key: cord-0733933-yure79ky authors: Bendib, Inès; Beldi-Ferchiou, Asma; Schlemmer, Frédéric; Maitre, Bernard; Surenaud, Mathieu; Hüe, Sophie; Carteaux, Guillaume; Razazi, Keyvan; Lelièvre, Jean-Daniel; Lévy, Yves; Mekontso Dessap, Armand; Godot, Véronique; de Prost, Nicolas title: Functional Ex Vivo Testing of Alveolar Monocytes in Patients with Pneumonia-Related ARDS date: 2021-12-15 journal: Cells DOI: 10.3390/cells10123546 sha: 74985839887e0ea89d7cea4d4f31fa28f91b5c0e doc_id: 733933 cord_uid: yure79ky Biomarkers of disease severity might help with individualizing the management of patients with acute respiratory distress syndrome (ARDS). During sepsis, a sustained decreased expression of the antigen-presenting molecule human leucocyte antigen-DR (HLA-DR) on circulating monocytes is used as a surrogate marker of immune failure. This study aimed at assessing whether HLA-DR expression on alveolar monocytes in the setting of a severe lung infection is associated with their functional alterations. BAL fluid and blood from immunocompetent patients with pneumonia-related ARDS admitted between 2016 and 2018 were isolated in a prospective monocentric study. Alveolar and blood monocytes were immunophenotyped using flow cytometry. Functional tests were performed on alveolar and blood monocytes after in vitro lipopolysaccharide (LPS) stimulation. Phagocytosis activity and intracellular tumor necrosis factor (TNF) production were quantified using fluorochrome-conjugated-specific antibodies. Ten ARDS and seven non-ARDS control patients were included. Patients with pneumonia-related ARDS exhibited significantly lower HLA-DR expression both on circulating (p < 0.0001) and alveolar (p = 0.0002) monocytes. There was no statistically significant difference observed between patient groups (ARDS vs. non-ARDS) regarding both alveolar and blood monocytes phagocytosis activity. After LPS stimulation, alveolar (p = 0.027) and blood (p = 0.005) monocytes from pneumonia-related ARDS patients had a significantly lower intracellular TNF expression than non-ARDS patients. Monocytes from pneumonia-related ARDS patients have a deactivated status and an impaired TNF production capacity but display potent phagocytic activity. HLA-DR level expression should not be used as a surrogate marker of the phagocytic activity or the TNF production capacity of alveolar monocytes. Pulmonary infections account for the vast majority of acute respiratory distress syndrome (ARDS) risk factors [1] and are associated with septic shock in about 70% of cases [2] . Although improvements regarding patient phenotyping have been made using multiparametric approaches combining clinical and biological variables [3, 4] , no single biomarker obtained from blood samples has been shown to reliably predict the outcomes of patients with pneumonia-related ARDS [5] , possibly because of an alveolar compartmentalization of biomarkers during severe pulmonary infections [6] . During sepsis, a sustained decreased expression of the antigen presenting molecule human leucocyte antigen-DR (HLA-DR) on circulating monocytes is used as a surrogate marker of immune failure and higher risk of death [7] [8] [9] . The overexpression of programmed cell death receptor ligand-1 (PD-L1) also occurs during sepsis and correlates with higher mortality [10] . Monocyte deactivation reflected by down regulation of HLA-DR expression on circulating monocytes [11, 12] has been associated with the phenomenon of endotoxin tolerance, defined by a reduction of TNF secretion capacity after ex vivo lipopolysaccharide (LPS) stimulation [13] . The appropriate characterization of sepsis-induced monocytes dysfunctions using phagocytosis or cytokine release assays has become a key field of research for the development of innovative therapeutic strategies. Unfortunately, routine assays provide only measurements of immune cell surface biomarkers [14, 15] . Down regulation of HLA-DR on circulating monocytes was consistently associated with an increased risk of nosocomial infections [16] and a higher risk of death [8, [16] [17] [18] . Monitoring circulating monocytes HLA-DR expression has been previously used to identify patients who might benefit from immunomodulatory interventions [19, 20] . However, few studies focused on alveolar monocytes despite their central role in the innate frontline defense of pulmonary infections. Contrasting with HLA-DR expression on circulating monocytes, the quantification of HLA-DR on alveolar monocytes was not a prognosis biomarker in patients with pneumonia-related ARDS [6] . This discrepancy led us to question the relationship between alveolar HLA-DR expression level and monocyte functions. In the current study, which is an ancillary study of the PICARD study [6] , we aimed to assess, in a prospective cohort of patients with moderate to severe pneumonia-related ARDS: (1) the phenotype of alveolar and blood monocytes (i.e., levels of HLA-DR and PD-L1 expressions) and compare it to those of non ARDS patients; (2) the function of alveolar and blood monocytes; and (3) explore alveolar monocytes functions according to their level of HLA-DR expression. This was a prospective single-center observational cohort study, which is an ancillary study of the PICARD study [6] . Consecutive patients diagnosed with pneumonia-related ARDS admitted to the medical intensive care unit (ICU) of Henri Mondor Hospital, Créteil, France, from January 2016 to December 2018 were eligible for inclusion in the study. All patients with moderate/severe pneumonia-related ARDS [1] were included consecutively with the following inclusion criteria: tracheal intubation and mechanical ventilation for less than 48 h; pulmonary infection diagnosed less than 7 days before ICU admission; bilateral pulmonary infiltrates on chest X-ray; PaO 2 /FiO 2 ratio ≤ 200 mm Hg with a positive end-expiratory pressure (PEEP) ≥ 5 cm H 2 O. Non-inclusion criteria were as follows: age < 18 years; pregnancy; chronic respiratory failure requiring long-term oxygen therapy; Child-Pugh C liver cirrhosis; lung fibrosis; immunosuppression; SAPS II (Simplified Acute Physiology II score) > 90; irreversible neurological disorders; patients with withholding/withdrawing of life-sustaining therapies and profound hypoxemia (PaO 2 /FiO 2 < 75 mm Hg). Control patients, (i.e., non-mechanically ventilated patients free of ARDS, any active infection, diffuse interstitial pneumonia or immunosuppression; n = 7) undergoing a bronchoscopy with broncho-alveolar lavage (BAL) and blood sampling as part of routine care, were also included (Table S1) . Demographics and clinical and laboratory variables were prospectively collected upon ICU admission, at samples collection time points and during ICU stay. Initial severity was assessed using the SAPS II [21] and sequential organ failure assessment (SOFA) scores. BAL fluid was collected from all ARDS patients during a bronchoscopy within 48 h of ARDS onset. BAL fluid samples were also collected from control patients. Concomitant heparin anticoagulated blood samples were obtained in ARDS and control patients. Samples were stored at room temperature and analyzed within 2 h. BAL fluid cytology was performed by direct microscopy after centrifuging bronchoalveolar lavage fluid samples (12,000 revolutions for 10 min) and dying under the May-Grünwald-Giemsa staining. Total (quantified in cells/mL) and differential (i.e., percent of neutrophils, macrophages and lymphocytes) cell counts were measured as recommended [22] . Directly after collection, blood and BAL samples were added to an equal volume (100 µL/tube) to IMDM (Iscove's Modified Dulbecco's Media, Thermo Fisher Scientific, Waltham, MA, USA) with or without 200 ng/mL of Escherichia coli LPS (E. coli K12 LPS, Invivogen, San Diego, CA, USA), then incubated for 4 h at 37 • C and 5% CO 2 [23] . Samples drawn to measure the intracellular cytokine synthesis of TNF-α were incubated with a Golgi inhibitor (GolgiStop™ 2 µM, Becton Dickinson, San Jose, CA, USA) for 4 h at 37 • C and 5% CO 2 . After treatment with E. coli LPS (200 ng/mL) or medium alone, a fraction of blood and BAL fluid samples were incubated for 30 min with 20 µL of fluorescent E. coli particles (fluorescent pHrodo™ Green E. coli BioParticles, Thermo Fisher Scientific, Waltham, MA, USA), either at 37 • C and 5% CO 2 to evaluate the phagocytic activity of cells or at +4 • C to assess fluorescent background for bound but not internalized bacteria. Red cells were then lysed using pHrodo™ BioParticles ® Phagocytosis kit for flow cytometry (Thermo Fisher Scientific, Waltham, MA, USA), following the manufacturer's instructions. Phagocytosis was quantified on both alveolar and circulating monocytes using Fl1/FITC channel and expressed both in percent of positive cells and in delta MFI by retrieving basal MFI of unstained cells. Blood and BAL fluid surface immunostaining was performed as follows: 100 µL of whole blood or BAL fluid were incubated with the following conjugated-monoclonal antibodies: CD14-ECD/HLADR-PACBLUE/PDL1-BV785 and, for alveolar samples, CD45-AF700 and CD169-AF647 were added to identify alveolar monocytes [24] (BD Biosciences, San Jose, CA, USA; eBioscience, San Diego, CA, USA; or Beckman Coulter, Brea, CA, USA). After washing steps, cells were fixed with PBS 1% PFA and further acquired with a LSRII cytometer (BD Biosciences, San Jose, CA, USA) within 48 h. Flow cytometer analyses were performed with the FlowJo software (version 10; Tree Star, Ashland, OR, USA). HLA-DR and PD-L1 quantification was expressed in percentage of positive monocytes (% positive cells) among the total monocyte population or in delta MFI. Flow cytometry results were expressed both in percentage of positive cells and delta MFI. A difference Cells 2021, 10, 3546 4 of 16 might be observed between percentage of positive cells and MFI as these provide different information: percentage of positive cells reflects the number of monocytes expressing the biomarker of interest, while MFI is the geometric mean of the biomarker fluorescence on each monocyte. After treatment with E. coli LPS (200 ng/mL) or medium alone, blood and BAL fluid samples were immunophenotyped and further used to quantify intracellular TNF synthesis according to the regular PerFix-no centrifuge (nc) (Beckman Coulter, Brea, CA, USA) procedure. Cells were acquired with a LSRII cytometer (BD Biosciences, San Jose, CA, USA) within 48 h. Flow cytometer analyses were performed with the FlowJo software (version 10; Tree Star, Ashland, OR, USA). TNF quantification was expressed in percentage of positive monocytes (% positive cells) among the total monocyte population (positivity threshold was defined with non-stimulated values from the same donor) or in delta MFI. Different gating strategies were used in blood and BAL fluid samples. In BAL fluid samples, and as reported by Yu et al. ([24] , we first represented cells on an FSC forward-area (FSC-A) versus CD45 (the leukocyte common antigen) dot blot. The non-granulocyte FSC-A low CD45 + cells were further examined on a CD14 versus CD45 dot blot. The subsequent CD14 + CD45 + cells were then examined in an FSC-A versus CD169 dot blot to distinguish alveolar monocytes (FSC low CD14 + CD169 − ) from alveolar macrophages (FSC low CD14 + CD169 + ) ( Figure S1a ). HLA-DR positive (HLA-DR +) monocytes were defined as monocytes with an HLA-DR expression greater than the 99% confidence interval of negative control values ( Figure S1 ). The monocytes CD45 + , CD14 + , CD 169 − and HLA-DR negative were identified as the monocytes HLA-DR − population in contrast of monocytes CD45 + , CD14 + , CD169 − and HLA-DR + issued from the same alveolar sample. Circulating monocytes were defined as FSC-A low CD14 + cells ( Figure S1b ) in blood samples. Expression of HLA-DR, PD-L1 and TNF on alveolar and blood monocytes was then analyzed. Concentrations of 22 biomarkers were measured using Luminex ® multiplex beadbased technology (R&D Systems, Minneapolis, MN, USA) in BAL fluid supernatant and serum from 70 pneumonia-related ARDS from the PICARD cohort [6] . These included inflammatory markers and cytokines/chemokines (interleukin (IL)-1Ra, IL-6, IL-7, IL-8, IL-10, IL-12/23p40, IL-13, IL-17A, interferon (IFN)-γ, tumor necrosis factor (TNF)-α, granulocytemacrophage-colony stimulating factor (GM-CSF), RANTES, IP-10/CXCL10, and Serpin E1), endothelial injury (intercellular adhesion molecule-1 (ICAM-1), vascular endothelial growth factor (VEGF), von Willebrand Factor (vWF), and Angiopoietin (Ang)-1/2) and alveolar epithelium injury (receptor for advanced glycation end products (RAGE), surfactant protein (SP)-D, and amphiregulin). The results of quantification were expressed as fluorescence intensities. Continuous variables are reported as median (1st-3rd quartiles) and compared using the Mann-Whitney test. When more than two groups were compared, comparisons were performed using two-way ANOVA with repeated measures, and post-hoc comparisons were performed using the Sidak's test. Variables are expressed as numbers and percentages and compared with the Chi 2 or Fischer tests. Spearman correlation coefficients were computed for continuous-continuous variables correlations (Benjamini-Hochberg correction was performed to account for test multiplicity). A p value < 0.05 was considered significant. Statistical analyses were performed using GraphPad Prism (version 8.0, GraphPad Software, Inc., San Diego, CA, USA) and R 3.1.2 (The R Foundation for Statistical Computing, Vienna, Austria). One hundred eighty-eight patients with moderate-to-severe pneumonia-related ARDS were admitted to the ICU during the four-year study period, of whom one hundred eighteen had non-inclusion criteria and seventy were included in the PICARD study [6] . Functional tests were performed on alveolar and blood samples from a subgroup of ten patients with pneumonia-related ARDS and a control group of seven non-ARDS control patients ( Figure 1 ). These patients were included in this sub-study consecutively over a sixmonth period. Among patients with pneumonia-related ARDS (n = 10), a microbiological documentation was obtained in eight patients, seven of whom had bacterial infections and one of whom had a viral infection (none of the patients had a bacterial and viral coinfection) (Table S2) . One hundred eighty-eight patients with moderate-to-severe pneumonia-related ARDS were admitted to the ICU during the four-year study period, of whom one hundred eighteen had non-inclusion criteria and seventy were included in the PICARD study [6] . Functional tests were performed on alveolar and blood samples from a subgroup of ten patients with pneumonia-related ARDS and a control group of seven non-ARDS control patients ( Figure 1 ). These patients were included in this sub-study consecutively over a six-month period. Among patients with pneumonia-related ARDS (n = 10), a microbiological documentation was obtained in eight patients, seven of whom had bacterial infections and one of whom had a viral infection (none of the patients had a bacterial and viral coinfection) (Table S2 ). gure 1. Flow chart of patients with pneumonia-related moderate/severe acute respiratory distress syndrome (ARDS) cluded in the study. BAL: broncho-alveolar lavage; CRD: chronic respiratory disease; LTO: long term oxygenotherapy; TI: oro-tracheal intubation; WH/WD of LST: withholding/withdrawal of life-sustaining therapies; * Patients included in e PICARD study are comprehensively described elsewhere [6] . The comorbidities and clinical and biological characteristics of patients at the time the BAL was sampled (i.e., after a median delay of one day following intubation) are presented in Table 1 . The comorbidities and clinical and biological characteristics of patients at the time the BAL was sampled (i.e., after a median delay of one day following intubation) are presented in Table 1 . Septic shock was present in 60% of patients (n = 6/10) at the time of BAL fluid sampling, and in-hospital mortality was 30% (n = 3/10, Table 2 ). As expected in pneumoniarelated ARDS, BAL fluid cellularity was elevated, as compared to non-ARDS controls (median (IQR 25-75): 567 (365-720) vs. 130 × 10 3 /mL (77-137) G/L; p = 0.0001) and differential cell counts showed a majority of neutrophils (80.5 (8.8-85.5) vs. 1.0% (0.7-1.0); p = 0.0001) and fewer macrophages (median 15.5 (8.8-85.5) vs. 66.0% (66.0-85.5); p = 0.001), consistent with alveolar inflammation (Table 1) . We quantified the monocytic expression of HLA-DR, a prognostic cell surface biomarker in septic shock patients [17] , on alveolar and circulating monocytes. As previously shown [6] , within 48 h of tracheal intubation, and as compared with non-ARDS controls, patients with pneumonia-related ARDS exhibited significantly lower HLA-DR expression both on circulating (p < 0.0001; Figure 2a Patients with pneumonia-related ARDS also displayed dramatically higher HLA-DR expression (p < 0.0001; Figure 2a ,b) on alveolar than on blood monocytes. In non-ARDS patients, we also observed a higher HLA-DR expression on alveolar than on blood monocytes (when expressed in MFI, p < 0.0001, Figure 2b ), indicating that the alveolar compartmentalization of monocytic HLA-DR expression is not specific to severe lung infections. In order to further explore the relationship between the HLA-DR expression of alveolar monocytes and the alveolar milieu, we quantified the alveolar concentration of 22 biomarkers and correlated it with monocytic HLA-DR level in a larger cohort of 70 ARDS patients from the PICARD study. We also included in the correlation matrix the clinical parameters of patients. HLA-DR on alveolar monocytes correlated negatively with two clusters: one cluster comprised BAL fluid cellularity and SOFA score, as a reflection of global lung inflammation and organ failures, while the second cluster included cytokines involved in the activation of innate immunity (RANTES, IL-6, IL-1Ra, TNF-α) as well as markers of alveolar epithelial (Amphiregulin, serpin) and endothelial (Ang2) injury ( Figure 3 ). biomarkers and correlated it with monocytic HLA-DR level in a larger cohort of 70 ARDS patients from the PICARD study. We also included in the correlation matrix the clinical parameters of patients. HLA-DR on alveolar monocytes correlated negatively with two clusters: one cluster comprised BAL fluid cellularity and SOFA score, as a reflection of global lung inflammation and organ failures, while the second cluster included cytokines involved in the activation of innate immunity (RANTES, IL-6, IL-1Ra, TNF-α) as well as markers of alveolar epithelial (Amphiregulin, serpin) and endothelial (Ang2) injury (Figure 3 ). The red circle delimits statistical significance (at the 5% level). The diagram also shows relationships among covariates. Their relative position is informative as follows: two covariates close to one another indicate a strong positive correlation between them; two diametrically opposed covariates indicate a strong negative correlation between them; two covariates making a right angle with the origin indicate absence of correlation between them. As another marker of monocyte dysfunction [25, 26] , we measured the expression of checkpoint inhibitor and marker of immune suppression, PD-L1, on alveolar and circulating monocytes. PD-L1 expression on monocytes obtained from pneumonia-related ARDS patients was not significantly different from that measured on monocytes of their non-ARDS counterparts (Figure 4a,b) . Notably, there was a higher PD-L1 expression on alveolar than on blood monocytes for both pneumonia-related ARDS and non-ARDS control patients (when expressed in MFI, Figure 4b) , reflecting an alveolar compartmentalization of monocytic PD-L1 expression. lating monocytes. PD-L1 expression on monocytes obtained from pneumonia-related ARDS patients was not significantly different from that measured on monocytes of their non-ARDS counterparts (Figure 4a,b) . Notably, there was a higher PD-L1 expression on alveolar than on blood monocytes for both pneumonia-related ARDS and non-ARDS control patients (when expressed in MFI, Figure 4b) , reflecting an alveolar compartmentalization of monocytic PD-L1 expression. Phagocytosis activity of alveolar and circulating monocytes after LPS pretreatment. The phagocytosis activity of alveolar and blood monocytes was measured before ( Figure 5a ) and after (Figure 5b ) LPS challenge in ten patients with pneumonia-related ARDS and seven non-ARDS controls. There was no statistically significant difference observed between patient groups (ARDS vs. non-ARDS) regarding both alveolar and blood monocytes phagocytosis activity. Yet, as compared to circulating monocytes, alveolar monocytes from ARDS patients exhibited a decreased phagocytosis activity both before (Figure 5c , MFI, p = 0.0002) and after (MFI, p = 0.0013) LPS challenge (Figure 5d ). • Phagocytosis activity of alveolar and circulating monocytes after LPS pretreatment. The phagocytosis activity of alveolar and blood monocytes was measured before ( Figure 5a ) and after (Figure 5b ) LPS challenge in ten patients with pneumonia-related ARDS and seven non-ARDS controls. There was no statistically significant difference observed between patient groups (ARDS vs. non-ARDS) regarding both alveolar and blood monocytes phagocytosis activity. Yet, as compared to circulating monocytes, alveolar monocytes from ARDS patients exhibited a decreased phagocytosis activity both before (  Intracellular TNF quantification in alveolar and circulating monocytes after LPS st ulation. One of the hallmark features of monocyte deactivation is the impaired capacit TNF production in response to LPS stimulation. We thus assessed the intracellular T production of both circulating and alveolar monocytes obtained from pneumonia-rela ARDS patients and non-ARDS patients. As expected, LPS challenge ex vivo significa increased the intracellular TNF synthesis ( Figure 6 ). Such effect was statistically sign cant in circulating ( Figure 6a ) and alveolar (Figure 6b ) monocytes of non-ARDS patie but not in those of ARDS patients. When considering intracellular TNF expression after LPS stimulation, alveolar m ocytes from pneumonia-related ARDS patients had a significantly lower intracellular T expression than non-ARDS patients (Figure 6b,d) . Likewise, blood monocytes from AR patients showed significantly lower intracellular TNF concentration after LPS challe than did those from non-ARDS patients (Figure 6c, p = 0.005 ). In addition, alveolar mo cytes from pneumonia-related ARDS had a significantly lower LPS-induced TNF exp sion than circulating monocytes issued from the same patients when expressed in perc of positive cells (p = 0.011). • Intracellular TNF quantification in alveolar and circulating monocytes after LPS stimulation. One of the hallmark features of monocyte deactivation is the impaired capacity of TNF production in response to LPS stimulation. We thus assessed the intracellular TNF production of both circulating and alveolar monocytes obtained from pneumonia-related ARDS patients and non-ARDS patients. As expected, LPS challenge ex vivo significantly increased the intracellular TNF synthesis ( Figure 6 ). Such effect was statistically significant in circulating ( Figure 6a ) and alveolar (Figure 6b ) monocytes of non-ARDS patients but not in those of ARDS patients. Cells 2021, 10, x 11 Our finding of a reduced responsiveness to an LPS challenge, illustrated by an paired capacity of alveolar and blood monocytes from ARDS patients to increase TNF synthesis capacity, is consistent with an endotoxin tolerant profile. Phagocytosis activity and TNF production of alveolar monocytes according to HLA-DR expression. Finally, we assessed whether the function of monocytes and their level of HLA expression was linked. We thus quantified alveolar monocytes phagocytosis cap ( Figure S2 ) and LPS-induced intracellular TNF concentrations ( Figure S3 , result pressed in percentage of positive cells and MFI) according to their HLA-DRvs. HLA phenotype and did not observe any statistical difference between these two phenoty The current study assessed the phenotype and function of alveolar and circul monocytes obtained from patients with pneumonia-related ARDS. The main results o current study are as follows: (1) Alveolar monocytes from ARDS patients showed creased HLA-DR expression, as compared with blood monocytes, and a significant c lation with cytokines involved in the activation of innate immunity, as well as with m When considering intracellular TNF expression after LPS stimulation, alveolar monocytes from pneumonia-related ARDS patients had a significantly lower intracellular TNF expression than non-ARDS patients (Figure 6b,d) . Likewise, blood monocytes from ARDS patients showed significantly lower intracellular TNF concentration after LPS challenge than did those from non-ARDS patients (Figure 6c , p = 0.005). In addition, alveolar monocytes from pneumonia-related ARDS had a significantly lower LPS-induced TNF expression than circulating monocytes issued from the same patients when expressed in percent of positive cells (p = 0.011). Our finding of a reduced responsiveness to an LPS challenge, illustrated by an impaired capacity of alveolar and blood monocytes from ARDS patients to increase their TNF synthesis capacity, is consistent with an endotoxin tolerant profile. Phagocytosis activity and TNF production of alveolar monocytes according to their HLA-DR expression. Finally, we assessed whether the function of monocytes and their level of HLA-DR expression was linked. We thus quantified alveolar monocytes phagocytosis capacity ( Figure S2 ) and LPS-induced intracellular TNF concentrations ( Figure S3 , results expressed in percentage of positive cells and MFI) according to their HLA-DR − vs. HLA-DR + phenotype and did not observe any statistical difference between these two phenotypes. The current study assessed the phenotype and function of alveolar and circulating monocytes obtained from patients with pneumonia-related ARDS. The main results of the current study are as follows: (1) Alveolar monocytes from ARDS patients showed a decreased HLA-DR expression, as compared with blood monocytes, and a significant correlation with cytokines involved in the activation of innate immunity, as well as with markers of alveolar epithelial/endothelial injury; alveolar monocytes of ARDS patients, together with those of controls, showed higher PD-L1 expression than those of blood monocytes; (2) The phagocytosis activity and intracellular production of TNF after ex vivo LPS stimulation of alveolar monocytes were decreased in ARDS patients; and (3) Alveolar monocytes phagocytosis capacity and LPS-induced intracellular TNF concentrations did not differ according to their HLA-DR − vs. HLA-DR + phenotype. These findings are consistent with the existence of functional immune alterations in the alveolar compartment of critically ill patients having severe pulmonary infections and ARDS. Monocytes have a pivotal role in antigen-presentation, together with pathogen clearance and induction and regulation of inflammation. The sequential measurement of HLA-DR expression on circulating monocytes has gained considerable interest over the past several decades in identifying altered immune status among severe ICU patients [27] . However, alveolar monocytes have been poorly investigated, although these represent the first immune lines during pulmonary infections. In the current study, we observed an alveolar compartmentalization of HLA-DR expression in ARDS patients, confirming our previous results [6] and illustrating our cohort is well representative of patients with pneumonia-associated ARDS regarding monocytic HLA-DR expression. Such an expression pattern might not be a consequence of the local activation of monocytes at the site of the primary infection but rather a global effect of inflammation as already reported by Skirecki et al. [28] . Yet, HLA-DR expression on alveolar monocytes obtained from patients with pneumonia-related ARDS was lower than that from non-ARDS patients, consistent with the recruitment of deactivated monocytes in the infected lungs. However, we previously showed that the level of alveolar monocytic HLA-DR expression was not a prognosis biomarker in ARDS patients with severe pneumonia, suggesting that, in the context of severe pulmonary infection, the function of alveolar monocytes might be more informative than their phenotype regarding outcome prediction. Monocyte PD-L1 overexpression was associated with defects in immune function [29] and independently associated with 28-day mortality in septic shock patients [30] . Genomewide expression measurements revealed that the expression of PD-L1 and PD-L1/PD-1 pathway-associated genes were significantly upregulated in patients with ARDS who survived or were extubated within 28 days compared to non-survivors or intubated patients [31] . In contrast, blockade of the PD-1 pathway induced ARDS-like pneumonitis in patients during anti-PD-1/PD-L1 therapy [32] . More recently, Monagham et al. reported soluble PD-1 as a potential biomarker in human and experimental extra-pulmonary ARDS [33] . These results suggest that the PD-1/PD-L1 axis is involved in the development of ARDS [3] . In our study, we observed a higher PD-L1 expression on alveolar than on blood monocytes in ARDS and non-ARDS patients, with possible downstream inhibitory effects on T-cell activation. Previous works showed that such a pattern could predispose the host to a dangerous situation upon lung infection [34] . This surface biomarker might be used as a therapeutic target in this setting. Indeed, anti-PD-L1 antibodies have shown benefits in animal models of sepsis and are currently being tested in clinical trials in sepsis [35, 36] . Yet, our data show no significant difference in alveolar monocyte expression levels between ARDS patients and controls, suggesting further studies are required to better delineate the involvement of the PD-1/PD-L1 axis in the alveolar compartment at the acute phase of ARDS. The primary aim of this study was to evaluate alveolar monocyte functions in patients with severe pneumonia and ARDS by exploring their phagocytosis capacity and intracellular TNF production after LPS exposure, together with their relationship with HLA-DR expression. The phagocytic capacity of monocytes was not different in ARDS patients than in controls, contrasting with the downregulation of HLA-DR expression on both alveolar and circulating monocytes, reflecting a defect in their antigen-presenting capacity. This finding was already reported in circulating monocytes from septic patients [37] . Such monocyte pattern resembles that described in alveolar monocytes from cystic fibrosis patients under the effects of pro-resolving mediators, which present enhanced phagocytic activity without evoking proinflammatory responses [15, 38] . In ARDS patients, no difference was observed between alveolar and circulating monocytes when the phagocytosis capacity was quantified in percentage of positive cells. In contrast, using MFI, we observed a lower E. coli-associated fluorescent signal in alveolar monocytes, which persisted after ex vivo LPS stimulation. It has been previously shown that functional, endotoxin-tolerant monocytes exhibit an increased phagocytic ability coupled with a conserved capacity to kill internalized pathogens, albeit with an impaired antigen-presentation capacity [15, 38, 39] . Our data suggest that in pneumonia-related ARDS patients, the phagocytosis of alveolar monocytes seems to be less efficient than that of circulating monocytes but as efficient as that of non-ARDS controls. In the present work, we took advantage of recent intracellular staining flow cytometry methods to detect intracellular TNF production [13] in alveolar and circulating monocytes. As expected, alveolar and circulating monocytes from pneumonia-related ARDS patients were hypo-responsive to ex vivo LPS stimulation. Regarding monocytes, many studies have previously reported the altered capacity of circulating monocytes of septic patients to release proinflammatory cytokines in response to LPS stimulation, TLR agonists, or whole bacteria in vitro [15, 40, 41] . Fumeaux et al. observed that septic circulating monocytes were characterized by an altered IL-10/TNF intracellular ratio [42] . Accordingly, transcriptomic assays in LPS-challenged peripheral blood mononuclear cells from patients facing gramnegative infections retrieved endotoxin tolerance while enhanced anti-microbial activity and tissue repair [43] . Alveolar monocytes from pneumonia-related ARDS patients exhibited a characteristic behavior of cytokine hypo-responsiveness while exhibiting preserved uptake functions, consistent with a "reprogrammed" rather than an "exhausted" phenotype. This modulation represents a state in which the host attempts to control the initial systemic inflammatory response while maintaining control over the infection. This modulation may represent the return to homeostasis in cases of successful antimicrobial therapy and recovery of underlying disease. In contrast, failure to mount a robust inflammatory response may represent a state of immunosuppression in protracted patients. Furthermore, we observed a negative correlation between HLA-DR expression on alveolar monocytes and the alveolar concentrations of cytokines involved in innate immunity (i.e., IL-6, RANTES, IL-1Ra, and TNF), suggesting that a proinflammatory microenvironment is associated with alveolar monocyte deactivation. As expected, the SOFA score was negatively correlated with HLA-DR expression on alveolar monocytes, illustrating that the number of organ failures was associated with monocyte deactivation in the lungs, as previously shown in circulating monocytes of septic shock patients [16] . Our study certainly has a number of limitations. This is a monocentric study including a homogeneous population of patients with pneumonia-related ARDS, thus limiting its external validity and the generalizability of the findings. The relatively small number of patients included precluded validating our results in an independent validation cohort, and our findings should thus be reconfirmed in a larger population. We included a limited population of non-ARDS controls free of infection and who were younger than patients from the ARDS group (63 vs. 40 years). On one hand, we cannot exclude that these patients might have mild systemic and/or lung inflammation, as these were patients undergoing a bronchoscopy as part of routine care. On the other hand, HLA-DR expression was previously shown to be reduced in elderly patients, possibly contributing to immunosenescence [44] . Therefore, age could have influenced the observed difference in HLA-DR expression between ARDS and non-ARDS patients. In addition, including COVID-19 patients would have been of great interest but was not feasible because of technical and logistical constraints. Therefore, while the results of this study do not point to a definitive association between monocyte phenotype (HLA-DR and PD-L1 expression) and its function, as a hypothesis-generating study, they do provide sufficient evidence to warrant additional research in this area. As there is no clinical sign of immune dysfunction, it is crucial to identify the best biological tools for patients' stratification according to their immune status. Since it directly measures the ex vivo capacity of a cell population to respond to an immune challenge, functional testing ideally represents the best method to establish the occurrence of immunosuppression. The current results indicate that the examination of the functional capacities of alveolar monocytes might provide new insights into the pathophysiology of severe lung infections and associated ARDS. In conclusion, in patients with pneumonia-related ARDS, this study showed that monocytes have a deactivated status and an impaired inflammatory cytokine production capacity but keep similar phagocytic activity to non-ARDS controls. HLA-DR expression level on alveolar monocytes should not be used as a surrogate marker of phagocytic activity or TNF production capacity. Dedicated tests exploring these key roles of monocytes' functions during severe lung infections might be interesting to better explore the pathophysiology of the disease and identify new prognostic biomarkers. Acute Respiratory Distress Syndrome: The Berlin Definition Thorsteinsson, A.; et al. Epidemiology and Outcome of Acute Lung Injury in European Intensive Care Units. Results from the ALIVE Study Subphenotypes in Acute Respiratory Distress Syndrome: Latent Class Analysis of Data from Two Randomised Controlled Trials Acute Respiratory Distress Syndrome Subphenotypes Respond Differently to Randomized Fluid Management Strategy A Systematic Review of Biomarkers Multivariately Associated with Acute Respiratory Distress Syndrome Development and Mortality Alveolar Compartmentalization of Inflammatory and Immune Cell Biomarkers in Pneumonia-Related ARDS Monitoring the Immune Response in Sepsis: A Rational Approach to Administration of Immunoadjuvant Therapies Changes of Monocyte Human Leukocyte Antigen-DR Expression as a Reliable Predictor of Mortality in Severe Sepsis Serial Increase of IL-12 Response and Human Leukocyte Antigen-DR Expression in Severe Sepsis Survivors Predictive Value of Soluble Programmed Death-1 for Severe Sepsis and Septic Shock During the First Week in an Intensive Care Unit A Dynamic View of MHLA-DR Expression in Management of Severe Septic Patients Immunosuppression in Sepsis: A Novel Understanding of the Disorder and a New Therapeutic Approach Novel Approach in Monocyte Intracellular TNF Measurement: Application to Sepsis-Induced Immune Alterations Impaired Antigen Presentation by Human Monocytes during Endotoxin Tolerance New Mechanisms, Molecules and Clinical Significance Low Monocyte Human Leukocyte Antigen-DR Is Independently Associated with Nosocomial Infections after Septic Shock Persisting Low Monocyte Human Leukocyte Antigen-DR Expression Predicts Mortality in Septic Shock Decreased HLA-DR Antigen-Associated Invariant Chain (CD74) MRNA Expression Predicts Mortality after Septic Shock Sepsis-Induced Immunosuppression: From Cellular Dysfunctions to Immunotherapy Advances in the Understanding and Treatment of Sepsis-Induced Immunosuppression A New Simplified Acute Physiology Score (SAPS II) Based on a European/North American Multicenter Study An Official American Thoracic Society Clinical Practice Guideline: The Clinical Utility of Bronchoalveolar Lavage Cellular Analysis in Interstitial Lung Disease Altered T Lymphocyte Proliferation upon Lipopolysaccharide Challenge Ex Vivo Flow Cytometric Analysis of Myeloid Cells in Human Blood, Bronchoalveolar Lavage, and Lung Tissues PD-L1 Blockade Improves Survival in Experimental Sepsis by Inhibiting Lymphocyte Apoptosis and Reversing Monocyte Dysfunction Immunotherapy: A Promising Approach to Reverse Sepsis-Induced Immunosuppression Clinical Review: Flow Cytometry Perspectives in the ICU-from Diagnosis of Infection to Monitoring of Injury-Induced Immune Dysfunctions The Early Expression of HLA-DR and CD64 Myeloid Markers Is Specifically Compartmentalized in the Blood and Lungs of Patients with Septic Shock Frontline Science: Defects in Immune Function in Patients with Sepsis Are Associated with PD-1 or PD-L1 Expression and Can Be Restored by Antibodies Targeting PD-1 or PD-L1 Monocyte Programmed Death Ligand-1 Expression after 3?4 Days of Sepsis Is Associated with Risk Stratification and Mortality in Septic Patients: A Prospective Cohort Study Cytometry TOF Identifies Alveolar Macrophage Subtypes in Acute Respiratory Distress Syndrome Therapeutic Effect of an Anti-Human Programmed Death-Ligand 1 (PD-L1) Nanobody on Polymicrobial Sepsis in Humanized Mice Soluble Programmed Cell Death Receptor-1 (SPD-1): A Potential Biomarker with Anti-Inflammatory Properties in Human and Experimental Acute Respiratory Distress Syndrome (ARDS) Association between Elevation of Plasma Biomarkers and Monocyte Dysfunction and Their Combination in Predicting Sepsis: An Observational Single-Centre Cohort Study Nivolumab plus Interferon-γ in the Treatment of Intractable Mucormycosis Immune Checkpoint Inhibition in Sepsis: A Phase 1b Randomized Study to Evaluate the Safety, Tolerability, Pharmacokinetics, and Pharmacodynamics of Nivolumab Modulation of Monocytes in Septic Patients: Preserved Phagocytic Activity, Increased ROS and NO Generation, and Decreased Production of Inflammatory Cytokines Potent Phagocytic Activity with Impaired Antigen Presentation Identifying Lipopolysaccharide-Tolerant Human Monocytes: Demonstration in Isolated Monocytes from Cystic Fibrosis Patients The Anti-Inflammatory Response Dominates after Septic Shock: Association of Low Monocyte HLA-DR Expression and High Interleukin-10 Concentration Bench-to-Bedside Review: Endotoxin Tolerance as a Model of Leukocyte Reprogramming in Sepsis Monitoring Immune Dysfunctions in the Septic Patient: A New Skin for the Old Ceremony Role of Interleukin-10 in the Intracellular Sequestration of Human Leukocyte Antigen-DR in Monocytes during Septic Shock Human Monocytes Undergo Functional Re-Programming during Sepsis Mediated by Hypoxia-Inducible Factor-1α Age-Dependent Alterations of Monocyte Subsets and Monocyte-Related Chemokine Pathways in Healthy Adults The authors wish to thank the patients and their families, the nurses of the medical ICU of Henri Mondor Hospital for their assistance in sampling patients, Aline Alves for her help in processing BAL fluid samples, and Jeanne Tran Van Nhieu, for performing BAL fluid cytological analyses. The authors declare no conflict of interest. The following are available online at https://www.mdpi.com/article/ 10.3390/cells10123546/s1, Figure S1 : Gating strategy of flow cytometric analyses of monocytes in broncho-alveolar lavage fluid (a,b) and blood (c,d), Figure S2 : Phagocytosis of E. coli particles by alveolar monocytes according to their HLA-DR expression measured by flow cytometry, Figure S3 : Alveolar monocytes intracel-lular TNF expression according to HLA-DR expression measured by flow cytometry, Table S1 : Characteristics of non-ARDS patients (n = 7) included in the study, Table S2 : Microbiological documentation of patients (n = 10) with pneumonia-related ARDS. Written informed consent has been obtained from the patients or their relatives to publish this paper. Contact the corresponding author for direct access to the dataset pertaining to data presented in this article.