Oxidative Stress and <svg     style="vertical-align:-3.69pt;width:12.5625px;" id="M1" height="20.075001" version="1.1" viewBox="0 0 12.5625 20.075001" width="12.5625"  xmlns:xlink="http://www.w3.org/1999/xlink" xmlns="http://www.w3.org/2000/svg">
	
		
			<g transform="matrix(.022,-0,0,-.022,.062,15.412)"><path id="x1D737" d="M54 -114l114 487q24 102 62.5 165t102.5 109q53 38 129 38q51 0 86 -33.5t35 -84.5q0 -57 -31.5 -105t-81.5 -68v-2q88 -14 88 -126q0 -64 -29 -127q-29 -62 -90 -107q-62 -44 -143 -44q-67 0 -97 18l-28 -124q-11 -51 -26 -87h-117q9 19 26 91zM304 480l-87 -393
q0 -29 19 -44t48 -15q63 0 110 74q46 74 46 153q0 117 -52 117q-6 0 -23.5 -3t-21.5 -3q-33 0 -33 25q0 15 15 25.5t41 10.5q8 0 30 -6q27 -5 28 -5q26 0 41 43t15 89q0 39 -17.5 62t-44.5 23q-46 0 -71 -35.5t-43 -117.5z" /></g>

		
	
</svg>-Thalassemic Erythroid Cells behind the Molecular Defect

De Franceschi, Lucia; Bertoldi, Mariarita; Matte, Alessandro; Santos Franco, Sara; Pantaleo, Antonella; Ferru, Emanuela; Turrini, Franco

doi:https://doi.org/10.1155/2013/985210

Oxidative Medicine and Cellular Longevity

On this page

Abstract Introduction Acknowledgments References Copyright Related Articles

Review Article | Open Access

Volume 2013 | Article ID 985210 | https://doi.org/10.1155/2013/985210

Oxidative Stress and -Thalassemic Erythroid Cells behind the Molecular Defect

Lucia De Franceschi,¹Mariarita Bertoldi,²Alessandro Matte,¹Sara Santos Franco,¹Antonella Pantaleo,³Emanuela Ferru,⁴and Franco Turrini⁴

Academic Editor: József Balla

Received28 Feb 2013

Accepted04 Jun 2013

Published24 Sept 2013

Abstract

β-thalassemia is a worldwide distributed monogenic red cell disorder, characterized by the absence or reduced β-globin chain synthesis. Despite the extensive knowledge of the molecular defects causing β-thalassemia, less is known about the mechanisms responsible for the associated ineffective erythropoiesis and reduced red cell survival, which sustain anemia of β-thalassemia. The unbalance of alpha-gamma chain and the presence of pathological free iron promote a severe red cell membrane oxidative stress, which results in abnormal β-thalassemic red cell features. These cells are precociously removed by the macrophage system through two mechanisms: the removal of phosphatidylserine positive cells and through the natural occurring antibody produced against the abnormally clustered membrane protein band 3. In the present review we will discuss the changes in β-thalassemic red cell homeostasis related to the oxidative stress and its connection with production of microparticles and with malaria infection. The reactive oxygen species (ROS) are also involved in ineffective erythropoiesis of β-thalassemia through still partially known pathways. Novel cytoprotective systems such as ASHP, eIF2α, and peroxiredoxin-2 have been suggested to be important against ROS in β-thalassemic erythropoiesis. Finally, we will discuss the results of the major in vitro and in vivo studies with antioxidants in β-thalassemia.

1. Introduction

The World Health Organization has identified the hereditary red cell disorders as emerging diseases with high impact on public health systems in both Western and developing countries. Approximately 7% of the global population is carrier of such disorders, and 300,000–400,000 babies with severe forms of these diseases are born each year [1–3]. Severe hereditary hemoglobin disorders of red cells occur at highest frequency in tropical regions, but pop0ulation migrations have ensured that they are present and growing in prevalence in most Western countries. Hemoglobinopathies constitute the single most common monogenic defect worldwide, and among hemoglobin disorders, the thalassemias prominently contribute to [1–4]. β-thalassemias (β-thal) are characterized by the presence of mutations on beta-globin gene resulting in the absence or reduced synthesis of β-globin chains. This is responsible for unbalance in globin chain synthesis with unpaired α-chains aggregation. Despite the extensive knowledge of the molecular defects causing β-thalassemia, less is known about the mechanisms responsible for the associated ineffective erythropoiesis and reduced red cell survival, which sustain anemia of β-thalassemia [5].

2. β-Thalassemic Red Cells and Oxidative Stress

β-thalassemic red cells are characterized by extensive red cell membrane oxidative damage related to the excess of unpaired chains, resulting in coclustering of denatured globin and band 3 protein with the generation of large membrane aggregates [6] and decreased membrane thiols [7]. The decompartmentalization of cellular free iron and its nonrandom association to the hemichrome band 3 aggregates [8] observed in β-thal red cells further amplifies the oxidative environment of β-thal erythrocytes [9]. These small amounts of pathological free iron from unpaired hemoglobin chains could initiate self-amplifying redox reactions that simultaneously deplete cellular reduction potential, oxidize additional hemoglobin, and trigger phosphorylative responses initiating membrane destabilization [10–12], accelerating the red cell blood destruction (Figure 1). The membrane–damaging effects of unpaired chains have been also demonstrated by entrapping hemoglobin chains in normal erythrocytes [13].

Figure 1

Schematic diagram of abnormalities observed in β-thalassemic red cells. The presence of pathological free iron (Fe) close to the membrane is involved in the Fenton reaction producing reactive oxygen species (ROS, ) contributing to the prooxidant environment of β-thalassemic red cells. The unbalance in α/β chain synthesis results in aggregation of highly oxidative α chains. The prooxidant environment is responsible for protein and lipid oxidative damage favoring abnormal clusterization of red cell membrane proteins such as band 3, promoting band 3 tyrosine phosphorylation (P) and exposure of phosphatidylserine (PS). The abnormally clustered band 3 is recognized by naturally occurring anti-band 3 antibody (IgG). The severely damaged β-thalassemic red cells released microparticles (MPs). The β-thalassemic red cells have short lifespan and are removed by macrophages of the reticuloendothelial systems through PS exposure and IgG anti-band 3 mediated mechanisms. The oxidative stress abnormally activates the K–Cl cotransport (KCC), which promotes K⁺, Cl⁻, and water loss contributing to the reduced red cell K⁺ content that characterizes β-thalassemic red cells.

Studies in β-thal erythrocytes have shown that proteins from both cytoskeleton network and membrane are targeted by the oxidative stress. In red cells spectrins are key proteins of the cytoskeleton network, [14, 15]. Studies in β-thal erythrocytes show that spectrins are involved by the oxidative damage, resulting in perturbation of their interactions with other cytoskeleton proteins such as actin or with proteins from multiprotein complexes bridging the membrane to the cytoskeleton as protein 4.1 [15]. In β-thal red cells, the loss of the stability between the cytoskeleton network and the junctional multiprotein complexes might favor the abnormal clusterization of transmembrane protein such as band 3 (Figure 1). In particular, two cysteine residues located in the cytoplasmic domain of band 3 show a peculiar reactivity to oxidants being 10-fold more reactive than GSH (Ferru E. and Pantaleo A., personal communication). This uncommon reactivity appears to be finalized to the regulation of band 3 tyrosine phosphorylation in anchoring of the membrane cytoskeleton to the lipid bilayer [16–18]. This function is linked specifically to its association with adducin and ankyrin in two distinct junctional complexes [19]. Rupture of either of these two bridges yields an erythrocyte that spontaneously loses membrane surface through vesiculation/blebbing. Recent studies from our lab demonstrate that Syk-mediated tyrosine phosphorylation of oxidatively modified band 3 leads to complete inhibition of ankyrin binding and the consequent dissociation of band 3 from the cytoskeleton [20]. When red cells are mechanically stressed, they bleb membrane surface and vesiculate. Indeed, in scrutinizing the literature, we have noted that membrane vesiculation and release of circulating microparticles (MPs) constitute a common characteristic of erythrocyte pathologies (sickle cell disease, G6PDH deficiency, β-thalassemia) that are characterized by elevated band 3 tyrosine phosphorylation. A study showed significantly higher levels of circulating MPs originated from red cell membranes in β-thalassemia intermedia patients compared to controls, especially in splenectomized patients [21]. MPs originating from red cell membranes are also considered a major cause of premature atherosclerosis described in thalassemia intermedia patients [22].

Band 3 tyrosine phosphorylation observed in β-thalassemia may impact additional erythrocyte functions. Band 3 organizes a complex of glycolytic enzymes on the membrane and thereby controls the flux of glucose between the pentose phosphate pathway (PPP) and glycolysis. Phosphorylation of band 3 by Syk leads to displacement of these glycolytic enzymes from an inhibitory site on band 3, resulting in activation of glycolysis and a decline in red cell reducing power through NADPH production [23].

Several lines of evidence indicate that in thalassemias and in unstable hemoglobin diseases, damaged red cells are removed by spleen through an immunological mechanism [6, 24]. High amounts of anti-band 3 antibodies (NAbs) and C3b are constantly found bound to band 3-hemichromes aggregates [6], leading to intense phagocytosis. Those high molecular weight complexes containing IgG and C3b were isolated from red cell membranes in thalassemic, sickle cell, and haemoglobin C patients [25, 26]. The colocalization of the various components was also demonstrated by fluorescence microscopy [26]. Interestingly, anti-band 3 NAbs eluted from thalassemic red cells recognize dimeric/oxidized band 3 [6]. In thalassemias, a correlation has been found between the degree of anemia and the amount of anti-band 3 NAbs and of band 3/hemichrome copolymers in red cell membranes indicating a central role of NAbs in β-thal red cells removal [24]. In conclusion, the most relevant membrane changes linked to hemolysis and complications in thalassemias appear to deal with the binding of naturally occurring antibodies and with the destabilization of the red cell membrane leading to membrane loss and microparticle release.

3. The Membrane Oxidative Damage Participates to the Removal of β-Thal Red Cells by the Macrophage System: The Connection with Malaria Infection

Previous studies indicate a major role of immune determinants in the removal of β thalassemic red cells [24]. The interactions between thalassemic red cells and plasmodia appear to play a major role in natural and acquired protection to malaria. Heterozygous α- and β-thalassemias are extremely frequent in malaria endemic areas displaying a well-balanced hematological situation [27], while there is a widespread consensus that thalassemias determine an efficient resistance to severe malaria [28]. In particular, α-thalassemias are the most common mutation in malaria endemic regions and are considered to confer protection against clinical manifestations related to both severe forms [29–32] or uncomplicated malaria [33]. Although the molecular basis of the mechanism of resistance is not completely understood it has been observed that α-thalassemic red cells infected with P. falciparum bind higher amounts of antibodies or complement factors from immune sera [34, 35]. Moreover, lower levels of the complement receptor-1 (CR1) have been found in α-thalassemic red cells, and a reduction of infected red cells to form rosettes (associated to severe malaria) has been associated to CR1 deficiency [36].

Heterozygous β-thalassemia also confers protection against severe malaria and uncomplicated malaria in children [35, 37]. One study indicates that heterozygous β-thalassemic red cells are unable to sustain the normal development of P. falciparum “in vitro” [38]. In addition, similarly to α-thalassemia, immunological determinants appear to be involved in a more efficient recognition of infected β-thalassemic red cells [34, 39]. More recently it has been observed that both heterozygous α- and β-thalassemic red cells do not apparently damage the parasites but induce a loss of viability of the infected erythrocytes and their removal by macrophages [40]. We have also observed that the deletion of 11 amino acids at the band 3 amino terminal (band 3 Neapolis) results in a profound red cell membrane destabilization, in increasing naturally occurring IgG binding, and a reduction of P. falciparum to grow in these red cells [41]. These findings suggest that different mutations, including Southeast Asian ovalocytosis, elliptocytosis, and unstable hemoglobins affecting structure, functions, and antigenic properties of the red cell membrane, might interfere with the development of malaria parasites [42–44].

In that respect, several studies have identified proteins that are phosphorylated upon malarial infection [41, 45–47]. Band 3 represents the earliest tyrosine phosphorylation event during parasite development, beginning at low levels during early ring stage parasitemia and increasing continuously until parasite egress [48]. We have recently shown that in red cells from heterozygous β-thalassemic subjects the process of band 3 phosphorylation is amplified [16], suggesting that band 3 related destabilization of the host red cell membrane may be involved in the mechanism of malaria resistance. In support to this hypothesis, recent data demonstrated that long-lived radicals, indolone-N-oxide derivatives (INODs), exert antiplasmodial activity in the low nanomolar range accelerating the rate of phosphorylation of band 3, its clustering, and altering the stability of the erythrocyte membrane without a direct effect on parasite targets [49]. The relationships between band 3 phosphorylation, its clustering, and the binding of naturally occurring antibodies in malaria and thalassemias remain to be fully established [50].

The observation of the relationship between hemoglobin precipitation and reduced cell K⁺ content in β-thal erythrocytes has suggested a link between red cell membrane oxidative damage and abnormalities of red cell membrane ion transport pathways in β-thal red cells [51, 52]. In vitro studies with oxidant agents mimicking β-thal red cell membrane damage as phenylhydrazine (PHZ) have helped in dissecting the contribution of the oxidative stress in activation of different membrane ion transport pathways involved in generation of red cell with reduced K⁺ content such as in β-thalassemia [51, 52]. The red cell membrane transport can be divided into (i) the energy driven systems as the Na–K ATPase pump; (ii) the gradient driven systems as the Na–K–2Cl cotransport and the K–Cl cotransport; (iii) the exchange as the Na–H or the Na–Li exchange; and (v) the channel as the Gardos channel [52–59]. In β-thal red cells we have shown that the activity of the K–Cl cotransport (KCC) is increased, and its abnormal activation is related to the severe membrane oxidative damage characterizing β-thal erythrocytes [51, 52] (Figure 1). When β-thal red cells are treated with DIOA ([(dihydroindenyl)oxy]alkanoic acid), the specific inhibitor of the K–Cl cotransport, the red cell K⁺ content increases supporting the key role of K–Cl cotransport in K⁺ loss of β-thal erythrocytes [51, 60]. However, the inhibition of the K–Cl cotransport by DIOA is limited by DIOA toxicity. Studies on K–Cl cotransport in hemoglobinopathies have shown that the activity of the K–Cl cotransport might also be increased by reduced red cell Mg²⁺ content, which characterized β-thal red cells [61–63] (Figure 1). Thus, different strategies have been evaluated to pharmacologically inhibit the activity of the K–Cl cotransport in β-thal erythrocytes. These target two factors involved in K–Cl cotransport activation: the membrane oxidative damage and the red cell Mg²⁺ content. The development of animal models for β-thal mimicking the human counterpart have been crucial to evaluate in vivo the pathophysiological events involved in activation of K–Cl cotransport and generation of red cells with low K⁺ content [64–66].

Deferiprone, an iron chelator that crosses the red cell membrane and accumulates in erythrocytes, has been shown to ameliorate β-thal red cell survival in a mouse model for β-thalassemia and to reduce the abnormal activation of K–Cl cotransport in red cells from human β-thal patients treated with deferiprone for 3 months [10, 67]. Abnormalities of Mg²⁺ metabolism have been described in β-thalassemia and abnormally low red cell Mg content characterized β-thal red cells, which contribute to K–Cl cotransport activation [64, 68, 69]. Studies in animal models for β-thalassemia have shown that dietary Mg²⁺ supplementation alone or in combination with hydroxyurea can reduce the activity of K–Cl cotransport, increase the red cell K⁺ content, and ameliorate the β-thal hemolytic phenotype [62, 64]. In untransfused β-thal intermedia patients treated with Mg-pidolate (1.2 mEq/Kg/d), we observed significant increase in red cell Mg²⁺ content, reduction in K–Cl cotransport activity, increase of red cell K⁺ content, and decrease of reticulocyte count [63]. These data suggest that modulation of K–Cl cotransport through different strategies ameliorates the hematological phenotype of both mouse model and human subjects with β-thalassemia.

5. Novel Cytoprotective Systems and β-Thalassemia

Although β-thal red cells have been largely studied in the last decades and the contribution of the oxidative stress has been documented in shortening β-thal red cell lifespan, the role of reactive oxygen species (ROS) in ineffective erythropoiesis of β-thalassemia has been only partially investigated.

Previous studies have identified a small protein stabilizing the α chains (AHSP, α hemoglobin-stabilizing protein) as an important protein facilitating hemoglobin assembly and partially protecting the erythroid precursors from the α chain excess (Figure 2). In fact, AHSP binds free α-globin chains, stabilizing their structure and prevents their precipitation [77–80]. Indeed, anemia of β-thalassemic mice is more severe in β-thalassemic/AHSP-deficient mice [77–79]. However, the impact of AHSP deficiency in β-thalassemia patients is still under evaluation and the link between decreased AHSP expression and severity of β-thalassemic syndromes remains speculative [79].

Figure 2

Schematic model of novel cytoprotective mechanisms in response to oxidative stress in β-thalassemic (β-thal) erythroid precursors. In β-thalassemic erythropoiesis the radical oxidative species (ROS) induces peroxiredoxin-2 (PRDX2) expression. In the early stage of β-thalassemic erythropoiesis, ROS and heme levels are both increased and PRDX2 acts on both targets; in more mature cells, when ROS levels are still high and heme levels are reduced, ROS might become the PRDX2 major target (see text for details). ROS promotes HRI activation, which requires the heat shock proteins 70 and 90 (HSP70,-90). HRI activation results in phosphorylation of the α-subunit of eIF2, an important regulatory translation initiating factor, which inhibits the α-, β-globin chain synthesis and activates the Atf4 pathway towards redox genes such as heme-oxygenase-1 (ho-1), glutathione S-transferase (gst), and NAD(P)H quinone oxidoreductase 1 (Nqo1). The upregulation of these genes in combination with the decrease in α-, β-globin chain synthesis might beneficially affect the ineffective erythropoiesis of β-thalassemia. The α chains (AHSP, α hemoglobin-stabilizing protein) is another cytoprotective system, which partially protects the erythroid precursors from the α chain excess. AHSP binds free α-globin chains, stabilizing their structure. AHSP prevents their precipitation and might be important in β-thalassemic erythropoiesis characterized by unbalance in globin chain synthesis.

Another protective factor in β-thalassemic erythropoiesis is the heme-regulated inhibitor of protein translation (HRI) that represses globin translation in heme-deficient erythroid precursors [81] (Figure 2). HRI is the heme-regulated eIF2α kinase that phosphorylates a subunit of eIF2, a crucial regulatory translational initiating factor. Studies in in vitro systems have shown that the activation of HRI involves also ROS and requires the molecular chaperones heat shock proteins 70 and 90 (HSP70 and -90) [82]. Thus, β-thalassemic erythropoiesis characterized by ROS and unbalance of globin chain synthesis might be an interesting model to validate the role of HRI-eIF2α pathway. In fact, β-thal mice genetically lacking HRI show a more severe hematological phenotype compared to β-thal mice, supporting the key role of eIF2α in stress erythropoiesis [81, 83]. Recently, HRI-dependent eIF2αP has been also shown to enhance the translation of the Atf4 in mouse erythroid cell precursors exposed to oxidative stress [81, 84]. This results in upregulation of genes from antioxidant systems such as heme-oxygenase-1 (ho-1), glutathione S-transferase-μ (gstμ), and NAD(P)H quinone oxidoreductase 1 (Nqo1). In β-thal erythroid precursors the increase of eIF2αP by salubrinal treatment results in inhibition of globin chain synthesis, suggesting that pharmacological modulation of eIF2αP might possibly impact the β-thal ineffective erythropoiesis through inhibition of globin chain synthesis and possibly through upregulation of antioxidant systems (Figure 2).

Another novel cytoprotective system recently described in β-thalassemia is peroxiredoxin-2 (PRDX2) (Figure 2). PRDX2 is a typical 2-cysteine (Cys51 and -172) peroxiredoxin, which acts as antioxidant and molecular chaperone in different cell types [85, 86].

5.1. Peroxiredoxin-2 and β-Thalassemia

PRDX2 is the third most abundant cytoplasmic protein in red cells and is able to reduce and detoxify a vast range of organic peroxides, H₂O₂, and peroxynitrite [87, 88]. Recently, we have shown that PRDX2 expression is increased in a mouse model for β-thalassemia [65, 89]. However, PRDX2 membrane translocation in β-thal red cells is reduced despite the severe membrane oxidative damage. Since β-thal red cells are characterized by the presence of hemichrome membrane association, we have shown that PRDX2 is displaced by the membrane in function of the proportion of denaturated and oxidized hemoglobin recovered on the membrane as hemichromes [89]. Thus, in β-thal red cells PRDX2 is unable to translocate to the membrane in response to oxidative damage since hemichromes mask PRDX2 binding site on the membrane. Based on the evidences that band 3 is the docking site for hemichrome on the red cell membrane [6, 41], we hypothesize that band 3 might be the binding site also for PRDX2. To address this question we have studied the interactions of recombinant PRDX2 with the cytoplasmic domain of band 3 [90]. We show that PRDX2 binds to the cytoplasmic domain of band 3 with different experimental methodological approaches including cross-linking studies, fluorescence and dichroic measurements, surface plasmon resonance analysis, and proteolytic digestion assay. This finding is also supported by the absence of PRDX2 membrane association in a patient with band 3 Neapolis, a truncated isoform of band 3 lacking the N-terminal 11 amino acid residues [41, 90]. We believe that the membrane association of PRDX2 with band 3 might be important in protecting band 3 from oxidative damage and its associated membrane proteins. In the context of β-thal red cells the presence of hemichrome masking the docking site for PRDX2 contributes to further amplification of red cell membrane oxidative damage characterizing β-thalassemic erythrocytes.

Looking for novel cytoprotective mechanisms in β-thal erythropoiesis we have carried out a classic proteomic analysis of erythroid precursors from healthy and β-thal intermedia subjects. We identify PRDX2 as one of the antioxidant systems differently expressed during erythroid maturation in β-thal erythroid cells compared to controls [91]. In other cell types PRDX2 has been demonstrated to be induced by oxidative stress and that cells overexpressing PRDX2 are more resistant to the oxidative stress [92, 93]. To evaluate the impact of PRDX2 during erythropoiesis in cells, exposed in vitro to oxidative stress, we silenced PRDX2 in K562 cells and we observed decreased differentiation and reduced cell survival, supporting the important role of PRDX2 as cytoprotective system during stress erythropoiesis [91]. Since PRDX2 is highly expressed during β-thal erythropoiesis, we speculate that its role might not be limited to antioxidant function. Using recombinant PRDX2 we demonstrate that PRDX2 specifically binds heme with decreased PRDX2 peroxidase activity. In β-thal erythropoiesis we propose that in early β-thal erythroid precursors, characterized by high levels of ROS and heme, PRDX2 targets both ROS and heme to reduce oxidative stress. While in late β-thal erythropoiesis, when ROS levels are still high but heme levels are reduced, ROS might be the major target of PRDX2 (Figure 2) [91]. Future studies using sorted erythroid precursors at different stage of maturation [94] need to be carried out to better characterize the role of PRDX2 in β-thal erythropoiesis.

6. Antioxidants as Therapeutic Strategy in β-Thalassemia

Since the oxidative stress plays a key role in the pathogenesis of β-thalassemia, the use of various molecules with antioxidant properties as possible therapeutic strategy in β-thalassemia has been explored (Table 1). A pilot trial with large dose of oral vitamin E, prompted by the abnormally low levels of this vitamin in plasma of patients with β-thal intermedia, showed a decrease in the levels of malonylaldehyde but not in transfusion requirements [70, 73]. Amelioration of β-thal red cell osmotic fragility has been also reported in β-thal major patients treated with vitamin E supplementation [71]. In another study with vitamin E supplementation involving β-thal intermedia patients, an improvement of plasma oxidative stress has been reported, supporting the role of vitamin E as antioxidant agent with multitarget effects in β-thalassemia [72]. The polyphenol curcumin caused a significant inhibition of lipid peroxidation in β-thal red cell ghosts [73] and an improvement in methemoglobin levels in β-thal patients treated with curcumin, with no effects on patients hemoglobin levels [74].

Another antioxidant molecule that has been evaluated in β-thalassemia is the fermented papaya preparation (FPP). Studies in vitro and in vivo in both mouse model for β-thalassemia and β-thal human subjects have shown that FPP reduces the β-thal red cell oxidative stress, the membrane lipid peroxidation, and the percentage of PS positive red cells, and increases reduced glutathione (GSH). The amelioration of red cell features induced by FPP is also associated with reduced red cell phagocytic index, suggesting possible reduction in removal of FPP treated β-thal red cells from the peripheral circulation by the macrophage system [73, 76]. Recently, in a mouse model for β-thal it was shown that a novel semisynthetic flavanoid, 7-monohydroxyethylrutoside (monoHER), reduces the percentage of PS positive cells, increases the red cell membrane and plasma vitamin E content and red cell K⁺ content with beneficial effects on mouse β-thal erythropoiesis [66]. The thiol compound N-acetylcysteine amide (AD4), the amide form of N-acetyl cysteine (NAC), has been studied both in vitro in β-thal red cells and in vivo in mouse model for β-thalassemia [75]. Amer et al. show that in β-thal mouse red cells in vitro and in vivo AD4 significantly improves GSH levels and reduces the percentage of PS positive cells and the β-thal phagocytic index, suggesting that the restoration of thiol levels in β-thal red cells might represent an additional strategy to antioxidant treatment in β-thalassemia. In a mouse model for β-thalassemia we have recently shown that resveratrol, a polyphenolic-stilbene, ameliorates the β-thal ineffective erythropoiesis through the activation of FOXO3, transcriptional factor, and reduces the oxidative stress in circulating β-thal red cells [95].

7. Future Prospective

In conclusion, the oxidative stress plays a central role in the pathogenesis of anemia in β-thalassemia. The emerging picture for treatment of β-thalassemia is that abnormalities ranging from red cell membrane proteins structure and function and membrane ion transport pathways to novel cytoprotective systems in erythropoiesis might constitute new pharmacological targets for treating β-thalassemia. Future studies should be designed to evaluate in vivo novel antioxidant strategies with multitarget effects on both mature β-thal red cells and erythropoiesis with the final goal to impact anemia of β-thalassemia.

Acknowledgments

This work was supported by grants from FUR2011-2012, University of Verona, to Mariarita Bertoldi and Lucia De Franceschi and by AITED (Associazione Italiana Talassemici e Drepanocitici) to Lucia De Franceschi.

References

D. J. Weatherall, “The global problem of genetic disease,” Annals of Human Biology, vol. 32, no. 2, pp. 117–122, 2005.
View at: Google Scholar
D. J. Weatherall and J. B. Clegg, “Inherited haemoglobin disorders: an increasing global health problem,” Bulletin of the World Health Organization, vol. 79, no. 8, pp. 704–712, 2001.
View at: Google Scholar
B. Modell and M. Darlison, “Global epidemiology of haemoglobin disorders and derived service indicators,” Bulletin of the World Health Organization, vol. 86, no. 6, pp. 480–487, 2008.
View at: Publisher Site | Google Scholar
L. de Franceschi, M. D. Cappellini, and O. Olivieri, “Thrombosis and sickle cell disease,” Seminars in Thrombosis and Hemostasis, vol. 37, no. 3, pp. 226–236, 2011.
View at: Publisher Site | Google Scholar
D. Rund and E. Rachmilewitz, “Beta-thalassemia,” The New England Journal of Medicine, vol. 353, no. 11, pp. 1135–1146, 2005.
View at: Google Scholar
F. Mannu, P. Arese, M. D. Cappellini et al., “Role of hemichrome binding to erythrocyte membrane in the generation of band-3 alterations in β-thalassemia intermedia erythrocytes,” Blood, vol. 86, no. 5, pp. 2014–2020, 1995.
View at: Google Scholar
E. Shinar and E. A. Rachmilewitz, “Oxidative denaturation of red blood cells in thalassemia,” Seminars in Hematology, vol. 27, no. 1, pp. 70–82, 1990.
View at: Google Scholar
T. Repka, O. Shalev, R. Reddy et al., “Nonrandom association of free iron with membranes of sickle and β- thalassemic erythrocytes,” Blood, vol. 82, no. 10, pp. 3204–3210, 1993.
View at: Google Scholar
S. L. Schrier and N. Mohandas, “Globin-chain specificity of oxidation-induced changes in red blood cell membrane properties,” Blood, vol. 79, no. 6, pp. 1586–1592, 1992.
View at: Google Scholar
L. de Franceschi, O. Shalev, A. Piga et al., “Deferiprone therapy in homozygous human β-thalassemia removes erythrocyte membrane free iron and reduces KCl cotransport activity,” Journal of Laboratory and Clinical Medicine, vol. 133, no. 1, pp. 64–69, 1999.
View at: Publisher Site | Google Scholar
A. Pantaleo, E. Ferru, G. Giribaldi et al., “Oxidized and poorly glycosylated band 3 is selectively phosphorylated by Syk kinase to form large membrane clusters in normal and G6PD-deficient red blood cells,” Biochemical Journal, vol. 418, no. 2, pp. 359–367, 2009.
View at: Publisher Site | Google Scholar
L. de Franceschi, A. Biondani, F. Carta et al., “PTPepsilon has a critical role in signaling transduction pathways and phosphoprotein network topology in red cells,” Proteomics, vol. 8, no. 22, pp. 4695–4708, 2008.
View at: Google Scholar
M. D. Scott, J. J. van den Berg, T. Repka et al., “Effect of excess alpha-hemoglobin chains on cellular and membrane oxidation in model beta-thalassemic erythrocytes,” Journal of Clinical Investigation, vol. 91, no. 4, pp. 1706–1712, 1993.
View at: Google Scholar
L. de Franceschi, C. Tomelleri, A. Matte et al., “Erythrocyte membrane changes of chorea-acanthocytosis are the result of altered Lyn kinase activity,” Blood, vol. 118, no. 20, pp. 5652–5663, 2011.
View at: Publisher Site | Google Scholar
E. Shinar, E. A. Rachmilewitz, and S. E. Lux, “Differing erythrocyte membrane skeletal protein defects in alpha and beta thalassemia,” Journal of Clinical Investigation, vol. 83, no. 2, pp. 404–410, 1989.
View at: Google Scholar
A. Pantaleo, L. de Franceschi, E. Ferru, R. Vono, and F. Turrini, “Current knowledge about the functional roles of phosphorylative changes of membrane proteins in normal and diseased red cells,” Journal of Proteomics, vol. 73, no. 3, pp. 445–455, 2010.
View at: Publisher Site | Google Scholar
A. Siciliano, F. Turrini, M. Bertoldi et al., “Deoxygenation affects tyrosine phosphoproteome of red cell membrane from patients with sickle cell disease,” Blood Cells, Molecules, and Diseases, vol. 44, no. 4, pp. 233–242, 2010.
View at: Publisher Site | Google Scholar
A. Iolascon, L. De Falco, F. Borgese et al., “A novel erythroid anion exchange variant (Gly796Arg) of hereditary stomatocytosis associated with dyserythropoiesis,” Haematologica, vol. 94, no. 8, pp. 1049–1059, 2009.
View at: Publisher Site | Google Scholar
N. Mohandas and X. An, “New insights into function of red cell membrane proteins and their interaction with spectrin-based membrane skeleton,” Transfusion Clinique et Biologique, vol. 13, no. 1-2, pp. 29–30, 2006.
View at: Publisher Site | Google Scholar
E. Ferru, K. Giger, A. Pantaleo et al., “Regulation of membrane-cytoskeletal interactions by tyrosine phosphorylation of erythrocyte band 3,” Blood, vol. 117, no. 22, pp. 5998–6006, 2011.
View at: Publisher Site | Google Scholar
M. Westerman, A. Pizzey, J. Hirschman et al., “Microvesicles in haemoglobinopathies offer insights into mechanisms of hypercoagulability, haemolysis and the effects of therapy,” The British Journal of Haematology, vol. 142, no. 1, pp. 126–135, 2008.
View at: Publisher Site | Google Scholar
G. Hahalis, A. Kalogeropoulos, G. Terzis et al., “Premature atherosclerosis in non-transfusion-dependent β-thalassemia intermedia,” Cardiology, vol. 118, no. 3, pp. 159–163, 2011.
View at: Publisher Site | Google Scholar
M. L. Harrison, P. Rathinavelu, P. Arese, R. L. Geahlen, and P. S. Low, “Role of band 3 tyrosine phosphorylation in the regulation of erythrocyte glycolysis,” Journal of Biological Chemistry, vol. 266, no. 7, pp. 4106–4111, 1991.
View at: Google Scholar
M. D. Cappellini, D. Tavazzi, L. Duca et al., “Metabolic indicators of oxidative stress correlate with haemichrome attachment to membrane, band 3 aggregation and erythrophagocytosis in β- thalassaemia intermedia,” The British Journal of Haematology, vol. 104, no. 3, pp. 504–512, 1999.
View at: Google Scholar
P. S. Low, “Structure and function of the cytoplasmic domain of band 3: center of erythrocyte membrane-peripheral protein interactions,” Biochimica et Biophysica Acta, vol. 864, no. 2, pp. 145–167, 1986.
View at: Google Scholar
F. Tokumasu, R. M. Fairhurst, G. R. Ostera et al., “Band 3 modifications in Plasmodium falciparum-infected AA and CC erythrocytes assayed by autocorrelation analysis using quantum dots,” Journal of Cell Science, vol. 118, no. 5, pp. 1091–1098, 2005.
View at: Publisher Site | Google Scholar
F. J. I. Fowkes, S. J. Allen, A. Allen, M. P. Alpers, D. J. Weatherall, and K. P. Day, “Increased microerythrocyte count in homozygous α⁺- thalassaemia contributes to protection against severe malarial anaemia,” PLoS Medicine, vol. 5, no. 3, article e56, pp. 0494–0501, 2008.
View at: Publisher Site | Google Scholar
C. López, C. Saravia, A. Gomez, J. Hoebeke, and M. A. Patarroyo, “Mechanisms of genetically-based resistance to malaria,” Gene, vol. 467, no. 1-2, pp. 1–12, 2010.
View at: Publisher Site | Google Scholar
T. N. Williams, K. Maitland, S. Bennett et al., “High incidence of malaria in α-thalassaemic children,” Nature, vol. 383, no. 6600, pp. 522–525, 1996.
View at: Publisher Site | Google Scholar
S. J. Allen, O. 'Donnell A, N. D. Alexander et al., “alpha+-Thalassemia protects children against disease caused by other infections as well as malaria.,” Proceedings of the National Academy of Sciences of the United States of America, vol. 94, no. 26, pp. 14736–14741, 1997.
View at: Google Scholar
F. P. Mockenhaupt, S. Ehrhardt, S. Gellert et al., “α⁺-thalassemia protects African children from severe malaria,” Blood, vol. 104, no. 7, pp. 2003–2006, 2004.
View at: Publisher Site | Google Scholar
S. Wambua, T. W. Mwangi, M. Kortok et al., “The effect of α⁺-thalassaemia on the incidence of malaria and other diseases in children living on the coast of Kenya,” PLoS Medicine, vol. 3, no. 5, article e158, 2006.
View at: Publisher Site | Google Scholar
A. Enevold, J. P. Lusingu, B. Mmbando et al., “Reduced risk of uncomplicated malaria episodes in children with alpha +-thalassemia in Northeastern Tanzania,” The American Journal of Tropical Medicine and Hygiene, vol. 78, no. 5, pp. 714–720, 2008.
View at: Google Scholar
G. A. Luzzi, A. H. Merry, C. I. Newbold, K. Marsh, and G. Pasvol, “Protection by α-thalassaemia against Plasmodium falciparum malaria: modified surface antigen expression rather than impaired growth or cytoadherence,” Immunology Letters, vol. 30, no. 2, pp. 233–240, 1991.
View at: Publisher Site | Google Scholar
Y. Yuthavong and P. Wilairat, “Protection against malaria by thalassaemia and haemoglobin variants,” Parasitology Today, vol. 9, no. 7, pp. 241–245, 1993.
View at: Publisher Site | Google Scholar
I. A. Cockburn, M. J. Mackinnon, A. O'Donnell et al., “A human complement receptor 1 polymorphism that reduces Plasmodium falciparum rosetting confers protection against severe malaria,” Proceedings of the National Academy of Sciences of the United States of America, vol. 101, no. 1, pp. 272–277, 2004.
View at: Publisher Site | Google Scholar
M. Willcox, A. Bjorkman, and J. Brohult, “Falciparum malaria and β-thalassaemia trait in northern Liberia,” Annals of Tropical Medicine and Parasitology, vol. 77, no. 4, pp. 335–347, 1983.
View at: Google Scholar
C. R. Brockelman, B. Wongsattayanont, P. Tan-Ariya, and S. Fucharoen, “Thalassemic erythrocytes inhibit in vitro growth of Plasmodium falciparum,” Journal of Clinical Microbiology, vol. 25, no. 1, pp. 56–60, 1987.
View at: Google Scholar
T. G. Smith, K. Ayi, L. Serghides, C. D. Mcallister, and K. C. Kain, “Innate immunity to malaria caused by Plasmodium falciparum,” Clinical and Investigative Medicine, vol. 25, no. 6, pp. 262–272, 2002.
View at: Google Scholar
K. Ayi, F. Turrini, A. Piga, and P. Arese, “Enhanced phagocytosis of ring-parasitized mutant erythrocytes: a common mechanism that may explain protection against falciparum malaria in sickle trait and beta-thalassemia trait,” Blood, vol. 104, no. 10, pp. 3364–3371, 2004.
View at: Publisher Site | Google Scholar
S. Perrotta, A. Borriello, A. Scaloni et al., “The N-terminal 11 amino acids of human erythrocyte band 3 are critical for aldolase binding and protein phosphorylation: implications for band 3 function,” Blood, vol. 106, no. 13, pp. 4359–4366, 2005.
View at: Publisher Site | Google Scholar
B. Genton, F. Al-Yaman, C. S. Mgone et al., “Ovalocytosis and cerebral malaria,” Nature, vol. 378, no. 6557, pp. 564–565, 1995.
View at: Google Scholar
S. J. Allen, A. O'Donnell, N. D. E. Alexander et al., “Prevention of cerebral malaria in children in Papua New Guinea by Southeast Asian ovalocytosis band 3,” The American Journal of Tropical Medicine and Hygiene, vol. 60, no. 6, pp. 1056–1060, 1999.
View at: Google Scholar
T. N. Williams, “Red blood cell defects and malaria,” Molecular and Biochemical Parasitology, vol. 149, no. 2, pp. 121–127, 2006.
View at: Publisher Site | Google Scholar
M. C. Murray and M. E. Perkins, “Phosphorylation of erythrocyte membrane and cytoskeleton proteins in cells infected with Plasmodium falciparum,” Molecular and Biochemical Parasitology, vol. 34, no. 3, pp. 229–236, 1989.
View at: Google Scholar
C. Magowan, J. Liang, J. Yeung, Y. Takakuwa, R. L. Coppel, and N. Mohandas, “Plasmodium falciparum: influence of malarial and host erythrocyte skeletal protein interactions on phosphorylation in infected erythrocytes,” Experimental Parasitology, vol. 89, no. 1, pp. 40–49, 1998.
View at: Publisher Site | Google Scholar
B. W. Suetterlin, B. Kappes, and R. M. Franklin, “Localization and stage specific phosphorylation of Plasmodium falciparum phosphoproteins during the intraerythrocytic cycle,” Molecular and Biochemical Parasitology, vol. 46, no. 1, pp. 113–122, 1991.
View at: Publisher Site | Google Scholar
A. Pantaleo, E. Ferru, F. Carta et al., “Analysis of changes in tyrosine and serine phosphorylation of red cell membrane proteins induced by P. falciparum growth,” Proteomics, vol. 10, no. 19, pp. 3469–3479, 2010.
View at: Publisher Site | Google Scholar
A. Pantaleo, E. Ferru, R. Vono et al., “New antimalarial indolone-N-oxides, generating radical species, destabilize the host cell membrane at early stages of Plasmodium falciparum growth: role of band 3 tyrosine phosphorylation,” Free Radical Biology and Medicine, vol. 52, no. 2, pp. 527–536, 2012.
View at: Publisher Site | Google Scholar
A. Pantaleo, G. Giribaldi, F. Mannu, P. Arese, and F. Turrini, “Naturally occurring anti-band 3 antibodies and red blood cell removal under physiological and pathological conditions,” Autoimmunity Reviews, vol. 7, no. 6, pp. 457–462, 2008.
View at: Publisher Site | Google Scholar
O. Olivieri, L. de Franceschi, M. D. Capellini, D. Girelli, R. Corrocher, and C. Brugnara, “Oxidative damage and erythrocyte membrane transport abnormalities in thalassemias,” Blood, vol. 84, no. 1, pp. 315–320, 1994.
View at: Google Scholar
L. de Franceschi, L. Ronzoni, M. D. Cappellini et al., “K-CL co-transport plays an important role in normal and β thalassemic erythropoiesis,” Haematologica, vol. 92, no. 10, pp. 1319–1326, 2007.
View at: Publisher Site | Google Scholar
C. Brugnara and L. de Franceschi, “Effect of cell age and phenylhydrazine on the cation transport properties of rabbit erythrocytes,” Journal of Cellular Physiology, vol. 154, no. 2, pp. 271–280, 1993.
View at: Publisher Site | Google Scholar
W. Su, B. E. Shmukler, M. N. Chernova et al., “Mouse K-Cl cotransporter KCC1: cloning, mapping, pathological expression, and functional regulation,” The American Journal of Physiology, vol. 277, no. 5, pp. C899–C912, 1999.
View at: Google Scholar
L. de Franceschi, F. Turrini, E. M. del Giudice et al., “Decreased band 3 anion transport activity and band 3 clusterization in congenital dyserythropoietic anemia type II,” Experimental Hematology, vol. 26, no. 9, pp. 869–873, 1998.
View at: Google Scholar
L. de Franceschi, O. Olivieri, E. Miraglia del Giudice et al., “Membrane cation and anion transport activities in erythrocytes of hereditary spherocytosis: effects of different membrane protein defects,” American Journal of Hematology, vol. 55, no. 3, pp. 121–128, 1997.
View at: Google Scholar
L. de Franceschi, R. S. Franco, M. Bertoldi et al., “Pharmacological inhibition of calpain-1 prevents red cell dehydration and reduces Gardos channel activity in a mouse model of sickle cell disease,” FASEB Journal, vol. 27, no. 2, pp. 750–759, 2013.
View at: Google Scholar
L. de Franceschi, N. Saadane, M. Trudel, S. L. Alper, C. Brugnara, and Y. Beuzard, “Treatment with oral clotrimazole blocks Ca²⁺-activated K+ transport and reverses erythrocyte dehydration in transgenic SAD mice. A model for therapy of sickle cell disease,” Journal of Clinical Investigation, vol. 93, no. 4, pp. 1670–1676, 1994.
View at: Google Scholar
A. Wieschhaus, A. Khan, A. Zaidi et al., “Calpain-1 knockout reveals broad effects on erythrocyte deformability and physiology,” The Biochemical Journal, vol. 448, no. 1, pp. 141–152, 2012.
View at: Google Scholar
L. de Franceschi, L. Fumagalli, O. Olivieri, R. Corrocher, C. A. Lowell, and G. Berton, “Deficiency of Src family kinases Fgr and Hck results in activation of erythrocyte K/Cl cotransport,” Journal of Clinical Investigation, vol. 99, no. 2, pp. 220–227, 1997.
View at: Google Scholar
L. de Franceschi et al., “Dietary magnesium supplementation reduces pain crises in patients with sickle cell disease,” Blood, vol. 90, 1997.
View at: Google Scholar
L. de Franceschi, P. Rouyer-Fessard, S. L. Alper, H. Jouault, C. Brugnara, and Y. Beuzard, “Combination therapy of erythropoietin, hydroxyurea, and clotrimazole in a β thalassemic mouse: a model for human therapy,” Blood, vol. 87, no. 3, pp. 1188–1195, 1996.
View at: Google Scholar
L. de Franceschi, M. D. Cappellini, G. Graziadei et al., “The effect of dietary magnesium supplementation on the cellular abnormalities of erythrocytes in patients with β thalassemia intermedia,” Haematologica, vol. 83, no. 2, pp. 118–125, 1998.
View at: Google Scholar
L. de Franceschi, C. Brugnara, and Y. Beuzard, “Dietary magnesium supplementation ameliorates anemia in a mouse model of β-thalassemia,” Blood, vol. 90, no. 3, pp. 1283–1290, 1997.
View at: Google Scholar
L. de Franceschi, F. Daraio, A. Filippini et al., “Liver expression of hepcidin and other iron genes in two mouse models of β-thalassemia,” Haematologica, vol. 91, no. 10, pp. 1336–1342, 2006.
View at: Google Scholar
L. de Franceschi, F. Turrini, M. Honczarenko et al., “In vivo reduction of erythrocyte oxidant stress in a murine model of beta-thalassemia,” Haematologica, vol. 89, no. 11, pp. 1287–1298, 2004.
View at: Google Scholar
O. Shalev, T. Repka, A. Goldfarb et al., “Deferiprone (L1) chelates pathologic iron deposits from membranes of intact thalassemic and sickle red blood cells both in vitro and in vivo,” Blood, vol. 86, no. 5, pp. 2008–2013, 1995.
View at: Google Scholar
C. B. Hyman, J. A. Ortega, G. Costin, and M. Takahashi, “The clinical significance of magnesium depletion in thalassemia,” Annals of the New York Academy of Sciences, vol. 344, pp. 436–443, 1980.
View at: Google Scholar
V. Abbasciano, G. Bader, L. Graziano et al., “Serum and erythrocyte levels of magnesium in microcytosis: comparison between heterozygous beta-thalassemia and sideropenic anemia,” Haematologica, vol. 76, no. 4, pp. 339–341, 1991.
View at: Google Scholar
E. A. Rachmilewitz, A. Shifter, and I. Kahane, “Vitamin E deficiency in β-thalassemia major: changes in hematological and biochemical parameters after a therapeutic trial with α-tocopherol,” The American Journal of Clinical Nutrition, vol. 32, no. 9, pp. 1850–1858, 1979.
View at: Google Scholar
I. Kahane and E. A. Rachmilewitz, “Alterations in the red blood cell membrane and the effect of vitamin E on osmotic fragility in β thalassemia major,” Israel Journal of Medical Sciences, vol. 12, no. 1, pp. 11–15, 1976.
View at: Google Scholar
L. Tesoriere, D. D'Arpa, D. Butera et al., “Oral supplements of vitamin E improve measures of oxidative stress in plasma and reduce oxidative damage to LDL and erythrocytes in β-thalassemia intermedia patients,” Free Radical Research, vol. 34, no. 5, pp. 529–540, 2001.
View at: Google Scholar
E. Fibach and E. A. Rachmilewitz, “The role of antioxidants and iron chelators in the treatment of oxidative stress in thalassemia,” Annals of the New York Academy of Sciences, vol. 1202, pp. 10–16, 2010.
View at: Publisher Site | Google Scholar
S. Srichairatanakool, C. Thephinlap, C. Phisalaphong, J. B. Porter, and S. Fucharoen, “Curcumin contributes to in vitro removal of non-transferrin bound iron by deferiprone and desferrioxamine in thalassemic plasma,” Medicinal Chemistry, vol. 3, no. 5, pp. 469–474, 2007.
View at: Publisher Site | Google Scholar
J. Amer, D. Atlas, and E. Fibach, “N-acetylcysteine amide (AD4) attenuates oxidative stress in beta-thalassemia blood cells,” Biochimica et Biophysica Acta, vol. 1780, no. 2, pp. 249–255, 2008.
View at: Publisher Site | Google Scholar
J. Amer, A. Goldfarb, E. A. Rachmilewitz, and E. Fibach, “Fermented papaya preparation as redox regulator in blood cells of β-thalassemic mice and patients,” Phytotherapy Research, vol. 22, no. 6, pp. 820–828, 2008.
View at: Publisher Site | Google Scholar
L. Weiss, “A rationale for an individualized administration frequency of epoetin β: a clinical perspective,” Nephrology Dialysis Transplantation, vol. 17, supplement 6, pp. 8–12, 2002.
View at: Google Scholar
M. I. Lai, J. Jiang, N. Silver et al., “Alpha-haemoglobin stabilising protein is a quantitative trait gene that modifies the phenotype of beta-thalassaemia,” The British Journal of Haematology, vol. 133, no. 6, pp. 675–682, 2006.
View at: Google Scholar
X. Yu, Y. Kong, L. C. Dore et al., “An erythroid chaperone that facilitates folding of alpha-globin subunits for hemoglobin synthesis,” The Journal of Clinical Investigation, vol. 117, no. 7, pp. 1856–1865, 2007.
View at: Google Scholar
E. Khandros, T. L. Mollan, X. Yu et al., “Insights into hemoglobin assembly through in vivo mutagenesis of α-hemoglobin stabilizing protein,” Journal of Biological Chemistry, vol. 287, no. 14, pp. 11325–11337, 2012.
View at: Publisher Site | Google Scholar
J. J. Chen, “Regulation of protein synthesis by the heme-regulated eIF2alpha kinase: relevance to anemias,” Blood, vol. 109, no. 7, pp. 2693–2699, 2007.
View at: Google Scholar
L. Lu, A.-P. Han, and J.-J. Chen, “Translation initiation control by heme-regulated eukaryotic initiation factor 2α kinase in erythroid cells under cytoplasmic stresses,” Molecular and Cellular Biology, vol. 21, no. 23, pp. 7971–7980, 2001.
View at: Publisher Site | Google Scholar
A.-P. Han, C. Yu, L. Lu et al., “Heme-regulated eIF2α kinase (HRI) is required for translational regulation and survival of erythroid precursors in iron deficiency,” EMBO Journal, vol. 20, no. 23, pp. 6909–6918, 2001.
View at: Publisher Site | Google Scholar
R. N. Suragani, R. S. Zachariah, J. G. Velazquez et al., “Heme-regulated eIF2alpha kinase activated Atf4 signaling pathway in oxidative stress and erythropoiesis,” Blood, vol. 119, no. 22, pp. 5276–5284, 2012.
View at: Google Scholar
H. H. Jang, K. O. Lee, Y. H. Chi et al., “Two enzymes in one: two yeast peroxiredoxins display oxidative stress-dependent switching from a peroxidase to a molecular chaperone function,” Cell, vol. 117, no. 5, pp. 625–635, 2004.
View at: Publisher Site | Google Scholar
Z. A. Wood, E. Schröder, J. R. Harris, and L. B. Poole, “Structure, mechanism and regulation of peroxiredoxins,” Trends in Biochemical Sciences, vol. 28, no. 1, pp. 32–40, 2003.
View at: Publisher Site | Google Scholar
F. M. Low, M. B. Hampton, and C. C. Winterbourn, “Peroxiredoxin 2 and peroxide metabolism in the erythrocyte,” Antioxidants and Redox Signaling, vol. 10, no. 9, pp. 1621–1630, 2008.
View at: Publisher Site | Google Scholar
B. Manta, M. Hugo, C. Ortiz, G. Ferrer-Sueta, M. Trujillo, and A. Denicola, “The peroxidase and peroxynitrite reductase activity of human erythrocyte peroxiredoxin 2,” Archives of Biochemistry and Biophysics, vol. 484, no. 2, pp. 146–154, 2009.
View at: Publisher Site | Google Scholar
A. Matte, P. S. Low, F. Turrini et al., “Peroxiredoxin-2 expression is increased in β-thalassemic mouse red cells but is displaced from the membrane as a marker of oxidative stress,” Free Radical Biology and Medicine, vol. 49, no. 3, pp. 457–466, 2010.
View at: Publisher Site | Google Scholar
A. Matte, M. Bertoldi, N. Mohandas et al., “Membrane association of peroxiredoxin-2 in red cells is mediated by the N-terminal cytoplasmic domain of band 3,” Free Radical Biology and Medicine, vol. 55, pp. 27–35, 2013.
View at: Google Scholar
L. de Franceschi, M. Bertoldi, L. de Falco et al., “Oxidative stress modulates heme synthesis and induces peroxiredoxin-2 as a novel cytoprotective response in β-thalassemic erythropoiesis,” Haematologica, vol. 96, no. 11, pp. 1595–1604, 2011.
View at: Publisher Site | Google Scholar
P. Zhang, B. Liu, S. W. Kang, M. S. Seo, S. G. Rhee, and L. M. Obeid, “Thioredoxin peroxidase is a novel inhibitor of apoptosis with a mechanism distinct from that of Bcl-2,” Journal of Biological Chemistry, vol. 272, no. 49, pp. 30615–30618, 1997.
View at: Publisher Site | Google Scholar
S. W. Kang, H. Z. Chae, M. S. Seo, K. Kim, I. C. Baines, and S. G. Rhee, “Mammalian peroxiredoxin isoforms can reduce hydrogen peroxide generatedin response to growth factors and tumor necrosis factor-α,” Journal of Biological Chemistry, vol. 273, no. 11, pp. 6297–6302, 1998.
View at: Publisher Site | Google Scholar
J. Liu, J. Zhang, Y. Ginzburg et al., “Quantitative analysis of murine terminal erythroid differentiation in vivo: novel method to study normal and disordered erythropoiesis,” Blood, vol. 121, no. 2, pp. e43–e49, 2013.
View at: Google Scholar
S. Santos Franco, L. De Falco, S. Ghaffari et al., “Resveratrol accelerates erythroid maturation by activation of FOXO₃ and ameliorates anemia in beta-thalassemic mice,” Haematologica, 2013.
View at: Publisher Site | Google Scholar

Copyright

Copyright © 2013 Lucia De Franceschi et al. This is an open access article distributed under the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

PDF Download Citation

Download other formats

Order printed copies

Views

3629

Downloads

2393

Citations