Sean C. McConnell

JunB and JunD regulate human heme oxygenase-1 gene expression in renal epithelial cells

Heme oxygenase-1 is a highly inducible gene, the product of which catalyzes breakdown of the prooxidant heme. The purpose of this study was to investigate the regulation of the human heme oxygenase-1 gene in renal epithelial cells. DNase I hyper-sensitivity studies identified three distal sites (HS-2, -3, and -4) corresponding to approximately -4.0, -7.2, and -9.2 kb, respectively, of the heme oxygenase-1 promoter in addition to one proximal region, HS-1, which we have shown previously to be an E box. In vivo dimethyl sulfate footprinting of the HS-2 region revealed six individual protected guanines. Two mutations within HS-2 combined with a third mutation of the proximal E box abolished hemin- and cadmium-driven heme oxygenase-1 promoter activation, suggesting that these three sites synergized for maximal heme oxygenase-1 induction. Jun proteins bound to the antioxidant response element in the HS-2 region in vitro and associated with the heme oxygenase-1 promoter in vivo. JunB and JunD contribute opposing effects; JunB activated whereas JunD repressed heme oxygenase-1 expression in human renal epithelial cells, results that were corroborated in junB-/- and junD-/- cells. We propose that heme oxygenase-1 induction is controlled by a dynamic interplay of regulatory proteins, and we provide new insights into the molecular control of the human heme oxygenase-1 gene.

Humanized Mouse Model of Cooley's Anemia

A novel humanized mouse model of Cooleys Anemia (CA) was generated by targeted gene replacement in embryonic stem (ES) cells. Because the mouse does not have a true fetal hemoglobin, a delayed switching human γ to β0 globin gene cassette (γβ0) was inserted directly into the murine β globin locus replacing both adult mouse β globin genes. The inserted human β0 globin allele has a mutation in the splice donor site that produces the same aberrant transcripts in mice as described in human cells. No functional human β globin polypeptide chains are produced. Heterozygous γβ0 mice suffer from microcytic anemia. Unlike previously described animal models of β thalassemia major, homozygous γβ0 mice switch from mouse embryonic globin chains to human fetal γ globin during fetal life. When bred with human α globin knockin mice, homozygous CA mice survive solely upon human fetal hemoglobin at birth. This preclinical animal model of CA can be utilized to study the regulation of globin gene expression, synthesis, and switching; the reactivation of human fetal globin gene expression; and the testing of genetic and cell-based therapies for the correction of thalassemia.

Preclinical transfusion-dependent humanized mouse model of β thalassemia major

A preclinical humanized mouse model of beta thalassemia major or Cooley anemia (CA) was generated by targeted gene replacement of the mouse adult globin genes in embryonic stem cells. The mouse adult alpha and beta globin genes were replaced with adult human alpha globin genes (alpha2alpha1) and a human fetal to adult hemoglobin (Hb)-switching cassette (gamma(HPFH)deltabeta(0)), respectively. Similar to human infants with CA, fully humanized mice survived postnatally by synthesizing predominantly human fetal Hb, HbF (alpha(2)gamma(2)), with a small amount of human minor adult Hb, HbA2 (alpha(2)delta(2)). Completion of the human fetal to adult Hb switch after birth resulted in severe anemia marked by erythroid hyperplasia, ineffective erythropoiesis, hemolysis, and death. Similar to human patients, CA mice were rescued from lethal anemia by regular blood transfusion. Transfusion corrected the anemia and effectively suppressed the ineffective erythropoiesis, but led to iron overload. This preclinical humanized animal model of CA will be useful for the development of new transfusion and iron chelation regimens, the study of iron homeostasis in disease, and testing of cellular and genetic therapies for the correction of thalassemia.

Human Globin Knock-in Mice Complete Fetal-to-Adult Hemoglobin Switching in Postnatal Development

ABSTRACT Elevated levels of fetal γ-globin can cure disorders caused by mutations in the adult β-globin gene. This clinical finding has motivated studies to improve our understanding of hemoglobin switching. Unlike humans, mice do not express a distinct fetal globin. Transgenic mice that contain the human β-globin locus complete their fetal-to-adult hemoglobin switch prior to birth, with human γ-globin predominantly restricted to primitive erythroid cells. We established humanized (100% human hemoglobin) knock-in mice that demonstrate a distinct fetal hemoglobin (HbF) stage, where γ-globin is the dominant globin chain produced during mid- to late gestation. Human γ- and β-globin gene competition is evident around the time of birth, and γ-globin chain production diminishes in postnatal life, with transient production of HbF reticulocytes. Following completion of the γ- to-β-globin switch, adult erythroid cells synthesize low levels of HbF. We conclude that the knock-in globin genes are expressed in a pattern strikingly similar to that in human development, most notably with postnatal resolution of the fetal-to-adult hemoglobin switch. Our findings are consistent with the importance of BCL11A in hemoglobin switching, since removal of intergenic binding sites for BCL11A results in human γ-globin expression in mouse definitive erythroid cells.

Humanized mouse models of Cooley's anemia: correct fetal‐to‐adult hemoglobin switching, disease onset, and disease pathology

β thalassemia major or Cooleys Anemia (CA) has been difficult to model in mice due to their lack of a fetal hemoglobin gene equivalent. This summary describes novel preclinical humanized mouse models of CA that survive on human fetal hemoglobin at birth and are blood‐transfusion dependent for life upon completion of their human fetal‐to‐adult hemoglobin switch after birth. These CA models are the first to recapitulate the temporal onset of the disease in human patients. These novel humanized CA disease models are useful for the study of the regulation of globin gene expression, synthesis, and switching; examining the onset of disease pathology; development of transfusion and iron chelation therapies; induction of fetal hemoglobin synthesis; and the testing of novel genetic and cell‐based therapies for the correction of thalassemia.

Erythropoiesis in the Absence of Adult Hemoglobin

ABSTRACT During erythropoiesis, hemoglobin (Hb) synthesis increases from early progenitors to mature enucleated erythrocytes. Although Hb is one of the most extensively studied proteins, the role of Hb in erythroid lineage commitment, differentiation, and maturation remains unclear. In this study, we generate mouse embryos and embryonic stem (ES) cells with all of the adult α and β globin genes deleted (Hb Null). While Hb Null embryos die in midgestation, adult globin genes are not required for primitive or definitive erythroid lineage commitment. In vitro differentiation of Hb Null ES cells generates viable definitive proerythroblasts that undergo apoptosis upon terminal differentiation. Surprisingly, all stages of Hb Null-derived definitive erythroblasts develop normally in vivo in chimeric mice, and Hb Null erythroid cells undergo enucleation to form reticulocytes. Free heme toxicity is not observed in Hb Null-derived erythroblasts. Transplantation of Hb Null-derived bone marrow cells provides short-term radioprotection of lethally irradiated recipients, whose progressive anemia results in an erythroid hyperplasia composed entirely of Hb Null-derived erythroblasts. This novel experimental model system enables the role played by Hb in erythroid cell enucleation, cytoskeleton maturation, and heme and iron regulation to be studied.