Enhancement of β-Globin Gene Expression in Thalassemic IVS2-654 Induced Pluripotent Stem Cell-Derived Erythroid Cells by Modified U7 snRNA

Phanthong, Phetcharat; Borwornpinyo, Suparerk; Kitiyanant, Narisorn; Jearawiriyapaisarn, Natee; Nuntakarn, Lalana; Saetan, Jirawat; Nualkaew, Tiwaporn; Sa‐ngiamsuntorn, Khanit; Anurathapan, Usanarat; Dinnyés, András; Kitiyanant, Yindee; Hongeng, Suradej

doi:10.1002/sctm.16-0121

Cited by 13 publications

(13 citation statements)

References 64 publications

(89 reference statements)

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“…IVS2–654 β-thalassemia is one of the most common of these splicing mutations, causing a C to T change in the position 654 of the IVS2 intron in the β-hemoglobin gene ( HBB ) to generate an aberrant 5′-donor splice site at position 652 and activates a cryptic 3′acceptor splice site at position 579. This allows for the aberrant inclusion of an intron and the translation of a non-functional β-globin protein [75]. Expression of this non-functional protein leads to low oxygen levels and a shortage of red blood cells, which can lead to life threatening anemia.…”

Section: Figmentioning

confidence: 99%

RNA Splicing and Disease: Animal Models to Therapies

et al. 2019

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Alternative splicing of pre-messenger RNA increases genetic diversity and recent studies estimate that most human multi-exon genes are alternatively spliced. If this process is not highly regulated and accurate, it leads to mis-splicing events which may result in proteins with altered function. A growing body of work has implicated mis-splicing events as contributing to a wide range of diseases including cancer, neurodegenerative diseases, and muscular dystrophies. Understanding the mechanisms that cause aberrant splicing events and how this leads to disease is vital for designing effective therapeutic strategies. This review focuses on advances in therapies targeting splicing and highlights the animal models developed to recapitulate disease phenotypes as a model for testing these therapies.

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Section: Figmentioning

confidence: 99%

RNA Splicing and Disease: Animal Models to Therapies

et al. 2019

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“…SSOs modulate RNA splicing by redirecting alternative splicing that can be categorized in four mechanisms: exon skipping, exon retention, restoration of correct splicing and displacement of splicing factors from triplets repeats which have been reviewed extensively. 28 The SSOs have been used to correct aberrant splicing in β-thalassemia alleles including the mutations IVS1-110, 34 , 35 IVS2-654, 36 – 38 IVS2-705, 39 IVS2-745, 40 and βE. 36 SSOs successfully induced correct splicing and increased normal β-globin production in cell-free extracts, stable cell lines with a mutated β-globin gene, erythroid mononuclear cells from peripheral blood of patients, thalassemic mouse erythroid progenitors, human iPSCs and β-thalassemic mouse model.…”

Section: Nucleic Acid Therapy For β-Thalassemiamentioning

confidence: 99%

“… 36 SSOs successfully induced correct splicing and increased normal β-globin production in cell-free extracts, stable cell lines with a mutated β-globin gene, erythroid mononuclear cells from peripheral blood of patients, thalassemic mouse erythroid progenitors, human iPSCs and β-thalassemic mouse model. 36 – 38 , 40 , 41 Among patients with β IVS2−654 thalassemia, erythroid cells, free uptake and syringe load of SSOs into cells increased correct β-globin mRNA up to 77% and HbA production up to 54%. 36 Moreover, in the β IVS2−654 -thalassemia mouse model, intravenous injection of SSOs restored 12% of correct β-globin mRNA in mice peripheral blood or increased 6-fold compared with untreated controls.…”

Section: Nucleic Acid Therapy For β-Thalassemiamentioning

confidence: 99%

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<p>Nucleic Acid Therapy for β-Thalassemia</p>

d'Arqom¹

2020

BTT

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β-thalassemia is caused by mutations in the β-globin gene which diminishes or abolishes β-globin chain production. This reduction causes an imbalance of the α/β-globin chain ratio and contributes to the pathogenesis of the disease. Several approaches to reduce the imbalance of the α/β ratio using several nucleic acid-based technologies such as RNAi, lentiviral mediated gene therapy, splice switching oligonucleotides (SSOs) and gene editing technology have been investigated extensively. These approaches aim to reduce excess free α-globin, either by reducing the α-globin chain, restoring β-globin expression and reactivating γ-globin expression, leading a reduced disease severity, treatment necessity, treatment interval, and disease complications, thus, increasing the life quality of the patients and alleviating economic burden. Therefore, nucleic acid-based therapy might become a potential targeted therapy for β-thalassemia.

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“…Apart from transfusion applications, understanding RBCs re-differentiation from iPS cells in vitro is also fundamental to recapitulate defects in erythroid differentiation and boost drug discovery [ 49 ] or to test the effectiveness of gene-edited iPS cell-derived HSCs [ 50 , 51 ].…”

Section: Advances In Rbcs Derivation From Ips Cellsmentioning

confidence: 99%

Induced Pluripotent Stem Cell-Derived Red Blood Cells and Platelet Concentrates: From Bench to Bedside

Focosi¹,

Amabile

2017

Cells

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Red blood cells and platelets are anucleate blood components indispensable for oxygen delivery and hemostasis, respectively. Derivation of these blood elements from induced pluripotent stem (iPS) cells has the potential to develop blood donor-independent and genetic manipulation-prone products to complement or replace current transfusion banking, also minimizing the risk of alloimmunization. While the production of erythrocytes from iPS cells has challenges to overcome, such as differentiation into adult-type phenotype that functions properly after transfusion, platelet products are qualitatively and quantitatively approaching a clinically-applicable level owing to advances in expandable megakaryocyte (MK) lines, platelet-producing bioreactors, and novel reagents. Guidelines that assure the quality of iPS cells-derived blood products for clinical application represent a novel challenge for regulatory agencies. Considering the minimal risk of tumorigenicity and the expected significant demand of such products, ex vivo production of iPS-derived blood components can pave the way for iPS translation into the clinic.

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Enhancement of β-Globin Gene Expression in Thalassemic IVS2-654 Induced Pluripotent Stem Cell-Derived Erythroid Cells by Modified U7 snRNA

Cited by 13 publications

References 64 publications

RNA Splicing and Disease: Animal Models to Therapies

RNA Splicing and Disease: Animal Models to Therapies

<p>Nucleic Acid Therapy for β-Thalassemia</p>

Induced Pluripotent Stem Cell-Derived Red Blood Cells and Platelet Concentrates: From Bench to Bedside

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