The erythroblastic island niche: modeling in health, stress, and disease

May, Alisha; Forrester, Lesley M.

doi:10.1016/j.exphem.2020.09.185

Cited by 35 publications

(38 citation statements)

References 119 publications

(106 reference statements)

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“…These islands are present at various stages of differentiation in the fetal liver and the adult bone marrow and have a key role in erythroid cell proliferation and differentiation. Erythroblastic islands are increased in patients during periods of stress erythropoiesis 1–3 . We agree that the increase of such Erythroblastic Islands in this patient, probably, was due to erythropoietic enlarged post chemotherapy.…”

Section: Imagesupporting

confidence: 59%

“…EBIs are situated predominantly in the bone marrow during steady‐state erythropoiesis. EBI consists of one central macrophage (nurse cell) that extends cytoplasmic protrusions to a ring of surrounding erythroblasts 1,2 . It has been proposed that early in erythroid maturation the macrophages provide required recycled iron from ferritin stocks to the erythroid cells, which is needed for hemoglobin production 3 .…”

Section: Imagementioning

confidence: 99%

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Erythroblastic Islands

Vicari

Queiroz

2021

American J Hematol

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Section: Imagesupporting

confidence: 59%

Section: Imagementioning

confidence: 99%

Erythroblastic Islands

Vicari

Queiroz

2021

American J Hematol

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“…In addition, a role for EKLF in proper programming of macrophage for island function is suggested by gain-of-function studies in macrophage derived from human iPS cells ( Lopez-Yrigoyen et al, 2019 ). There remains a need to increase the expansion capability of erythroid cells in culture for their clinical use ( Migliaccio et al, 2012 ; Heshusius et al, 2019 ; Olivier et al, 2019 ; Deleschaux et al, 2020 ; Pellegrin et al, 2021 ), and identification of the relevant macrophage subtype can inform approaches to overcome heterogeneity and utilize the optimal cells to aid efficient in vitro erythropoiesis ( Rhodes et al, 2008 ; Hom et al, 2015 ; May and Forrester, 2020 ). Indeed, human island macrophage function can be recapitulated in culture by inclusion of lipids and by glucocorticoid receptor activation ( Falchi et al, 2015 ; Heideveld et al, 2018 ).…”

Section: Summary and Outstanding Questionsmentioning

confidence: 99%

“…However, EBI alterations or defects during steady-state erythropoiesis may not necessarily be manifest as severe phenotypes because adequate coping mechanisms to recover and repair EBIs are only required during stress. This is supported by the fact that EBI macrophages are critical for recovery from stress erythropoiesis in the splenic red pulp ( Sadahira et al, 2000 ; Chow et al, 2013 ; Ramos et al, 2013 ; Jacobsen et al, 2015 ; Liao et al, 2018 ; May and Forrester, 2020 ). Recovery is effectively aided by de novo differentiation of monocytes into macrophages ( Ulyanova et al, 2016 ; Liao et al, 2018 ) and via epo-induced signaling in island macrophage that yields prostaglandin mediators of stress erythroid progenitors ( Chen et al, 2020 ).…”

Section: Introductionmentioning

confidence: 98%

Transcriptional Control of Gene Expression and the Heterogeneous Cellular Identity of Erythroblastic Island Macrophages

Mukherjee

Bieker

2021

Front. Genet.

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During definitive erythropoiesis, maturation of erythroid progenitors into enucleated reticulocytes requires the erythroblastic island (EBI) niche comprising a central macrophage attached to differentiating erythroid progenitors. Normally, the macrophage provides a nurturing environment for maturation of erythroid cells. Its critical physiologic importance entails aiding in recovery from anemic insults, such as systemic stress or acquired disease. Considerable interest in characterizing the central macrophage of the island niche led to the identification of putative cell surface markers enriched in island macrophages, enabling isolation and characterization. Recent studies focus on bulk and single cell transcriptomics of the island macrophage during adult steady-state erythropoiesis and embryonic erythropoiesis. They reveal that the island macrophage is a distinct cell type but with widespread cellular heterogeneity, likely suggesting distinct developmental origins and biological function. These studies have also uncovered transcriptional programs that drive gene expression in the island macrophage. Strikingly, the master erythroid regulator EKLF/Klf1 seems to also play a major role in specifying gene expression in island macrophages, including a putative EKLF/Klf1-dependent transcription circuit. Our present review and analysis of mouse single cell genetic patterns suggest novel expression characteristics that will enable a clear enrichment of EBI subtypes and resolution of island macrophage heterogeneity. Specifically, the discovery of markers such as Epor, and specific features for EKLF/Klf1-expressing island macrophages such as Sptb and Add2, or for SpiC-expressing island macrophage such as Timd4, or for Maf/Nr1h3-expressing island macrophage such as Vcam1, opens exciting possibilities for further characterization of these unique macrophage cell types in the context of their critical developmental function.

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“…This suggested the existence of discrete niches for multipotent and lineage-committed progenitors. The existence of a distinct niche for erythropoiesis comes from classical electron microscopy studies that showed that rare macrophages, adjacent to sinusoids, provide a niche for islands of erythroblast maturation ( 30 ), and these have been the focus of many studies in the field ( 31 ). More recently, Comazzetto et al., demonstrated imaging of unipotent erythroid progenitors and showed that they selectively localize next to perivascular stromal cells that maintain them via SCF production ( 32 ).…”

Section: The Anatomy Of Hematopoiesis Is Spatially Organized By Local Microenvironmentsmentioning

confidence: 99%

Anatomy of Hematopoiesis and Local Microenvironments in the Bone Marrow. Where to?

Zhang

Lucas

2021

Front. Immunol.

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The shape and spatial organization -the anatomy- of a tissue profoundly influences its function. Knowledge of the anatomical relationships between parent and daughter cells is necessary to understand differentiation and how the crosstalk between the different cells in the tissue leads to physiological maintenance and pathological perturbations. Blood cell production takes place in the bone marrow through the progressive differentiation of stem cells and progenitors. These are maintained and regulated by a heterogeneous microenvironment composed of stromal and hematopoietic cells. While hematopoiesis has been studied in extraordinary detail through functional and multiomics approaches, much less is known about the spatial organization of blood production and how local cues from the microenvironment influence this anatomy. Here, we discuss some of the studies that revealed a complex anatomy of hematopoiesis where discrete local microenvironments spatially organize and regulate specific subsets of hematopoietic stem cells and/or progenitors. We focus on the open questions in the field and discuss how new tools and technological advances are poised to transform our understanding of the anatomy of hematopoiesis.

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The erythroblastic island niche: modeling in health, stress, and disease

Cited by 35 publications

References 119 publications

Erythroblastic Islands

Erythroblastic Islands

Transcriptional Control of Gene Expression and the Heterogeneous Cellular Identity of Erythroblastic Island Macrophages

Anatomy of Hematopoiesis and Local Microenvironments in the Bone Marrow. Where to?

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