The pyruvate kinase activator mitapivat reduces hemolysis and improves anemia in a β-thalassemia mouse model
Alessandro Matte, … , Carlo Brugnara, Lucia De Franceschi
Alessandro Matte, … , Carlo Brugnara, Lucia De Franceschi
Published April 6, 2021
Citation Information: J Clin Invest. 2021;131(10):e144206. https://doi.org/10.1172/JCI144206.
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Research Article Hematology

The pyruvate kinase activator mitapivat reduces hemolysis and improves anemia in a β-thalassemia mouse model

Abstract

Anemia in β-thalassemia is related to ineffective erythropoiesis and reduced red cell survival. Excess free heme and accumulation of unpaired α-globin chains impose substantial oxidative stress on β-thalassemic erythroblasts and erythrocytes, impacting cell metabolism. We hypothesized that increased pyruvate kinase activity induced by mitapivat (AG-348) in the Hbbth3/+ mouse model for β-thalassemia would reduce chronic hemolysis and ineffective erythropoiesis through stimulation of red cell glycolytic metabolism. Oral mitapivat administration ameliorated ineffective erythropoiesis and anemia in Hbbth3/+ mice. Increased ATP, reduced reactive oxygen species production, and reduced markers of mitochondrial dysfunction associated with improved mitochondrial clearance suggested enhanced metabolism following mitapivat administration in β-thalassemia. The amelioration of responsiveness to erythropoietin resulted in reduced soluble erythroferrone, increased liver Hamp expression, and diminished liver iron overload. Mitapivat reduced duodenal Dmt1 expression potentially by activating the pyruvate kinase M2-HIF2α axis, representing a mechanism additional to Hamp in controlling iron absorption and preventing β-thalassemia–related liver iron overload. In ex vivo studies on erythroid precursors from patients with β-thalassemia, mitapivat enhanced erythropoiesis, promoted erythroid maturation, and decreased apoptosis. Overall, pyruvate kinase activation as a treatment modality for β-thalassemia in preclinical model systems had multiple beneficial effects in the erythropoietic compartment and beyond, providing a strong scientific basis for further clinical trials.

Authors

Alessandro Matte, Enrica Federti, Charles Kung, Penelope A. Kosinski, Rohini Narayanaswamy, Roberta Russo, Giorgia Federico, Francesca Carlomagno, Maria Andrea Desbats, Leonardo Salviati, Christophe Leboeuf, Maria Teresa Valenti, Francesco Turrini, Anne Janin, Shaoxia Yu, Elisabetta Beneduce, Sebastien Ronseaux, Iana Iatcenko, Lenny Dang, Tomas Ganz, Chun-Ling Jung, Achille Iolascon, Carlo Brugnara, Lucia De Franceschi

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Figure 3

Mitapivat improved mitochondrial dysfunction and biogenesis in Hbbth3/+ mice.

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Mitapivat improved mitochondrial dysfunction and biogenesis in Hbbth3/+ ...
(A, left panel) Flow cytometric analysis using MitoTracker in erythroblasts from WT (red) and Hbbth3/+ (proerythroblasts [pop I, green], basophilic erythroblasts [pop II, blue], polychromatic erythroblasts [pop III, purple], and orthochromatic erythroblasts [pop IV, pink]) mice. One representative scatter from 4 with similar results is presented. (A, right panel) Mitochondrial content of erythroblasts from WT and Hbbth3/+ mice treated with vehicle or mitapivat. Data are mean ± SD (n = 6). (B) mRNA expression of Atp6, Mtco1, Cytb, and Pgc1a genes by qRT-PCR on sorted erythroblasts from bone marrow of Hbbth3/+ mice treated with vehicle or mitapivat. Data are mean ± SD (n = 6 per group). (C) mRNA expression of Yme1l by qRT-PCR on sorted erythroblasts from bone marrow of WT and Hbbth3/+ mice treated with vehicle or mitapivat. Data are mean ± SD (n = 6 per group). (AC) #P < 0.05 compared with WT mice and *P < 0.05 compared with vehicle-treated mice by 2-way ANOVA with Bonferroni multiple comparison correction.