Browsing by Author "Gibbons, R.J."

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Editing an α-globin enhancer in primary human hematopoietic stem cells as a treatment for β-thalassemia
(Nature Pub. Group, 2017) Mettananda, S.; Fisher, C.A.; Hay, D.; Badat, M.; Quek, L.; Clark, K.; Hublitz, P.; Downes, D.; Kerry, J.; Gosden, M.; Telenius, J.; Sloane-Stanley, J.A.; Faustino, P.; Coelho, A.; Doondeea, J.; Usukhbayar, B.; Sopp, P.; Sharpe, J.A.; Hughes, J.R.; Vyas, P.; Gibbons, R.J.; Higgs, D.R.
β-Thalassemia is one of the most common inherited anemias, with no effective cure for most patients. The pathophysiology reflects an imbalance between α- and β-globin chains with an excess of free α-globin chains causing ineffective erythropoiesis and hemolysis. When α-thalassemia is co-inherited with β-thalassemia, excess free α-globin chains are reduced significantly ameliorating the clinical severity. Here we demonstrate the use of CRISPR/Cas9 genome editing of primary human hematopoietic stem/progenitor (CD34+) cells to emulate a natural mutation, which deletes the MCS-R2 α-globin enhancer and causes α-thalassemia. When edited CD34+ cells are differentiated into erythroid cells, we observe the expected reduction in α-globin expression and a correction of the pathologic globin chain imbalance in cells from patients with β-thalassemia. Xenograft assays show that a proportion of the edited CD34+ cells are long-term repopulating hematopoietic stem cells, demonstrating the potential of this approach for translation into a therapy for β-thalassemia.β-thalassemia is characterised by the presence of an excess of α-globin chains, which contribute to erythrocyte pathology. Here the authors use CRISP/Cas9 to reduce α-globin expression in hematopoietic precursors, and show effectiveness in xenograft assays in mice.
Phenotypic and molecular characterization of a serum-free miniature erythroid differentiation system suitable for high-throughput screening and single-cell assays
(Elsevier Science Inc., 2018) Mettananda, S.; Clark, K.; Fisher, C.A.; Sloane-Stanley, J.A.; Gibbons, R.J.; Higgs, D.R.
In vitro erythroid differentiation systems are used to study the mechanisms underlying normal and abnormal erythropoiesis and to test the effects of various extracellular factors on erythropoiesis. The use of serum or conditioned medium in liquid cultures and the seeding of cultures with heterogeneous peripheral blood mononuclear cells confound the reproducibility of these systems. Newer erythroid differentiation culture systems have overcome some of these limitations by using a fully defined, serum-free medium and initiating cultures using purified CD34+ cells. Although widely used in bulk cultures, these protocols have not been rigorously tested in high-throughput or single-cell assays. Here, we describe a serum-free erythroid differentiation system suitable for small-scale and single-cell experiments. This system generates large numbers of terminally differentiated erythroid cells of very high purity. Here we have adapted this culture system to a 96-well format and have developed a protocol to grow erythroid colonies from single erythroid progenitors in minute culture volumes.
Selective silencing of α-globin by the histone demethylase inhibitor IOX1: A potentially new pathway for treatment of β-thalassemia
(Pavia, Italy : Ferrata Storti Foundation, 2017) Mettananda, S.; Fisher, C.A.; Sloane-Stanley, J.A.; Taylor, S.; Oppermann, U.; Gibbons, R.J.; Higgs, D.R.
Understanding α-globin gene regulation and implications for the treatment of β-thalassemia.
(Wiley-Blackwell, 2016) Mettananda, S.; Gibbons, R.J.; Higgs, D.R.
Over the past three decades, a vast amount of new information has been uncovered describing how the globin genes are regulated. This knowledge has provided significant insights into the general understanding of the regulation of human genes. It is now known that molecular defects within and around the α- and β-globin genes, as well as in the distant regulatory elements, can cause thalassemia. Unbalanced production of globin chains owing to defective synthesis of one, and the continued unopposed synthesis of another, is the central causative factor in the cellular pathology and pathophysiology of thalassemia. A large body of clinical, genetic, and experimental evidence suggests that altering globin chain imbalance by reducing the production of α-globin synthesis ameliorates the disease severity in patients with β-thalassemia. With the development of new genetic-based therapeutic tools that have a potential to decrease the expression of a selected gene in a tissue-specific manner, the possibility of decreasing expression of the α-globin gene to improve the clinical severity of β-thalassemia could become a reality.