1. As for IL-6, the anti-HMGB1 mAb inhibited further activation of HMVECs, which may have inhibited the release of IL-6 into the supernatant. By inhibiting extracellular HMGB1 and suppressing the release of IL-6, the activation of HMVECs by IL-6 may also have been suppressed. This might also inhibit the subsequent release of cytokines/chemokines and the morphological changes of the HMVECs. In terms of the relationship between anti-HMGB1 mAb and HMVECs, anti-HMGB1 mAb might, not only directly inhibit the inflammatory effect of extracellular HMGB1, but also indirectly inhibit IL-6-induced activation of HMVECs.

In this study, anti-HMGB1 mAb exerted the antiinflammatory effect by inhibiting extracellular HMGB1 from activating HMVECs. On the other hand, there was no effect of anti-HMGB1 mAb on the direct HMVEC activation due to TNF-α stimulation or influenza A (H3N2) infection. Here we confirmed that the production of RANTES from HMVECs was not suppressed by anti-HMGB1 mAb. This result indicates that the activation of HMVECs by extracellular HMGB1 was not mainly involved in RANTES production. IP-10 was produced in a much larger amount by influenza A (H3N2) infection than TNF-α stimulation. Since IP-10 production from HMVECs was decreased by treatment of anti-HMGB1 mAb, activation of HMVECs by extracellular HMGB1 would be involved in IP-10 production. However, the IP-10 production owing to influenza A (H3N2) infection was so high that the inhibition of IP-10 by anti-HMGB1 mAb in influenza A (H3N2) infection needs to be carefully examined.

We observed that the effect of anti-HMGB1 mAb on HMVECs in suppressing hyper-permeability or cytokine/ chemokine production might be due to suppression of influenza A virus infection or propagation. Therefore, we evaluated the effect of anti-HMGB1 mAb on influenza A virus replication. The gene expression of influenza virus M1 protein increased after influenza A (H3N2) infection in a time-dependent manner. However, no decrease in viral M1 protein gene expression was observed, despite the introduction of the anti-HMGB1 mAb. We previously reported that the administration of HMGB1 mAb improved the survival rate and inhibited the cytokine/ chemokine expression in the lungs, but it did not decrease virus propagation in vivo [18, 19] , which is consistent with our observation in this study. We suppose that the inhibitory effect of hyper-permeability or cytokine/chemokine production observed in our study was not due to the inhibition of virus infection or replication, but to the inhibition of downstream inflammation after infection.

We showed that an anti-HMGB1 mAb could suppress hyper-permeability and cytokine production in HMVECs caused by TNF-α stimulation or influenza A (H3N2) infection. These observations may facilitate the development of new therapeutic strategies for severe viral pneumonia and ARDS.

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Data availability All data generated or analyzed during this study are included in this published article.

The authors have no conflicts of interest to declare.