The expression of embryonic globin mRNA in a severely anemic mouse model induced by treatment with nitrogen-containing bisphosphonate

Mammalian hematopoiesis occurs in two distinct waves, commonly referred to as primitive and definitive, that originate in the yolk sac and in the fetal liver and bone marrow (BM), respectively [1]. Yolk sac-derived primitive erythroid cells remain nucleated and enucleated terminally in the circulation, whereas definitive erythroid cells produced in the fetal liver are released into circulation after complete maturation [2‐5]. The components of the globin tetramer are encoded by the α- and β-globin gene loci. There are 3 functional α-globins (ζ-, α1- and α2) and 4 β-globins (Ey-, βh1-, β1- and β2-) in mice [2, 6, 7]. Primitive erythrocytes express the embryonic complement of globin chains, which initially consist of ζ- and βh1-globins, followed by α1- and α2-, and Ey-globins at the primitive proerythroblast stage [2, 6, 7]. Definitive erythroid cells complete their maturation and enucleation at erythropoietic sites, the fetal liver and BM, where the adult complement of globin chains consists of α1-, α2- β1- and β2- are expressed. All of the globin genes in the α- and β-globin clusters are expressed in primitive erythroid cells, whereas definitive erythroid cells express only the adult globin genes [8].

The expression of globin genes is jointly regulated by elements in the promoter regions and an upstream enhancer region called, the locus control region (LCR) [5]. The TATA, CAAT and CACCC regulatory elements are found within the promoters of all globin genes. A variety of nuclear factors that are involved in transcriptional regulation have been suggested to be related to globin gene expression and switches between them [9, 10]. Members of the KLF (Kruppel-like factor) family are known as an essential transcription factor that bind GC-rich sequences, such as the CACCC element, to regulate the biological dynamic during development [11]. KLF1 (EKLF: erythroid Kruppel-like factor) is a member of the KLF family that plays an essential role in erythropoiesis and is involved in the expression of β-like embryonic globin by binding to its promoter region [12, 13]. KLF2 has been found to regulate biological activity in various tissues and to enhance the expression of β-like embryonic globin [14, 15].

All hematopoietic cells are derived from hematopoietic stem cells (HSC) that develop into mature lineage cells during definitive hematopoiesis [2, 5]. Definitive erythropoiesis requires a specific microenvironment that contacts stromal cells; these groups of cells are called “erythroblastic islands”. Macrophages directly contact erythroid progenitors in the BM and fetal liver via several types of adhesion molecules, including EMP, α_V integrin and VCAM-1, which participate in their differentiation, survival and maturation during erythropoiesis [16‐19]. These central macrophages may also be an important source of cytokines, particularly erythropoietin (EPO), which supports the maturation of erythroid cells [20, 21]. However, primitive erythropoiesis occurs without macrophages and some cytokines, such as SCF and EPO, are essential for definitive erythropoiesis [3]. These results indicate that erythroblast-macrophage interactions might be specifically essential for definitive erythropoiesis.

Bisphosphonates (BPs) are potent inhibitors of osteoclast-mediated bone resorption and are used as therapeutic agents against bone resorptive disorders such as osteoporosis and metastatic bone diseases [22, 23]. The use of nitrogen-containing bisphosphonates (NBPs) results in strong anti-bone resorptive effects that are much more potent than the effect of non-nitrogen-containing bisphosphonates (non-NBPs). In addition, NBPs have inflammatory side effects including fever, jaw osteomyelitis, osteonecrosis and extramedullary erythropoiesis [24‐26]. Our previous study reported that a single injection of a relatively large dose of the NBP into mice inhibited bone resorption by osteoclasts, induced extramedullary erythropoiesis by depleting resident BM macrophages and increased the number of granulocytes in the peripheral blood [26]. Moreover, the injection of an NBP into splenectomized mice induced extramedullary erythropoiesis without anemia and alterations in EPO concentrations in the liver [27]. Phenylhydrazine (PHZ) is used to experimentally induce hemolytic anemia in laboratory animals [28]. The mechanism by which it causes anemia is RBC lipid peroxidation [29]. These results lead to suggest the change of erythropoiesis in the medullary and extramedullary hematopoietic sites by treatment with both NBP and PHZ, which indirectly inhibits erythropoiesis and directly disrupts erythrocytes.

In this study, we established a model of critical anemia in mice through the combined use of NBP with PHZ and analyzed the expression pattern of hemoglobin as well as changes in erythropoiesis and erythropoiesis-regulated factors in medullary and extramedullary erythropoietic sites.

Primitive and definitive erythroid cells display many differences that are consistent with the notion that they constitute distinct erythroid lineages. The two sequences of erythropoietic events that lead to the development of these cells never occur simultaneously in adults; therefore, embryonic globin is not expressed in adult mammals under normal conditions [2, 5, 9, 31]. However, in this study, we detected the expression of embryonic globins in genetically normal adult splenectomized mice under specific conditions including the the elimination of BM resident macrophages and the induction of critical anemia. Moreover, numerous nucleated erythrocytes appeared in the peripheral blood, and some erythroid cells were found to be CD71-positive. These cells were very similar to primitive erythrocytes [32]. Although certain diseases such as thalassemia and some knockout models that contain deletions in some important hemoglobin switching genes are associated with the expression of embryonic globins after birth, there are no reports showing that wild type adult mice express embryonic globins [32‐34]. Therefore, the present study contributes a novel experimental model that can be used to analyze the expression of embryonic globins and the results of this study suggests that yolk sac-derived primitive erythroid precursors are maintained in adult mammals in this model.

Various transcription factors related to erythropoiesis and the regulation of hemoglobin expression have been identified [5, 11]. In this study, the up-regulation of Klf1 and Klf2 was detected in the BM and liver. Moreover, we also confirmed KLF1 and KLF binding to the promoter region of β-like embryonic globin. These results indicate that KLF1 and KLF2 regulate the expression of β-like embryonic globin. We detected the expression of Gata1 and Bcl11a mRNAs in the BM and liver in splenectomized mice that were treated with both NBP and PHZ. A recent study has shown that Bcl11a expression is regulated by KLF1, suggesting an intricate mechanism in which the developmental regulation of β-like globin genes is coordinated by KLF1 and Bcl11a [35]. In fact, the conditional knock out of Bcl11a in mice resulted in a decrease in the expression levels of embryonic globins in the BM compared to levels in the E18.5 fetal liver [36]. In this study, Bcl11a was constitutively expressed in the BM and liver under normal conditions, and its expression levels were unchanged even in animals with anemia. These results suggest that Bcl11a may not be associated with the expression of embryonic globin in this study because the cells expressing embryonic globin contained decreased levels of Bcl11a and the cells that expressed adult globin showed no change in the expression of Bcl11a. In addition, Bcl11a is essential for normal lymphocyte development mice.

During embryogenesis, the embryo is exposed to hypoxemia. Therefore, primitive hemoglobin has a higher affinity for oxygen than adult hemoglobin because it must provide all oxygenation to the body, and changes in the partial pressure of oxygen has been associated with globin switching [37, 38]. Our data suggest that the expression of embryonic globins might be more effectively rescuing the hypoxemia that is associated with critical anemia than the enhanced production of normal definitive erythroid cells. The hypoxic response is controlled by two transcriptional regulatory complexes called hypoxia inducible factors (HIFs). These link iron homeostasis and erythropoiesis by targeting EPO [5, 39]. Although a direct association between the HIFs and the expression of embryonic globins has not been described, EPO has been suggested to support primitive hematopoiesis and to increase the expression of embryonic globin during embryogenesis [40, 41]. Therefore, the high EPO concentration caused by hypoxia might be partially responsible for the expression of embryonic globins in this study.

We confirmed that there were differences in expression patterns between the BM and liver, suggesting that cells in the liver originate in a different microenvironment, via a different mechanism and/or from a cell origin that is different from that in the BM. In fact, some hematopoiesis-related factors show different expression patterns between the E18.5 fetal BM and liver [42]. Our ISH data indicate that a relatively large number of cells expressed embryonic globins in the liver whereas only a few cells expressed these mRNAs in the BM. qRT-PCR analysis also showed that the expression level of embryonic globin in the liver was higher than level in the BM (Additional file 2). Erythropoiesis in the BM may primarily produce definitive erythroid cells, and the primitive-type may originate from a small population of hematopoietic cells. The liver is associated with fetal hematopoiesis, including primitive erythropoiesis [43]. These results may be related to the availability for quick induction of extramedullary hematopoiesis and the formation of a niche for primitive erythropoiesis in the liver.

Resident macrophages act as pivotal stromal cells during definitive erythropoiesis. In fact, erythropoiesis was inhibited by the elimination of BM resident macrophages in our previous studies [26, 27]. In addition, macrophages perform essential roles even in extramedullary erythropoiesis and abnormal erythropoiesis, such as that observed in β-thalassemia, whereas primitive erythroid cells do not require macrophages in the stroma [44]. An ISH study indicated that some TER119-positive colonies were composed of both embryonic globin-expressing and -non-expressing cells. In the early stage of the transition from primitive to definitive hematopoiesis, primitive hematopoietic cells migrate to the fetal liver, contact macrophages, and continue to express embryonic type globins within a short period of time. In our experiments, some of the TER119-positive cells did not express embryonic globin mRNAs. These results did not clearly indicate the origin of the hematopoietic cells expressing embryonic globins, but they do suggest that the expression of embryonic globins in this study could have been caused by both the depletion of macrophages and stimulation with an acute hypoxemia.

In this study, we were unable to define the origin of the erythroid cells that expressed embryonic globins. Because some tissue macrophages originate in the yolk sac and then proliferate in peripheral tissues [45, 46], we were unable to eliminate the possibility that these cells were derived from primitive hematopoietic cells and that these primitive erythroid precursor cells might be reactivated by the elimination of stroma cells and the presence of hypoxic stress. Further studies will be necessary to determine the origin of these cells.

New structures were unexpectedly induced in the peritoneum and/or omentum of some of the splenectomized mice that were treated with both NBP and PHZ (Fig. 6). These were wine-colored structures that resembled hemal nodes and showed active hematopoiesis. Extramedullary erythropoiesis is induced in various organs by certain conditions such as acute anemia, NBP injection, myelofibrosis, and blood cancer [26‐28]. The induction of hemal node-like structures could be caused by insufficient hematopoiesis in the BM and the liver. Further study is required to clarify the mechanism that cause the induction of these newly hematopoietic organs.

The results showing that a relatively large number of erythroblasts form clusters and nucleated erythrocytes in the peripheral blood suggest the existence of primitive erythroid cells in the mice. These cells were large, nucleated erythrocytes. The presence of embryonic or fetal hemoglobin has been suggested in hematopoietic progenitors in human peripheral blood, but this does not explain the expression of these hemoglobin in hematopoietic sites [47, 48]. Several reports have also demonstrated the expression of embryonic or fetal globins in vitro [49, 50]; however, our study has shown for the first time, the simultaneous expression of embryonic and adult globins in erythrocytes in genetically normal mice. These results contribute to our understanding of normal and disease-related hematopoiesis.

We established a severely anemic mice model by the sequential treatment with NBP and PHZ. This model showed the emergence of nucleated erythrocytes in peripheral blood and the expressions of embryonic types of hemoglobin in hematopoietic sites. Our results might indicate the flexible property of hematopoiesis and the possibility that yolk sac-derived primitive erythroid cells may persist into adulthood in mice.