Reproducible Immortalization of Erythroblasts from Multiple Stem Cell Sources Provides Approach for Sustainable RBC Therapeutics

Overview

Journal Mol Ther Methods Clin Dev

Publisher Cell Press

Date 2021 Sep 6

PMID 34485592

Citations 12

Authors

Deborah E Daniels

Daniel C J Ferguson

Rebecca E Griffiths

Kongtana Trakarnsanga

Nicola Cogan

Katherine A MacInnes

Kathryn E Mordue

Tatyana Andrienko

Ivan Ferrer-Vicens

Daniel Ramos Jimenez

Phillip A Lewis

Marieangela C Wilson

Maurice A Canham

Ryo Kurita

Yukio Nakamura

David J Anstee

Jan Frayne

Affiliations

Soon will be listed here.

Abstract

Developing robust methodology for the sustainable production of red blood cells is essential for providing an alternative source of clinical-quality blood, particularly for individuals with rare blood group phenotypes. Immortalized erythroid progenitor cell lines are the most promising emergent technology for achieving this goal. We previously created the erythroid cell line BEL-A from bone marrow CD34 cells that had improved differentiation and enucleation potential compared to other lines reported. In this study we show that our immortalization approach is reproducible for erythroid cells differentiated from bone marrow and also from far more accessible peripheral and cord blood CD34 cells, consistently generating lines with similar improved erythroid performance. Extensive characterization of the lines shows them to accurately recapitulate their primary cell equivalents and provides a molecular signature for immortalization. In addition, we show that only cells at a specific stage of erythropoiesis, predominantly proerythroblasts, are amenable to immortalization. Our methodology provides a step forward in the drive for a sustainable supply of red cells for clinical use and for the generation of model cellular systems for the study of erythropoiesis in health and disease, with the added benefit of an indefinite expansion window for manipulation of molecular targets.

Citing Articles

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