Abstract
Backgroundα-Thalassemia, a congenital hemoglobinopathy, is characterized by deficiency and/or reduced levels of α-globin chains in serious forms of α-thalassemia (HbH disease/Hb Bart’s). This research work deals with a Protein Replacement Therapy approach in order to manage α-thalassemia manifestations, caused by the excess of β-globin chain into HbH RBCs. The main goal was to produce the recombinant human α-globin chain in fusion with TAT, a Protein Transduction Domain, to ex vivo deliver it into HbH patients RBCs, to replace the endogenous missing α-globin chain.ResultsCloning of the α-globin coding sequence, fused to the nucleotide sequence of TAT peptide was conducted and the human recombinant fusion proteins, 10xHis-XaSITE-α-globin-HA and 10xHis-XaSITE-TAT-α-globin-HA were produced. The ability of human recombinant 10xHis-XaSITE-α-globin-HA to interact in vitro with the previously produced 10xHis-XaSITE-TAT-β-globin-HA and form α-/β-globin heterodimers, was assessed and confirmed by size exclusion chromatography. The recombinant 10xHis-XaSITE-TAT-α-globin-HA was successfully delivered into human proerythroid K-562 cells, during the preliminary transduction evaluation experiments. Finally, the recombinant, TAT-fused α-globin was successfully transduced into RBCs, derived from HbH patients and reduced the formation of HbH-Inclusion Bodies, known to contain harmful β4-globin chain tetramers.ConclusionsOur data confirm the successful ex vivo transduction of recombinant α-globin chains in HbH RBCs to replace the missing a-globin chain and reduce the HbH-inclusion bodies, seen in α-thalassemias. These findings broaden the possibility of applying a Protein Replacement Therapy approach to module sever forms of α-thalassemia, using recombinant α-globin chains, through PTD technology.
Highlights
Protein Replacement Therapy (PRT) confers an alternative therapeutic approach to monogenic disorders, where a mutated gene encodes either an abnormal protein or no protein at all
TAT peptide, as the first Protein Transduction Domains (PTDs) derived from HIV TAT protein sequence [13, 14], has attracted worldwide attention as suitable for efficient intracellular transduction of cargo
This study aimed to: (i) produce the fusion recombinant 10xHis-XaSITE-αglobin-HA and 10xHis-XaSITE-TAT-α-globin-HA proteins, (ii) assess the in vitro formation of a stable complex of the 10xHis-XaSITE-α-globin-HA with the corresponding 10xHis-XaSITE-TAT-β-globin-HA and (iii) transduce the 10xHis-XaSITE-TAT-α-globin-HA deliberately in vitro, into K-562 proerythroid cells and ex vivo, into Red blood cells (RBC) derived from HBH patients, in order to alter the disease’s phenotype, by reducing the formation of the harmful β4-tetramers into patients’ RBCs
Summary
Protein Replacement Therapy (PRT) confers an alternative therapeutic approach to monogenic disorders, where a mutated gene encodes either an abnormal protein or no protein at all. Biologics must be either highly lipophilic or of very small size or there must be transported via a specific uptake mechanism. Due to this inability to cross the cellular membrane, efficient intracellular delivery of recombinant protein therapeutics remains problematic. With safety and efficacy being still major issues for wider application of gene therapy of monogenic disorders, PTD technology for protein delivery in the frame of PRT has been considered an alternative approach, without interfering with the host’s genome [15], and there are many ongoing clinical trials [2, 6] towards this goal
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