Abstract
Hereditary hemochromatosis and iron imbalance are associated with susceptibility to bacterial infection; however, the underlying mechanisms are poorly understood. Here, we performed in vivo bacterial infection screening using several mouse models of hemochromatosis, including Hfe (Hfe−/−), hemojuvelin (Hjv−/−), and macrophage-specific ferroportin-1 (Fpn1fl/fl;LysM-Cre+) knockout mice. We found that Hjv−/− mice, but not Hfe−/− or Fpn1fl/fl;LysM-Cre+ mice, are highly susceptible to peritoneal infection by both Gram-negative and Gram-positive bacteria. Interestingly, phagocytic cells in the peritoneum of Hjv−/− mice have reduced bacterial clearance, IFN-γ secretion, and nitric oxide production; in contrast, both cell migration and phagocytosis are normal. Expressing Hjv in RAW264.7 cells increased the level of phosphorylated Stat1 and nitric oxide production. Moreover, macrophage-specific Hjv knockout mice are susceptible to bacterial infection. Finally, we found that Hjv facilitates the secretion of IFN-γ via the IL-12/Jak2/Stat4 signaling pathway. Together, these findings reveal a novel protective role of Hjv in the early stages of antimicrobial defense.
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Introduction
In the 1960s, researchers first suggested a link between iron metabolism and the immune system [1]. Since then, many iron-related genes have been found to play a role in immune function. For example, the proteins lactoferrin, hepcidin, and Hfe have all been found to modulate the host defense against bacterial infection [2–6]. Moreover, the expression of several genes involved in iron metabolism, including hemojuvelin (HJV) [7], hepcidin (HAMP) [8], and ferroportin1 (FPN1) [9, 10], are modulated during inflammation. Interestingly, a recent case report described a patient with hemochromatosis who died from bacterial infection [11]. These findings prompted us to investigate the putative role of hemochromatosis-related genes in bacterial infection. We therefore screened several hemochromatosis mouse models for their immune phenotype and susceptibility to bacterial infection.
HJV is a bone morphogenetic protein (BMP) co-receptor that regulates the expression of hepcidin [12]. In humans, mutations in the HJV gene cause juvenile hemochromatosis [13]. In mice, deleting Hjv expression causes a similar iron-overload phenotype [7, 14]. HJV is also a member of the repulsive guidance molecule (RGM) family [15]. However, the role of HJV in the immune response is currently unknown. Recent studies suggest that two other RGM family members—RGMa and RGMb—play a role in immune regulation. For example, RGMa is found in bone marrow-derived dendritic cells, where it modulates T cell responses [16]. RGMb is strongly expressed in macrophages, and increased IL-6 levels were measured in macrophages isolated from Rgmb-knockout mice [17]. Notably, the Hjv gene (also known as RGMc) is also expressed in macrophages [17], and studies suggest that lipopolysaccharide (LPS) stimulation induces organ-specific patterns of Hjv expression [7]. However, whether Hjv plays a role in the immune system’s response to bacterial infection is currently unknown. Here, we used an acute infection mouse model to investigate the potential immunomodulatory roles of hemochromatosis genes. Our results indicate that Hjv plays a major role in mediating the host innate immune response to bacterial infection.
Results
Hjv-knockout mice have increased susceptibility to bacterial infection
To investigate the function of hemochromatosis-related genes in response to acute bacterial infection, we administered an intraperitoneal (i.p.) injection of a lethal dose of the Gram-negative bacterium Salmonella typhimurium (S. typhimurium) [5, 18 ] to the following hemochromatosis mouse models: Hfe-knockout (Hfe−/−) mice (Figure 1a), hemojuvelin-knockout (Hjv−/−) mice (Figure 1b), and macrophage-specific ferroportin1-knockout (Fpn1fl/fl;LysM-Cre+) mice (Figure 1c). Although all three models are reported to develop systemic iron overload [9], only the Hjv−/− mice were highly susceptible to S. typhimurium infection, reaching 100% mortality within 20 h of infection.
Two factors may contribute to the high sensitivity of Hjv−/− mice to bacterial infection. First, of these three models of hemochromatosis, Hjv−/− mice develop the most severe form of iron overload; second, Hjv−/− mice have the lowest basal hepcidin levels. With respect to the first factor, iron overload has been shown to facilitate bacterial proliferation [19, 20]. Consistent with this finding, the Hjv−/− mice had significantly more bacteria in the major organs and peritoneal fluid compared with wild-type mice (Figure 1d). In order to reduce the tissue iron burden in Hjv−/− mice to wild-type levels, we fed 4-week-old Hjv−/− mice an iron-deficient (ID) diet for four weeks producing Hjv−/−-ID mice, which had comparable iron contents compared with wild-type mice (Supplementary Figures S1A and C). Injecting Escherichia coli into both Hjv−/− and Hjv−/−-ID mice caused high mortality (Figure 1e). Given its relatively higher safety compared with S. typhimurium, we used E. coli infection for further experiments.
Consistent with increased mortality, the peritoneal cavity of Hjv−/−-ID mice contained higher levels of bacterial colony-forming units (CFUs) (Figure 1f). Thus, decreasing iron levels to wild-type levels was not sufficient to fully restore bacterial clearance in Hjv−/− mice; therefore, factors other than iron overload likely contribute to the susceptibility of Hjv−/− mice to bacterial infection.
Hepcidin, the downstream target of Hjv encoded by the Hamp gene, has been reported to regulate inflammatory responses in mice [4]. Moreover, hepcidin-knockout mice are sensitive to LPS stimulation [4]. Because hepcidin levels are low in Hjv−/− mice under basal conditions [7], we hypothesized that low hepcidin levels may contribute to the high susceptibility of Hjv−/− mice to bacterial infection.
To test this hypothesis, we challenged Hjv−/− mice with LPS and D-galactosamine [21] to induce endotoxic shock. We found that the mortality rate was similar between LPS-treated Hjv−/− mice and LPS-treated wild-type mice (Figure 1g). Interestingly, LPS stimulation induces hepcidin in Hjv−/− mice [7], and Hamp mRNA levels were similar between wild-type and Hjv−/− mice following E. coli infection (Supplementary Figure S2A). Moreover, serum TNF-α levels (measured 1 h after LPS stimulation) and IL-6 levels (measured 2.5 h after LPS stimulation) were similar between Hjv−/− and wild-type mice (Supplementary Figure S2B and C). Taken together, these results suggest that reduced hepcidin expression does not contribute significantly to the increased mortality of Hjv−/− mice in response to bacterial infection.
To determine whether Hjv−/− mice are also susceptible to infection by Gram-positive bacterium, we gave Hjv−/− and wild-type mice a lethal i.p. dose of the Gram-positive bacterium Staphylococcus aureus (S. aureus) and found considerably higher mortality in the infected Hjv−/− mice (Figure 1h). Thus, our acute lethal infection experiments indicate that Hjv−/− mice are highly susceptible to infection by both Gram-negative and Gram-positive bacteria, suggesting that Hjv may play an essential role in the host defense against bacterial infection.
Impaired microbial clearance in Hjv−/− macrophages and neutrophils
Our findings suggest that bacterial clearance is impaired in Hjv−/− mice. However, bacteremia induced by an intravenous (i.v.) injection of E. coli [22, 23] caused similar mortality between Hjv−/− and wild-type mice (Figure 2a). Houghton et al. [18] reported that impaired macrophage function within the peritoneal cavity can result in bacterial dissemination to other sites. Thus, local defense processes are partially independent of systemic protection and may play an essential role in host survival.
Based on these findings, we hypothesized that the local defense process is impaired in the peritoneal cavity of Hjv−/− mice. We therefore measured the immune response in the peritoneal cavity following bacterial infection. In the early stages of bacterial infection, macrophages and neutrophils mediate bacterial clearance [24]. To determine the relative proportions of these two cell types in infected Hjv−/− mice, we isolated peritoneal cells, stained the cells with F4/80 and Gr-1, and performed flow cytometry [25]. Our analysis revealed that 6–12 h after bacterial infection, neutrophils (F4/80−, Gr-1+) and macrophages (F4/80+) comprised ~80% and 10%, respectively, of the total population of phagocytes; after 24 h, the percentage of neutrophils decreased to ~50%, and the percentage of macrophages increased to ~40% (Figure 2b). Interestingly, the relative proportions of both cell types were similar between Hjv−/− and wild-type mice following bacterial infection, indicating that the migration of macrophages and neutrophils to the peritoneal cavity is intact in Hjv−/− mice.
Next, we examined further the phagocytic function of peritoneal cells. Primary peritoneal macrophages were obtained from Hjv−/− and wild-type mice by peritoneal lavage with Thioglycollate medium [26]. We then incubated the cells with Alexa Fluor 488 conjugated heat-killed E. coli and measured phagocytosis using flow cytometry. We found no difference between Hjv−/− macrophages and wild-type macrophages with respect to phagocytosis ratio (Figure 2c) or mean fluorescence intensity (Figure 2d), suggesting that Hjv−/− macrophages have normal phagocytic activity. Despite normal phagocytosis measured in vitro, we observed more GFP fluorescence in peritoneal cells obtained from Hjv−/− mice 12 h after infection with GFP-expressing E. coli compared with wild-type mice (Figure 2e). This stronger immune response in Hjv−/− mice may be due to bacterial overload in the phagocytes; on the other hand, bacteria in the peritoneal cavity were over-proliferated in Hjv−/− mice (Figure 1f). Taken together, these data suggest that although more bacteria are engulfed by Hjv−/− phagocytes, they are not efficiently killed and/or degraded.
Reduced IFN-γ expression in Hjv−/− neutrophils and macrophages
To test for a possible immune deficiency in Hjv−/− mice, we measured the levels of circulating inflammatory cytokines, which generally reflect the presence of an ongoing immune response and can be used to monitor bacteria clearance. We therefore collected serum samples after infecting mice with of E. coli (2×108 CFU) by i.p. injection; serum was collected 1, 2.5, and 6 h after infection for measuring TNF-α, IL-6 and IFN-γ levels, respectively. Both TNF-α and IL-6 levels were approximately twofold higher in the serum of Hjv−/− mice compared with wild-type mice; in contrast, IFN-γ levels were significantly lower in the Hjv−/− mice (Figure 3a).
IFN-γ is secreted primarily by NK (natural killer) cells and T cells [27]. However, in our acute infection models, the mice died within 24 h, well before NK cells and T cells are activated [27]. We first confirmed that splenocytes isolated from infected Hjv−/− mice and wild-type mice have extremely low IFN-γ secretion (Supplementary Figure S3A). We then examined several cell types in the peritoneal cavity. Macrophages and neutrophils are potential sources of IFN-γ in the early stage of infection [28, 29]. Thus, a lack of IFN-γ autocrine secretion may underlie the impaired killing capacity of Hjv−/− macrophages and neutrophils. Indeed, the myeloid lineage cell fraction in the peritoneal cavity contained considerable numbers of IFN-γ positive (IFN-γ+) cells (Figure 3b). Six hours after E. coli infection, 17.5 and 4% of wild-type and Hjv−/− peritoneal myeloid lineage cells were IFN-γ+ (Figure 3b). Twelve hours after infection, the percentage of IFN-γ+ cells decreased in both genotypes; however, the percentage of IFN-γ+ cell was still 2-fold higher in the wild-type mice than in the Hjv−/− mice. We then examined the identity of the IFN-γ+ cells 6, 12, and 24 h after infection. For wild-type peritoneal cells, 6 h after infection, 75% and 25% of the IFN-γ+ cells were neutrophils (that is, Gr-1+, F4/80− cells) and macrophages (that is, F4/80+ cells), respectively; however, 12 h after infection, the percentage of IFN-γ+ neutrophils cells decreased to only 13%, and the percentage of macrophages increased to 87%. Moreover, in wild-type mice we detected only a very small proportion of T cells (CD8b+) and NK cells (NK1.1+) within the peritoneal population of IFN-γ+ cells 12 h after infection (Supplementary Figure S3B); thus, phagocytes—rather than NK cells or T cells—are the principal source of IFN-γ in the early stages of peritoneal infection.
Recent studies found that cellular iron content can affect macrophage function [19, 30]. In Hjv−/− mice, splenic iron content is low (Supplementary Figure S1A) because ferroportin retained in the plasma membrane exports more iron out of these macrophages in the spleen. To exclude this effect, we generated macrophage-specific Hjv-knockout (Hjvfl/fl;LysM-Cre+) mice; iron content in the major organs and macrophages of these mice was normal (Supplementary Figure S1B and D), and E. coli-induced mortality was similar between Hjvfl/fl;LysM-Cre+ mice and Hjv−/−-ID mice (compare Figure 3c with Figure 1e). Notably, treating Hjvfl/fl;LysM-Cre+ mice with IFN-γ (10 units per mouse) [31, 32 ] significantly improved survival following E. coli infection (Figure 3d).
Next, we examined the specific functions of macrophages and neutrophils. We performed adoptive transfer experiments by injecting 2×106 wild-type neutrophils or macrophages into the peritoneal cavity of Hjv−/− mice; 4 h later, these mice were challenged with a lethal dose of E. coli (2×108 CFU). Although transferring wild-type neutrophils conferred no protection to these mice (Figure 3e), transferring wild-type macrophages conferred a significant protective effect against bacterial infection compared with Hjv−/− macrophages (Figure 3f). Thus, impaired macrophage function, possibly due to reduced IFN-γ production and/or secretion, appears to play a key role in the susceptibility of Hjv−/− mice to bacterial infection.
Decreased IFN-γ secretion in Hjv−/− macrophages reduces their nitric oxide production and killing capacity
IFN-γ is a critical mediator of protective immunity against both viral and bacterial infections; consistent with this role, IFN-γ-knockout mice are highly susceptible to bacterial infection [33, 34]. Specifically, peritoneal cells produce IFN-γ and are essential for the survival of infected mice, and bacterial clearance by these cells is impaired when IFN-γ secretion is reduced [35]. To further investigate the function of IFN-γ release by macrophages in the early stages of bacterial infection, we isolated and cultured peritoneal macrophages, then stimulated the cells with E. coli that was heat-killed to prevent lethality due to uncontrolled bacterial replication, thereby mimicking infection in vivo. Twenty-four hours after stimulation, both Hjv−/− and Hjvfl/fl;LysM-Cre+ macrophages secreted significantly fewer amounts of IFN-γ compared with wild-type macrophages (Figure 4a); in contrast, both TNF-α and IL-6 were produced at wild-type levels (Supplementary Figure S4A and B). In macrophages, IFN-γ activates the enzyme iNOS (inducible nitric oxide synthase), thereby increasing nitric oxide (NO) production in these cells [36, 37]. We used thioglycollate-elicited macrophages as our primary cell model, as NO synthesis is robust in these cells [38, 39]. After cells were stimulated with heat-killed E. coli, both phosphorylated Stat1 (pStat1, an upstream activator of iNOS) and iNOS expression were significantly lower in Hjv−/− macrophages compared with wild-type cells (Figure 4b and c). Moreover, the amount of NO released was significantly lower in both Hjv−/− and Hjvfl/fl;LysM-Cre+ macrophages compared with wild-type cells (Figure 4d). Applying exogenous IFN-γ (100 ng ml−1) to Hjv−/− macrophages restored both their pStat1 levels and NO secretion (Figure 4e and f). Macrophages utilize NO production to confer protection from invading pathogens [40]. We, therefore, collected thioglycollate-elicited macrophages from both Hjvfl/fl;LysM-Cre+ mice and Hjvfl/fl;LysM-Cre− control mice. After 90 min in culture, the bacterial killing capacity of the Hjvfl/fl;LysM-Cre+ macrophages was significantly decreased compared with Hjvfl/fl;LysM-Cre− controls (that is, the Hjvfl/fl;LysM-Cre+ macrophages contained significantly more CFUs than the control cells) (Figure 4g). Notably, pretreating both Hjvfl/fl;LysM-Cre+ and control macrophages with IFN-γ significantly increased bacterial killing capacity, thereby rescuing the phenotype in Hjvfl/fl;LysM-Cre+ macrophages. Moreover, co-treating cells with IFN-γ and an IFN-γ neutralizing antibody (NeuAb) significantly reduced the bacterial killing capacity of both Hjvfl/fl;LysM-Cre+ and control macrophages (Figure 4g).
To investigate other possible mechanisms involved in the killing capacity of macrophages, we also measured the level of reactive oxygen species (ROS) within the cells. However, we found no significant difference between Hjv−/− and wild-type macrophages (Figure 4h). We therefore conclude that impaired IFN-γ production in Hjv−/− macrophages plays a principal role in the reduced killing capacity of these cells, possibly explaining the unrestricted growth of bacteria in the peritoneal cavity and major organs of Hjv−/− mice.
Hjv is upregulated and facilitates the NO cascade in infected macrophages
We found that elicited wild-type macrophages treated with heat-killed E. coli had significantly increased levels of Hjv mRNA (Figure 5a); in contrast, and consistent with a previous report [7], Hjv expression was decreased in the liver (Supplementary Figure S5). These results suggest that Hjv may play a regulatory role during infection. Interestingly, stimulating Hjv-transfected RAW264.7 cells (a murine macrophage cell line) with either LPS or heat-killed E. coli led to significantly increased NO production compared with control cells and cells transfected with an empty vector (Figure 5b). Consistent with these results, both iNOS expression (Figure 5c) and pStat1 levels (Figure 5d) were also increased. These results suggest that Hjv plays a key role in both iNOS expression and NO production in macrophages. Given that IFN-γ treatment rescued iNOS signaling (Figure 4e, f), Hjv likely modulates the iNOS cascade primarily via IFN-γ signaling.
IL-12/Stat4 signaling is impaired in Hjv−/− macrophages
Hjv is a major regulator of Bmp/Smad signaling [41]. However, whether Bmp/Smad signaling is altered in Hjv−/− macrophages and/or whether crosstalk exists between the inflammatory response and Bmp/Smad signaling is not currently known. Bmp6 can induce NO production in macrophages independent of Smad [42], and inflammatory stimuli can reduce Smad1/5/8 phosphorylation in macrophages [43]. However, we found similar levels of phosphorylated Smad1/5/8 levels between Hjv−/− and wild-type macrophages following stimulation with heat-killed E. coli (Supplementary Figure S6A). When we treated wild-type macrophages with LDN193189, a classic inhibitor of Bmp/Smad signaling, [44] pSmad1/5/8 levels were significantly reduced (Supplementary Figure S6A), whereas iNOS expression was increased (Supplementary Figure S6B). Moreover, the effect of heat-killed E. coli on Bmp/Smad signaling was unaffected by Hjv deletion (Supplementary Figure S6A). Together, these results indicate that Bmp/Smad signaling is likely not altered in Hjv−/− macrophages during bacterial infection.
Both IL-18 [45] and IL-12 [46] are key regulators of IFN-γ secretion. Therefore, to investigate the possible mechanism by which Hjv regulates IFN-γ, we collected serum from Hjv−/− and wild-type mice following E. coli infection. We found no significant difference between Hjv−/− and wild-type mice with respect to either IL-12 (Figure 6a) or IL-18 (Figure 6b). We therefore hypothesized that the capacity for IL-12 and IL-18 to induce IFN-γ might be reduced in Hjv−/− mice. To test this hypothesis, we examined the signaling pathways downstream of IL-12 and IL-18. Previous studies showed that IL-18 regulates IFN-γ via the MAP kinase (MAPK) pathway, [47] and IL-12 drives the phosphorylation of Stat4 to induce IFN-γ expression. [48] To investigate the role of these two pathways, we measured phosphorylated MAPK proteins and phosphorylated Stat4 in macrophages stimulated with heat-killed E. coli. We found no defect in Hjv−/− macrophages with respect to p38 (Figure 4c), Erk1/2, or Jnk phosphorylation (Figure 6c). However, E. coli stimulated phosphorylation of Stat4 was significantly impaired in Hjv−/− macrophages compared with wild-type macrophages (Figure 6d). Consistent with reduced Stat4 phosphorylation, Jak2 phosphorylation was also reduced in Hjv−/− macrophages compared with wild-type cells (Figure 6e). Finally, we performed in vitro co-immunoprecipitation experiments using HEK293 cells co-transfected with Flag-tagged HJV and Myc-tagged IL-12RB1 (the beta-1 subunit of the IL-12 receptor). Although weakly pulled down by IL-12RB1-Myc, HJV-Flag was highly effective at pulling down IL-12RB1-Myc (Figure 6f), suggesting that HJV may play a direct role in IL-12 signaling. Taken together, these results suggest that HJV may regulate IFN-γ in macrophages via the IL-12/Jak2/Stat4 pathway.
Discussion
A clear relationship between hemochromatosis and infection has been established by several groups [49–52]. The majority of these results suggest that both HFE and Hepcidin (encoded by the HFE and HAMP genes, respectively) play a protective role against bacterial infection in human and mouse. Here, we performed a novel screen using several hemochromatosis mouse models to investigate the mechanisms that underlie the putative link between iron metabolism and immunity. Importantly, our in vivo screening strategy differed from previous studies [5, 18] in that we focused on the acute infection phase. Thus, our bacterial dose was based on the lethal dose established for modeling severe peritonitis in 129/svj mice [18].
Of the three hemochromatosis mouse models in our initial screen, we found that only Hjv−/− mice were highly susceptible to bacterial infection, and we excluded iron burden as the main contributing factor using iron-deficient Hjv−/− (Hjv−/−-ID) mice. However, under standard dietary conditions, splenic iron content is lower in Hjv−/− mice than in wild-type mice [7], and placing Hjv−/− mice on an iron-deficient diet lowered iron content in the macrophages even further (Supplementary Figure S1A). These factors complicate the phenotype of Hjv−/− mice and may have affected survival. Therefore, after we identified which specific immune cells (that is, macrophages and neutrophils) are functionally impaired in Hjv−/− mice, we performed survival experiments using Hjvfl/fl;LysM-Cre+ mice, in which Hjv expression is deleted selectively in macrophages and neutrophils. Our results revealed that Hjvfl/fl;LysM-Cre+ mice have a survival profile similar to Hjv−/−-ID mice. Given that the iron content in the major organs and macrophages of Hjvfl/fl;LysM-Cre+ mice was similar to wild-type littermates (Supplementary Figure S1B and C), we conclude that iron burden does not play a major role in the high susceptibility of Hjv−/− mice to bacterial infection.
We observed significantly reduced levels of circulating IFN-γ in Hjv−/− mice 6 h after bacterial infection. IFN-γ is primarily secreted by T helper type 1 (Th1) cells [53] and NK cells [54]. However, given the time frame of the increased IFN-γ levels (that is, within 6 h), the principal source of IFN-γ during the early stages of infection is likely not Th1 or NK cells. Interestingly, peritoneal macrophages and neutrophils have been reported as a source of IFN-γ [55–58], although this remains controversial [59]; nevertheless, it is worth noting that Schleicher et al. [59] treated peritoneal cells with IL-12, IL-18, and LPS for 72 h, which differs from our bacterial infection model (6–24 h). A recent study in mice also found that Gr-1+ cells produce IFN-γ in the early stages of Streptococcus infection, and these cells are responsible for promoting the survival of infected mice [35]. We therefore conclude that peritoneal phagocytes secrete IFN-γ, thereby self-activating via an autocrine pathway, providing an essential step in fighting peritoneal infection and improving survival.
Our results indicate that Hjv deletion affects the IL-12/Jak2/Stat4 signaling pathway, but not the IL-18/MAPK pathway. Nevertheless, additional research is warranted in order to better understand the underlying mechanisms.
In conclusion, we identified a novel role for HJV in mediating bacterial clearance via macrophages. Our findings indicate that HJV may serve as a potential target for boosting protection against bacterial peritoneal infection, thereby improving clinical outcome.
Materials and methods
Mice
Hfe−/−, Hjv−/−, Fpn1floxflox, Hjvflox/flox and wild-type mice were maintained on the 129S6/SvEvTac background and were housed in a specific pathogen-free animal facility [9, 14, 60, 61]. Fpn1 knockout in macrophages (Fpn1fl/fl;LysM-Cre+) was achieved by crossing LysM-Cre mice [62] with Fpn1floxflox mice, and Hjv knockout in macrophages (Hjvfl/fl;LysM-Cre+) was achieved by crossing LysM-Cre mice [62] with Hjvflox/flox mice. LysM-Cre mice were maintained as heterozygotes. All animal experiments were approved and performed in accordance with guidelines established by the Institutional Animal Care and Use Committee of the School of Medicine, Zhejiang University.
In vivo infection models and bacterial growth measurements
Mice were infected with various bacterial species via i.p. or i.v. injection in order to induce peritonitis and bacteremia, respectively. S. typhimurium, E. coli and S. aureus were grown in LB and isolated on LB agar plates. For the IFN-γ rescue experiments, 10 units of IFN-γ in saline (or saline alone) were subcutaneously injected into the right flank of the mice, immediately followed by an i.p. injection of E. coli TOP10 bacteria, which carries the GFP gene on the Puc19 plasmid [63]. Organ/peritoneal cavity colony-forming units (CFUs) were determined by plating dilutions of organ homogenates or peritoneal lavage fluid on LB plates.
Dietary induction of iron deficiency
To induce iron deficiency, 4-week-old mice were fed a diet containing reduced iron content (0.9 mg Fe kg−1, AIN-76A-diet, D08080402, Research Diets, Inc., New Brunswick, NJ, USA) for 4 weeks. Standard diet contained 50 mg Fe kg−1, (AIN-76A-diet, D08080401, Research Diets, Inc.).
Phagocytosis assay and macrophage killing assays
For the phagocytosis assay, thioglycollate-stimulated peritoneal macrophages were incubated with Alexa Fluor 488-conjugated heat-killed E. coli (Molecular Probes) for 1 h. Extracellular fluorescence was then quenched by adding 100 μl of trypan blue [64]. Cells were then washed in cold PBS and examined using fluorescence microscopy or flow cytometry (FACS analysis). For the killing assay, thioglycollate-stimulated peritoneal macrophages were incubated with TOP10 E. coli for 20 min. The macrophages were then washed with phosphate-buffered saline (PBS) to remove the bacteria, incubated in 100 μg ml−1 gentamycin in DMEM for 20 min (to kill extracellular bacteria), and then incubated for an additional 120 min in 25 μg ml−1 gentamycin in DMEM. CFUs were then measured from macrophage lysates [40, 65]. In some experiments, the cells were pretreated for 12 h with IFN-γ (Peprotech) in the presence or absence of IFN-γ-neutralizing antibody (NeuAb; bp0055, Bio X Cell) prior to adding the bacteria.
ELISA
ELISA kits for measuring IL-6, TNF-α and IFN-γ were purchased from R&D Systems. ELISA kits for measuring IL-12 and IL-18 were purchased from Pierce. Sera were collected from E. coli-infected wild-type and Hjv−/− mice at indicated time. Briefly, 50 μl serum, blank or standard were added in 96-well plate, incubated at room temperature for 2 h, washed by wash buffer for five times. Then, 100 μl conjugated antibodies were incubated at room temperature for 2 h, washed by wash buffer for five times. TMB mix (100 μl) was added into wells for 30 min, and stop solution was then added to stop the reaction. OD values were read at 450 nm by Microplate reader (Molecular Devices, Sunnyvale, CA , USA).
Antibodies
Primary antibodies: rabbit anti-pStat1 (1:1000, Cell Signaling Technology [CST, Boston, MA, USA]), rabbit anti-Stat1 (1:1000, CST), rabbit anti-pErk1/2 (1:1000, CST), rabbit anti-Erk1/2 (1:1000, CST), mouse anti-pJnk (1:1000, CST), rabbit anti-Jnk (1:1000, CST), rabbit anti-pStat4 (1:500, Santa Cruz (Santa Cruz, CA, USA)), rabbit anti-Stat4 (1:1000, CST), rabbit anti-pJak2 (1:500, CST), rabbit anti-Jak2 (1:1000, CST), rabbit anti-pSmad1/5/8 (1:1000, CST), rabbit anti-Smad1 (1:1000, CST), rabbit anti-pSmad3 (1:1000, CST), rabbit anti-Smad3 (1:1000, CST), rabbit anti-FLAG (1:1000, CST), mouse anti-Myc (1:1000, CST), or mouse anti-β-actin (Sigma, San francisco, CA, USA). Secondary antibodies: peroxidase-conjugated goat anti-Rabbit or Goat anti mouse IgG (Proteintech (Chicago, IL,USA), 1:2000).
Western blot analysis
Western blot was perform as previously described [9]. Briefly, cells/tissues were lysed by RIPA buffer (Beyotime, Shanghai, China) with protease inhibitor cocktail (Sigma) for 10 min; Sonicate for 10 s to complete cell lysis and shear DNA followed by adding loading buffer (containing 5% β-Me). Then samples were heated to 95–100 °C for 5 min (alternatively 37 °C 30 min for membrane protein detection), cool on ice and microcentrifuge for 5 min. Samples were loaded onto SDS-PAGE gel and then electrotransfer to PVDF membrane (Bio-Rad, Hercules, CA, USA). The transferred membrane was incubated in blocking buffer (5% skim milk in TBST) for 1 h followed by incubation with primary antibody overnight at 4 °C. Membrane was washed three times for 10 min each with TBST, and incubated with HRP-linked secondary antibody for 1 h at room temperature. Wash three times for 10 min each with TBST. After incubation with ECL (Pierce (Rockford, IL, USA), Thermo (Waltham, MA, USA)) mixture for 5 min, wrap the membrane in plastic and expose to X-ray film. Co-IP experiments were performed using anti-Flag (1:50, CST) and anti-Myc (1:1000, CST) antibodies.
Real-time quantitative PCR
Total RNA was isolated from peritoneal macrophages or liver tissue using Trizol (Invitrogen, Carlsbad, CA, USA). Real-time PCR was then performed using two-step quantitative real-time PCR with the primer pairs listed in Supplementary Table S1. The expression level of each target gene was normalized to the corresponding β-actin mRNA level.
Expression of Hjv in RAW264.7 macrophages
Hjv-expressing constructs were cloned into the pCMV-3Tag-3A vector and transfected into RAW264.7 cells using the FuGENE HD transfection reagent (Promega, Madison, WI, USA).
Quantification of nitric oxide (NO) and ROS
NO concentration was measured using the Griess assay [66]. 50 μl cell medium, blank or standard control were added into a 96-well plate, followed by adding 50 μl Griess reagent I and II, incubated at room temperature for 10 min, OD values were read at 540 nm by Microplate reader (Molecular Devices). Intracellular reactive oxygen species were measured using the dichloro-dihydro-fluorescein diacetate (DCFH-DA) method [67]. HK-E. coli-stimulated macrophages in 6-well plate were incubated in serum-free DMEM-containing 10 μM DCFH-DA for 20 min at 37 °C in cell culture hood. Cells were then detached by trypsin digestion and followed by FACS analysis at the excitation wavelength of 488 nm and emission wavelength of 525 nm.
Statistical analysis
All summary data are presented as the mean±s.e.m. The log-rank test or Mann–Whitney U-test was used to analyze the Kaplan–Meier survival curves. The Student’s t-test was used to compare two groups, and an ANOVA was used to compare multiple groups. Differences with a P-value<0.05 were considered significant.
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Acknowledgements
We are grateful to Dr Nancy Andrews for generously providing the Hfe−/−, Hjv−/−, Hjvflox/flox, and Fpn1flox/flox mice. We also thank Dr Baoxue Ge at Tongji University for providing the E. coli TOP10 strain carrying the GFP gene on the Puc-19 plasmid. This work was supported by grants from the National Natural Science Foundation of China (31530034, 31330036, and 31225013 to FW; 31570791 and 91542205 to JM), and Zhejiang Provincial Natural Science Foundation of China (LZ15H160002 to JM). We thank members of the Wang and Min laboratories for discussion.
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QW, YS, FW and JM designed the experiments. QW, YS, YT, PA, HW, ZZ, JW and HG performed the experiments. QW, YS, YT, FW and JM analyzed the data. QW, YS, TZ, FW and JM drafted and revised the manuscript.
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Wu, Q., Shen, Y., Tao, Y. et al. Hemojuvelin regulates the innate immune response to peritoneal bacterial infection in mice. Cell Discov 3, 17028 (2017). https://doi.org/10.1038/celldisc.2017.28
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DOI: https://doi.org/10.1038/celldisc.2017.28
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