Dectin-1-Mediated Production of Pro-Inflammatory Cytokines Induced by Yeast β-Glucans in Bovine Monocytes

Yeast-derived products containing β-glucans have long been used as feed supplements in domesticated animals in an attempt to increase immunity. β-glucans are mainly recognized by the cell surface receptor CLEC7A, also designated Dectin-1. Although the immune mechanisms elicited through Dectin-1 activation have been studied in detail in mice and humans, they are poorly understood in other species. Here, we evaluated the response of bovine monocytes to soluble and particulate purified β-glucans, and also to Zymosan. Our results show that particulate, but not soluble β-glucans, can upregulate the surface expression of costimulatory molecules CD80 and CD86 on bovine monocytes. In addition, stimulated cells increased production of IL-8 and of TNF, IL1B, and IL6 mRNA expression, in a dose-dependent manner, which correlated positively with CLEC7A gene expression. Production of IL-8 and TNF expression decreased significantly after CLEC7A knockdown using two different pairs of siRNAs. Overall, we demonstrated here that bovine monocytes respond to particulate β-glucans, through Dectin-1, by increasing the expression of pro-inflammatory cytokines. Our data support further studies in cattle on the induction of trained immunity using dietary β-glucans.


INTRODUCTION
Immune modulation by natural compounds has long been studied in domesticated animals such as poultry, fish, and livestock, to enhance immunity and improve animal welfare and wellbeing, ultimately reducing the incidence of disease and the overuse of pharmaceutical compounds, such as antibiotics. Dietary supplementation with yeasts (1-6) and yeast-derived compounds, such as mannan-oligosaccharides (MOS) and bglucans (1,(4)(5)(6)(7), is one of the most used strategies to enhance immunity in domesticated animals. b-glucans are naturally occurring polymers present in the cell wall of fungi, bacteria, algae, and plants. Yeast b-glucans are usually composed of linear molecules of D-glucose units linked by b-1,3 glycosidic bonds with b-1,6 branching (8,9). b-glucans are recognized by immune cell surface pattern recognition receptors (PRR) such as C-type lectin domain family 7 member A (CLEC7A), also designated as Dectin-1, complement receptor-3 (CR3), scavenger receptors, and lactosylceramide (10). In addition, Toll-like receptor (TLR)-2 and TLR-6 can synergistically contribute to the recognition and elicited biological effects of particulate b-glucans, such as Zymosan (11)(12)(13)(14). Biological activities of b-glucans depend on their recognition and downstream cell signalling, which in turn depend largely on the structure, conformation, and physical properties of the different b-glucans (9,15). Although both particulate and soluble b-glucans bind Dectin-1, only the particulate form can induce Dectin-1 signalling and generate a "phagocytic synapse" (16). Activation of Dectin-1 triggers an intracellular signalling cascade eliciting phagocytosis, production of cytokines, and reactive-oxygen species (ROS) (14)(15)(16)(17)(18)(19).
The immune recognition of b-glucans and elicited response has been extensively studied in mice and humans at mechanistic level (15,20,21). However, in other species, including cattle, the effects of b-glucans on the immune system are mainly supported by observational reports and in vivo studies (22)(23)(24)(25). A homologous transcript for human Dectin-1 has been described in bovines (boDectin-1) (26). However, b-glucan recognition and its effects on bovine leukocytes were not fully elucidated.
Bovine monocytes express CLEC7A (26) and this cell type is the most used in innate immune memory studies in other species (27,28). Here, the response of bovine monocytes to soluble and particulate b-glucans, and to b-glucan-containing particles (Zymosan) was assessed. Our results show that only the particulate b-glucan forms trigger the production of proinflammatory cytokines, and implicate boDectin-1 in this effect.

Cell Culture and Stimulation With b-Glucans
Bovine CD14 + monocytes were plated at 2 × 10 5 cells/well in flatbottom 96-well culture plates. Stimulation was done with a pure soluble b-glucan preparation (WGP ® -Soluble), a purified insoluble preparation of Saccharomyces cerevisiae lacking TLR activity, composed mainly of b-1,3-glucans (WGP ® -Dispersible), and an insoluble preparation of S. cerevisiae cell wall (Zymosan), described to have Dectin-1-and TLR2/6-stimulatory activity (all from InvivoGen, San Diego, CA, USA). b-glucans, labelled endotoxin-free (endotoxin level below 0.001 EU/mg), were prepared according to manufacturer's instructions. All assays were performed using sterile, pyrogen-free material. Cells were cultured with 10, 50 and 100 µg/mL of WGP-Soluble, WGP-Dispersible or Zymosan. Cells cultured with 1 µg/mL of Escherichia coli lipopolysaccharide (LPS, strain O111:B4; Sigma-Aldrich) or Pam3CSK4 (P3C; InvivoGen) were used as positive controls. A kinetic cytokine mRNA expression analysis was performed in cells cultured for 8, 16, and 24 h at 37°C and 5% CO 2 to define the time point for sequent analyses. Cytokine production, mRNA expression, and lactate dehydrogenase (LDH) release, were assessed in cells cultured for 24 h at 37°C and 5% CO 2 . Cell surface activation markers were assessed by flow cytometry in 8 and 16 h bovine monocyte cultures. Nonstimulated cells were always used as negative controls.

Cell Viability Assays
LDH release was quantified in cell culture supernatants using CyQUANT ™ LDH Cytotoxicity Assay kit, according to manufacturer's instructions (Invitrogen, Waltham, MA, USA).

Cytokine Production
Cytokine levels were assessed in cell culture supernatants by sandwich ELISA. Assessment of bovine Tumor Necrosis Factor Alpha (TNF-a) and bovine Interleukin (IL)-6 was done using Bovine TNF-alpha and Bovine IL-6 DuoSet ELISA kits (R&D Systems, Minneapolis, MN, USA) according to the manufacturer's protocol with a minor modification: 1% molecular grade bovine serum albumin (BSA, Albumine Bovine Fraction V, NZYTech, Lisbon, Portugal) in DPBS was used as reagent diluent, instead of 5% Tween 20 in DPBS. Bovine IL-8 (Bovine IL-8 [CXCL8] ELISA development kit, Mabtech AB, Nacka Strand, Sweden) was quantified according to manufacturer's instructions. Detection limits: 8 pg/mL for IL-8 and 125 pg/mL for TNF-a and IL-6. Bovine IL-1b was quantified using the IL-1 beta Bovine Uncoated ELISA Kit (Invitrogen), according to manufacturer's instructions. Detection limit <31.3 pg/mL. Bovine IL-10 was assessed in cell culture supernatants using an in-house ELISA kit, following the standard procedure of Mabtech ELISA Bovine IL-8 kit. Briefly, Nunc Maxisorp ™ plates were coated with 1 µg/mL anti-bovine IL-10 mAb (clone CC318; Bio-Rad) in PBS and incubated overnight at 4°C. A nine-point standard curve from 2000 to 8 pg/mL was done using Recombinant Bovine Interleukin-10 (Bio-Rad). Cell supernatants and standards were incubated at room temperature for 2 h, followed by incubation for 1 h with the detection antibody at 0.5 µg/mL (mouse anti-Bovine Interleukin-10:Biotin; clone CC320; Bio-Rad) and 1 h with Mabtech's streptavidin-HRP, according to manufacturer's instructions. Detection limit: 8 pg/mL. Only samples above detection limits were used for comparison.

RNA Extraction and cDNA Synthesis
Total RNA was obtained using NZYol according to manufacturer's protocol, with minor modifications. Bovine monocytes were lysed with 200 µL NZYol and incubated with 0.1 µg/mL RNA-grade Glycogen (Thermo Fisher Scientific). Each sample was incubated with 80 µL chloroform for phase separation and 200 µL isopropanol was added for RNA precipitation. The precipitated RNA was washed with 70% ethanol and resuspended in 5 µL RNase-free water. Synthesis of first-strand cDNA was done in an Applied Biosystems ® 2720 Thermal Cycler (Thermo Fisher Scientific) at 25°C for 10 min, 50°C for 30 min, and 85°C for 5 min using NZY First-Strand cDNA Synthesis Kit, according to manufacturer's instructions (NZYtech). Samples were kept at -20°C. Negative controls using RNA samples for cDNA synthesis without reverse transcriptase (no RT control), and with no added template (no template control) were also included for all primer pairs.

Real-Time qPCR
Primers for b2 microglobulin (B2M), CLEC7A, IL1B, and IL6 were designed using Primer-BLAST web tool developed by NCBI (30). Primers for TNF and IL10 were previously designed (31,32). Sequences of each primer and expected amplicon sizes are detailed in Table 1. Primers targeting CLEC7A were designed to both short and long isoforms. Determination of TNF, IL1B, IL6, IL10 and CLEC7A mRNA levels was performed in a CFX96 ™ Real-Time PCR Detection System (Bio-Rad), using NZYSpeedy qPCR Green Master Mix (2×) ROX plus (NZYTech). B2M and MARVEL domain containing 1 (MARVELD1), already used as reference genes in bovine gene expression studies, were used for mRNA normalization (33)(34)(35). Reaction was performed in low profile, non-skirted, 96-well PCR plates (Thermo Fisher Scientific) containing 5 µL Master Mix, 1 µL cDNA, 3.6 µL H2O and 0.2 mM of specific forward and reverse primers (all from Sigma-Aldrich). PCR program was as follows: denaturation for 5 min at 95°C followed by 40 cycles at 95°C for 5 s and 62°C for 20 s for amplification. Gene expression values were analyzed by the comparative threshold cycle method using the formula 2 -(CT gene of interest -CT housekeeping gene) (36). CLEC7A PCR products were run in 1.5% (w/v) Tris-acetate-EDTA (TAE) agarose gel electrophoresis to confirm amplicon size. Bands were visualized in a Syngene ™ NuGenius Gel Documentation System, excised from the gel and purified using NZYGelpure columns (NZYTech) following manufacturer's instructions. PCR products and DNA purified from excised gel bands were Sanger sequenced to confirm primer specificity.

Flow Cytometry
Since the commercially existing labelled antibodies for the bovine species are available in limited fluorophore diversity, we conjugated mouse monoclonal anti-bovine MHC class II DR (clone CC108, Bio-Rad) antibody with peridinin-chlorophyll protein-cychrome 5.5 (PerCP-Cy5.5) with LYNX Rapid PerCP-Cy5.5 Antibody Conjugation Kit (Bio-Rad), according to manufacturers' instructions, and used it at 1:200 to allow multiparametric simultaneous analysis with the monoclonal antibodies mouse anti-bovine CD80 conjugated with R-Phycoerythrin (RPE) (clone IL-A159, Bio-Rad) and mouse antibovine CD86 conjugated with Fluorescein isothiocyanate (FITC) (clone IL-A190, Bio-Rad), both used at 1:50. All the antibodies were previously titrated to determine the optimal concentration for bovine monocyte staining. A fixable viability dye (FVD) was included before surface antibody staining to exclude dead cells from the analysis. For that, cells were incubated with eFluor ® 506 Fixable Viability Dye (eBioscience, San Diego, CA, USA) diluted at 1:1000 in DPBS for 15 min at 4°C. After washing cells with DPBS, cells were incubated in 2% mouse serum in FACS Buffer (1% BSA in DPBS) for 15 min at 4°C in the dark before antibody staining to minimize nonspecific binding. A mix containing all antibodies was added to samples that were incubated for 25 min at 4°C in the dark. Cells were washed with FACS Buffer and analyzed by flow cytometry. Single stainings using UltraComp beads (eBioscience) or/and cells were used for compensation. Fluorescence minus one controls (FMO) of each antibody and FVD were used for gating purposes. Data were acquired in a BD CantoII ™ equipment (BD Biosciences) and analyzed with FlowJo version 10.6.2. (FlowJo LLC, Ashland, OR, USA).
Imaging of Dectin-1 on the surface of bovine monocytes and HEK-Blue ™ hDectin-1b cells was done in cells stained as before. Nuclei were stained with DAPI and samples were plated in 8 well microscopy chamber plates (Ibidi, Gräfelfing, Germany) and observed in a laser scanning confocal microscope Leica TCS SP5 II system (Leica DMI6000-CS microscope with LAS AF Software, Leica Microsystems, Wetzlar, Germany). Images were obtained with a HC PL APO CS 40x/1.10 CORR Water objective. Cells were observed using 405 nm and 488 nm lasers, in the xy plane.

Statistical Analysis
Log transformations were applied to cytotoxicity, cytokine production, mRNA expression, siRNA assays, and flow cytometry data following a lognormal distribution. All data were analyzed using the MIXED Procedure of the SAS

Bovine Monocyte Stimulation
Viability assays were performed to assure none of the stimuli were cytotoxic to bovine monocytes at the working concentrations. None of the b-glucan sources, LPS, or P3C induced statistically significant cell death when compared to unstimulated cells (Supplementary Figure 2). The production/expression of the pro-inflammatory cytokines IL-1b, IL-6, IL-8, and TNF-a, and of the anti-inflammatory cytokine IL-10 by bovine monocytes was evaluated after stimulation with different b-glucans, LPS or P3C. These cytokines are the most commonly assessed in b-glucanstimulated cell studies (16,28,37,38). Cells were stimulated for 8, 16, and 24 h to evaluate the kinetics of cytokine expression (Supplementary Figure 3). The 24 h time point was selected for further studies since it allows simultaneous cytokine protein and mRNA analysis. Cytokine production and mRNA expression were affected by treatment (P<0.0001 for IL-8, IL-6, TNF-a levels, and IL1B, IL6 and TNF mRNA expression; P=0.0013 for IL-1b and P=0.0002 for IL-10 levels; P=0.0005 for IL10 mRNA expression) and a dose-response effect was observed for IL-8 levels (Figure 1), and IL1B, IL6 and TNF expression ( Figure 2). WGP-Soluble treatment did not significantly affect the production or gene expression of any cytokine compared with unstimulated cells (P>0.05). WGP-Dispersible, Zymosan, LPS and P3C induced the production of IL-8 ( Figure 1A). IL-6 levels ( Figure 1B) were increased in bovine monocyte cell cultures stimulated with Zymosan, LPS and P3C. TNF-a ( Figure 1C) and IL-10 ( Figure 1E) levels were only increased in bovine monocytes cultured with Zymosan. A tendency for increased IL-1b production was observed in cells stimulated with Zymosan ( Figure 1D). Expression of TNF (Figure 2A) was significantly increased in cells stimulated with WGP-Dispersible, while IL6 ( Figure 2B) and IL1B ( Figure 2C) were overexpressed in cells stimulated with WGP-Dispersible, Zymosan, and LPS.
Although there was an effect of treatment on IL10 mRNA transcript levels ( Figure 2D), the expression of this cytokine gene was only upregulated in cells stimulated with Zymosan at 100 µg/mL, when compared to unstimulated cells. The cytokine mRNA expression results were similar when normalization was done to B2M mRNA expression (Supplementary Figure 4). Since WGP-Dispersible and Zymosan stimulated cytokine production by bovine monocytes, we next examined the correlation between bovine CLEC7A expression of nonstimulated cells and cytokine levels or mRNA expression in response to stimulation with 10, 50 and 100 µg/mL of WGP-Dispersible and Zymosan. A positive correlation was found between CLEC7A mRNA expression and IL-8 concentration in the supernatants of cells stimulated with 10 µg/mL (r = 0.7702) and 50 µg/mL (r = 0.6629) ( Figures 3A, B, respectively), but not with 100 µg/mL ( Figure 3C) of WGP-Dispersible. TNF mRNA expression was positively correlated with CLEC7A mRNA expression at 10 µg/mL (r = 0.7067) and 50 µg/mL (r = 0.6429) ( Figures 3D, E), but not at 100 µg/mL ( Figure 3F). IL6 mRNA expression was also correlated with CLEC7A expression in cells stimulated with WGP-Dispersible at 10 µg/mL (r = 0.7093, Figure  3G) and a tendency was observed in cells stimulated with 50 µg/mL (r = 0.5939, Figure 3H). No such correlation was observed when cells were stimulated with 100 µg/mL WGP-Dispersible ( Figure 3I). A tendency was observed between CLEC7A mRNA expression and IL1B mRNA expression in cells stimulated with 10 µg/mL (r = 0.6672, Figure 3J), but not when cells were stimulated with 50 µg/mL or 100 µg/mL WGP-Dispersible ( Figures 3K, L, respectively). Interestingly, a negative correlation was observed between CLEC7A and IL10 mRNA expression in cells stimulated with 10 µg/mL (r = -0.6978, Figure 3M) and 100 µg/mL (r = -0.7718, Figure 3O) of WGP-Dispersible, and a tendency to a negative correlation in cells stimulated with 50 µg/mL (r = -0.5926, Figure 3N) of this bglucan form. No correlation was found between CLEC7A mRNA expression and cytokine mRNA expression or production in cells stimulated with Zymosan (Supplementary Figure 5).
Sequencing of PCR products was done to confirm primers' specificity (Supplementary Figure 6). Since more than one CLEC7A amplicon was amplified in each sample, PCR products were also visualized in agarose gels to confirm the molecular size of the amplicons (Supplementary Figure 6A). According to our data, different CLEC7A isoforms were expressed simultaneously in monocyte samples, since two different bands, matching the expected molecular size distribution for the two different isoform amplicons (97 bp for the short or 235 bp for the long) appeared on the electrophoresis gel. This is in line with what was previously observed and described by Willcocks et al. (26) for short and long isoforms of boDectin-1. The expression of CLEC7A was decreased upon treatment with WGP-Dispersible and Zymosan, but not with WGP-Soluble (Supplementary Figure 7). Previous reports have shown a downregulation of Dectin-1 expression on the surface of human monocyte-and mouse bone marrow-derived dendritic cells and mouse bone marrow-derived macrophages in response to particulate b-glucan stimulation (39)(40)(41). However, no mention was made therein whether CLEC7A gene expression was also reduced.

Expression of MHC Class II and Costimulatory Molecules
The expression of costimulatory (CD80 and CD86) and MHC class II molecules on the cell surface of monocytes upon stimulation with the different b-glucans or b-glucan-containing particles was evaluated by flow cytometry, as indicated in Supplementary Figure 8  increased the expression of CD80 ( Figure 4B). No differences in the expression of MHC class II were observed at any of these timepoints ( Figures 4E, F), besides a decrease in LPS-treatedcells at 16 h post stimulation.

Small Interference mRNA and Bovine
Dectin-1 Knockdown IL-8 levels and TNF and IL6 expression were significantly increased in monocytes stimulated with either WGP-Dispersible or Zymosan, and their increase was found to be correlated with CLEC7A expression in WGP-Dispersibletreated cells. Therefore, we further investigated the role of boDectin-1 in IL-8 production and TNF and IL6 expression by silencing the receptor using a siRNA approach. Three pairs of siRNA duplexes were designed to target and silence the two bovine Dectin-1 isoforms. Transfection did not affect cell viability (Supplementary Figure 9). Bovine CLEC7A was successfully knocked down by siRNA duplex #3 (85.5%, P<0.01) and, to a lesser extent, by siRNA #2 (66.6%, P<0.05) at 300 nM ( Figure 5A). The knockdown efficiency of this siRNA design was particularly evident in two of the samples tested (Biological samples #2 and #3, Supplementary Table 1). siRNA design #1 was not able to successfully knock down bovine CLEC7A in any of the samples tested ( Figure 5A).
Lower IL-8 levels were found in the supernatants of cells transfected with siRNA pairs #2 and #3 upon stimulation with WGP-Dispersible at 50 µg/mL, comparatively to cells treated with medium alone (X-Vivo), ScreenFect ® siRNA transfection reagent (Screenfect), and MISSION ® siRNA Universal Negative Control #1 (UNC). The percentual change of cytokine production was then calculated considering IL-8 production of Negative Control transfected cells. IL-8 production was significantly decreased (P<0.05) in WGP-Dispersible stimulated cells ( Figure 5B) when transfection was performed with siRNA duplex #2 (57.6% decrease) and siRNA duplex #3 (54.1% decrease). Only siRNA duplex #2 was able to successfully reduce IL-8 production (56.4% decrease, P<0.05) in cells stimulated with Zymosan at 50 µg/mL ( Figure 5C). siRNA duplex #2 led to a clear decrease in IL-8 production in two of the samples stimulated with WGP-Dispersible at 50 µg/mL ( Figure 5B). A smaller reduction was observed in one of the samples used. The observed effect matches the low CLEC7A knockdown efficiency observed in this particular sample ( Figures 5A and Supplementary Table 1). The expression of TNF in cells stimulated with WGP-Dispersible at 50 µg/mL was also significantly affected by CLEC7A knockdown ( Figure 5D). No such effect was observed in Zymosan-treated cells ( Figure  5E). Although not statistically different, the expression of IL6 and  IL1B was decreased upon siRNA#2 treatment in response to WGP-Dispersible (Supplementary Figure 10). Given the high homology of bovine and human Dectin-1, and since no bovinespecific anti-Dectin-1 antibody is available, neutralization of this receptor was attempted using an anti-human Dectin-1 mAb. The used antibody did not recognize boDectin-1 as evaluated by flow cytometry and confocal microscopy ( Supplementary Figures 11,  12, respectively).

DISCUSSION
The effects of b-glucans or b-glucan-containing products have been explored in ruminants, either in vitro (42)(43)(44) or in vivo, by oral administration (23,24,(44)(45)(46)(47), with the purpose of increasing immunity or response to stressors. However, the immunostimulatory effect of b-glucan-containing products, such as Zymosan, on bovine cells mostly involved the analysis of reactive oxygen and nitrogen species production by neutrophils and monocyte-derived macrophages (48)(49)(50). BoDectin-1 has been previously identified and CLEC7A gene expression was detected in several bovine immune cell populations, such as monocytes, monocyte-derived dendritic cells, CD4 + T cells, CD21 + B cells, and NK cells (26). Contrary to human and mouse (10,51) neutrophils, bovine neutrophils do not seem to express CLEC7A (52). Thus, although bovine neutrophils respond to Zymosan by increasing ROS production, this effect was dependent on Ca + influx and mediated, at least in part, by CD11b (52), a component of CR3, an important b-glucan receptor in human neutrophils (53). Bovinederived macrophages also increased the production of ROS in response to Zymosan, although the receptor involved was unraveled (54). In that line, a bovine macrophage cell line (BOMAC) challenged with S. cerevisiae cell wall components consistently expressed higher levels of IL-6, regardless of the yeast strain used, but no confirmation of the receptor responsible for cell activation nor evaluation of putative b-glucan-receptors' expression were done (55). Nevertheless, a human fibroblast cell line (HEK293) transfected with boDectin-1 responded to Zymosan by increasing the production of IL-8, indicating that this bovine receptor could directly recognize b-glucan-containing particles (37).
Here we demonstrated that bovine monocytes respond to particulate b-glucans, through Dectin-1 triggering, resulting in increased expression of pro-inflammatory cytokines. Incubation of bovine monocytes with soluble b-glucans did not induce the production and mRNA expression of any of the cytokines assessed, nor the expression of MHC class II and costimulatory molecules CD80 and CD86 on the surface of monocytes, suggesting that soluble b-glucans do not activate bovine CLEC7A in vitro. Soluble b-glucans, despite being ligands of human and murine Dectin-1, are not able to cluster and activate in vitro the receptor (16), thus not inducing downstream cell signaling and activation (56). Proinflammatory cytokine production and cytokine gene expression were significantly increased in cells stimulated with dispersible bglucans and Zymosan in a dose-dependent manner. These results are consistent with in vitro data obtained with murine bone marrow-derived macrophages and dendritic cells (57), murine resident macrophages (56), human whole blood (58), and porcine innate immune cells, namely peripheral-blood mononuclear cells and neutrophils (59). Cytokine response was in accordance with the increased costimulatory molecule expression observed on the surface of WGP-Dispersible and Zymosan-treated monocytes. Dispersible b-glucans and Zymosan, induced the upregulation of costimulatory molecules, which might contribute to improve T cell stimulation. Other authors (12,14) have previously highlighted the importance of a crosstalk between different receptors, such as Dectin-1 and TLR-2. When several PRRs are activated simultaneously by particulate b-glucans, a complex cascade of cell signaling is usually amplified by this collaboration (60). Both Dectin-1 and TLR-2 recognize Zymosan, thus Zymosan is likely able to induce a more sustained and marked cell stimulation with a concomitant higher cytokine production. The positive correlation found here between CLEC7A expression and TNF and IL6 expression and IL-8 production in cells stimulated with WGP-Dispersible indicates that BoDectin-1 mediates b-glucan recognition in bovine monocytes. We found, however, no correlation between CLEC7A expression and cytokine production or gene expression in Zymosan stimulated cells. Since Zymosan contains other pathogen-associated molecular patterns besides b-glucans, other receptors being triggered by those compounds could be contributing to cytokine production and hamper a direct association. Although a combined recognition of Zymosan by multiple PRRs, was reported in human and mouse cells, namely by Dectin-1 plus TLR-2 (61), Willcocks et al. (37) have reported that HEK293 cell line transfected with both boDectin-1 and boTLR-2 did not increase the production of IL-8 in response to Zymosan comparatively to HEK293 cells expressing boDectin-1 alone. Indeed, in that particular study, HEK293-boTLR-2 did not respond to Zymosan (37).
We found a negative correlation between CLEC7A and IL10 gene expression, reinforcing the ability of this highly pure bglucan in inducing the production of pro-inflammatory cytokines, rather than anti-inflammatory cytokines. In contrast, Zymosan at 100 µg/mL induced the expression of the antiinflammatory cytokine IL-10, comparatively to control cells. This is in accordance with previous reports describing an increased production of IL-10 in human and murine dendritic cells in response to these b-glucan-containing particles, which may confer immunological cell tolerance (62). Since WGP-Dispersible, which does not trigger TLR-signaling, did not induce IL10 gene expression, we hypothesize that TLR-2, a receptor already associated with high IL-10 production (63), is being activated upon recognizing other Zymosan components.
These results indicate that boDectin-1 on bovine monocytes is effectively being triggered by particulate b-glucans similarly to mouse and human monocytes. In contrast, in porcine macrophages, Dectin-1 silencing did not affect cytokine production (38), reinforcing the species-specific nature of the PRR response to several agonists (37,54). We have attempted Dectin-1 blockade with an anti-human Dectin-1 neutralizing mAb without success. The availability of a bovine anti-Dectin-1 mAb, with neutralizing functions, would be of most importance to both assess cell surface Dectin-1 expression and perform further functional assays. This would more directly allow to uncover the signaling pathways elicited by particulate b-glucans. Since Dectin-1 knockdown using siRNAs did not completely resume IL-8 production and TNF, IL6, and IL1B expression to negative control levels, it is possible that other receptors could additionally be involved in the recognition of WGP-Dispersible. It thus remains to be elucidated whether bovine CR3 is also playing a role on the recognition of particulate b-glucans by bovine monocytes, as in human monocytes (64) and in mouse (65) and swine macrophages (38).
Recognition of b-glucans by Dectin-1 has been shown to induce epigenetic modifications in immune cells, that render them more efficient in responding to infection (66), a phenomenon referred to as trained immunity (66,67). It is therefore conceivable that bovine monocytes, such as those of mice (68), humans (28), dogs (69), and chicken (70) may be prone to induction of trained immunity. That would provide a plausible explanation for the beneficial effects of b-glucancontaining dietary supplements observed in vivo in cattle (23,(45)(46)(47). The in vitro results obtained in this study may help clarify b-glucan recognition by bovine monocytes and lend support to further studies addressing trained immunity events in this species.

DATA AVAILABILITY STATEMENT
The raw data supporting the conclusions of this article will be made available by the authors, without undue reservation.

AUTHOR CONTRIBUTIONS
AP conducted the experiments, performed data acquisition and analysis, and wrote the manuscript. AC, TL, RF-M, and BL participated in the experiments. EM and IR assisted in the design of the experiments. ARJC and AF assisted in the interpretation of data. AC, MM, and MV conceived and designed the experiments, supervised the experimental work, assisted in data acquisition and analysis, and assisted in manuscript writing. All authors contributed to the article and approved the submitted version. (supported by POCI-01-0145-FEDER-022122), and the technical assistance of Maria Azevedo, and Genomics, and the technical assistance of Ana Mafalda Rocha and Rob Mensink. Sequencing data are a result of the GenomePT project (POCI-01-0145-FEDER-022184).