Stress Erythropoiesis is a Key Inflammatory Response

Robert F. Paulson; Baiye Ruan; Siyang Hao; Yuanting Chen

doi:10.3390/cells9030634

BMP4/Madh5 Dependent Signaling Is Required for the Expansion of a Population of Stress Erythroid Progenitors in the Fetal Liver.

Blood ◽

10.1182/blood.v106.11.4195.4195 ◽

2005 ◽

Vol 106 (11) ◽

pp. 4195-4195

Author(s):

Robert F. Paulson ◽

Prashanth Porayette

Keyword(s):

Bone Marrow ◽

Steady State ◽

Fetal Liver ◽

Erythroid Progenitors ◽

Acute Anemia ◽

Erythroid Response ◽

Stress Erythropoiesis ◽

And Control ◽

Flexed Tail

Abstract Fetal liver hematopoiesis is primarily erythropoiesis, which robustly produces erythrocytes to meet the growing need of the developing embryo. In many ways fetal liver erythropoiesis resembles stress erythropoiesis in the adult, where in response to acute anemia, a unique population of stress erythroid progenitors is rapidly expanded in the spleen. The development of these stress progenitors requires BMP4/Madh5 dependent signals. Spleen stress progenitors exhibit properties that are distinct from bone marrow steady state progenitors in that they are able to rapidly form large BFU-E colonies, which require only Epo stimulation for their generation. Mice mutant at the flexed-tail locus exhibit a defective stress erythroid response because of a mutation in Madh5. In addition to this defect, flexed-tail mice also exhibit a severe fetal-neonatal anemia. We have analyzed fetal liver erythropoiesis in flexed-tail and control embryos. We show that BMP4 is expressed in the fetal liver and its expression correlates with the time of maximum erythropoiesis. In flexed-tail mutant embryos the expression is delayed and this correlates with both a delay and a defect in the expansion of erythroid progenitors. Our analysis also shows that the fetal liver contains two types of erythroid progenitors. One type exhibits the properties of stress BFU-E found in the adult spleen, which are compromised in flexed-tail embryos and a second type that is similar to bone marrow steady state BFU-E. These data demonstrate that BMP4 dependent signaling drives the expansion of erythroid progenitors in the fetal liver in a manner similar to stress erythropoiesis in the adult spleen.

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Bone Marrow Mesenchymal Stem Cells Inhibit Lipopolysaccharide-Induced Inflammatory Reactions in Macrophages and Endothelial Cells

Mediators of Inflammation ◽

10.1155/2016/2631439 ◽

2016 ◽

Vol 2016 ◽

pp. 1-9 ◽

Cited By ~ 4

Author(s):

Dequan Li ◽

Cong Wang ◽

Chuang Chi ◽

Yuanyuan Wang ◽

Jing Zhao ◽

...

Keyword(s):

Stem Cells ◽

Bone Marrow ◽

Endothelial Cells ◽

Mesenchymal Stem Cells ◽

Inflammatory Response ◽

Alveolar Macrophages ◽

Inflammatory Responses ◽

Enzyme Linked Immunosorbent Assay ◽

Human Umbilical Cord ◽

Marrow Mesenchymal Stem Cells

Background. Systemic inflammatory response syndrome (SIRS) accompanied by trauma can lead to multiple organ dysfunction syndrome (MODS) and even death. Early inhibition of the inflammation is necessary for damage control. Bone marrow mesenchymal stem cells (BMSCs), as a novel therapy modality, have been shown to reduce inflammatory responses in human and animal models.Methods. In this study, we used Western blot, quantitative PCR, and enzyme-linked immunosorbent assay (ELISA) to assess the activity of BMSCs to suppress the inflammation induced by lipopolysaccharide (LPS) in human umbilical cord endothelial cells (HUVECs) and alveolar macrophages.Results. Our results demonstrated that LPS caused an inflammatory response in alveolar macrophages and HUVECs, increased permeability of HUVEC, upregulated expression of toll-like receptor (TLR) 2, TLR4, phosphorylated p65, downregulated release of IL10, and promoted release of TNF-αin both cells. Coculture with BMSCs attenuated all of these activities induced by LPS in the two tested cell types.Conclusions. Together, our results demonstrate that BMSCs dosage dependently attenuates the inflammation damage of alveolar macrophages and HUVECs induced by LPS.

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ROCK1 Functions As a Critical Regulator of Stress Erythropoiesis and Survival by Regulating p53

Blood ◽

10.1182/blood.v118.21.916.916 ◽

2011 ◽

Vol 118 (21) ◽

pp. 916-916

Author(s):

Sasidhar Vemula ◽

Jianjian Shi ◽

Raghuveer Mali ◽

Peilin Ma ◽

Philip Hanneman ◽

...

Keyword(s):

Bone Marrow ◽

Stem Cell ◽

Steady State ◽

Erythroid Cell ◽

Cell Phenotype ◽

Double Positive ◽

Stress Erythropoiesis ◽

Significant Difference ◽

Rho Kinases ◽

Deficient Mice

Abstract Abstract 916 Erythropoiesis is a dynamic, multistep process in which hematopoietic stem cells differentiate toward a progressively committed erythroid lineage through intermediate progenitors. Under normal physiologic condition, erythropoiesis takes place primarily in the bone marrow of humans and mice. Efficient stress erythropoiesis is crucial to survival and recovery from various pathophysiologic conditions including blood loss, anemia, and therapeutic procedures used in the treatment of hematological malignancies such as chemotherapy and stem cell transplantation. Impaired stress erythropoiesis can be fatal under these conditions. In order to develop improved strategies to stimulate stress erythropoiesis in patients with such conditions, it is critical to identify the molecular mechanisms that regulate this process. While many of the downstream signaling molecules and pathways have been elucidated in steady state erythroid cell development, the major regulators under stress conditions remain to be defined. The small families of Rho GTPases and their downstream effectors, Rho kinases have been implicated in regulating various cellular functions including actin cytoskeleton organization, cell adhesion, and cell motility in non-hematopoietic cells and inflammatory cells. Rho kinases (ROCK1 and ROCK2) belong to a family of serine/threonine kinases, and their physiologic role in erythropoiesis is not known. Utilizing mice deficient in the expression of ROCK1, we demonstrate no significant difference with respect to erythroid parameters in peripheral blood under steady-state conditions (n=19 mice for each genotype). The frequency of Ter119+, CD71+ or double-positive erythroid cells in the bone marrow and spleen of ROCK1-deficient mice was comparable to wild type (WT) controls at basal levels (n=7). In response to myelotoxic stress, ROCK1 deficient Ter119 positive cells demonstrated enhanced survival and recovery compared to WT controls (n=3–6, *p< 0.05). Further, using a phenylhydrazine (PHZ)-induced murine model of hemolytic anemia, we demonstrate that ROCK1-deficient mice exhibit increased red blood cells and enhanced hematocrits relative to WT mice (n=6, *p< 0.05). In addition, ROCK1−/− mice support efficient erythro-splenomegaly, and exhibit a threefold increase in splenic weight after PHZ injection compared to WT controls (n=6, *p< 0.05). Flow cytometric analysis revealed increased frequency of Ter119/CD71 double positive erythroid progenitor pool in ROCK1−/− spleens after PHZ treatment compared to WT (n=6, *p< 0.05). Furthermore, histopathological analysis of WT and ROCK1−/− spleens following PHZ treatment revealed a defined population of white pulp and red pulp in control spleens but enhanced extramedullary erythropoiesis in ROCK1−/− spleens (n=3, *p< 0.05). In vitro colony forming assays showed that ROCK1-deficient splenocytes generated more erythroid colony forming units (CFU-Es) and eventually generated more erythroid-burst forming units (BFU-Es) compared to WT splenocytes in response to different concentrations of EPO and combination of EPO and SCF (n=3, *p< 0.05). Deficiency of ROCK1 also resulted in enhanced survival of mice treated with PHZ compared to controls (n=17 mice per group, *p< 0.05). The enhanced survival of ROCK1-deficient mice in response to PHZ was associated with reduced reactive oxygen species (ROS) levels compared to WT (n=6 mice per group, *p< 0.05). Bone marrow transplantation studies revealed that enhanced stress erythropoiesis in ROCK1-deficient mice is stem cell autonomous (n=6 mice per genotype, *p< 0.05). Remarkably, the red cell phenotype observed in ROCK1−/− mice is similar to that reported in mice deficient in p53. We show that ROCK1 binds p53 directly and regulates its stability and expression (n=3). In absence of ROCK1, p53 phosphorylation and expression is reduced in ROCK1−/− erythroblasts (n=3). Our findings reveal that ROCK1 functions as a physiologic regulator of p53 under conditions of erythroid stress. These findings are expected to offer new perspectives on stress erythropoiesis and may provide a potential therapeutic target in human disease characterized by anemia. Disclosures: No relevant conflicts of interest to declare.

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Ablation of Gata1 in adult mice results in aplastic crisis, revealing its essential role in steady-state and stress erythropoiesis

Blood ◽

10.1182/blood-2007-09-115121 ◽

2008 ◽

Vol 111 (8) ◽

pp. 4375-4385 ◽

Cited By ~ 57

Author(s):

Laura Gutiérrez ◽

Saho Tsukamoto ◽

Mikiko Suzuki ◽

Harumi Yamamoto-Mukai ◽

Masayuki Yamamoto ◽

...

Keyword(s):

Bone Marrow ◽

Steady State ◽

Erythroid Progenitors ◽

Hematopoietic Development ◽

Stress Erythropoiesis ◽

Adult Mice ◽

Aplastic Crisis ◽

Excessive Proliferation ◽

Erythropoietic Response

Abstract The transcription factor Gata1 is expressed in several hematopoietic lineages and plays essential roles in normal hematopoietic development during embryonic stages. The lethality of Gata1-null embryos has precluded determination of its role in adult erythropoiesis. Here we have examined the effects of Gata1 loss in adult erythropoiesis using conditional Gata1 knockout mice expressing either interferon- or tamoxifen-inducible Cre recombinase (Mx-Cre and Tx-Cre, respectively). Mx-Cre–mediated Gata1 recombination, although incomplete, resulted in maturation arrest of Gata1-null erythroid cells at the proerythroblast stage, thrombocytopenia, and excessive proliferation of megakaryocytes in the spleen. Tx-Cre–mediated Gata1 recombination resulted in depletion of the erythroid compartment in bone marrow and spleen. Formation of the early and late erythroid progenitors in bone marrow was significantly reduced in the absence of Gata1. Furthermore, on treatment with a hemolytic agent, these mice failed to activate a stress erythropoietic response, despite the rising erythropoietin levels. These results indicate that, in addition to the requirement of Gata1 in adult megakaryopoiesis, Gata1 is necessary for steady-state erythropoiesis and for erythroid expansion in response to anemia. Thus, ablation of Gata1 in adult mice results in a condition resembling aplastic crisis in human.

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Defects in Management of Labile Iron and Oxidative Stress Underpin Red Cell Enucleation Defects in Rb Null Mice.

Blood ◽

10.1182/blood.v106.11.1351.1351 ◽

2005 ◽

Vol 106 (11) ◽

pp. 1351-1351

Author(s):

Kay F. Macleod ◽

Benjamin T. Spike

Keyword(s):

Oxidative Stress ◽

Bone Marrow ◽

Steady State ◽

Fetal Liver ◽

Red Cells ◽

Red Cell ◽

Stress Erythropoiesis ◽

Labile Iron ◽

End Stage ◽

And Oxidative Stress

Abstract The Rb tumor suppressor is critically required for end-stage red cell maturation under conditions of oxidative stress, including in the developing fetal liver, in the bone marrow of aging mice, in the spleen and bone marrow of young mice treated with phenylhydrazine to induce hemolytic anemia, and in lethally irradiated mice reconstituted with donor tissue [1]. Loss of Rb resulted in a failure of end-stage red cells to enucleate, accumulation of red cells with a 4N DNA content and aberrant chromatin structure [1]. The molecular basis of these defects is not defined nor do we understand the reasons why pRb should be required under stress conditions, but not during normal “steady-state” erythropoiesis. The work presented will address both of these questions. In determining why pRb is critically required for stress erythropoiesis but not for steady-state erythropoiesis, we have demonstrated increased levels of reactive oxygen species (ROS) and labile iron in Rb null erythroblasts relative to wild-type control erythroblasts derived from E12.5 fetal liver. Furthermore, we show that quenching of ROS in Rb null erythroblasts by treatment of mice with the anti-oxidant N-acetyl cysteine (NAC) rescued aspects of the erythroid defect, including red cell enucleation and also extended the lifespan of Rb null mice. Similarly, chelation of labile iron with desferroxiamine restored enucleation capacity to Rb null erythroblasts. Furthermore, we show that the transferrin receptor (CD71) is transcriptionally repressed by pRb/E2F and examine whether deregulated expression of CD71 contributes to increased labile iron and oxidative stress in Rb null erythroblasts. These results suggest that loss of pRb limits the ability of erythroblasts to manage labile iron and oxidative stress, in part through deregulated expression of CD71, and that this contributes to the enucleation defect observed in Rb null mice. Given that pRb is itself regulated by ROS, we present a model in which the timely induction and repression of the CD71 receptor in differentiating erythroblasts is required to manage labile iron, oxidative stress and to coordinate cell cycle exit with end-stage maturation.

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Complete Spatial Mapping of Steady-State and Stress Erythropoiesis

Blood ◽

10.1182/blood-2020-142973 ◽

2020 ◽

Vol 136 (Supplement 1) ◽

pp. 7-7

Author(s):

Qingqing Wu ◽

Jizhou Zhang ◽

Courtney Johnson ◽

Anastasiya Slaughter ◽

Margot Lindsay May ◽

...

Keyword(s):

Bone Marrow ◽

Steady State ◽

Single Cells ◽

Differentially Expressed ◽

Published Data ◽

Erythroid Progenitors ◽

Erythroid Progenitor ◽

Clonal Architecture ◽

Stress Erythropoiesis

The anatomy of differentiation in the bone marrow (BM) is poorly understood due to lack of markers to image stepwise HSPC differentiation. We analyzed 250+ cell surface molecules in all hematopoietic progenitors and identified 56 differentially expressed markers in at least one HSPC that can be "mixed and matched" to prospectively image any HSPC of interest in the bone marrow. We used this data to develop a pipeline to map stepwise erythropoiesis in vivo. We found that all erythroid progenitors can be defined as Ly6C-CD27-ESAM-CD117+ cells and then Pre-MegE (earliest erythroid progenitor Cell Stem Cell. 2007 1(4):428-42) are CD150+CD71-. These give rise to CD71+CD150+ Pre-CFU-E that differentiate into CD71+CD150- CFU-E that then generate early erythroblasts. All BFU-E activity was restricted to Pre-MegE and Pre- CFU-E (70 and 30% of all BFU-E) whereas all CFU-E colonies were spread between Pre-MegE (44%), pre-CFU-E (10%) and CFU-E (46%). We also confirmed previously published data showing that CD71 and Ter119 can be used to image stepwise terminal erythropoiesis; CD71+Ter119dim early erythroblasts, CD71+Ter119bright late erythroblasts, CD71dimTer119bright reticulocytes and CD71-Ter119bright erythrocytes. Importantly, all populations were detected at identical frequencies using FACS or confocal imaging indicating that our imaging strategy detects all erythroid cells (Pre-CFU-E: 0.022 vs 0.027 %; CFUE: 0.32 vs 0.30%; Early-Ery: 0.62 vs 0.66%; Late-Ery: 32.05 vs 32.12%; Reticulocyte: 5.98 vs. 3.36%; Erythrocytes: 12.49 vs. 13.47%). We mapped the 3D location of every erythroid lineage cell in mouse sternum and interrogated the spatial relationships between the different maturation steps and with candidate niches. We compared the interactions found in vivo with those found in random simulations. Specifically, we used CD45 and Ter119 to obtain the spatial coordinates of every hematopoietic cell. Then we randomly placed each type of erythroid lineage cell at identical frequencies as those found in vivo to generate random simulations. We found erythroid progenitors show no specific association with HSC, indicating that Pre-Meg-E or more primitive progenitors leave the HSC niche after differentiation. Both Pre-Meg-E and Pre-CFU-E are found as single cells through the central BM space and do not specifically associate with other progenitors, or components of the microenvironment. In contrast almost all CFU-E locate to strings (28 strings per sternum) containing 8 CFU-E that are selectively recruited to sinusoids (mean CFU-E to sinusoid distance=2.2µm). As soon as CFU-E detach from sinusoids they downregulate CD117 and upregulate CD71 giving rise to a cluster of early erythroblasts that buds from the vessel. These progressively upregulate Ter119 to generate large clusters of late erythroblasts that in turn differentiate into clusters of reticulocytes and erythrocytes. To examine the clonal architecture of erythropoiesis we used Ubc-creERT2:confetti mice where a tamoxifen pulse leads to irreversible expression of GFP, CFP, YFP or RFP. Four weeks later we found that the CFU-E strings are oligoclonal with each clone contributing 2-6 CFU-E to the string. The budding erythroblasts clusters are similarly organized. These indicate that different CFU-E are serially recruited to the same sinusoidal spot where they self-renew 1-2 times and then undergo terminal differentiation. We then tracked how this architecture changed in response to stress (hemorrhage). Two days after bleeding we found that Pre-Meg-E and Pre-CFU-E numbers and locations were unaltered. The number of CFU-E strings remained constant (30 CFUE strings/sternum) but all strings contained more CFU-E (2-fold) suggesting increased self-renewal. Unexpectedly, fate mapping showed that the size of CFU-E clones did not increase when compared to steady-state. These results indicate that all CFU-E expand in respond to stress and that this is mediated via increased recruitment and differentiation of upstream progenitors. In summary we have found 56 differentially expressed markers that can be combined to detect most HSPC; validated a 5-color stain to image and fate map all steps of red blood cell maturation in situ; demonstrated that terminal erythropoiesis emerges from strings of sinusoidal CFU-E, and revealed the clonal architecture of normal and stress erythropoiesis. Disclosures No relevant conflicts of interest to declare.

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The MAPK ERK1 is a negative regulator of the adult steady-state splenic erythropoiesis

Blood ◽

10.1182/blood-2009-09-242487 ◽

2010 ◽

Vol 115 (18) ◽

pp. 3686-3694 ◽

Cited By ~ 31

Author(s):

Soizic Guihard ◽

Denis Clay ◽

Laurence Cocault ◽

Nathalie Saulnier ◽

Paule Opolon ◽

...

Keyword(s):

Bone Marrow ◽

Steady State ◽

Bone Marrow Cells ◽

Serum Levels ◽

Negative Regulator ◽

Erythroid Progenitors ◽

Stress Erythropoiesis ◽

Extracellular Signal ◽

Mitogen Activated Protein

Abstract The mitogen-activated protein kinases (MAPKs) extracellular signal-regulated kinase 1 (ERK1) and ERK2 are among the main signal transduction molecules, but little is known about their isoform-specific functions in vivo. We have examined the role of ERK1 in adult hematopoiesis with ERK1−/− mice. Loss of ERK1 resulted in an enhanced splenic erythropoiesis, characterized by an accumulation of erythroid progenitors in the spleen, without any effect on the other lineages or on bone marrow erythropoiesis. This result suggests that the ablation of ERK1 induces a splenic stress erythropoiesis phenotype. However, the mice display no anemia. Deletion of ERK1 did not affect erythropoietin (EPO) serum levels or EPO/EPO receptor signaling and was not compensated by ERK2. Splenic stress erythropoiesis response has been shown to require bone morphogenetic protein 4 (BMP4)–dependent signaling in vivo and to rely on the expansion of a resident specialized population of erythroid progenitors, termed stress erythroid burst-forming units (BFU-Es). A great expansion of stress BFU-Es and increased levels of BMP4 mRNA were found in ERK1−/− spleens. The ERK1−/− phenotype can be transferred by bone marrow cells. These findings show that ERK1 controls a BMP4-dependent step, regulating the steady state of splenic erythropoiesis.

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A Shared Signaling Network That Maintains Erythroid Homeostasis By Activating Stress Erythropoiesis Regulates Inflammation: Implications for the Anemia of Chronic Inflammation

Blood ◽

10.1182/blood-2018-99-113448 ◽

2018 ◽

Vol 132 (Supplement 1) ◽

pp. 629-629

Author(s):

James Fraser ◽

Adwitia Dey ◽

Shaneice Nettleford ◽

Siyang Hao ◽

Luming Zhao ◽

...

Keyword(s):

Bone Marrow ◽

T Cells ◽

Steady State ◽

Inflammatory Cytokines ◽

Red Cell ◽

Erythroid Progenitors ◽

Stress Erythropoiesis ◽

Inflammatory Signals ◽

Treg Development ◽

Pro Inflammatory Cytokines

Abstract Anemia is a common secondary pathology resulting from inflammatory diseases including cancer or infection. Its exact prevalence is difficult to determine, yet its contributions to the morbidity and mortality of patients and its negative impact on quality of life are clear. Despite the diverse set of factors that can lead to inflammatory anemia, its core pathology of hyperinflammation, iron dysregulation, and lack of red cell production suggests the possibility of a common etiology. Inflammation induces pro-inflammatory cytokines including TNFα, IL-1β and IFNγ that drive myelopoiesis at the expense of steady state bone marrow erythropoiesis. In addition, other cytokines increase the expression of hepcidin, haptoglobin and hemopexin by the liver, leading to the sequestration of iron. While limiting iron can be beneficial in the context of infection, the consequence of this restriction is a further reduction in red cell production in the bone marrow. To compensate for the loss of bone marrow erythropoiesis, inflammation induces stress erythropoiesis in the spleen or liver. Stress erythropoiesis is regulated by different signals which include BMP4 and GDF15 and utilizes stress erythroid progenitors that are distinct from steady state erythroid progenitors. Our work shows that in contrast to steady state erythropoiesis, pro-inflammatory cytokines like TNFα promote the proliferation of stress erythroid progenitors, while anti-inflammatory signals such as PGJ2 and IL-10 promote their differentiation. These studies demonstrate that the expansion and differentiation stages of stress erythropoiesis are coordinated with, and influenced by, signals that initiate and resolve inflammation. In addition, we show that this regulation is reciprocal. Signals that regulate the differentiation of stress erythroid progenitors (GDF15 and BMP4) promote the resolution of inflammation. Mice infected with the model gut pathogen Citrobacter rodentium, exhibit stress erythropoiesis in the spleen, while steady state erythropoiesis in the bone marrow is suppressed until pathogen clearance. We observed that hepcidin expression in the liver increases initially, but then decreases as the expression of erythroferrone by stress erythroid progenitors increased in the spleen, but not the bone marrow. Using mice mutant for GDF15 (GDF15-/-) and for BMP4 signaling (flexed-tail f/f), which exhibit defective stress erythropoiesis, we observed that the expression of hepcidin was dysregulated suggesting that stress erythroid progenitors are responsible for iron regulation at this time. In addition, infection of mutant mice led to increased lethality. During peak infection, we observed morphological differences in the colons of these mice indicative of increased inflammation and systemic infection. These changes were associated with increased expression of pro-inflammatory genes, as well as decreased numbers of FoxP3+ regulatory T-cells (Tregs). Using naïve CD4+ T-cells isolated from uninfected control, f/f or GDF15-/- mice, we observed significantly altered gene expression from mutant T-cells following Treg induction in vitro. However, the addition of BMP4 and GDF15 into these cultures rescued Treg development of mutant naïve T-cells and enhanced Treg development of naïve control T cells. Analysis of the BMP4 and GDF15 signaling pathways in both stress erythroid progenitor differentiation and in Treg development revealed that in both systems these signals converge on the transcription factor HIF1α. Taken together these data support a new model showing that the loss of steady state erythropoiesis due to pro-inflammatory signals is balanced by the activation of stress erythropoiesis by those same factors. Similarly, the differentiation of stress erythroid progenitors appears to regulate iron, and is itself regulated by the same signals that drive the development of Tregs and the expression of anti-inflammatory cytokines during immune resolution. This work supports a novel model where initiation and resolution of inflammatory immune responses are co-regulated with stress erythropoiesis, which allows for a robust immune response while maintaining erythroid homeostasis. Furthermore, this model predicts that alterations to this shared signaling network will underlie the development of chronic inflammatory anemia. Disclosures No relevant conflicts of interest to declare.

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Inflammation induces stress erythropoiesis through heme-dependent activation of SPI-C

Science Signaling ◽

10.1126/scisignal.aap7336 ◽

2019 ◽

Vol 12 (598) ◽

pp. eaap7336 ◽

Cited By ~ 12

Author(s):

Laura F. Bennett ◽

Chang Liao ◽

Michael D. Quickel ◽

Beng San Yeoh ◽

Matam Vijay-Kumar ◽

...

Keyword(s):

Bone Marrow ◽

Steady State ◽

Proinflammatory Cytokines ◽

Lymphoid Cells ◽

Sterile Inflammation ◽

Erythroid Progenitors ◽

Gene Encoding ◽

Immune Effector ◽

Effector Cells ◽

Stress Erythropoiesis

Inflammation alters bone marrow hematopoiesis to favor the production of innate immune effector cells at the expense of lymphoid cells and erythrocytes. Furthermore, proinflammatory cytokines inhibit steady-state erythropoiesis, which leads to the development of anemia in diseases with chronic inflammation. Acute anemia or hypoxic stress induces stress erythropoiesis, which generates a wave of new erythrocytes to maintain erythroid homeostasis until steady-state erythropoiesis can resume. Although hypoxia-dependent signaling is a key component of stress erythropoiesis, we found that inflammation also induced stress erythropoiesis in the absence of hypoxia. Using a mouse model of sterile inflammation, we demonstrated that signaling through Toll-like receptors (TLRs) paradoxically increased the phagocytosis of erythrocytes (erythrophagocytosis) by macrophages in the spleen, which enabled expression of the heme-responsive gene encoding the transcription factor SPI-C. Increased amounts of SPI-C coupled with TLR signaling promoted the expression ofGdf15andBmp4, both of which encode ligands that initiate the expansion of stress erythroid progenitors (SEPs) in the spleen. Furthermore, despite their inhibition of steady-state erythropoiesis in the bone marrow, the proinflammatory cytokines TNF-α and IL-1β promoted the expansion and differentiation of SEPs in the spleen. These data suggest that inflammatory signals induce stress erythropoiesis to maintain erythroid homeostasis when inflammation inhibits steady-state erythropoiesis.

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Fra-2 Expression in Osteoblasts Regulates Systemic Inflammation and Lung Injury through Osteopontin

Molecular and Cellular Biology ◽

10.1128/mcb.00022-18 ◽

2018 ◽

Vol 38 (22) ◽

Cited By ~ 4

Author(s):

Yubin Luo ◽

Bettina Grötsch ◽

Nicole Hannemann ◽

Maria Jimenez ◽

Natacha Ipseiz ◽

...

Keyword(s):

Bone Marrow ◽

Lung Injury ◽

Inflammatory Response ◽

Immune Cells ◽

Inflammatory Responses ◽

Bone Marrow Microenvironment ◽

Innate Immune ◽

Bone Marrow Niche ◽

Innate Immune Cells ◽

Molecular Changes

ABSTRACT Inflammatory responses require mobilization of innate immune cells from the bone marrow. The functionality of this process depends on the state of the bone marrow microenvironment. We therefore hypothesized that molecular changes in osteoblasts, which are essential stromal cells of the bone marrow microenvironment, influence the inflammatory response. Here, we show that osteoblast-specific expression of the AP-1 transcription factor Fra-2 (Fra-2Ob-tet) induced a systemic inflammatory state with infiltration of neutrophils and proinflammatory macrophages into the spleen and liver as well as increased levels of proinflammatory cytokines, such as interleukin-1β (IL-1β), IL-6, and granulocyte-macrophage colony-stimulating factor (GM-CSF). By in vivo inhibition of osteopontin (OPN) in Fra-2Ob-tet mice, we demonstrated that this process was dependent on OPN expression, which mediates alterations of the bone marrow niche. OPN expression was transcriptionally enhanced by Fra-2 and stimulated mesenchymal stem cell (MSC) expansion. Furthermore, in a murine lung injury model, Fra-2Ob-tet mice showed increased inflammatory responses and more severe disease features via an enhanced and sustained inflammatory response to lipopolysaccharide (LPS). Our findings demonstrate for the first time that molecular changes in osteoblasts influence the susceptibility to inflammation by altering evasion of innate immune cells from the bone marrow space.

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