P2Y2 and P2X4 Receptors Mediate Ca2+ Mobilization in DH82 Canine Macrophage Cells

Purinergic receptors of the P2 subclass are commonly found in human and rodent macrophages where they can be activated by adenosine 5′-triphosphate (ATP) or uridine 5′-triphosphate (UTP) to mediate Ca2+ mobilization, resulting in downstream signalling to promote inflammation and pain. However, little is understood regarding these receptors in canine macrophages. To establish a macrophage model of canine P2 receptor signalling, the expression of these receptors in the DH82 canine macrophage cell line was determined by reverse transcription polymerase chain reaction (RT-PCR) and immunocytochemistry. P2 receptor function in DH82 cells was pharmacologically characterised using nucleotide-induced measurements of Fura-2 AM-bound intracellular Ca2+. RT-PCR revealed predominant expression of P2X4 receptors, while immunocytochemistry confirmed predominant expression of P2Y2 receptors, with low levels of P2X4 receptor expression. ATP and UTP induced robust Ca2+ responses in the absence or presence of extracellular Ca2+. ATP-induced responses were only partially inhibited by the P2X4 receptor antagonists, 2′,3′-O-(2,4,6-trinitrophenyl)-ATP (TNP-ATP), paroxetine and 5-BDBD, but were strongly potentiated by ivermectin. UTP-induced responses were near completely inhibited by the P2Y2 receptor antagonists, suramin and AR-C118925. P2Y2 receptor-mediated Ca2+ mobilization was inhibited by U-73122 and 2-aminoethoxydiphenyl borate (2-APB), indicating P2Y2 receptor coupling to the phospholipase C and inositol triphosphate signal transduction pathway. Together this data demonstrates, for the first time, the expression of functional P2 receptors in DH82 canine macrophage cells and identifies a potential cell model for studying macrophage-mediated purinergic signalling in inflammation and pain in dogs.


Introduction
The activation of purinergic receptors by nucleotides such as adenosine 5 -triphosphate (ATP) and uridine 5 -triphosphate (UTP) is crucial for a number of inflammatory processes, including those in the central nervous system (CNS) such as chronic pain [1][2][3][4] and remyelination of nerves following injury to the CNS [5,6]. The P2 receptor family consists of seven mammalian ionotropic P2X receptors (P2X1-7) and eight mammalian metabotropic P2Y receptors (P2Y 1,2,4,6,[11][12][13][14] ) that can modulate intracellular Ca 2+ concentrations through direct ion channel permeation or mobilization of intracellular Ca 2+ stores, respectively [7]. P2 receptors, such as the P2X4 and P2Y 2 receptors, are commonly expressed on human and rodent macrophages and macrophage cell lines [8][9][10][11][12][13][14], and have demonstrated roles in signalling Figure 1. Expression of P2X and P2Y receptor mRNA in DH82 cells. RNA was isolated from DH82 cells and cDNA was synthesized and amplified using primer pairs designed to each respective P2RX or P2RY genes, with glyceraldehyde 3-phosphate dehydrogenase (GAPDH) as a positive control. Amplification in absence of cDNA was conducted for each primer pair to ensure primer specificity. Amplicons were visualized by agarose gel electrophoresis using GelRed and the GelDoc XR+ imaging system and semiquantitatively analysed by densitometry. Data shown are the mean ± SEM relative to GAPDH expression from three independent experiments.

Nucleotides Mediate Ca 2+ Responses in DH82 Cells
To establish an agonist profile for functional P2 receptors in DH82 cells, nucleotides which have previously demonstrated activity towards P2 receptors from dogs, humans or rodents [39,40] were utilised to measure changes in intracellular Ca 2+ . These nucleotides were ATP, 3'-O-(4-benzoyl)benzoyl-ATP (BzATP), adenosine-5′-diphosphate (ADP), 2-methylthio-ADP (2MeSADP), uridine-5′triphosphate (UTP) and uridine-5′-diphosphate (UDP). ADP was preincubated with hexokinase to remove trace amounts of ATP [41]. Incubation with ATP or UTP induced robust Ca 2+ responses (ΔF340/380) in DH82 cells, which peaked approximately 15 s after application of nucleotides ( Figure  2A,B). Ca 2+ responses then decayed more slowly, returning to baseline approximately 70-80 s after the initial peak was observed (Figure 2A,B). Incubation with ADP or BzATP resulted in much smaller Ca 2+ responses compared to ATP and UTP ( Figure 2C,D). UDP and 2MeSADP were unable to induce Ca 2+ responses up to 30 µ M and 100 µ M, respectively ( Figure 2E,F). Decay time, calculated as the time constant (τ), was similar for ATP and UTP (τ = 56.9 ± 4.8 s and 56.7 ± 5.9 s, respectively), however, BzATP (τ = 102.3 ± 17.9 s) had a significantly longer decay time compared to ATP (p < 0.05), UTP (p < 0.05) or ADP (τ = 23.8 ± 0.4 s; p < 0.001), while UDP and 2MeSADP did not respond and as such, decay time could not be calculated ( Figure 2G). Expression of P2X and P2Y receptor mRNA in DH82 cells. RNA was isolated from DH82 cells and cDNA was synthesized and amplified using primer pairs designed to each respective P2RX or P2RY genes, with glyceraldehyde 3-phosphate dehydrogenase (GAPDH) as a positive control. Amplification in absence of cDNA was conducted for each primer pair to ensure primer specificity. Amplicons were visualized by agarose gel electrophoresis using GelRed and the GelDoc XR+ imaging system and semi-quantitatively analysed by densitometry. Data shown are the mean ± SEM relative to GAPDH expression from three independent experiments.
As Ca 2+ responses were observed with a number of nucleotides, including those known to activate mammalian ionotropic P2X (ATP, BzATP) and metabotropic P2Y receptors (ATP, UTP, ADP), both the peak nucleotide-induced Ca 2+ responses ( Figure 2H) and net Ca 2+ movement ( Figure 2I; calculated as area under the curve [AUC]) were used for constructing concentration-response curves to account for potential differences in Ca 2+ response phenotypes in a model of co-expression of P2X and P2Y receptor subtypes. In DH82 cells, nucleotides induced concentration-dependent Ca 2+ responses with the rank order of potency of UTP > ATP >> ADP ≈ BzATP, with UDP and 2MeSADP being unresponsive (Figure 2H,I; Table 1). There were no significant differences between the EC 50 values calculated for net Ca 2+ movement and peak Ca 2+ response for any nucleotide ( Table 1).
As Ca 2+ responses were observed with a number of nucleotides, including those known to activate mammalian ionotropic P2X (ATP, BzATP) and metabotropic P2Y receptors (ATP, UTP, ADP), both the peak nucleotide-induced Ca 2+ responses ( Figure 2H) and net Ca 2+ movement ( Figure 2I; calculated as area under the curve [AUC]) were used for constructing concentration-response curves to account for potential differences in Ca 2+ response phenotypes in a model of co-expression of P2X and P2Y receptor subtypes. In DH82 cells, nucleotides induced concentration-dependent Ca 2+ responses with the rank order of potency of UTP > ATP >> ADP ≈ BzATP, with UDP and 2MeSADP being unresponsive ( Figure  2H,I; Table 1). There were no significant differences between the EC50 values calculated for net Ca 2+ movement and peak Ca 2+ response for any nucleotide (Table 1). (G) One phase decay time (τ) calculated from the peak of each Ca 2+ trace, ND = no data. (H) Peak nucleotide-induced Ca 2+ responses and (I) net Ca 2+ movement were fit to the Hill equation to produce concentration-response curves (n values correspond to respective individual traces above). (A-I) Data shown are the mean ± SEM from three to six independent experiments as indicated. (G) * p < 0.05 and *** p < 0.001 between nucleotides as indicated analysed using a one-way ANOVA with Bonferroni post hoc test. To determine if the observed Ca 2+ responses were mediated by P2X receptors, DH82 cells were preincubated with the non-selective P2X receptor antagonist, 2 ,3 -O-(2,4,6-trinitrophenyl)-ATP (TNP-ATP) [42], then exposed to ATP. Preincubation with 50 µM TNP-ATP partially reduced Ca 2+ responses mediated by 10 µM ATP, but did not significantly inhibit Ca 2+ responses evoked by 1 µM or 100 µM ATP ( Figure 3A-C). This was supported by a significant reduction in net Ca 2+ movement at 10 µM ATP, but not at other ATP concentrations ( Figure 3E). Despite this, no significant change in peak Ca 2+ response or shift in decay time was observed ( Figure 3D,F). Preincubation with TNP-ATP did not result in a significant shift in the peak Ca 2+ response EC 50 for ATP, compared to cells preincubated in the absence of TNP-ATP ( Figure 3D; pEC 50 5.38 ± 0.08 vs. 5.57 ± 0.13, respectively; p = 0.133 Student's t-test). In contrast, preincubation with TNP-ATP did result in a significant shift in the net Ca 2+ movement EC 50 compared to cells preincubated in absence of TNP-ATP ( Figure 2E; pEC 50 5.04 ± 0.14 vs. 5.69 ± 0.13, respectively; p = 0.007 Student's t-test).

2MeSADP
ND (<10%) -ND (<10%) -Abbreviations: AUC, area under the curve; ND, not determined (pEC50 not calculated due to lack of response). Values in parentheses indicate the percent of each maximum agonist response compared to 100 µ M ATP. 1 ADP in the presence of hexokinase to remove contaminating ATP. 2 p < 0.05 compared to the respective pEC50 of ATP and UTP (one-way ANOVA). 3 p < 0.01 compared to the respective pEC50 of ATP and UTP (one-way ANOVA).

TNP-ATP Partially Reduces ATP-Induced Net Ca 2+ Movement
To determine if the observed Ca 2+ responses were mediated by P2X receptors, DH82 cells were preincubated with the non-selective P2X receptor antagonist, 2′,3′-O-(2,4,6-trinitrophenyl)-ATP (TNP-ATP) [42], then exposed to ATP. Preincubation with 50 µ M TNP-ATP partially reduced Ca 2+ responses mediated by 10 µ M ATP, but did not significantly inhibit Ca 2+ responses evoked by 1 µ M or 100 µ M ATP ( Figure 3A-C). This was supported by a significant reduction in net Ca 2+ movement at 10 µ M ATP, but not at other ATP concentrations ( Figure 3E). Despite this, no significant change in peak Ca 2+ response or shift in decay time was observed ( Figure 3D,F). Preincubation with TNP-ATP did not result in a significant shift in the peak Ca 2+ response EC50 for ATP, compared to cells preincubated in the absence of TNP-ATP ( Figure 3D; pEC50 5.38 ± 0.08 vs. 5.57 ± 0.13, respectively; p = 0.133 Student's t-test). In contrast, preincubation with TNP-ATP did result in a significant shift in the net Ca 2+ movement EC50 compared to cells preincubated in absence of TNP-ATP ( Figure 2E; pEC50 5.04 ± 0.14 vs. 5.69 ± 0.13, respectively; p = 0.007 Student's t-test).

Paroxetine Partially Reduces ATP-Induced Net Ca 2+ Movement
To further investigate the role of P2X receptors in DH82 cells, ATP-induced Ca 2+ responses were measured in cells preincubated with paroxetine, a selective serotonin reuptake inhibitor which has been shown to inhibit P2X4 receptors [41,43,44] and human (but not rodent) P2X7 receptors [45,46]. Preincubation with paroxetine partially reduced Ca 2+ responses mediated by ATP concentrations of 10 µM or greater, with a small, but non-significant inhibitory effect observed at 1 µM or below ( Figure 4A-C). Similar to TNP-ATP, preincubation with paroxetine did not significantly reduce peak Ca 2+ responses ( Figure 4D), however, did significantly reduce net Ca 2+ movement and decay kinetics ( Figure 4E,F). Preincubation with paroxetine did not significantly shift the EC 50 of ATP compared to cells preincubated in absence of paroxetine for peak Ca + response ( Figure 4D; pEC 50 5.55 ± 0.31 vs. 5.51 ± 0.48, respectively; p = 0.479 Student's t-test) or net Ca 2+ movement ( Figure 4E; pEC 50 5.27 ± 0.35 vs. 5.4 ± 0.28, respectively; p = 0.387 Student's t-test).

Paroxetine Partially Reduces ATP-Induced Net Ca 2+ Movement
To further investigate the role of P2X receptors in DH82 cells, ATP-induced Ca 2+ responses were measured in cells preincubated with paroxetine, a selective serotonin reuptake inhibitor which has been shown to inhibit P2X4 receptors [41,43,44] and human (but not rodent) P2X7 receptors [45,46]. Preincubation with paroxetine partially reduced Ca 2+ responses mediated by ATP concentrations of 10 µ M or greater, with a small, but non-significant inhibitory effect observed at 1 µ M or below ( Figure  4A-C). Similar to TNP-ATP, preincubation with paroxetine did not significantly reduce peak Ca 2+ responses ( Figure 4D), however, did significantly reduce net Ca 2+ movement and decay kinetics ( Figure  4E,F). Preincubation with paroxetine did not significantly shift the EC50 of ATP compared to cells preincubated in absence of paroxetine for peak Ca + response ( Figure 4D; pEC50 5.55 ± 0.31 vs. 5.51 ± 0.48, respectively; p = 0.479 Student's t-test) or net Ca 2+ movement ( Figure 4E; pEC50 5.27 ± 0.35 vs. 5.4 ± 0.28, respectively; p = 0.387 Student's t-test).  (D-F) * p < 0.05, ** p < 0.01 and *** p < 0.001 compared to respective concentration of ATP alone analysed using a two-way ANOVA with Bonferroni post hoc test.

5-BDBD Partially Reduces ATP-Induced Net Ca 2+ Movement
To determine further if P2X4 receptors played a role in the observed ATP-induced Ca 2+ responses, DH82 cells were preincubated with the selective P2X4 receptor antagonist, 5-BDBD, of which was recently demonstrated to inhibit the canine P2X4 receptor [41]. Preincubation with 30 µM 5-BDBD had no significant inhibitory effects on the Ca 2+ response mediated by ATP ( Figure 5A-C). There was no significant difference in the EC 50 for cells preincubated in the absence or presence of 5-BDBD for ATP-induced peak Ca 2+ response ( Figure 5D; pEC 50 5.87 ± 0.12 vs. 5.82 ± 0.10, respectively; p = 0.372 Student's t-test) or net Ca 2+ movement ( Figure 5E; pEC 50 5.73 ± 0.18 vs. 5.64 ± 0.14, respectively; p = 0.358 Student's t-test), although a trend towards decreased net Ca 2+ movement was observed at 10 µM ATP ( Figure 5E). Of note, there was a significant reduction in decay kinetics at 10 µM ATP for cells preincubated in the presence of 5-BDBD compared to those in absence of the antagonist ( Figure 5F). no significant inhibitory effects on the Ca 2+ response mediated by ATP ( Figure 5A-C). There was no significant difference in the EC50 for cells preincubated in the absence or presence of 5-BDBD for ATPinduced peak Ca 2+ response ( Figure 5D; pEC50 5.87 ± 0.12 vs. 5.82 ± 0.10, respectively; p = 0.372 Student's t-test) or net Ca 2+ movement ( Figure 5E; pEC50 5.73 ± 0.18 vs. 5.64 ± 0.14, respectively; p = 0.358 Student's t-test), although a trend towards decreased net Ca 2+ movement was observed at 10 µ M ATP ( Figure  5E). Of note, there was a significant reduction in decay kinetics at 10 µ M ATP for cells preincubated in the presence of 5-BDBD compared to those in absence of the antagonist ( Figure 5F).

Ivermectin Positively Modulates ATP-Induced Net Ca 2+ Movement
It has recently been demonstrated that ivermectin can effectively potentiate Ca 2+ responses mediated by canine P2X4 receptors [41]. To further investigate if DH82 cells express functional P2X4 receptors, cells were preincubated with ivermectin prior to activation with increasing concentrations of ATP. Preincubation with 3 µ M ivermectin revealed a strong potentiation of ATP-induced Ca 2+ responses in DH82 cells ( Figure 6A-C), with significant increases in ATP-induced net Ca 2+ movement and peak Ca 2+ response observed in the presence of ivermectin compared to cells preincubated in absence of ivermectin at ATP concentrations upwards of 10 µ M ( Figure 6D,E). Despite this, there was no significant difference in the EC50 in the absence or presence of ivermectin for ATP-induced peak Ca 2+ response ( Figure 6D; pEC50 5.76 ± 0.19 vs. 5.37 ± 0.35; p = 0.372 Student's t-test) or net Ca 2+ movement ( Figure 6E; pEC50 5.62 ± 0.01 vs. 5.57 ± 0.12, respectively; p = 0.358 Student's t-test). Additionally, there were no significant differences in decay kinetics between cells preincubated in absence or presence of

Ivermectin Positively Modulates ATP-Induced Net Ca 2+ Movement
It has recently been demonstrated that ivermectin can effectively potentiate Ca 2+ responses mediated by canine P2X4 receptors [41]. To further investigate if DH82 cells express functional P2X4 receptors, cells were preincubated with ivermectin prior to activation with increasing concentrations of ATP. Preincubation with 3 µM ivermectin revealed a strong potentiation of ATP-induced Ca 2+ responses in DH82 cells ( Figure 6A-C), with significant increases in ATP-induced net Ca 2+ movement and peak Ca 2+ response observed in the presence of ivermectin compared to cells preincubated in absence of ivermectin at ATP concentrations upwards of 10 µM ( Figure 6D,E). Despite this, there was no significant difference in the EC 50 in the absence or presence of ivermectin for ATP-induced peak Ca 2+ response ( Figure 6D; pEC 50 5.76 ± 0.19 vs. 5.37 ± 0.35; p = 0.372 Student's t-test) or net Ca 2+ movement ( Figure 6E; pEC 50 5.62 ± 0.01 vs. 5.57 ± 0.12, respectively; p = 0.358 Student's t-test). Additionally, there were no significant differences in decay kinetics between cells preincubated in absence or presence of ivermectin ( Figure 6F). Collectively this and the above data suggests that DH82 cells express functional P2X4 receptors. ivermectin ( Figure 6F). Collectively this and the above data suggests that DH82 cells express functional P2X4 receptors.

ATP and UTP Mediate Both Ca 2+ Influx and Store-Operated Ca 2+ Entry in DH82 Cells
Despite the apparent P2X4-mediated effects on Ca 2+ responses in DH82 cells, a lack of complete inhibition by P2X receptor antagonists, as well as the responsiveness to UTP, suggest the presence of functional P2Y receptors in DH82 cells. To determine if Gq/11-coupled P2Y receptors, which have demonstrated roles in store-operated Ca 2+ entry [47], were involved in the observed Ca 2+ responses in DH82 cells, nucleotide-induced changes in intracellular Ca 2+ were measured in the presence of extracellular or intracellular Ca 2+ chelators. Compared to cells in the presence of extracellular Ca 2+ ( Figure Figure 7L,M) in DH82 cells. Treatment with thapsigargin, to inhibit sarco/endoplasmic reticulum Ca 2+ ATPase pumps [48], near completely reduced ATP-and UTP-induced Ca 2+ responses in the presence of extracellular Ca 2+ (ECS; Figure 7D,I,L,M) and completely reduced these responses in the absence of extracellular Ca 2+ (EGTA; Figure 7E,J,L,M). Together, this suggests the involvement of both P2X and P2Y receptors in DH82 cells for mediating changes in intracellular Ca 2+ in response to activation by nucleotides.

ATP and UTP Mediate Both Ca 2+ Influx and Store-Operated Ca 2+ Entry in DH82 Cells
Despite the apparent P2X4-mediated effects on Ca 2+ responses in DH82 cells, a lack of complete inhibition by P2X receptor antagonists, as well as the responsiveness to UTP, suggest the presence of functional P2Y receptors in DH82 cells. To determine if G q/11 -coupled P2Y receptors, which have demonstrated roles in store-operated Ca 2+ entry [47], were involved in the observed Ca 2+ responses in DH82 cells, nucleotide-induced changes in intracellular Ca 2+ were measured in the presence of extracellular or intracellular Ca 2+ chelators. Compared to cells in the presence of extracellular Ca 2+ ( Figure Figure 7L,M) in DH82 cells. Treatment with thapsigargin, to inhibit sarco/endoplasmic reticulum Ca 2+ ATPase pumps [48], near completely reduced ATP-and UTP-induced Ca 2+ responses in the presence of extracellular Ca 2+ (ECS; Figure 7D,I,L,M) and completely reduced these responses in the absence of extracellular Ca 2+ (EGTA; Figure 7E,J,L,M). Together, this suggests the involvement of both P2X and P2Y receptors in DH82 cells for mediating changes in intracellular Ca 2+ in response to activation by nucleotides. independent experiments. * p < 0.05, ** p < 0.01 and *** p < 0.001 compared to respective ECS alone control; † p < 0.05, † † p < 0.01 and † † † p < 0.001 compared to EGTA; # p < 0.05 compared to BAPTA-AM analysed using a (K) Student's t-test or (L,M) one-way ANOVA with Bonferroni post hoc test.

Suramin Reduces ATP-and UTP-Induced Ca 2+ Mobilization
The data presented above suggests a major role for an ATP-and UTP-responsive P2Y receptor in Ca 2+ mobilization within DH82 cells. Previous studies have demonstrated that the canine P2Y2 receptor in Madin-Darby canine kidney (MDCK) cells responds to both ATP and UTP with similar potency [49]. Therefore, to determine if nucleotide-induced Ca 2+ mobilization was mediated by P2Y2 receptors, DH82 cells were preincubated with increasing concentrations of the non-selective P2 receptor antagonist, suramin [50], which is selective for P2Y2 over P2Y4 receptors [51]. Cells were then incubated with ATP or UTP at their respective EC80 to determine the optimal concentration for P2Y receptor inhibition. Preincubation of DH82 cells with 1 mM suramin inhibited Ca 2+ responses evoked by 3 µ M ATP, however lower concentrations of suramin (<100 µ M) had little to no inhibitory effect ( Figure 8A). In * p < 0.05, ** p < 0.01 and *** p < 0.001 compared to respective ECS alone control; † p < 0.05, † † p < 0.01 and † † † p < 0.001 compared to EGTA; # p < 0.05 compared to BAPTA-AM analysed using a (K) Student's t-test or (L,M) one-way ANOVA with Bonferroni post hoc test.

Suramin Reduces ATP-and UTP-Induced Ca 2+ Mobilization
The data presented above suggests a major role for an ATP-and UTP-responsive P2Y receptor in Ca 2+ mobilization within DH82 cells. Previous studies have demonstrated that the canine P2Y 2 receptor in Madin-Darby canine kidney (MDCK) cells responds to both ATP and UTP with similar potency [49]. Therefore, to determine if nucleotide-induced Ca 2+ mobilization was mediated by P2Y 2 receptors, DH82 cells were preincubated with increasing concentrations of the non-selective P2 receptor antagonist, suramin [50], which is selective for P2Y 2 over P2Y 4 receptors [51]. Cells were then incubated with ATP or UTP at their respective EC 80 to determine the optimal concentration for P2Y receptor inhibition. Preincubation of DH82 cells with 1 mM suramin inhibited Ca 2+ responses evoked by 3 µM ATP, however lower concentrations of suramin (<100 µM) had little to no inhibitory effect ( Figure 8A). In contrast, preincubation with 100 µM and 1 mM, but not 10 µM suramin or less inhibited Ca 2+ responses evoked by 1 µM UTP ( Figure 8B). Inhibitory effects observed in the presence of 100 µM suramin resulted in significant shifts in the IC 50 of suramin between ATP-and UTP-induced peak Ca 2+ responses ( Figure 8C; pIC 50 3.02 ± 0.06 and 3.70 ± 0.05, respectively; p < 0.001 Student's t-test) and net Ca 2+ movement ( Figure 8D; pIC 50 3.03 ± 0.12 and 3.54 ± 0.14, respectively; p = 0.025 Student's t-test). contrast, preincubation with 100 µ M and 1 mM, but not 10 µ M suramin or less inhibited Ca 2+ responses evoked by 1 µ M UTP ( Figure 8B). Inhibitory effects observed in the presence of 100 µ M suramin resulted in significant shifts in the IC50 of suramin between ATP-and UTP-induced peak Ca 2+ responses ( Figure 8C; pIC50 3.02 ± 0.06 and 3.70 ± 0.05, respectively; p < 0.001 Student's t-test) and net Ca 2+ movement ( Figure 8D; pIC50 3.03 ± 0.12 and 3.54 ± 0.14, respectively; p = 0.025 Student's t-test).

AR-C118925 Reduces ATP-and UTP-Induced Ca 2+ Mobilization
To determine if the P2Y2 receptor was mediating nucleotide-induced Ca 2+ mobilization in DH82 cells, the selective P2Y2 receptor antagonist AR-C118925 [52] was preincubated with cells prior to incubation with ATP or UTP at their respective EC80 concentrations. AR-C118925 at concentrations of 1 µ M or greater could only partially inhibit Ca 2+ responses evoked by 3 µ M ATP ( Figure 8E). In contrast, preincubation with AR-C118925 at concentrations of 10 µ M or greater near completely inhibited Ca 2+ responses evoked by 1 µ M UTP ( Figure 8F). A significant shift was observed in the IC50 of AR-C118925 in response to activation by ATP and UTP calculated using peak Ca 2+ responses ( Figure 8G; pIC50 6.18 ± 0.16 and 6.61 ± 0.09, respectively; p = 0.033 Student's t-test), but not net Ca 2+ movement ( Figure 8H; pIC50 6.67 ± 0.19 and 6.87 ± 0.12, respectively; p = 0.198 Student's t-test). The inhibition of nucleotideinduced Ca 2+ responses by AR-C118925 supports the presence of P2Y2 receptors in DH82 cells. Moreover, the differing effect of this antagonist on ATP-and UTP-induced responses indicates the presence of other P2 receptors in this cell line. Additionally, preincubation of DH82 cells together with 5-BDBD and AR-C118925 resulted in a complete inhibition of both ATP-and UTP-induced net Ca 2+ movement ( Figure S1), further suggesting a role for both P2X4 and P2Y2 receptors in nucleotidemediated Ca 2+ responses in DH82 cells. Cells were then exposed to 3 µM ATP or 1 µM UTP (respective EC 80 values) and Fura-2 fluorescence was recorded. Nucleotide-induced (C,G) peak Ca 2+ response and (D,H) net Ca 2+ movement were normalised to 3 µM ATP or 1 µM UTP alone and expressed as a percentage of the response in absence of inhibitor (% of control). Data were then to fit data to the Hill equation to produce concentration-response curves and calculate the IC 50 . (A-H) Data shown are mean ± SEM from three independent experiments. * p < 0.05, ** p < 0.01 and *** p < 0.001 compared to respective concentration of antagonist with ATP or UTP analysed using a two-way ANOVA with Bonferroni post hoc test.

AR-C118925 Reduces ATP-and UTP-Induced Ca 2+ Mobilization
To determine if the P2Y 2 receptor was mediating nucleotide-induced Ca 2+ mobilization in DH82 cells, the selective P2Y 2 receptor antagonist AR-C118925 [52] was preincubated with cells prior to incubation with ATP or UTP at their respective EC 80 concentrations. AR-C118925 at concentrations of 1 µM or greater could only partially inhibit Ca 2+ responses evoked by 3 µM ATP ( Figure 8E). In contrast, preincubation with AR-C118925 at concentrations of 10 µM or greater near completely inhibited Ca 2+ responses evoked by 1 µM UTP ( Figure 8F). A significant shift was observed in the IC 50 of AR-C118925 in response to activation by ATP and UTP calculated using peak Ca 2+ responses ( Figure 8G; pIC 50 6.18 ± 0.16 and 6.61 ± 0.09, respectively; p = 0.033 Student's t-test), but not net Ca 2+ movement ( Figure 8H; pIC 50 6.67 ± 0.19 and 6.87 ± 0.12, respectively; p = 0.198 Student's t-test). The inhibition of nucleotide-induced Ca 2+ responses by AR-C118925 supports the presence of P2Y 2 receptors in DH82 cells. Moreover, the differing effect of this antagonist on ATP-and UTP-induced responses indicates the presence of other P2 receptors in this cell line. Additionally, preincubation of DH82 cells together with 5-BDBD and AR-C118925 resulted in a complete inhibition of both ATPand UTP-induced net Ca 2+ movement ( Figure S1), further suggesting a role for both P2X4 and P2Y 2 receptors in nucleotide-mediated Ca 2+ responses in DH82 cells.

DH82 Canine Macrophages Predominantly Express Cell Surface P2Y 2 Receptors
To confirm the presence of P2X4 and P2Y 2 receptors, DH82 cells were analysed by immunocytochemistry and confocal microscopy using anti-P2X4 or anti-P2Y 2 receptor antibodies. Confocal microscopy revealed the presence of both P2X4 and P2Y 2 receptors in fixed and permeabilised DH82 cells (Figure 9A,B). The expression of P2X4 receptors was relatively low and largely intracellular ( Figure 9A). The expression of P2Y 2 receptors on DH82 cells was considerably higher and predominantly localised to the cell surface ( Figure 9B), consistent with its reported expression in the membrane of MDCK cells [53,54]. No fluorescence was detected in DH82 cells stained with secondary antibodies alone ( Figure S2).

DH82 Canine Macrophages Predominantly Express Cell Surface P2Y2 Receptors
To confirm the presence of P2X4 and P2Y2 receptors, DH82 cells were analysed by immunocytochemistry and confocal microscopy using anti-P2X4 or anti-P2Y2 receptor antibodies. Confocal microscopy revealed the presence of both P2X4 and P2Y2 receptors in fixed and permeabilised DH82 cells (Figure 9A,B). The expression of P2X4 receptors was relatively low and largely intracellular ( Figure 9A). The expression of P2Y2 receptors on DH82 cells was considerably higher and predominantly localised to the cell surface ( Figure 9B), consistent with its reported expression in the membrane of MDCK cells [53,54]. No fluorescence was detected in DH82 cells stained with secondary antibodies alone ( Figure S2).

P2Y 2 Receptor Activation Downstream Ca 2+ Mobilization Is Coupled to the Phospholipase C/Inositol Triphosphate Signal Transduction Pathway in DH82 Cells
Functional P2Y 2 receptors have been reported in human and rodent macrophages [9,10], where they can activate phospholipase C (PLC) and inositol trisphosphate (IP 3 ) receptors, leading to Ca 2+ mobilization from endoplasmic reticulum stores [8,12]. To determine if activation of canine P2Y 2 receptors in DH82 macrophage cells results in a similar downstream signalling pathway, cells were preincubated with antagonists of PLC (U-73122) and IP 3 receptors (2-aminoethoxydiphenyl borate; 2-APB), and nucleotide-induced intracellular Ca 2+ mobilization was recorded in absence of extracellular Ca 2+ . The presence of AR-C118925 under these conditions was also examined. Preincubation of DH82 cells with AR-C118925 near completely inhibited intracellular Ca 2+ mobilization mediated by ATP (Figure 10A; 90.5 ± 3.3% inhibition) or UTP ( Figure 10B; 87.3 ± 7.4% inhibition). Similarly, preincubation of DH82 cells with 75 µM 2-APB near completely inhibited intracellular Ca 2+ mobilization mediated by ATP ( Figure 10A; 90.7 ± 4.4% inhibition) or UTP ( Figure 10B; 91.2 ± 3.1% inhibition). In contrast, preincubation with 5 µM U-73122 only partially reduced intracellular Ca 2+ mobilization mediated by ATP ( Figure 10A; 64.9 ± 5.9% inhibition) or UTP ( Figure 10B; 55.5 ± 8.7% inhibition). The combination of two or three of these antagonists completely impaired ATP-and UTP-induced Ca 2+ responses ( Figure 10A,B). Thus, preincubation with AR-C118925, 2-APB, U-73122 or any combination of these antagonists resulted in a significant reduction of intracellular Ca 2+ mobilization (p < 0.001, one-way ANOVA) compared to that mediated by ATP ( Figure 10A) or UTP ( Figure 10B) in the absence of antagonists. Cells were then exposed to (A) 10 µ M ATP or (B) 10 µ M UTP and Fura-2 fluorescence was recorded. Data shown are the mean ± SEM from five independent experiments. ** p < 0.01 and *** p < 0.001 compared to respective nucleotide alone, analysed using a one-way ANOVA with Bonferroni post hoc test.

Discussion
To date, the DH82 canine macrophage cell line has primarily been utilized as a model of viral and protozoan infection [23][24][25], such as for the study of canine distemper and its oncolytic potential [55][56][57]. Although studies have described the expression of functional P2 receptors in human or rodent macrophages and macrophage cell lines [8,10,11,34], studies directly investigating P2 receptors in canine macrophages have been absent. The current study described, for the first time, the expression and function of P2 receptors in DH82 cells, demonstrating a primary role for cell surface P2Y2 receptors in nucleotide-mediated Ca 2+ mobilization through PLC/IP3 signal transduction. This study also demonstrates a minor functional role for P2X4 receptors in DH82 cells, suggesting this cell line may present as a suitable model for studying P2 receptor-mediated inflammation and pain signalling in dogs.
The agonist profile of ATP on DH82 cells demonstrated pharmacological similarities to the recombinant canine P2X4 receptor [41], as well as studies of endogenous P2X4 receptors in a human macrophage cell model [34]. BzATP induced partial Ca 2+ responses in DH82 cells with significantly lower potency compared to ATP, consistent with the recent report that BzATP is a partial agonist of recombinant canine P2X4 receptors [41]. In addition, the increased decay kinetics of Ca 2+ responses evoked by BzATP, compared to ATP, further supports a role for P2X4 receptors in the observed Ca 2+ responses [41]. TNP-ATP and paroxetine, two non-selective antagonists of P2X4 receptors [44], as well as 5-BDBD, a selective P2X4 receptor antagonist [58], had minor inhibitory effects on ATP-induced Ca 2+ responses in DH82 cells. Although it has recently been demonstrated that these antagonists can inhibit recombinant canine P2X4 receptors, the minor inhibition observed with these antagonists in DH82 cells were potentially in part due a lack of potency towards the canine P2X4 receptor [41], as well as the relatively low expression of P2X4 receptors in DH82 cells observed by immunocytochemistry. In contrast, ivermectin, the positive allosteric modulator which is routinely used to investigate P2X4 receptor activity [59], demonstrated strong potentiation of ATP-induced Ca 2+ responses and efficacy of ATP, with little effect on decay time. This data further supports the expression of functional P2X4 receptors in canine macrophages, however, it suggests that potentiation or upregulation of P2X4 receptors may first be required to observe notable responses. for 5 min. Cells were then exposed to (A) 10 µM ATP or (B) 10 µM UTP and Fura-2 fluorescence was recorded. Data shown are the mean ± SEM from five independent experiments. ** p < 0.01 and *** p < 0.001 compared to respective nucleotide alone, analysed using a one-way ANOVA with Bonferroni post hoc test.

Discussion
To date, the DH82 canine macrophage cell line has primarily been utilized as a model of viral and protozoan infection [23][24][25], such as for the study of canine distemper and its oncolytic potential [55][56][57]. Although studies have described the expression of functional P2 receptors in human or rodent macrophages and macrophage cell lines [8,10,11,34], studies directly investigating P2 receptors in canine macrophages have been absent. The current study described, for the first time, the expression and function of P2 receptors in DH82 cells, demonstrating a primary role for cell surface P2Y 2 receptors in nucleotide-mediated Ca 2+ mobilization through PLC/IP 3 signal transduction. This study also demonstrates a minor functional role for P2X4 receptors in DH82 cells, suggesting this cell line may present as a suitable model for studying P2 receptor-mediated inflammation and pain signalling in dogs.
The agonist profile of ATP on DH82 cells demonstrated pharmacological similarities to the recombinant canine P2X4 receptor [41], as well as studies of endogenous P2X4 receptors in a human macrophage cell model [34]. BzATP induced partial Ca 2+ responses in DH82 cells with significantly lower potency compared to ATP, consistent with the recent report that BzATP is a partial agonist of recombinant canine P2X4 receptors [41]. In addition, the increased decay kinetics of Ca 2+ responses evoked by BzATP, compared to ATP, further supports a role for P2X4 receptors in the observed Ca 2+ responses [41]. TNP-ATP and paroxetine, two non-selective antagonists of P2X4 receptors [44], as well as 5-BDBD, a selective P2X4 receptor antagonist [58], had minor inhibitory effects on ATP-induced Ca 2+ responses in DH82 cells. Although it has recently been demonstrated that these antagonists can inhibit recombinant canine P2X4 receptors, the minor inhibition observed with these antagonists in DH82 cells were potentially in part due a lack of potency towards the canine P2X4 receptor [41], as well as the relatively low expression of P2X4 receptors in DH82 cells observed by immunocytochemistry. In contrast, ivermectin, the positive allosteric modulator which is routinely used to investigate P2X4 receptor activity [59], demonstrated strong potentiation of ATP-induced Ca 2+ responses and efficacy of ATP, with little effect on decay time. This data further supports the expression of functional P2X4 receptors in canine macrophages, however, it suggests that potentiation or upregulation of P2X4 receptors may first be required to observe notable responses.
Consistent with the pharmacological profiles reported for the canine P2Y 2 receptor cloned from MDCK cells [49], both ATP and UTP induced robust Ca 2+ responses in DH82 cells with similar EC 50 values. These responses were observed even in the absence of extracellular Ca 2+ , consistent with the P2Y-mediated mobilization of intracellular Ca 2+ [60]. Similar to the current study with DH82 cells, other studies have also demonstrated that ADP is a low-potency agonist of the canine P2Y 2 receptor cloned from MDCK cells [49,61]. In addition, incubation of DH82 cells with BzATP revealed pharmacological similarities to that observed with human P2Y 2 receptors, where BzATP is ineffective at concentrations below 100 µM [33,62]. Collectively, this suggests that functional P2Y 2 receptors were responsible for nucleotide-induced Ca 2+ mobilization in DH82 cells. This was supported by inhibition observed in the presence of the P2Y 2 receptor antagonists, suramin and AR-C118925. Despite suramin lacking potency and selectivity, it remains a valuable tool in characterising P2Y receptor responses, as it is considered a low-potency antagonist of P2Y 2 receptors, but is relatively insensitive to P2Y 4 receptors [51,63]. This suggests that the ATP/UTP-sensitive P2Y 2 , but not P2Y 4 receptor, is responsible for the observed Ca 2+ mobilization, consistent with the expression of P2Y 2 receptors in DH82 cells determined by confocal microscopy. Notably, P2Y 2 receptor protein expression was greater than that of P2X4 receptor protein expression, with an opposite pattern observed for mRNA expression of these receptors. Reasons for this discrepancy remain unknown, but a lack of correlation between mRNA and protein expression is well documented and attributed to various contributing factors related to post-transcriptional and post-translational regulation of mRNA and protein expression [64].
A number of other canine P2Y receptors from MDCK cells have been cloned and characterised, including the P2Y 1 and P2Y 11 receptors [49,65,66], of which mRNA of both these receptors were detected in DH82 cells. The nucleotide agonist profile of canine P2Y 11 receptors differs markedly from the human P2Y 11 receptor, where ATP is a potent agonist of human, but not canine P2Y 11 receptors, and ADP and its analogue 2MeSADP are potent agonists of canine, but not human P2Y 11 receptors [66]. In the current study, it was revealed that ATP, but not ADP, was a moderately potent mediator of Ca 2+ responses in DH82 cells, while no such responses were observed with 2MeSADP. BzATP is also a full agonist of human P2Y 11 receptors [67], further suggesting that DH82 cells likely do not express functional P2Y 11 receptors. ADP and 2MeSADP have also been reported as potent agonists of the canine P2Y 1 receptor [68]. However, it was demonstrated in the current study that only ADP, but not 2MeSADP, induced a small Ca 2+ response in DH82 cells. Although this could suggest that DH82 cells express low amounts of functional P2Y 1 receptors, the complete lack of response to 2MeSADP suggests that P2Y 1 receptors are unlikely to be responsible for P2Y receptor-mediated Ca 2+ mobilisation in DH82 cells. Additionally, a complete lack of Ca 2+ response in DH82 cells incubated with the P2Y 6 receptor agonist, UDP [69,70], strongly suggests that DH82 cells do not express functional P2Y 6 receptors.
The current study demonstrated that nucleotide-mediated Ca 2+ mobilization in DH82 cells was also inhibited by antagonists of PLC and IP 3 receptors, U-73122 and 2-APB, respectively. This was consistent with previous studies that demonstrate coupling of P2Y 2 receptors to G q/11 and downstream signalling pathways in MDCK cells [49,65,71]. While 2-APB near completely inhibited Ca 2+ mobilisation, U-73122 only resulted in partial inhibition, although higher concentrations (>10 µM) have been shown to completely block P2Y 2 receptor-mediated Ca 2+ responses [72]. Notably, pre-incubation with P2Y 2 receptor antagonists resulted in approximately two-fold greater inhibition of UTP-induced Ca 2+ responses compared to ATP-induced responses, suggesting that ATP remained active at other receptors involved in mediating changes in intracellular Ca 2+ , such as P2X4 receptors, which are also relatively insensitive to suramin [73]. In addition, both ATP-and UTP-induced Ca 2+ responses could be completely inhibited by co-incubation with 5-BDBD and AR-C118925, supporting a role for both P2X4 and P2Y 2 receptors in DH82 cells.
Pro-monocytic and macrophage-like cell lines, such as human THP-1 cells, have recently proven useful models for studying endogenous purinergic signalling via P2X4 and P2Y 2 receptors [10,13,34]. However, studies have demonstrated that these cell lines can be polarised towards a more specialised macrophage phenotype, in which the expression of P2 receptors, such as P2X4 and P2X7 receptors, are commonly upregulated [34,38,74]. A study has recently demonstrated that DH82 canine macrophage cells could be polarised towards the M1 or M2a subtype through cytokine stimulation [20]. However, the DH82 cells utilised throughout this study remained unpolarised (M0) and, thus, it remains to be determined if cytokine stimulation influences P2 receptor expression or function. To this end, future studies could determine the purinergic signalling landscape of polarised DH82 cells. Future studies could also analyse P2 receptor expression and signalling in native canine macrophages. Given the known expression of P2X7 receptors on canine monocytes [29,30], canine monocyte-derived macrophages may provide a suitable candidate for the study of other purinergic receptors in native canine macrophages.
The upregulation of P2X4 receptors in macrophages and microglia has been highlighted as a key component in the signalling of inflammatory conditions, including chronic inflammatory and neuropathic pain [75,76], and remyelination of damaged nerves in the CNS [77]. P2X4 receptors, which reside primarily within lysosomes of macrophages, can be upregulated at the cell surface through lysosomal exocytosis [78]. This process plays a key role in Ca 2+ homeostasis, ATP release and local activation of cell surface purinergic receptors [79]. Notably, activation of the C-C chemokine receptor 2 (CCR2) by C-C chemokine ligand 2 (CCL2) is known to mediate lysosomal exocytosis [80], while in rat alveolar macrophages and human THP-1 cells it has been demonstrated that the activation of cell surface P2Y 2 receptors induces the upregulation and secretion of CCL2 [8,10]. Thus, it could be suggested that activation of macrophage P2Y 2 receptors results in a P2 receptor signalling feedback mechanism which results in an increase in Ca 2+ flux through upregulation of lysosomal exocytosis and trafficking of P2X4 receptors to the cell surface, leading to the release of prostaglandin E 2 and subsequent chronic inflammatory pain signalling [2]. These activated macrophages may also modulate microglial P2X4 receptors to control neuroinflammatory signalling following injury to the central nervous system [81]. Given the expression profile of these receptors in DH82 canine macrophages, this cell line may provide a suitable model for studying inflammatory pain signalling mechanisms of dogs in vitro, as well as for the pre-clinical testing of novel therapeutics targeting chronic pain.
Finally, although the sequence of P2X4 and P2Y 2 receptors in DH82 cells is yet to be determined, it remains of interest to identify novel single nucleotide polymorphisms should they exist in the genes encoding these receptors in dogs. A recent whole genome study of 582 dogs has revealed at least one missense variant (Ala9Asp) within the canine P2RX4 gene and two missense variants (Gly193Ser and Val375Ile) within the canine P2RY2 gene [82] (data accessed from the European Variation Archive; https://www.ebi.ac.uk/eva/). Whilst the effects of single nucleotide polymorphisms in the canine P2RX4 and P2RY2 genes are largely unknown, it has been demonstrated that single nucleotide polymorphisms of the genes encoding the human P2X4 and P2Y 2 receptors can alter receptor function [83,84]. Notably, in human macrophages, a 312Ser polymorphism of the P2Y 2 receptor has been demonstrated to alter secretion of CCL 2 following activation by UTP [10], suggesting a potential association with macrophage-mediated chronic inflammatory pain signalling. Despite this however, studies by our group have demonstrated that the canine P2RX4 and P2RX7 genes are much more conserved than their human counterparts [41,85,86] and, as such, naturally-occurring polymorphisms in the canine P2RY2 gene may also be rare or limited to uncommon breeds not frequently sampled in canine whole genome studies.
In conclusion, the current study demonstrates for the first time, that DH82 canine macrophages primarily express functional P2Y 2 receptors and low levels of functional P2X4 receptors. As such, DH82 cells provide the first canine macrophage cell line for the study of endogenous P2X4 and P2Y 2 receptors. The data presented here provides indirect evidence that P2X4 and P2Y 2 receptors play a role in mediating changes in intracellular Ca 2+ in canine macrophages in vivo. This mimics events observed in human and rodent macrophages and macrophage cell lines, where these P2 receptors have been suggested to play a key role in inflammation and chronic pain. Thus, DH82 cells may aid in the study of P2 receptor-mediated inflammation, including neuroinflammatory signalling processes, as well as preclinical screening of novel P2 receptor-targeting compounds for potential use in the treatment of inflammatory conditions, such as chronic pain in dogs.

RNA Isolation, cDNA Synthesis and RT-PCR
Total RNA was extracted from DH82 cells using the ISOLATE II RNA Mini Kit (Bioline, London, UK) according to manufacturer's instructions. cDNA was synthesised from RNA using the qScript cDNA SuperMix Kit (Quanta Biosciences, Gaithersburg, MD, USA) according to manufacturer's instructions. RT-PCR amplification of cDNA was carried out using the primer pairs and conditions listed in Table S1, the MangoTaq DNA polymerase kit (Bioline) and a Mastercycler Pro S (Eppendorf, Hamburg, Germany). PCR cycling consisted of initial denaturation at 95 • C for 2 min, followed by 35 cycles of denaturation at 95 • C for 30 s, annealing at 49-61 • C for 30 s and extension at 72 • C for 1 min. Amplicons were treated with ExoSAP-IT and loaded onto a 1% agarose gel and imaged using GelRed Nucleic Acid Gel Stain (Biotium, Fremont, CA, USA) and a Bio-Rad Molecular Imager Gel Doc XR+ (Hercules, CA, USA). Densitometry quantification was carried out using ImageJ [87] analysis software.

Measurement of Intracellular Ca 2+
Measurements of intracellular Ca 2+ were determined using Fura-2 AM as previously described [41]. Recordings were performed in extracellular Ca 2+ solution (ECS; 145 mM NaCl, 2 mM CaCl 2 , 1 mM MgCl 2 , 5 mM KCl, 13 mM glucose and 10 mM HEPES, pH 7.4) or in Ca 2+ free solution (145 mM NaCl, 1 mM MgCl 2 , 5 mM KCl, 13 mM glucose and 10 mM HEPES, pH 7.4) for recordings in absence of Ca 2+ . Cells were plated at 6 × 10 4 cells/well in poly-D -lysine-coated black-walled µClear bottom 96-well plates (Greiner Bio-One, Frickenheisen, Germany) and incubated at 37 • C/5% CO 2 for 18-24 h. Cells were washed in ECS then preincubated with Fura-2 AM loading buffer (2.5 µM Fura-2 AM/0.2% pluronic acid in ECS) in the dark for 30 min at 37 • C. Prior to recording fluorescence, excess Fura-2 was removed and cells were washed with ECS (or Ca 2+ free solution for recordings in absence of Ca 2+ ), then incubated for a further 20 min to allow for complete de-esterification. Fura-2 fluorescence emission at 510 nm was recorded every 5 s at 37 • C using a Flexstation3 (Molecular Devices, Sunnyvale, CA, USA) following excitation at 340 and 380 nm. Recordings were taken for 15 s prior to addition of compounds to establish baseline fluorescence then for 3-5 min after addition of agonists. Where indicated, cells were preincubated with antagonists for up to 30 min prior to addition of nucleotides. The relative change in intracellular Ca 2+ (∆Ca 2+ ) was calculated as ratio of Fura-2 fluorescence following excitation at 340 nm and 380 nm (F 340/380 ) was determined and normalized to the mean basal fluorescence according to the formula (1): where F is the F 340/380 at any given time and F rest is the mean fluorescence of the given well prior to the addition of nucleotides [88]. To investigate endogenous P2X and P2Y receptor-mediated Ca 2+ responses in DH82 canine macrophages, both the peak Ca 2+ response (F 340/380 ) and the net Ca 2+ movement (calculated as area under the curve using GraphPad Prism) were calculated and, where indicated, used for fitting concentration-response curves fit to the Hill equation using the least squares method. Decay time (τ, time constant) was calculated from the peak F 340/380 using the nonlinear regression one phase decay model for GraphPad Prism. Decay times were not calculated where no response to agonists was recorded. Where antagonist IC 50 was calculated against the approximate EC 80 of ATP or UTP, responses were normalized to the response in absence of antagonist to allow data to be fit to a curve.

Data and Statistical Analysis
All data were analysed using GraphPad Prism 5. Half-maximal effective and inhibitory concentrations (EC 50 and IC 50 , respectively) are expressed as their negative logarithm (pEC 50 /pIC 50 ) ± SEM. Data were compared using a two-tailed Student's t test or one-way ANOVA with Bonferroni post hoc test for single or multiple comparisons, respectively. Multiple comparisons involving two interdependent variables were analysed using a two-way ANOVA with Bonferroni post hoc test. Throughout this study p < 0.05 was considered statistically significant.

Nomenclature of Targets and Ligands
All targets and ligands used throughout this manuscript conform with the guidelines outlined by the International Union of Basic and Clinical Pharmacology and British Pharmacological Society (IUPHAR/BPS) Guide to Pharmacology [40,89].

Acknowledgments:
We thank the staff of the Technical Services Unit of the Illawarra Health and Medical Research Institute for technical assistance.

Conflicts of Interest:
The authors declare no conflict of interest. The funders had no role in the design of the study; in the collection, analyses, or interpretation of data; in the writing of the manuscript; or in the decision to publish the results. C-C chemokine receptor 2 DMSO Dimethyl sulfoxide EC 50 Half maximal effective concentration EGTA Ethylene glycol tetraacetic acid FBS Fetal Bovine Serum IC 50 Half-maximal inhibitory concentration IL Interleukin IP 3 Inositol