Abstract
Glutathione peroxidase 4 (GPX4) is unique as it is the only enzyme that can prevent detrimental lipid peroxidation in vivo by reducing lipid peroxides to the respective alcohols thereby stabilizing oxidation products of unsaturated fatty acids. During reticulocyte maturation, lipid peroxidation mediated by 15-lipoxygenase in humans and rabbits and by 12/15-lipoxygenase (ALOX15) in mice was considered the initiating event for the elimination of mitochondria but is now known to occur through mitophagy. Yet, genetic ablation of the Alox15 gene in mice failed to provide evidence for this hypothesis. We designed a different genetic approach to tackle this open conundrum. Since either other lipoxygenases or non-enzymatic autooxidative mechanisms may compensate for the loss of Alox15, we asked whether ablation of Gpx4 in the hematopoietic system would result in the perturbation of reticulocyte maturation. Quantitative assessment of erythropoiesis indices in the blood, bone marrow (BM) and spleen of chimeric mice with Gpx4 ablated in hematopoietic cells revealed anemia with an increase in the fraction of erythroid precursor cells and reticulocytes. Additional dietary vitamin E depletion strongly aggravated the anemic phenotype. Despite strong extramedullary erythropoiesis reticulocytes failed to mature and accumulated large autophagosomes with engulfed mitochondria. Gpx4-deficiency in hematopoietic cells led to systemic hepatic iron overload and simultaneous severe iron demand in the erythroid system. Despite extremely high erythropoietin and erythroferrone levels in the plasma, hepcidin expression remained unchanged. Conclusively, perturbed reticulocyte maturation in response to Gpx4 loss in hematopoietic cells thus causes ineffective erythropoiesis, a phenotype partially masked by dietary vitamin E supplementation.Introduction
Glutathione peroxidase 4 (GPX4) is unique in its ability to reduce lipid peroxidation products in biological membranes in vivo. Lipid peroxidation is brought about either enzymatically by lipoxygenases at specific sites or unselectively by non-enzymatic mechanisms, usually through Fe-driven Fenton chemistry.3 Lipoxygenases are dioxygenases that catalyze the incorporation of molecular oxygen into polyunsaturated fatty acids (PUFA) in a site- and stereospecific manner thus yielding the respective hydroxyperoxides. Lipoxygenases become activated by low concentrations of peroxides (the so called “peroxide tone”) that oxidize Fe to Fe in the catalytic site.4 The peroxide tone and the activity of lipoxygenases is under the control of GPX4. 12/15-Lipoxygenase and GPX4 act antagonistically as far as oxidation (lipoxygenases) and reduction (GPX4) of substrates, and induction of cell death and cell survival are concerned. 12/15-Lipoxygenase induces cell death in murine fibroblasts, whereas GPX4 rescues cells from lipoxygenase-induced cell death.5 But in other settings, lipoxygenases and GPX4 biochemically cooperate: lipoxygenases generate highly reactive peroxidation products of unsaturated fatty acids (P-O-O-H) that are prone to further uncontrolled lipid membrane peroxidation. GPX4 reduces these peroxides to stable hydroxyl-derivatives (P-O-H).96 Thereby, 15-lipoxygenase in humans or 12/15-lipoxygenase, its functional homolog in mice, and GPX4 constitute a pair of enzymes whose activities are tightly interconnected. In the interplay of lipoxygenases and GPX4 the role of vitamin E also has to be considered. Vitamin E intercalates into membranes, acts as a chain breaker of lipid peroxidation through its high affinity for unpaired electrons and thus antagonizes peroxide production.
GPX4 is 1 of 24 (25 in man) selenoproteins in mammals10 and is positioned at the top of the hierarchy of selenoproteins, i.e. Gpx4 expression is maintained even under severe selenium-deficiency when the synthesis of most other selenoproteins has ceased.11 GPX4 has evolved to carry the 21 amino acid selenocysteine rather than its functional counterpart cysteine in the active site which renders the enzyme highly resistant to irreversible overoxidation through peroxides.12 Dietary selenium is known to be required for stress erythropoiesis in mice and blockage of the synthesis of all selenoproteins in hematopoietic cells by selective deletion of the selenocysteine-specific t-RNA Trsp in the BM of chimeric mice severely impairs stress erythropoiesis.13
Mitochondria are removed from reticulocytes by a particular form of autophagy, called mitophagy, and oxidized lipids are considered to play a crucial role in triggering autophagy in various cell types. Furthermore, macrophages from 12/15-lipoxygenase knockout (k.o.) mice exhibit abnormal mitochondria, cytoplasmic vacuoles and an altered phospholipidomics pattern indicative of impaired autophagy.19 In addition, the 12/15-lipoxyge-nase oxidation product 12-hydroxyeicosatetraenoic acidphosphatidylethanolamine (12-HETE-PE) was shown to be a better substrate for yeast Atg8 than native PE, whereas native as well as oxidized PE were both effective substrates for LC3 lipidation. With regard to reticulocyte maturation current data suggest that elimination of mitochondria through mitophagy may be stimulated by oxidation products of polyunsaturated membrane phospholipids.
15-lipoxygenase is highly expressed in reticulocytes and was reported to be involved in the elimination of mitochondria by Rapoport and his coworkers.2320 The initial work of the Rapoport group was confirmed and extended by van Leyen et al. who reported a similar 12/15-lipoxyge-nase-driven mechanism that degrades organelles in the eye lens.2524 Yet, the great interest in this early work decreased with the findings that erythrocyte and reticulocyte counts were normal in 12/15-lipoxygenase ko mice.26 Definitive genetic proof for a role of lipid oxidation during reticulocyte maturation is thus still lacking. Several reasons may account for the fact that 12/15-lipoxygenase k.o. mice exhibit normal red blood and reticulocyte counts: (i) lipoxygenases other than 12/15-lipoxygenase may compensate for the targeted loss of reticulocyte 12/15-lipoxyge-nase; (ii) lipoxygenases may become dispensable if non-enzymatic mechanisms of lipid oxidation prevail;2927 or (iii) lipid oxidation events are dispensable during reticulocyte maturation.
Our present work was conceived to definitively answer if lipid oxidation is indeed critically involved in mitophagy in reticulocytes using a well-defined genetic approach. Whereas many different enzymatic and non-enzymatic mechanisms may account for the initial lipid oxidation step, GPX4 stands out as the only enzyme that effectively prevents detrimental lipid peroxidation and allows lipid oxidation to proceed in a highly controlled manner. Thus, if lipid oxidation is an essential step in the elimination of mitochondria in reticulocytes, ablation of Gpx4 should result in uncontrolled lipid peroxidation and perturbation of reticulocyte maturation. Since GPX4 is essential for early embryonic development and the survival of adult mice,3130 Gpx4 had to be deleted specifically in hematopoietic cells. To this end, we took advantage of the Tamoxifen-inducible Cre/lox system,32 which is of invaluable help when the side effects of Cre3733 and Cre activators38 or inducers39 are properly controlled. We show that GPX4 is required for stress erythropoiesis. Deletion of Gpx4 in adult mice causes anemia and ineffective erythropoiesis due to impaired reticulocyte maturation, a phenotype dramatically aggravated by depleting vitamin E from the diet. As a consequence hepatic iron overload develops despite the continuous iron demand for red blood cell production.
Methods
Mice
Mice were bred under SPF conditions. Gpx4fl/fl;CreERT2 mice were backcrossed for at least ten generations onto C57BL/6J mice (Taconic Biosciences, Köln, Germany). All animal experiments were performed according to the institutional guidelines and were approved by the local ethic committees on animal experimentation and by the Government of Upper Bavaria and Kantonales Veterinäramt in Zürich, respectively.
Generation of chimeric mice with Gpx4-proficient and Gpx4-deficient hematopoietic cells and analysis of blood parameters
Female wild-type (wt) recipient mice of 10 to 12 weeks (Taconic Biosciences, Köln) were lethally irradiated with 850 cGy and reconstituted with 10 BM cells from Gpx4fl/fl;CreERT2 or Gpx4wt/wt;CreERT2 donor mice. BM cells had been collected by flushing the leg bones and crushing the pelvic bone. Gpx4fl/fl;CreERT2 and Gpx4wt/wt;CreERT2 mice have been described.32315 150 mg/kg 5-fluorouracil (FU) had been administered to donor mice by intraperitoneal (i.p.) injection 24 hours prior to collecting BM cells from donor mice. After hematopoietic reconstitution mice were allowed to recover for 25 weeks. Mice were fed a tamoxifen citrate containing diet for three weeks following the protocol of Kiermayer et al.40 to delete Gpx4. Ethylenediamine tetraacetic acid (EDTA)-blood was collected from the tail vein before, at the last day of and at different time points after tamoxifen administration, and subjected to the analysis of blood parameters using a Sysmex XT-2000iV apparatus as described.41
Vitamin E depletion and repletion
Mice were deprived from vitamin E by feeding a vitamin E-depleted diet (SSNIFF, Soest, Germany) containing 7ppm α-tocopherol as compared to 55ppm in the normal diet. In initial experiments the conditions for ruling out side effects of Cre activation33 with and without vitamin E-depletion using Gpx4wt/wt;CreERT2 mice as controls were defined (Online Supplementary Figure S1). This allowed to apply a simplified proto col with C57BL/6J mice as controls and tamoxifen-treated, lethally irradiated wt mice reconstituted with BM cells of Gpx4fl/fl;CreERT2 mice receiving a normal or a vitamin E-depleted diet as experimental groups (Figure 2–5 and Online Supplementary Figure S5). The vitamin E-repleted diet (5x vitamin E) contained 275ppm α-tocopherol (SSNIFF, Soest, Germany).
Staining of erythroid precursor cells from BM and spleen
Spleens were smashed and washed and the four leg bones flushed with 5 mL PBS containing 1mM EDTA and 2% fetal calf serum. Cells were individualized, filtered through a 40 μm cell strainer (BD Falcon) and incubated with 0.5 μg anti-CD16/32 antibody in 50 μL.
PBS for 30min on ice. BM cells were stained with 0.3 μg CD44-PE-Cy7 (or CD71-PE-Cy7), 0.3 μg Ter119-PE or Ter119-APC-Cy7 antibodies. Spleen cells were stained with the following lineage mix: each 0.5 μg biotinylated CD3e (clone 145-2C11), CD11b (clone M1/70), CD19 (clone 1D3), B220 (clone RA3-6B2) and Gr-1 (clone RB6-8C5) antibodies. Cells were washed and stained with Streptavidin-Pacific Blue (Thermo Fisher) and 0.3 μg CD71-PE-Cy7 and 0.3 μg Ter119-PE (or Ter119-APC-Cy7) antibodies. Lineage-negative cells were gated and plotted as CD71-PE-Cy7-versus Ter119-APC-Cy7-positive cells. Cells were analysed on a FACSAriaI (Becton Dickinson).
Antibodies and primers
See Online Supplementary Materials and Methods.
Results
Gpx4-deficiency in hematopoietic cells impairs stress erythropoiesis
To study the role of GPX4 in hematopoiesis, chimeric mice were generated by reconstitution of lethally irradiated wt mice with Gpx4fl/fl;Cre ERT2 or Gpx4wt/wt;Cre-ERT2 BM cells. Gpx4 deletion in the hematopoietic system was induced by feeding tamoxifen citrate for three weeks.40 At the last day of feeding tamoxifen red blood cell (RBC) parameters and white blood cell (WBC) counts were significantly decreased and platelet indices increased in the experimental as well as in the control group revealing apparent Cre-mediated side effects33 (Online Supplementary Figure S1). Lymphocyte and monocyte counts were further decreased by simultaneous deletion of Gpx4 (Online supplementary Figure S1N-O).
Thus, the inducible activation of Cre-ERT2 by tamoxifen caused an aplastic anemia with a moderate decrease in red blood cell RBC counts presumably through induction of a DNA damage response regardless of the presence or absence of Gpx4 in hematopoietic cells. To separate a phenotype caused by Gpx4-deficiency from that of Cre side effects, tamoxifen-treated mice harboring Gpx4fl/fl;Cre ERT2 and Gpx4wt/wt;Cre ERT2 BM cells were allowed to recover and blood was drawn every three weeks (Figure 1). Mice with Gpx4-deficient BM cells remained anemic with strongly elevated reticulocyte counts, whereas mice harboring Gpx4wt/wt;Cre ERT2 BM normalized their RBC parameters within three to six weeks (Figure 1E-H, additional RBC parameters in the Online Supplementary Figure S2B-F). Since recovery from anemia involves stress erythropoiesis,42 Gpx4-deficiency in the hematopoietic compartment thus impairs stress erythropoiesis. The erythropenic phenotype could be serially transplanted into lethally irradiated wt mice in two further rounds using Gpx4-deficient BM donor cells. Gpx4fl/fl;Cre-ERT2 mice served as controls except that tamoxifen feeding was omitted after the first transplantation (Online Supplementary Figure S3). WBC and platelet parameters remained normal except for single outliers that were not reproduced during serial transplantation. The stable transmission of the erythropenic phenotype by serial transplantation is consistent with a marked defect in stress erythropoiesis, as hematopoietic reconstitution after lethal irradiation is driven by stress hematopoiesis.43
Gpx4-deficient macrophages do not contribute to the development of erythropenia induced by deletion of Gpx4 in the hematopoietic system
In our experimental strategy Gpx4 was deleted in all hematopoietic cells including cells of the myeloid lineage. As macrophages are known to contribute to erythropoiesis by forming erythropoietic islands in the BM,44 it was important to discriminate whether erythropenia is brought about by a cell-autonomous effect of GPX4 on the erythroid lineage or by a cell-non-autonomous effect of GPX4 on macrophages. Liao et al. recently described that loss of all selenoproteins in hematopoietic cells by deletion of selenocysteine-specific t-RNA impairs stress erythropoiesis and have attributed this to the loss of selenoprotein W in macrophages.13 Despite the high position of GPX4 in the hierarchy of selenoproteins, a cell-autonomous contribution of GPX4 to stress erythropoiesis was not considered by the authors.
To address a potential contribution of GPX4 in macrophages on stress erythropoiesis, we used Gpx4fl/fl;LysM-Cre mice that delete Gpx4 in macrophages and neutrophils45 and analyzed BM erythroblastic island macrophages (BMEIM) and spleen red pulp macrophages (RPM) by flow cytometry. The number of BMEIM was slightly reduced, while the number of RPM remained unaffected in the absence of Gpx4 (Online Supplementary Figure S4A-C). Importantly, erythrocyte and reticulocyte counts were unaltered as well as hemoglobin and hematocrit values (Figure 1T-W) indicating that GPX4 in macrophages plays a minor if any role in the development of the erythropenia. This strongly argues for a cell-autonomous action of GPX4 in the erythroid system.
Vitamin E-deficiency severely aggravates erythropenia caused by Gpx4-deficiency
In cell culture and in certain tissues (endothelium, T cells, hepatocytes) the phenotype of Gpx4-deficiency can be partially or completely masked by vitamin E in vivo. Vitamin E thus acts as a full or partial backup system for GPX4 in some cell types in vitro and in vivo. To exclude unintended side effects of Cre and Cre inducers or activators with vitamin E deficiency, Gpx4 was deleted prior to vitamin E deprivation. Feeding the vitamin E-depleted diet for three to four weeks to mice with Gpx4-deficiency severely aggravated erythropenia. Despite the strong decrease in RBC count as well as hemoglobin and hematocrit levels, reticulocyte counts were increased only to a small and non-significant extent (Figure 1I-M). This indicates that the anemia caused by Gpx4-deficiency could no longer be compensated by increased production of reticulocytes when the dietary vitamin E level was reduced. In wt control mice, dietary vitamin E deprivation had no impact on RBC parameters (Online Supplementary Figure S5). An increase of the vitamin E (i.e. α-tocopherol) concentration to the 5-fold level in the diet had no impact on erythrocyte counts, hemoglobin and hematocrit values but led to a significant decrease in reticulocyte counts (Figure 1N-R) corroborating the fact that reticulocyte counts respond more sensitively to external factors with impact on erythropoiesis than do other RBC parameters.
Ineffective erythropoiesis in mice with Gpx4-deficient hematopoietic cells
To get deeper insight into the dynamics of Gpx4-deficient erythropoiesis, we quantified the percentage of erythroid precursor cells in the BM and spleen by fluorescence-activated cell sorting (FACS) analysis (Figure 2) and calculated the total numbers of erythroid precursors in these organs (Figure 3A-B). Cell suspensions of BM and spleen were stained with antibodies for CD44 or CD71 and Ter119. Erythroid precursor cells were classified into proerythroblasts based on the expression level of CD44 or CD71 and Ter119. These analyses revealed a marked increase in extramedullary erythropoiesis in the spleen of mice with Gpx4-deficient hematopoiesis (Figure 2H,K), and a pronounced shift towards immature precursors cells in the BM and spleen when vitamin E was additionally depleted (Figure 2 F,L). The dynamic changes became more apparent when the total numbers of erythroid precursors were calculated under the different conditions. In mice with Gpx4-deficient hematopoietic cells the total number of proerythroblasts increased by a factor of 1.7-fold under a normal diet, and to about 4-fold when vitamin E was additionally depleted (Figure 3F). This increase was due to an increase of proerythroblasts in the spleen (Figure 3H). The number of erythroblasts in the spleen of these mice also increased significantly, and again to a much higher extent when vitamin E was depleted (Figure 3K). Under both conditions of Gpx4-deficiency (normal versus vitamin E-depleted diet) the number of erythroblasts in the spleen increased at the expense of erythroblasts in the BM leaving the total number of erythroblasts virtually unchanged (Figure 3 I-K).
The ratio of erythrocytes to proerythroblasts illustrates the efficacy of erythropoiesis. It decreased from about 3400 in wt mice to 1340 in mice with Gpx4-deficient hematopoiesis (Figure 3C-D). While the total number of reticulocytes increased by almost 3-fold and the ratio of reticulocytes to total proerythroblasts increased from 140 in wt mice to 240 in mice with Gpx4-deficient hematopoiesis, RBC counts decreased to 65% (Figure 3L-M) indicating that maturation of reticulocytes to erythrocytes is defective under Gpx4-deficiency.
Under combined Gpx4- and vitamin E-deficiency, the ratio of erythrocytes to proerythroblasts decreased to about 250 (Figure 3E). Erythrocyte counts dropped to less than 30% (compared to wt) (Figure 3M), while the number of reticulocyte counts increased only by about 1.3 fold (Figure 3L). The only moderate and non-significant increase in reticulocyte counts is in stark contrast to the severe anemia under these conditions. The ratio of reticulocytes to total proerythroblasts decreased from 240 in mice with Gpx4-deficient hematopoiesis to 45 in mice with combined Gpx4- and vitamin E-deficiency suggesting that erythroid progenitor cells were lost during differentiation from proerythroblasts to reticulocytes, in addition to the reticulocyte maturation defect observed under these conditions. Mice with Gpx4-deficiency in hematopoietic cells (on a normal diet) showed an increase in the size of the red pulp and the number of Ter119-positive cells (Figure 4B,E) corroborating data showing ineffective erythropoiesis. Yet, iron deposits in the red pulp stemming from physiological RBC turnover diminished (Figure 4B), arguing against hemolysis as the cause of anemia. Upon Gpx4-deficiency and vitamin E depletion, the white pulp dispersed to a large extent and was intermingled with Ter119-positive erythroid cells (Figure 4C,F).
Impaired reticulocyte maturation and increased lipid peroxidation in Gpx4-deficient erythroid cells and aggravation of the phenotype by vitamin E-depletion
Next, we attempted to define the maturation state of the reticulocytes in the anemic mice. To this end, peripheral blood cells were stained with CD71, Ter119, Mitotracker Deep Red, and thiazol orange. Representative examples of mice are depicted in Figure 5A-C (quantification of total numbers of mature, immature and highly immature reticulocytes in the Online Supplementary Figure S6A-F). Deletion of Gpx4 increased not only the total number of reticulocytes, but also that of each fraction: 2.1-fold of mature, 3.5-fold of immature, and 4.2-fold of highly immature reticulocytes (Online Supplementary Figure S6D-F). The differentially higher increase in more immature reticulocytes led to a general shift towards more immature reticulocytes. Under combined Gpx4 and vitamin E deficiency, the number of highly immature reticulocytes increased 7-fold, while the total number of mature reticulocytes decreased by 20%. The failure of reticulocytes to undergo maturation was associated with an increase in lipid peroxidation of reticulocytes and erythrocytes as revealed by Bodipy 581/591-C11-staining. Lipid peroxidation was particularly pronounced in immature reticulocytes when vitamin E was additionally depleted (Figure 5D).
To further study potential subcellular alterations in response to Gpx4 loss, erythrocytes and reticulocytes of the peripheral blood were subjected to ultrastructural analysis by electron microscopy (Figure 5G-L). Reticulocytes in blood of wt mice and in blood of mice lacking Gpx4 in hematopoietic cells were characterized by remnants of ribosomes (fine granular structure) and mitochondria. An accumulation of unphagocytosed mitochondria in large vacuoles was evident when vitamin E was depleted in mice with Gpx4-deficient hematopoiesis in vivo (white arrows in Figure 5G-L) indicating that GPX4 and vitamin E physiologically contribute to mitochondrial clearance during reticulocyte maturation.
Iron overload and oxidative stress in the liver of mice with Gpx4-deficient hematopoiesis
As shown above, Gpx4-deficiency in the hematopoietic system is characterized by ineffective erythropoiesis that is severely aggravated by additional vitamin E deprivation. Ineffective erythropoiesis is also a hallmark of β-thalassemia, and β-thalassemia is associated with iron overload that is known to sustain and to aggravate the anemia in mouse models of β-thalassemia.51 To address whether similar mechanisms are operating in Gpx4-deficient erythropoiesis, iron-related parameters were analyzed in the liver, spleen, and plasma of mice with Gpx4-deficient hematopoiesis. Non-heme iron content in the liver was significantly increased upon deletion of Gpx4 (Figure 6D). At the molecular level iron overload in the liver was confirmed by elevated levels of the iron storage protein Ferritin L (FTL) (Figure 6V). An excess of free iron triggers the formation of reactive oxygen species (ROS) and lipid peroxidation via the Fenton reaction.3 Consistently, markers of oxidative stress such as increased lipid peroxidation products (as revealed by TBARS production) (Figure 6G) and elevated heme oxygenase-1 mRNA and protein levels (Figure 6F,V) were detected in the liver. Combined Gpx4- and vitamin E-deficiency further increased heme oxygenase-1 mRNA and protein levels as well as TBARS production in the liver.
Unaltered hepcidin levels despite higher erythropoietic iron demand
Systemic iron homeostasis is maintained by the hepcidin/ferroportin regulatory system. Hepcidin regulates the amount of iron exported into systemic circulation by modulating cell surface expression of the iron exporter ferroportin on iron exporting cells. Remarkably, despite increased liver non-heme iron levels in mice with Gpx4-deficient hematopoietic cells, hepatic hepcidin mRNA expression was not affected, regardless whether mice were kept on a normal or on a vitamin E-depleted diet (Figure 6H). Likewise, target genes of the iron-sensing BMP/SMAD signaling pathway in the liver (SMAD6, SMAD7, and ID1) were not significantly altered by Gpx4- and vitamin E-deficiency (Figure 6I-K). Hepatic ferroportin mRNA and protein levels were increased upon Gpx4 ablation with or without vitamin E-deficiency (Figure 6E,V), a finding explained by the oxidative stress that occurs in the liver (Figure 6G). Ferroportin expression in the duodenum was unaltered (Online Supplementary Figure S7).
We next measured iron-related plasma parameters. Plasma iron levels were not increased upon Gpx4 deletion, but were increased when Gpx4 was deleted and vitamin E simultaneously depleted (Figure 6N). Despite this, hepcidin levels in the plasma were not altered (Figure 6R). Bilirubin levels appeared to increase with the ablation of Gpx4 under both conditions (± vitamin E), but the standard deviation (SD) was high so that differences became barely significant (Figure 6S-U). Consistent with elevated liver iron levels, plasma ferritin was highly increased under combined Gpx4- and vitamin E-deficiency (Figure 6O).
In mouse models with β-thalassemia plasma erythropoietin (EPO) levels are increased. EPO stimulates the expression of the blood hormone erythroferrone (ERFE) in erythroid precursor cells, which then down regulates hepcidin levels. Similarly, EPO and ERFE levels appeared to be increased in mice with Gpx4-deficient hematopoiesis, but only EPO levels reached significance. Under combined Gpx4- and vitamin E-deficiency plasma EPO and ERFE levels increased to very high and highly significant levels (Figure 6P,Q), apparently mirroring the severity of erythropenia under combined Gpx4- and vitamin E-deficiency.52 Taken together, the defect in reticulocyte maturation by loss of the Gpx4 gene causes ineffective erythropoiesis with simultaneous iron overload in the liver and iron-deficiency in the hematopoietic system and this phenotype is to a large part masked by vitamin E in the normal diet.
Discussion
Based on biochemical studies Schewe et al. reported in 1975 that mitochondrial clearance during reticulocyte maturation is initiated by enzymatic lipid peroxidation.20 These authors purified the enzyme 15-lipoxygenase from rabbit reticulocytes and showed that it oxidizes polyunsaturated fatty acids in mitochondrial membranes as an initiating event in the disposal of mitochondria. Even though the work has been confirmed and extended by others, these studies fell into oblivion due to the fact that erythropoiesis including erythrocyte and reticulocyte counts appeared to be normal in mice lacking 12/15-lipoxygenase.26
However, for a few years the work of the Rapoport group has been regaining attention due to several important novel findings: (i) GPX4 was shown to be an antagonist of a novel 12/15-lipoxygenase-induced, non-apoptotic cell death pathway in murine fibroblasts,5 (ii) this mode of cell death initiated by ablation of Gpx4 has been shown to be driven by iron-induced lipid peroxidation and is now known as ferroptosis, (iii) distinct phospholipid hydroperoxide species have been identified that act as death signals and inducers of ferroptosis in various cell types,54 (iv) vitamin E synergizes with GPX4 in antagonizing the action of lipid hydroxyperoxides in vitro and in vivo, (v) 12/15-lipoxygenase and its hydroxylated oxidation products are involved in the regulation of autophagy in murine macrophages,19 (vi) autophagy is inhibited by oxidation of enzymes like ATG3 and ATG7 that catalyze ATG8/LC3 lipidation,56 (vii) lipoxygenases are not necessarily the decisive source of lipid hydroperoxides, they may rather sensitize cells to iron-mediated non-enzymatic autoxidation.29
It was the aim of our study to identify a missing link between membrane lipid oxidation and reticulocyte maturation by genetic means. Based on the finding that GPX4 is unique in antagonizing lipid membrane hydroperoxides and stabilizing the hydroxylated oxidation products, we hypothesized that deletion of Gpx4 in hematopoietic cells would perturb mitophagy and thus reticulocyte maturation.
The role of GPX4 in hematopoietic cells had already been studied by Canli et al. using Gpx4fl/fl;Mx1-Cre mice.55 These authors primarily focused, however, on the mode of cell death in hematopoietic precursor cells and not on a comprehensive view on Gpx4-deficient erythropoiesis at a quantitative level.
As an inducible k.o. model for Gpx4 exclusively in hematopoietic cells, we have reconstituted lethally irradiated wt mice with Gpx4fl/fl;Cre-ERT2 or Gpx4wt/wt;CreERT2 BM cells. We now show that activation of Cre by feeding a tamoxifen-containing diet induces an aplastic anemia affecting RBC as well as WBC not only in mice reconstituted with Gpx4-deficient, but also in control mice with Gpx4wt/wt;CreERT2 BM cells thus confirming the acute toxic effect of Cre activation on the hematopoietic system described by Higashi et al.33 There is, however, a clear difference between mice harboring or lacking the Gpx4 gene in hematopoietic cells: mice reconstituted with Gpx4wt/wt;CreERT2 BM cells recovered within three to six weeks whereas mice reconstituted with cells lacking the Gpx4 gene failed to fully recover and remained partially anemic. The erythropenic phenotype could be stably transmitted into lethally irradiated wt mice by two consecutive rounds of transplantation. It is noteworthy that Cre activation by tamoxifen and Gpx4 ablation cause different types of anemia. Cre activation leads to an aplastic anemia with cessation of RBC (Online Supplementary Figure S1F) and WBC formation (Online Supplementary Figure S1L-P), whereas ablation of Gpx4 in the hematopoietic system causes ineffective erythropoiesis with increased formation of reticulocytes (Figure 1H). As recovery from anemia as well as from hematopoietic reconstitution is driven by stress erythropoiesis,43 stress erythropoiesis is perturbed by Gpx4-deficiency in hematopoietic cells. Depletion of vitamin E in the diet strongly aggravated the anemic phenotype. To exclude unintended side effects of vitamin E depletion with the well-known toxicity of Cre and Cre inducers and activators, the Gpx4 gene was deleted prior to vitamin E depletion. The dynamics of erythropoiesis under the various conditions including the maturation state of reticulocytes was assessed by FACS staining of proerythroblasts and erythroblasts in the BM and spleen and of reticulocytes in the peripheral blood. A more comprehensive picture emerged (i) by calculating the total number of proerythroblasts and erythroblasts in the BM and spleen, (ii) by extrapolating to the total number of reticulocytes and erythrocytes per mouse, and (iii) by quantifying the fraction of mature, immature and highly immature reticulocytes.
In mice with Gpx4-deficient hematopoiesis the total number of proerythroblasts was increased, mainly due to an increase in extramedullary erythropoiesis. Total numbers of mature, immature as well as highly immature reticulocytes were also increased. The differentially higher increase in immature and highly immature reticulocytes led to a shift towards immature reticulocytes. This indicates that under hematopoietic Gpx4-deficiency the rate of reticulocyte production exceeded the rate of reticulocyte maturation, a disequilibrium that resulted in ineffective erythropoiesis.
Under combined Gpx4- and vitamin E-deficiency the number of proerythroblasts in the spleen was further strongly increased. Within the reticulocyte fraction, there was a pronounced shift towards highly immature reticulocytes. Yet, production of reticulocytes did not keep up with the production of proerythroblasts as total reticulocyte counts were not significantly higher than in wt mice. This suggests that, in addition to the severe reticulocyte maturation defect, erythroid progenitor cells were lost during differentiation from the proerythroblast to the reticulocyte stage. Highest levels of lipid peroxidation, as assessed by C11-Bodipy(581/591)-staining, were observed in immature reticulocytes under combined Gpx4- and vitamin E-deficiency which correlates with the severity of the phenotype. Ultrastructural analysis revealed remnants of mitochondria and ribosomes in reticulocytes of wt mice and mice with Gpx4-deficient hematopoiesis, and a pronounced accumulation of large vacuoles containing unphagocytosed mitochondria, when dietary vitamin E was lowered. The data support the model that mitophagy is triggered by lipid oxidation that is kept in check by GPX4. Hence, loss of Gpx4, especially under vitamin E-restricted conditions, leads to uncontrolled lipid peroxidation and as a consequence, to severely perturbed mitophagy (Figure 7).
The anemia caused by hematopoietic Gpx4-deficiency shares a number of features with β-thalassemia, for which the term ineffective erythropoiesis has been coined: decreased RBC, elevated reticulocyte counts, overactive extramedullary erythropoiesis, elevated erythroid progenitors, absence of hemolysis, and systemic iron overload linked to severe iron demand for the erythroid system.51 This prompted us to study iron metabolism in mice with Gpx4-deficient hematopoiesis. Hematopoietic Gpx4-deficiency caused liver iron overload and oxidative stress, elevated plasma ferritin and iron levels, parameters aggravated by vitamin E depletion. Despite signs of iron overload in the liver and plasma, there was continuous demand for iron in the erythroid system. As a consequence of the anemia, plasma EPO and ERFE levels were elevated. Likewise, Erfe splenic mRNA expression was increased, particularly when Gpx4 deletion and vitamin E-deficiency were combined. Since ERFE mirrors the erythropoietic activity and there is virtually no background of extramedullary erythropoiesis in the spleen of wt mice under steady state conditions, spleen Erfe mRNA emerged as the most sensitive parameter of iron demand.
Despite the dramatic increase in ERFE production in mice with combined Gpx4- and vitamin E-deficiency, hepcidin expression in the liver plasma was unchanged. This is reminiscent to what has been observed in β-thalassemic Th mice older than six weeks.57 Suppression of hepcidin expression is only seen when the mice are young and still loading their livers with iron. Once enough iron has been loaded, hepcidin begins to rise, driven by hepatic iron stores, despite high erythroferrone, so that older mice have high liver iron but normal hepcidin which slows down further iron loading. Thus, hypoxia and elevated iron demand for erythropoiesis decrease hepcidin expression, whereas high plasma and hepatic iron levels counteract the response to ERFE in the liver. An alternative explanation is that a yet-unrecognized factor induced in response to oxidative stress or a direct oxidative modification of ERFE counteracts the action of ERFE on hepcidin expression.
The pronounced similarity between anemia caused by hematopoietic Gpx4-deficiency and β-thalassemia raises the question whether underlying pathogenic principles are shared between both conditions. A common denominator is by no doubt the involvement of oxygen radicals. In case of Gpx4-deficiency, they arise from increased lipid peroxidation, in case of β-thalassemia from inappropriate folding of globin chains and hemoglobin assembly. This liberates oxygen, heme and iron thus favoring the production of oxygen radicals through non-enzymatic autoxidation. There is ample evidence in the literature that increased lipid peroxidation in RBC and decreased lipid-soluble antioxidant levels in the plasma as well as in erythrocytes are consistent features of β-thalassemia.6359 Administration of vitamin E normalized the plasma oxidant/antioxidant balance and vitamin E content of erythrocytes, yet, the clinical benefit of vitamin E administration remained limited due to the persistence of iron-overload in affected patients.6562 Taken together, perturbed reticulocyte maturation through uncontrolled lipid peroxidation may be the underlying cause of ineffective erythropoiesis in both conditions.
It still remains unclear to which extent lipoxygenase-mediated enzymatic and/or non-enzymatic mechanisms contribute to lipid peroxidation in the anemia described here. Lipoxygenases lower the threshold for non-enzymatic autoxidation29 and may be required for initiating lipid oxidation in mitochondrial membranes. In the absence of 12/15-lipoxygenase other lipoxygenases may functionally compensate for the loss of the missing enzyme. A scenario of non-enzymatic lipid peroxidation is, however, also conceivable. Once lipid peroxidation is triggered, the process may be self-sustaining due to the high concentration of iron, heme compounds and oxygen rendering enzymatic lipid peroxidation dispensable.
Another critical determinant of physiological reticulocyte maturation is the cholesterol concentration in the reticulocyte membrane as well as in the plasma. Holm et al. have shown in an elegant study that mice lacking apolipoprotein E and high-density lipid protein receptor I (SR-BI) are unable to expel autophagocytosed organelles and accumulate autophagolysosomes in their reticulocytes.66 These mice lack mature erythrocytes and their gas transport relies exclusively on reticulocytes. Remarkably, the block in terminal reticulocyte maturation is cell-non-autonomous in these mice and reversible: transfusion of these reticulocytes into wt mice or hematopoietic reconstitution of lethally irradiated wt mice with apoliporotein E- and SR-BI-deficient BM cells completely normalized reticulocyte maturation. The phenotype could also be reversed through sequestration of free cholesterol: administration of cyclodextrin led to immediate expulsion of stored autophagolysosomes in vivo and in vitro and normalized the phenotype. Contrary to the apolipoprotein E- and SR-BI-model of Holm et al., we are dealing in our model with a cell-autonomous effect of Gpx4-deficiency to which cell-nonautonomous factors like the plasma concentration of vitamin E also contribute to a significant extent. In both conditions, the precise molecular underpinnings underlying the defects in reticulocyte maturation await to be elucidated.
Acknowledgments
We thank Prof. Anton Berns, the Netherland Cancer Institute, Amsterdam, for providing Rosa26-CreERT2 mice. MC and GWB thank Matilde Maiorino and Fulvio Ursini for many helpful discussions. We are most grateful to Martina Mötscher, Jasmin Teutsch and Michael Hagemann for breeding the mice.
Footnotes
- ↵* These authors contributed equally to this work
- Check the online version for the most updated information on this article, online supplements, and information on authorship & disclosures: www.haematologica.org/content/105/4/937
- FundingMUM acknowledges funding from the Deutsche Forschungsgemeinschaft (SFB1036, SFB1118); SA is supported by the European Hematology Association (Advanced Research fellowship). Support by the German Federal Ministry of Education and Research Infrafrontier grant 01KX1012 for German Mouse Clinic (GMC) infrastructure (to MHA). MK and KO were funded by a grant from SNF 310030_163443/1.
- Received November 24, 2018.
- Accepted June 20, 2019.
References
- Ursini F, Maiorino M, Valente M, Ferri L, Gregolin C. Purification from pig liver of a protein which protects liposomes and bio-membranes from peroxidative degradation and exhibits glutathione peroxidase activity on phosphatidylcholine hydroperoxides. Biochim Biophys Acta. 1982; 710(2):197-211. PubMedGoogle Scholar
- Maiorino M, Conrad M, Ursini F. GPx4, Lipid Peroxidation, and Cell Death: Discoveries, Rediscoveries, and Open Issues. Antioxid Redox Signal. 2018; 29(1):61-74. Google Scholar
- Hentze MW, Muckenthaler MU, Andrews NC. Balancing acts: molecular control of mammalian iron metabolism. Cell. 2004; 117(3):285-297. PubMedhttps://doi.org/10.1016/S0092-8674(04)00343-5Google Scholar
- Bordet JC, Guichardant M, Lagarde M. Hydroperoxides produced by n-6 lipoxygenation of arachidonic and linoleic acids potentiate synthesis of prostacyclin related compounds. Biochim Biophys Acta. 1988; 958(3):460-468. PubMedGoogle Scholar
- Seiler A, Schneider M, Forster H. Glutathione peroxidase 4 senses and translates oxidative stress into 12/15-lipoxyge-nase dependent- and AIF-mediated cell death. Cell Metab. 2008; 8(3):237-248. PubMedhttps://doi.org/10.1016/j.cmet.2008.07.005Google Scholar
- Thomas JP, Maiorino M, Ursini F, Girotti AW. Protective action of phospholipid hydroperoxide glutathione peroxidase against membrane-damaging lipid peroxidation. In situ reduction of phospholipid and cholesterol hydroperoxides. J Biol Chem. 1990; 265(1):454-461. PubMedGoogle Scholar
- Weitzel F, Wendel A. Selenoenzymes regulate the activity of leukocyte 5-lipoxyge-nase via the peroxide tone. J Biol Chem. 1993; 268(9):6288-6292. PubMedGoogle Scholar
- Schnurr K, Belkner J, Ursini F, Schewe T, Kuhn H. The selenoenzyme phospholipid hydroperoxide glutathione peroxidase controls the activity of the 15-lipoxygenase with complex substrates and preserves the specificity of the oxygenation products. J Biol Chem. 1996; 271(9):4653-4658. PubMedhttps://doi.org/10.1074/jbc.271.9.4653Google Scholar
- Kuhn H, Borchert A. Regulation of enzymatic lipid peroxidation: the interplay of peroxidizing and peroxide reducing enzymes. Free Radic Biol Med. 2002; 33(2):154-172. PubMedhttps://doi.org/10.1016/S0891-5849(02)00855-9Google Scholar
- Kryukov GV, Castellano S, Novoselov SV. Characterization of mammalian selenoproteomes. Science. 2003; 300(5624):1439-1443. PubMedhttps://doi.org/10.1126/science.1083516Google Scholar
- Burk RF, Hill KE. Regulation of selenium metabolism and transport. Annu Rev Nutr. 2015; 35:109-134. PubMedhttps://doi.org/10.1146/annurev-nutr-071714-034250Google Scholar
- Ingold I, Berndt C, Schmitt S. Selenium Utilization by GPX4 is required to orevent hydroperoxide-induced ferroptosis. Cell. 2018; 172(3):409-422. https://doi.org/10.1016/j.cell.2017.11.048Google Scholar
- Liao C, Hardison RC, Kennett MJ, Carlson BA, Paulson RF, Prabhu KS. Selenoproteins regulate stress erythroid progenitors and spleen microenvironment during stress erythropoiesis. Blood. 2018; 131(23):2568-2580. PubMedhttps://doi.org/10.1182/blood-2017-08-800607Google Scholar
- Kaushal N, Hegde S, Lumadue J, Paulson RF, Prabhu KS. The regulation of erythropoiesis by selenium in mice. Antioxid Redox Signal. 2011; 14(8):1403-1412. PubMedhttps://doi.org/10.1089/ars.2010.3323Google Scholar
- Schweers RL, Zhang J, Randall MS. NIX is required for programmed mitochondrial clearance during reticulocyte maturation. Proc Natl Acad Sci U S A. 2007; 104(49):19500-19505. PubMedhttps://doi.org/10.1073/pnas.0708818104Google Scholar
- Sandoval H, Thiagarajan P, Dasgupta SK. Essential role for Nix in autophagic maturation of erythroid cells. Nature. 2008; 454(7201):232-235. PubMedhttps://doi.org/10.1038/nature07006Google Scholar
- Chu CT, Ji J, Dagda RK. Cardiolipin externalization to the outer mitochondrial membrane acts as an elimination signal for mitophagy in neuronal cells. Nat Cell Biol. 2013; 15(10):1197-1205. PubMedhttps://doi.org/10.1038/ncb2837Google Scholar
- Kagan VE, Tyurina YY, Tyurin VA. Cardiolipin signaling mechanisms: collapse of asymmetry and oxidation. Antioxid Redox Signal. 2015; 22(18):1667-1680. PubMedhttps://doi.org/10.1089/ars.2014.6219Google Scholar
- Morgan AH, Hammond VJ, Sakoh-Nakatogawa M. A novel role for 12/15-lipoxygenase in regulating autophagy. Redox Biol. 2015; 4:40-47. Google Scholar
- Schewe T, Halangk W, Hiebsch C, Rapoport SM. A lipoxygenase in rabbit reticulocytes which attacks phospholipids and intact mitochondria. FEBS Lett. 1975; 60(1):149-152. PubMedhttps://doi.org/10.1016/0014-5793(75)80439-XGoogle Scholar
- Rapoport SM, Schewe T, Wiesner R. The lipoxygenase of reticulocytes. Purification, characterization and biological dynamics of the lipoxygenase; its identity with the respiratory inhibitors of the reticulocyte. Eur J Biochem. 1979; 96(3):545-561. PubMedGoogle Scholar
- Rapoport SM, Schewe T. The maturational breakdown of mitochondria in reticulocytes. Biochim Biophys Acta. 1986; 864(3–4):471-495. PubMedhttps://doi.org/10.1016/0304-4157(86)90006-7Google Scholar
- Kuhn H, Brash AR. Occurrence of lipoxyge-nase products in membranes of rabbit reticulocytes. Evidence for a role of the reticulocyte lipoxygenase in the maturation of red cells. J Biol Chem. 1990; 265(3):1454-1458. PubMedGoogle Scholar
- van Leyen K, Duvoisin RM, Engelhardt H, Wiedmann M. A function for lipoxygenase in programmed organelle degradation. Nature. 1998; 395(6700):392-395. PubMedhttps://doi.org/10.1038/26500Google Scholar
- Grullich C, Duvoisin RM, Wiedmann M, van Leyen K. Inhibition of 15-lipoxygenase leads to delayed organelle degradation in the reticulocyte. FEBS Lett. 2001; 489(1):51-54. PubMedhttps://doi.org/10.1016/S0014-5793(01)02080-4Google Scholar
- Sun D, Funk CD. Disruption of 12/15-lipoxygenase expression in peritoneal macrophages. Enhanced utilization of the 5-lipoxygenase pathway and diminished oxidation of low density lipoprotein. J Biol Chem. 1996; 271(39):24055-24062. PubMedhttps://doi.org/10.1074/jbc.271.39.24055Google Scholar
- Szebeni J, Winterbourn CC, Carrell RW. Oxidative interactions between haemoglobin and membrane lipid. A liposome model. Biochem J. 1984; 220(3):685-692. PubMedhttps://doi.org/10.1042/bj2200685Google Scholar
- NaveenKumar SK, SharathBabu BN, Hemshekhar M, Kemparaju K, Girish KS, Mugesh G. The role of reactive oxygen species and ferroptosis in heme-mediated activation of human platelets. ACS Chem Biol. 2018; 13(8):1996-2002. Google Scholar
- Shah R, Shchepinov MS, Pratt DA. Resolving the role of lipoxygenases in the initiation and execution of ferroptosis. ACS Cent Sci. 2018; 4(3):387-396. Google Scholar
- Yant LJ, Ran Q, Rao L. The selenopro-tein GPX4 is essential for mouse development and protects from radiation and oxidative damage insults. Free Radic Biol Med. 2003; 34(4):496-502. PubMedhttps://doi.org/10.1016/S0891-5849(02)01360-6Google Scholar
- Friedmann Angeli JP, Schneider M, Proneth B. Inactivation of the ferroptosis regulator Gpx4 triggers acute renal failure in mice. Nat Cell Biol. 2014; 16(12):1180-1191. PubMedhttps://doi.org/10.1038/ncb3064Google Scholar
- Hameyer D, Loonstra A, Eshkind L. Toxicity of ligand-dependent Cre recombinases and generation of a conditional Cre deleter mouse allowing mosaic recombination in peripheral tissues. Physiol Genomics. 2007; 31(1):32-41. PubMedhttps://doi.org/10.1152/physiolgenomics.00019.2007Google Scholar
- Higashi AY, Ikawa T, Muramatsu M. Direct hematological toxicity and illegitimate chromosomal recombination caused by the systemic activation of CreERT2. J Immunol. 2009; 182(9):5633-5640. PubMedhttps://doi.org/10.4049/jimmunol.0802413Google Scholar
- Loonstra A, Vooijs M, Beverloo HB. Growth inhibition and DNA damage induced by Cre recombinase in mammalian cells. Proc Natl Acad Sci U S A. 2001; 98(16):9209-9214. PubMedhttps://doi.org/10.1073/pnas.161269798Google Scholar
- Zhu J, Nguyen MT, Nakamura E, Yang J, Mackem S. Cre-mediated recombination can induce apoptosis in vivo by activating the p53 DNA damage-induced pathway. Genesis. 2012; 50(2):102-111. PubMedGoogle Scholar
- Janbandhu VC, Moik D, Fassler R. Cre recombinase induces DNA damage and tetraploidy in the absence of loxP sites. Cell Cycle. 2014; 13(3):462-470. PubMedhttps://doi.org/10.4161/cc.27271Google Scholar
- Pepin G, Ferrand J, Honing K. Cre-dependent DNA recombination activates a STING-dependent innate immune response. Nucleic Acids Res. 2016; 44(11):5356-5364. PubMedhttps://doi.org/10.1093/nar/gkw405Google Scholar
- Huh WJ, Khurana SS, Geahlen JH, Kohli K, Waller RA, Mills JC. Tamoxifen induces rapid, reversible atrophy, and metaplasia in mouse stomach. Gastroenterology. 2012; 142(1):21-24. PubMedhttps://doi.org/10.1053/j.gastro.2011.09.050Google Scholar
- Velasco-Hernandez T, Sawen P, Bryder D, Cammenga J. Potential pitfalls of the Mx1-Cre system: implications for experimental modeling of normal and malignant Hematopoiesis. Stem Cell Reports. 2016; 7(1):11-18. Google Scholar
- Kiermayer C, Conrad M, Schneider M, Schmidt J, Brielmeier M. Optimization of spatiotemporal gene inactivation in mouse heart by oral application of tamoxifen citrate. Genesis. 2007; 45(1):11-16. PubMedhttps://doi.org/10.1002/dvg.20244Google Scholar
- Rathkolb B, Fuchs H, Gailus-Durner V, Aigner B, Wolf E, Hrabe de Angelis M. Blood collection from mice and hematological analyses on mouse blood. Curr Protoc Mouse Biol. 2013; 3(2):101-119. PubMedGoogle Scholar
- Lenox LE, Perry JM, Paulson RF. BMP4 and Madh5 regulate the erythroid response to acute anemia. Blood. 2005; 105(7):2741-2748. PubMedhttps://doi.org/10.1182/blood-2004-02-0703Google Scholar
- Harandi OF, Hedge S, Wu DC, McKeone D, Paulson RF. Murine erythroid short-term radioprotection requires a BMP4-dependent, self-renewing population of stress erythroid progenitors. J Clin Invest. 2010; 120(12):4507-4519. PubMedhttps://doi.org/10.1172/JCI41291Google Scholar
- Chasis JA, Mohandas N. Erythroblastic islands: niches for erythropoiesis. Blood. 2008; 112(3):470-478. PubMedhttps://doi.org/10.1182/blood-2008-03-077883Google Scholar
- Clausen BE, Burkhardt C, Reith W, Renkawitz R, Forster I. Conditional gene targeting in macrophages and granulocytes using LysMcre mice. Transgenic Res. 1999; 8(4):265-277. PubMedhttps://doi.org/10.1023/A:1008942828960Google Scholar
- Wortmann M, Schneider M, Pircher J. Combined deficiency in glutathione peroxidase 4 and vitamin E causes multiorgan thrombus formation and early death in mice. Circ Res. 2013; 113(4):408-417. PubMedhttps://doi.org/10.1161/CIRCRESAHA.113.279984Google Scholar
- Matsushita M, Freigang S, Schneider C, Conrad M, Bornkamm GW, Kopf M. T cell lipid peroxidation induces ferroptosis and prevents immunity to infection. J Exp Med. 2015; 212(4):555-568. PubMedhttps://doi.org/10.1084/jem.20140857Google Scholar
- Carlson BA, Tobe R, Yefremova E. Glutathione peroxidase 4 and vitamin E cooperatively prevent hepatocellular degeneration. Redox Biol. 2016; 9:22-31. Google Scholar
- Chen K, Liu J, Heck S. Resolving the distinct stages in erythroid differentiation based on dynamic changes in membrane protein expression during erythropoiesis. Proc Natl Acad Sci U S A. 2009; 106(41):17413-17418. PubMedhttps://doi.org/10.1073/pnas.0909296106Google Scholar
- Marsee DK, Pinkus GS, Yu H. CD71 (transferrin receptor): an effective marker for erythroid precursors in bone marrow biopsy specimens. Am J Clin Pathol. 2010; 134(3):429-435. PubMedhttps://doi.org/10.1309/AJCPCRK3MOAOJ6ATGoogle Scholar
- Rivella S. Ineffective erythropoiesis and thalassemias. Curr Opin Hematol. 2009; 16(3):187-194. PubMedhttps://doi.org/10.1097/MOH.0b013e32832990a4Google Scholar
- Kautz L, Jung G, Valore EV, Rivella S, Nemeth E, Ganz T. Identification of erythroferrone as an erythroid regulator of iron metabolism. Nat Genet. 2014; 46(7):678-684. PubMedhttps://doi.org/10.1038/ng.2996Google Scholar
- Yang WS, SriRamaratnam R, Welsch ME. Regulation of ferroptotic cancer cell death by GPX4. Cell. 2014; 156(1–2):317-331. PubMedhttps://doi.org/10.1016/j.cell.2013.12.010Google Scholar
- Kagan VE, Mao G, Qu F. Oxidized arachidonic and adrenic PEs navigate cells to ferroptosis. Nat Chem Biol. 2017; 13(1):81-90. PubMedhttps://doi.org/10.1038/nchembio.2238Google Scholar
- Canli O, Alankus YB, Grootjans S. Glutathione peroxidase 4 prevents necroptosis in mouse erythroid precursors. Blood. 2016; 127(1):139-148. PubMedhttps://doi.org/10.1182/blood-2015-06-654194Google Scholar
- Frudd K, Burgoyne T, Burgoyne JR. Oxidation of Atg3 and Atg7 mediates inhibition of autophagy. Nat Commun. 2018; 9(1):95. PubMedhttps://doi.org/10.1038/s41467-017-02352-zGoogle Scholar
- Kautz L, Jung G, Du X. Erythroferrone contributes to hepcidin suppression and iron overload in a mouse model of beta-thalassemia. Blood. 2015; 126(17):2031-2037. PubMedhttps://doi.org/10.1182/blood-2015-07-658419Google Scholar
- Tappel AL. Unsaturated lipide oxidation catalyzed by hematin compounds. J Biol Chem. 1955; 217(2):721-733. PubMedGoogle Scholar
- Rachmilewitz EA, Shohet SB, Lubin BH. Lipid membrane peroxidation in beta-thalassemia major. Blood. 1976; 47(3):495-505. PubMedGoogle Scholar
- Rachmilewitz EA, Shifter A, Kahane I. Vitamin E deficiency in beta-thalassemia major: changes in hematological and biochemical parameters after a therapeutic trial with alpha-tocopherol. Am J Clin Nutr. 1979; 32(9):1850-1858. PubMedGoogle Scholar
- Rachmilewitz EA, Kornberg A, Acker M. Vitamin E deficiency due to increased consumption in beta-thalassemia and in Gaucher’s disease. Ann N Y Acad Sci. 1982; 393:336-347. PubMedhttps://doi.org/10.1111/j.1749-6632.1982.tb31273.xGoogle Scholar
- Fibach E, Rachmilewitz EA. The role of antioxidants and iron chelators in the treatment of oxidative stress in thalassemia. Ann N Y Acad Sci. 2010; 1202:10-16. PubMedhttps://doi.org/10.1111/j.1749-6632.2010.05577.xGoogle Scholar
- Livrea MA, Tesoriere L, Pintaudi AM. Oxidative stress and antioxidant status in beta-thalassemia major: iron overload and depletion of lipid-soluble antioxidants. Blood. 1996; 88(9):3608-3614. PubMedGoogle Scholar
- Giardini O, Cantani A, Donfrancesco A. Biochemical and clinical effects of vitamin E administration in homozygous beta-thalassemia. Acta Vitaminol Enzymol. 1985; 7(1–2):55-60. PubMedGoogle Scholar
- Tesoriere L, D’Arpa D, Butera D. Oral supplements of vitamin E improve measures of oxidative stress in plasma and reduce oxidative damage to LDL and erythrocytes in beta-thalassemia intermedia patients. Free Radic Res. 2001; 34(5):529-540. PubMedhttps://doi.org/10.1080/10715760100300461Google Scholar
- Holm TM, Braun A, Trigatti BL. Failure of red blood cell maturation in mice with defects in the high-density lipoprotein receptor SR-BI. Blood. 2002; 99(5):1817-1824. PubMedhttps://doi.org/10.1182/blood.V99.5.1817Google Scholar