Erythropoietin enhances Kupffer cell number and activity in the challenged liver

Erythropoietin (EPO) is the main hormone driving mammalian erythropoiesis, with activity mediated via the surface receptor, EPO-R, on erythroid progenitor cells. Recombinant human EPO is currently used clinically for the treatment of anemia in patients with end-stage renal disease, and in certain cancer patients suffering from anemia induced either by the tumor itself or by chemotherapy. EPO-R expression is also detected in non-erythroid cells, including macrophages present in the peritoneum, spleen, and bone marrow (BM). Here we demonstrate that Kupffer cells (KCs) - the liver-resident macrophages - are EPO targets. We show that, in vitro, EPO initiated intracellular signalling and enhanced phagocytosis in a rat KC line (RKC-2) and in sorted KCs. Moreover, continuous EPO administration in mice, resulted in an increased number of KCs, up-regulation of liver EPO-R expression and ﻿﻿﻿elevated﻿ production of the monocyte chemoattractant CCL2, with corresponding egress of Ly6Chi monocytes from the BM. In a model of acute acetaminophen-induced liver injury, EPO administration increased the recruitment of Ly6Chi monocytes and neutrophils to the liver. Taken together, our results reveal a new role for EPO in stimulating KC proliferation and phagocytosis, and in recruiting Ly6Chi monocytes in response to liver injury.

as determined by quantitative analysis of the fluorescent fields and flow cytometry, respectively. This was further confirmed in sorted KCs, where EPO increased the phagocytosis of microbeads by 2-fold (p < 0.01) (Fig. 2C). Similarly, EPO augmented RKC-2 cell phagocytosis of CFSE-labeled heat killed E. coli, as detected by fluorescence microscopy (Fig. 2D) and flow cytometry (Fig. 2E), by 340% increase (p < 0.01) and 13% increase (p < 0.01), respectively. Our results thus indicate that KCs are direct targets of EPO and that treatment with EPO enhances their phagocytic ability.

EPO increases liver KC number and liver EPO-R gene expression. We next investigated in vivo,
the effect of EPO on liver KCs. Livers from C75BL/6 J mice injected with diluent or EPO (3 injections of 180 U EPO on alternating days) were harvested (Fig. 3A). There was an EPO-associated increase in the levels of EPO-R mRNA in total liver and a tendency to increased EPO-R mRNA levels in the non-parenchymal cell fraction (Fig. 3B). Among these non-parenchymal cells, sorted KCs from EPO-injected mice tended to have higher EPO-R gene expression than their counterparts from diluent-injected mice (Fig. 3B). This EPO-associated increase in vivo was in line with our findings in the RKC-2 cells (Fig. 1A). Notably, EPO-R expression in Ly6C hi and Ly6C lo monocytes (CD45 + /CD11b hi /F4/80 −/lo /CD64 lo /Ly6C hi or Ly6C lo , respectively), which were sorted from untreated livers, as well as in BMDM (positive control), was profoundly lower than in KCs (Fig. 3B).
Immunofluorescence staining for the KC-associated macrophage marker F4/80 revealed a 2-fold (p < 0.01) increase in the number of KCs following EPO treatment (Fig. 3C). Flow cytometry analysis further confirmed a 33% increase (p < 0.05) in KC number normalized for tissue mass in the livers of the EPO-treated mice compared to diluent-treated mice (Fig. 3D). Of note, the numbers of hepatic lymphocytes, defined as CD45 + /CD11b − cells, were not affected by EPO administration (Fig. 3D). Similar EPO-governed effects were also observed in Tg6 mice that are genetically modified to constitutively overexpress EPO in an oxygen-independent manner 40,41 . On the next day, DAPI-labeled RKC-2 cells were incubated ±10 U/ml EPO for 30 min, followed by 30 min incubation with fluorescently labeled polystyrene microbeads (green). Rhodamine phalloidin (red) and DAPI (blue) label actin and nuclei, respectively. The graph represents quantification of phagocytosed beads (mean ± SEM), N = 6, **p < 0.01. Bar = 50 µm. (B) Cells were treated ± EPO as in (A) and analyzed by flow cytometry for uptake of fluorescent beads (representative histogram). Grey and black represent control and EPO-treated cells, respectively. The graph depicts the fold increase in MFI reflecting the phagocytosis by cells treated with EPO compared to saline-treated cells (control, considered as 1). Results are mean ± SEM, N = 5, **p < 0.01. (C) 100,000 sorted KCs (CD45 + /F4/80 hi /CD11b lo ) were treated as described in (A). Phagocytosis by EPO-treated cells was normalized to control (considered as 1). Results are mean ± SEM, N = 5, **p < 0.01. (D) 2.5 × 10 6 RKC-2 cells were cultured for 24 h. On the next day, DAPI-labeled RKC-2 cells were incubated ±10U/ml EPO for 30 min followed by 1 h incubation with 4 × 10 7 CFSE-labeled E. coli (green). Rhodamine phalloidin (red) and DAPI (blue) label actin and nuclei, respectively. The graph represents a quantification of phagocytosed CFSE labeled E. coli (mean ± SEM), N = 5, **p < 0.01, Bar = 25 µm. (E) Cells were treated ± EPO as in (D) and analyzed by flow cytometry to assay the uptake of CFSE-labeled E. coli (representative histogram). Grey and black represent control and EPO-treated cells, respectively. The graph depicts the MFI fold increase reflecting the phagocytosis of cells treated with EPO compared to saline-treated cells (control, considered as 1). Results are mean ± SEM, N = 6, **p < 0.01. Accordingly, we observed an approximately 3-fold increase (p < 0.01) in KC levels in Tg6 mice compared to their wild type littermates (Fig. 3E). KCs are normally considered a self-sustaining population that is independent of adult BM hematopoiesis 39,[42][43][44] . To examine whether the EPO-induced increase in KCs results from local cell proliferation, we analyzed their expression of the Ki67 marker of active proliferation as previously reported 39 . Flow cytometry revealed a 56% increase (p < 0.05) in Ki67 + KCs following EPO administration (Fig. 3F), supporting the premise that EPO increases proliferation of KCs in vivo. These findings are in line with the EPO-associated increase in liver weight measured in EPO-treated mice compared to diluent-treated mice (10% increase, p < 0.01) (Fig. 3G).
We next sought to study whether the EPO-mediated increase in KC number is driven by a direct intrinsic cellular mechanism in these cells. An EPO-R-deficiency in the myeloid lineage was obtained by generating LysM cre -Epor fl/fl mice. In the liver of these mice, Cre expression driven by the M lysozyme (LysM) promoter mainly affects KCs 45 , though other myeloid cells including macrophages in other tissues are also targeted. While total liver cells from LysM cre -Epor fl/fl mice did not exhibit a significant change in Epor gene expression levels compared to total liver cells from the relevant controls (Epor fl/fl mice), KCs sorted from these mice displayed a 73% decrease (p < 0.01) in Epor transcript levels (Fig. 4A). EPO significantly increased the number of KCs in the control Epor fl/fl mice, but had no effect on KC numbers in the LysM cre -Epor fl/fl mice (Fig. 4B). These results suggest that direct EPO signalling can instruct KC proliferation. However, we cannot exclude the possibility that EPO signalling in other myeloid cells may also contribute to the increased proliferation of KCs.
EPO increases CCL2-mediated recruitment of Ly6C hi monocytes to the injured liver. Following liver injury, liver resident cells including KCs initiate an innate immune response by releasing chemokines such as CCL2, which attracts Ly6C hi monocytes 39,[46][47][48] . Specifically following challenge with stressed erythrocytes, KCs up-regulate CCL2 expression 25 . EPO treatment induced a 1.5-fold increase (p < 0.01) in serum CCL2 (Fig. 5A), which was also significantly higher (p < 0.05) in constitutively EPO-overexpressing Tg6 mice compared to their wild type counterparts (Fig. 5B). Cells extracted from total livers of EPO treated mice displayed a 3.7-fold-increase (p < 0.01) in the levels of CCL2 transcripts (Fig. 5C). A breakdown analysis of CCL2 transcripts in the livers of EPO-injected mice revealed a 1.43-fold-increase (p = 0.06) in non-parenchymal cells, and a 1.82-fold increase (p < 0.05) in sorted KCs, compared to their control counterparts (Fig. 5C). Moreover, both RKC-2 cells and enriched KC cultures (95% positive for F4/80, see Fig. S1) treated with EPO in vitro, showed a significant elevation of CCL2 transcripts compared to diluent-treated cells (Fig. 5D). Importantly, while LysM cre -Epor fl/fl mice did not display an EPO-driven increase in the levels of serum CCL2 (Fig. 5E) and CCL2 transcripts in sorted KCs (Fig. 5F), they still exhibited an increase in the levels of CCL2 transcripts in total liver cells ( Fig. 5F). Thus, EPO may induce CCL2 production by other EPO-R-expressing liver cells, such as hepatocytes. Collectively, these findings strongly endorse a central role for EPO in the promotion of KC-governed CCL2 production.
Egress of Ly6C hi monocytes from the BM to the circulation is known to be mediated by CCR2 49 . As expected from its positive effect on CCL2 expression, EPO administration led to an 8-fold (p < 0.05) decrease in the levels of CD45 + CD11b + CSF1R(CD115) + /Ly6C hi monocytes in the BM (Fig. 5G), while the numbers of their mature descendants in the blood were increased by 1.7-fold (p < 0.05) (Fig. 5H). Interestingly, EPO treatment had no effect on the expression of other chemokines such as CCL5, CCL8, and CXCL2, although there was a marked reduction in the fractalkine chemokine CX 3 CL1, and an increase in the expression of the neutrophil chemoattractant CXCL1 (Fig. S2). Furthermore, livers from EPO-treated mice exhibited elevated expression of the genes encoding for EPO and the anti-inflammatory cytokines IL-10 and TGFβ, with unchanged expression of the pro-inflammatory mediators IFNγ and nitric oxide synthase 2 (NOS2) (Fig. S2). To study whether these genes are expressed by KCs, we revisited our gene expression database of sorted KCs from steady state livers 39 . To establish the background expression level, their gene expression was compared with that of adiponectin (Adipoq), which is uniquely expressed by adipocytes. The gene expression of C-type lectin domain family 4 member F (Clec4f), previously defined as a KC specific marker 44 , was used as a positive control. KCs exhibited clear expression of the genes encoding for IL-10, TGFβ1, CCL2, and CXCL1, as well as EPO-R, while they were negative for EPO and CX 3 CL1 (Fig. S2).
We next examined the effect of EPO on the active recruitment of monocytes to the liver in a well-characterized murine model of AILI, induced by an overdose of N-acetyl-p-aminophenol (APAP) 39 . In this model, Ly6C hi monocytes massively infiltrate the injured liver during the necro-inflammatory phase (first 24 h) to become the dominant mononuclear phagocyte subset in the tissue 39 . Mice were treated with EPO or saline 24 h before APAP administration and then together with the APAP treatment. The impact of EPO treatment on liver infiltration of Ly6C hi monocytes was analyzed 24 h after APAP challenge (24 h APAP), as this is the time at which they reach maximum accumulation 39 . Livers were also evaluated 48 h following APAP challenge, when Ly6C hi monocytes are still present in the liver and differentiation towards Ly6C lo macrophages is not yet complete 39 . In this "48 h APAP" group, an additional EPO or saline treatment was administrated 24 h after the APAP injection. CD11b + / CD11b − cell ratio basically indicates the distribution of phagocytes and lymphoid cells. Treatment with EPO led to a 72% and 44% increase (p < 0.01 and p < 0.05, respectively) in phagocyte/lymphoid cell ratio in the liver, at 24 and 48 h following APAP injection, respectively (Fig. 6A). These results are coupled with the lack of EPO effect on the lymphocyte population (Fig. 3D). Treatment with EPO led to a 37% increase (p < 0.05) and 54% increase (p < 0.05) in Ly6C hi monocyte levels (defined as CD45 + CD11b + Ly6C hi F4/80 lo CD64 lo CX 3 CR1 + MHCII lo ) in the liver, at 24 and 48 h after APAP injection, respectively (Fig. 6C). Serum levels of CCL2 were similarly high at 24 h post APAP, which may be expected given that this is the time of peak induction following AILI 39 . Notably, EPO treatment maintained higher levels of CCL2 [2-fold increase] in the serum at 48 h, when it was already reduced in the control group (Fig. 6B). We have recently demonstrated a spatial and temporal overlap in the migration pattern of liver infiltrating Ly6C hi monocytes and neutrophils following AILI 50 . Given the increased expression of the neutrophil chemoattractant CXCL1 in EPO treated livers (Fig. S2), and the observation that KCs express this chemokine (Fig. S2), we next followed the effect of EPO treatment on neutrophil recruitment to the injured liver. Indeed, flow cytometry analysis revealed a significantly higher infiltration of neutrophils (defined as CD45 + CD11b + Ly6C lo F4/80 -CD64 -C X 3 CR1 -) at 24 h following AILI (Fig. 6C). Moreover, KCs exhibited increased production of CXCL1 transcripts in response to direct EPO treatment (Fig. S2), suggesting that KC-EPO axis may be involved in the attraction of neutrophils to the injured liver. Nevertheless, CXCL1 gene expression levels were significantly up-regulated in EPO-treated LysM cre -Epor fl/fl mice (Fig. S2), suggesting that EPO-governed signalling in myeloid cells, and in particular KCs, is not solely responsible for the elevated expression of this neutrophil chemoattractant. Collectively, these results support a role for EPO in promoting KC-mediated recruitment of Ly6C hi monocytes and neutrophils in response to liver injury.

Discussion
While the main classical role of EPO is considered to be the regulation of red blood cell production, non-erythroid effects of EPO have been repeatedly reported [7][8][9][10][11][12][13][14][15] . These findings underline the importance of investigating the global actions of rHuEPO and its derivatives in pre-clinical and clinical settings. The goal is to maximize benefits, while reducing harm. One of the non-erythroid targets of EPO is the immune system. Work with mouse models and clinical studies 51-53 , including our own 27, 54-59 , have concluded that EPO treatment modulates immunological functions. As an example, EPO enhanced BMDM phagocytic activity and nitric oxide secretion in mice, and led to augmented IL-12 secretion and decreased IL-10 secretion in response to lipopolysaccharide 27 . Moreover, dendritic cells derived from rat BM responded to EPO stimulation with increased expression of dendritic cell activation markers and a higher allostimulatory capacity for T cells 51 . In chronic renal failure patients, who did not require hemodialysis, administration of rHuEPO stimulated rejuvenation of cellular CD8 + T-dependent immunity 53 . Importantly, we 29, 54-56, 58, 60 and others 61,62 have linked EPO administration to prolonged survival and improved immunological functions in multiple myeloma (MM) mouse models and MM patients. Moreover, EPO treatment in hematologic patients improved the response to influenza vaccination 63 and normalized the levels of impaired CD4 + and CD8 + T cell and CD4 + CD25 + cell numbers in low risk myelodysplastic syndrome patients (MDS) 64 .
KCs, the resident tissue macrophages of the liver, play a central role in the pathogenesis and resolution of various liver diseases 65 . We 27, 57, 59 and others 26 have found functional EPO-R on macrophages derived from BM, peritoneum and spleen. By data mining in a gene expression database of steady state KCs 39 , we show here that these cells express EPO-R at the gene level. This has previously been shown for rat KCs 66 . Nevertheless, it was not yet clear whether this receptor is functional and the nature of the effect of EPO on KC immunity remained elusive. Here we demonstrate for the first time that KCs express a functional EPO-R, which activates downstream signalling in response to EPO, to regulate KC number and function. We also show that EPO promotes KC-mediated Ly6C hi monocyte and neutrophil recruitment to the challenged liver via production of CCL2 and CXCL1, respectively.
Being strategically positioned in the liver, KCs are characteristically involved in the phagocytosis of debris, pathogens, and apoptotic, damaged or senescent cells (including erythrocytes) [67][68][69] . They display high phagocytic and lysosomal activities, which relate to their specialization in filtering blood that enters the sinusoids. Thus, they are considered to play a key role in immune surveillance, iron metabolism, and detoxification in the liver. Our results demonstrate that treatment with EPO elicits EPO-R downstream signalling in cultured KCs and increases the capacity of cultured and sorted primary KCs to phagocytose. Therefore, EPO may directly license the ability of KCs to reduce any excess of red blood cells in the liver after its administration. This is also in line with a previous report indicating that peritoneal macrophages from EPO-treated mice, display enhanced apoptotic cell clearance through the peroxisome proliferator activated receptor-γ (PPARγ) 26,37,38 as well as increased removal of debris 37 .
Under homeostatic conditions, KCs are replenished by a self-renewal process that is independent of adult BM hematopoiesis 39, 42-44 . Our results indicate that the increase in KCs following EPO administration in vivo is mediated, at least in part, by their local proliferation. Emerging evidence indicates that macrophage niche availability restricts tissue resident macrophage self-maintenance capacity 70 . The expansion in liver tissue mass following EPO treatment that we report here, may be accompanied by the inauguration of new macrophage niches that are then available for the arrival of de-novo KCs generated by self-proliferation of the already existing resident KC population. This is supported by our observation that the EPO-driven increase in KC levels is abrogated in LysM cre Epor fl/fl mice, where EPO-R-deficiency is targeted to myeloid cells. KCs are the main myeloid resident cell population in the normal liver 45 , and they exhibit a 73% reduction in EPO-R expression in the LysM cre Epor fl/ fl mice. These results thus suggest that EPO can directly instruct KC proliferation; although we cannot exclude an alternative possibility that EPO indirectly affects KC expansion. Under certain circumstances in which resident macrophage niches are open, circulating Ly6C hi monocytes can also differentiate into self-maintaining tissue-resident macrophages that resemble their embryonic counterparts 70 . Indeed, in cases when the KC pool is diminished such as following lethal irradiation or diphtheria toxin induced ablation 44 , or more physiologically, following Listeria monocytogenes-induced KC necroptosis 71 , Ly6C hi monocytes are capable of reconstituting the KC compartment. Our results, demonstrating that EPO mediates the egress of Ly6C hi monocytes from the BM to the circulation, suggest that these cells may also contribute to the expansion of KC population.
Prolonged EPO administration, as is often prescribed in clinical conditions such as anemia, may pose a challenge to the liver. Our results suggest that in such a scenario, activation of the EPO/EPO-R axis in KCs induces their proliferation and phagocytic activity, and thus licenses them to clear damaged and stressed red blood cells. Further substantiating this argument, are the results showing that EPO stimulates CCL2 production in KCs, and promotes the egress of Ly6C hi monocytes from the BM to the circulation. It has been recently shown in a mouse model of hemolytic anemia, that CCL2-dependent Ly6C hi monocyte recruitment to the liver is important for the clearance of senescent and dying erythrocytes, and protection from iron toxicity 25 . Therefore, EPO-mediated up-regulation of CCL2 production by KCs may be an additional pathway participating in the clearance of excess erythrocytes in the liver.
The EPO mediated in vivo increase in serum and liver CCL2 (protein and transcripts, respectively), and the absence of this EPO-driven phenotype in KCs isolated from LysM cre -Epor fl/fl mice, strongly suggest that activation of EPO-R in KCs contributes to this EPO mediated response. It should be noted that in LysM cre mice, Cre-mediated deletion, specificity and efficiency is mainly restricted to macrophages, monocytes and neutrophils with little effect on other immune cells such as T cells, B cells, NK cells, eosinophils, dendritic cells, and mast cells 72 . Indeed, the depletion of EPO-R in the KC compartment, but not in total liver preparations from LysM cre -Epor fl/fl mice, indicates that EPO-R is mainly restricted to KCs. In addition, we show that monocytes have significantly less EPO-R than KCs and although we could not directly examine the expression of a functional EPO-R in sorted neutrophils due to their poor viability following isolation, a previous study has indicated that extended EPO administration has no effect on neutrophil pools in vivo 73 . Moreover, neutrophils were profoundly outnumbered by KCs in the liver following EPO treatment (Data not shown). We provide a direct evidence for the existence of an EPO-KCs-CCL2 axis. First, EPO treatment stimulated CCL2 production in a Kupffer cell line as well as in enriched cultured primary KCs. Second; the EPO-mediated increase in CCL2 transcripts was abrogated in KCs sorted from LysM cre -Epor fl/fl mice and not in KCs from the control mice. Nevertheless, we cannot negate the participation of other cells in the liver that can produce monocyte and neutrophil attracting chemokines. This is especially true for hepatocytes, which are a prominent source for specific chemokines such as CCL2 under various challenging conditions 74 . As hepatocytes also express a functional EPO-R 66, 75 they may contribute to the EPO driven increase in total liver CCL2 transcripts and serum CCL2. In support of this, we show that the EPO driven increase in CCL2 gene expression is maintained in the livers of LysM cre -Epor fl/fl mice, whose KCs lack EPO-R expression. Therefore, EPO may favor hepatocyte-mediated recruitment of Ly6C hi monocytes to the challenged liver.
We show that EPO transcripts are elevated in the liver following systemic EPO treatment, although the mechanism of action and the nature of the cells that mediate this response remain elusive. Notably, extra-renal EPO production has been demonstrated in resident liver cells including hepatocytes and perisinusoidal Ito cells 44 , and was shown to increase following an acute-phase response in a rat model 46 . Local elevation in EPO levels has been documented in various liver pathologies, including AILI, and iron loading may perpetuate hepatic damage and compromise healing 76, 77 . Moreover, EPO has been suggested to play a protective role in the resolution of liver injury [16][17][18] . Hepatic infiltration of Ly6C hi monocytes was reported in various acute or chronic liver injuries 39,[78][79][80][81] and we have previously shown that Ly6C hi monocytes in the liver give rise to pro-restorative ephemeral macrophages during AILI 39 . This is in accordance with our results here showing that the administration of EPO in an acute model of AILI maintains high levels of CCL2 in the serum and promotes the downstream recruitment of Ly6C hi monocytes to the liver. Since KCs are also pivotal players in the recovery from AILI 82 , the role of EPO in liver resolution may therefore be through stimulation of KC proliferation, phagocytosis and recruitment of Ly6C hi monocytes. Interestingly, neutrophil recruitment to the injured liver was also significantly augmented by EPO treatment at 24 h following APAP. The CXCL1 neutrophil chemoattractant was elevated in response to a week of EPO treatment in steady state mice. Notably, we show that KCs express elevated CXCL1 transcripts in response to EPO, raising the possibility that these cells also drive neutrophil mobilization in response to EPO. However, the observation that EPO also increased the levels of CXCL1 transcripts in the liver of LysM cre -Epor fl/ fl mice, suggests that EPO-responsive cells other than KCs may produce CXCL1. Hepatocytes have been shown to express a functional EPO-R 66,75 and these cells may be candidates to mobilize neutrophils from the BM via their release of CXCL1 83 . In conclusion, we report a novel function of EPO associated with the regulation of KC number and function in the liver.

Materials and Methods
Mice. Female C57BL/6J-OlaHsd mice (8-12-weeks old) were purchased from Envigo Laboratories (Israel, formerly Harlan Laboratories). Mice were injected subcutaneously (s.c.) three times (every other day during 1 week) with 180 U rHuEPO (EPO, Epoetin α, Eprex ® , Janssen), with diluent (saline) as previously described 27  Kupffer cells enrichment ex vivo. KCs were separated from hepatocytes and other sinusoidal cells by gradient centrifugation. Specifically, mice were perfused with 30 ml of cold PBS and the liver was excised. Livers were cut into small fragments, incubated with mixing (37 °C, 250 rpm for 45 min) with 5 ml digestion buffer [5% FCS, 0.5 mg/ml collagenase IV (Sigma-Aldrich, Rehovot, Israel, C5138-500MG) in PBS] and filtered through 200 μM wire mesh. Cells were suspended in 5 ml RPMI 1640 and centrifuged at 300 g for 5 min at 4 °C, then the top aqueous phase was discarded. The cell sediments were resuspended in 10 ml RPMI 1640 and centrifuged at 50 g for 3 min at 4 °C. The top aqueous phase (cleared cell suspension) was transferred into a new 10 ml centrifuge tube and centrifuged at 300 g for 5 min at 4 °C, then the top aqueous phase was discarded, and the cell sediments were reserved. The cell sediments mainly contained non-parenchymal cells of the liver including KCs, sinusoidal endothelial cells, and satellite cells. Selective adherence to plastic as described by Blomhoff et al. 84 was used to purify this cell population further. The cells were then seeded into 10 cm plates in DMEM containing 10% FBS, 1% L-Glutamine (L-Glu) and 0.1% Penicillin Streptomycin (PS), and incubated for 1 h in a 5% CO 2 atmosphere at 37 °C. Non-adherent cells were then removed from the dish by gently washing with PBS, to leave the adherent KCs. Cells were grown for 7-10 days in culture until they displayed morphologic features typical of macrophages.
Erythropoietin (EPO). GMP-manufactured sterile syringes containing rHuEPO (Epoetin alfa, Eprex ® ) as used for patient care, were kindly provided by Janssen Cilag, Israel, and employed throughout this study, thus ensuring the absence of toxins in the rHuEPO preparation. APAP administration. Mice were fasted overnight for 12 h prior to administration of diluent (saline) or 300 mg/kg APAP (CAT# 7085, SIGMA) by intraperitoneal injection (i.p). Drinking water was provided at the same time as APAP administration and access to food was restored 2 h later.
Surface EPO-R expression. Rat RKC-2 cells (1 × 10 5 cells) were incubated in 6-well plates and stimulated in the presence or absence of EPO 5 U/ml. After 24 h, the cells were collected and labeled with anti EPO-R antibody (GM1202, Aldevron, Freiburg 31 ), followed by FITC conjugated Goat anti mouse antibody (Jackson ImmunoResearch, CAT#115-0095-003). The stained cells were examined by Gallios TM Flow cytometer and analyzed using Kaluza Analysis Software (Beckman Coulter, Nyon Switzerland).
PhosphoFlow of RKC-2 cell line. RKC-2 cells were starved for 1 h and aliquoted to Eppendorf tubes (10 6 cells/ 90 µl RPMI 1640). They were then incubated (37 °C, 5 min) followed by activation with 10 U/ml EPO for 0, 10, and 30 min. The reaction was stopped with 10 µL of 37% formalin, giving a final concentration of 3.7% formalin. Cells were incubated for 1 min at 37 °C, and then cooled on ice for 5 min and centrifuged (3,000 rpm for 2 min). After this, the cells were washed once with 1% BSA/PBS and centrifuged (3,000 rpm for 2 min). Staining for the intracellular proteins [(PE eFluor 610 pSTAT5 (eBioscience 61-9010-42) and p-ERK (sc-7383) followed by an FITC conjugated Goat anti-mouse antibody] was done in Saponin (Invitrogen) 1%BSA/PBS. The cells were incubated for 1 h in the dark at room temperature and then centrifuged and resuspended in Flow buffer. The stained cells were examined by Gallios TM Flow cytometer and analyzed using Kaluza Analysis Software (Beckman Coulter, Nyon Switzerland).
Macrophage phagocytosis of fluorescently labelled E. coli or fluorescently labelled beads. 2 × 10 5 RKC-2 cells were seeded in 60 mm plates overnight at 37 °C to allow cell adhesion. The next day, E. coli (strain BL21) were heat killed by incubation at 65 °C for 1 h and washed twice with PBS. They were then labelled with CFSE [M CFDA (Molecular Probes)] for 15 min at room temperature and washed thoroughly in PBS. RKC-2 cells were incubated ±10 U/ml EPO followed by stimulation with CFSE-labeled E coli (40 million cells) or fluorescently labeled beads diluted 1:800 (Fluoresbrite TM Plain YG 1.0 Micron Microspheres, CAT#17154, Polysciences Inc) for the indicated concentrations and time points. Free bacteria that had not been phagocytosed by RKC-2 cells were washed away. Cells were aliquoted to FACS tubes and analyzed on a Gallios TM Flow Cytometer (Beckman Coulter). Similarly, 1 × 10 5 sorted KCs (CD45 + /F4/80 hi /CD11b lo ) were cultured in 6-well plates for 24 h. On the next day, the cells were incubated ±10 U/ml EPO for 30 min, followed by 30 min incubation with fluorescently labeled polystyrene microbeads. Cells were analyzed by flow cytometry for uptake of fluorescent beads.
Immunofluorescence assay. RKC-2 cells (10 5 cells in 500 µl per well in 24 well plates) were treated with EPO and E. coli or beads (as described above) then washed three times with PBS and fixed in 4% paraformaldehyde diluted in PBS for 30 min at room temperature. The cells were then washed three times with PBS, perforated by incubation in quenching buffer (0.1% Triton × 100, 2% BSA, 5% FBS in PBS) for 15 min at room temperature, and stained with Rhodamine-phalloidin according to manufacturer's instructions (Molecular Probes). Cells were mounted on slides using Fluorescent Mounting Medium with DAPI (GBI Labs, WA, USA) and were visualized using a Leica SP5 microscope, (Buffalo Grove, IL, NA), lens × 63. Images were captured and analyzed using LAS LF lite software.

Isolation of hepatic non-parenchymal cells for flow cytometry and sorting.
Mice were perfused with 30 ml of cold PBS and the liver was excised. Livers were cut into small fragments, incubated (37 °C, 250 rpm for 45 min) with 5 ml digestion buffer [5% FCS, 0.5 mg/ml collagenase IV (Sigma-Aldrich, Rehovot, Israel, C5138-500MG) in PBS] and filtered through 200 μM wire mesh. This was followed by three cycles of washings with PBS at 400 rpm, 4 °C, 5 min, harvesting the supernatant and discarding the parenchymal cell pellet. The supernatant was centrifuged at 1500 rpm, 4 °C, 5 min and the erythrocytes in the cell pellet were lysed by a 2 min incubation with ACK Lysing buffer (Quality Biological, CAT# 118-156-721).