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3373 Pathophysiology and Treatment of Beta-Thalassemia: Investigations of Heme Oxygenase 1 and Its Inhibitors

Thalassemia and Globin Gene Regulation
Program: Oral and Poster Abstracts
Session: 112. Thalassemia and Globin Gene Regulation: Poster III
Monday, December 7, 2015, 6:00 PM-8:00 PM
Hall A, Level 2 (Orange County Convention Center)

Daniel Garcia dos Santos, PhD1*, Zuzana Zidova, MSc2*, Marc Mikhael, PhD3*, Amel Hamdi, PhD4*, Monika Horvathova, PhD5 and Prem Ponka, MD, PhD, FCMA1

1Lady Davis Institute for Medical Research, Montreal, QC, Canada
2Faculty of Medicine and Dentistry, Palacky University, Olomouc, Czech Republic
3School of Arts and Science, Lebanese American University, Beirut, Lebanon
4Department of Physiology and Medicine, McGill University, Montreal, QC, Canada
5Department of Biology, Faculty of Medicine and Dentistry, Palacky University, Olomouc, Czech Republic

Thalassemias are a heterogeneous group of red blood cell disorders ranging from a clinically severe phenotype requiring life-saving transfusions (thalassemia major) to a relatively moderate symptomatic disorder, sometimes requiring transfusions (thalassemia intermedia). Thalassemia minor, the least severe form of the disorder, is characterized by minimal to mild symptoms. Though considered a major cause of morbidity and mortality worldwide, there is still no universally available cure for thalassemia major. The reason for this is, at least in part, due to the lack of full understanding of pathophysiology of thalassemia. The underlying basis of thalassemia pathology is the premature apoptotic destruction of erythroblasts causing ineffective erythropoeisis. Normally, the assembly of adult hemoglobin (consisting of a tetramer of two α- and two β-globin chains) features a very tight coordination of α- and β-globin chain synthesis. However, in β-thalassemia, β-globin synthesis is diminished causing α-globin accumulation; while in α-thalassemia the opposite scenario occurs. Unpaired globin chains that accumulate in thalassemic erythroblasts are bound to heme. In addition, in β-thalassemia an erythroid specific protease destroys excess α-globin chains, likely leading to the generation of a pool of “free” heme in erythroblasts. “Unshielded” heme is toxic, but this toxicity will likely be augmented, if heme oxygenase 1 (HO-1) can release iron from heme.

    So far, virtually no information about the expression of HO-1 in erythroblasts has been produced. However, we have recently provided unequivocal evidence that this enzyme is present in several model erythroid cells1. Based on this novel and important finding, we hypothesize that in β-thalassemic erythroblasts HO-1-mediated release of iron from heme is the major culprit responsible for cellular damage. To test this hypothesis, we exploited the mouse model of β-thalassemia known as th3/th3. Our data indicates that HO-1 expression is increased in the liver, spleen and kidney of β-thalassemic mice compared to wild-type mice. Importantly, we observed that erythropoietin-mediated erythroid differentiation of fetal liver (FL) cells isolated from β-thalassemic fetuses have increased levels of HO-1 at mRNA and protein levels as well as a decrease in phosphorylated eIF2-α levels. Ferritin levels were  increased in β-thalassemic FL cells suggesting increased heme catabolism and iron release. To investigate the contribution of HO-1 to the pathology associated with β-thalassemia, wild-type and thalassemic (th3/+) mice were injected with 40 µmoles/kg/d of tin-protoporphyrin IX (SnPP, HO-1 inhibitor) during a 4-week period, 3 times a week. Our results show that β-thalassemic mice injected with SnPP display a decrease in the spleen index, hemoglobin levels, red blood cell counts, reticulocyte counts and liver iron content when compared to PBS injected β-thalassemic mice. Additionally, HO-1 inhibition reduced ineffective erytropoiesis in β-thalassemia mice. Our results indicate that β-thalassemic erythroblasts have inappropriately high levels of “free” heme that is continuously degraded by HO-1. Further research is needed to determine whether iron liberated from heme by HO-1 is directly responsible for the damage of β-thalassemic erythroblasts.

 1Garcia-Santos D, et al. Heme oxygenase 1 is expressed in murine erythroid cells where it controls the level of regulatory heme. Blood 123 (14): 2269-77, 2014.

Disclosures: No relevant conflicts of interest to declare.

*signifies non-member of ASH