Delineating stages of erythropoiesis using imaging flow cytometry

• Published in: Methods (San Diego, Calif.) Vol. 112; pp. 68 - 74
• Main Authors: McGrath, K.E., Catherman, S.C., Palis, J.
• Format: Journal Article
• Language: English
• Published: United States Elsevier Inc 01.01.2017
• Subjects: Animals; Biomarkers - metabolism; Bone marrow; Bone Marrow Cells - classification; Bone Marrow Cells - cytology; Bone Marrow Cells - metabolism; Cell cycle; Cell Cycle - genetics; Cell Differentiation; Cell Lineage - genetics; Cell Nucleus - ultrastructure; Erythroblasts - cytology; Erythroblasts - metabolism; Erythrocytes - cytology; Erythrocytes - metabolism; Erythroid; Erythropoiesis - genetics; Flow Cytometry - instrumentation; Flow Cytometry - methods; Humans; Image Cytometry - instrumentation; Image Cytometry - methods; ImageStream; Imaging flow cytometry; Mice; Primary Cell Culture; RBC; Reticulocytes - cytology; Reticulocytes - metabolism; Ribosomes - ultrastructure; Staining and Labeling - methods; Bone marrow; ImageStream; RBC; Erythroid; Imaging flow cytometry; Cell cycle
• ISSN: 1046-2023; 1095-9130
• DOI: 10.1016/j.ymeth.2016.08.012

[Display omitted] •Imaging flow cytometry (IFC) can delineate seven erythroid populations in bone marrow.•IFC-based erythroid intermediates correlate with histologically-defined intermediates.•Intermediate erythroid precursors are not distinguished by CD71 or CD44 staining.•Better separation of erythroid precursors is achieved using cell and nuclear size.•IFC can address challenges of limited cell markers and gating on a continuum. Adult humans need to make 2.5million red blood cells (RBCs) every second to maintain a steady state level of 25trillion circulating RBCs. Understanding normal erythropoiesis as well as diseases that afflict the erythron, such as genetic anemias, hyperproliferative disorders, and myelodysplastic syndromes, requires a robust method to delineate erythropoietic intermediates. In order to apply the power of flow cytometry to these studies, challenges of limited immunophenotypic markers, incorporation of significant changes in morphology, and maturational changes that occur along a continuum need to be met. Imaging flow cytometry (IFC) provides a solution to address these challenges. Integration of changes in immunophenotype, loss of RNA (ribosomes), and enucleation, with morphological characteristics of cell and nuclear size, can be used to delineate erythroblasts that correlate with classical histological classifications. A protocol is described that demonstrates the basic approaches of staining panel selection, mask generation and selection of features to best sequentially refine erythroid intermediates and remove contaminating cells with overlapping immunophenotype. Ultimately erythroid cells in the murine bone marrow are divided into seven sub-populations using IFC including four erythroblasts (pro-, basophilic, polychromatophilic and orthochromatic), the pyrenocyte, which contains the eliminated nucleus, the enucleated reticulocyte and the mature RBC.