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Endothelial Cell-Selective Adhesion Molecule Marks Human Hematopoietic Stem Cells Regardless Of The HSC Sources

Ishibashi, Tomohiko ; Yokota, Takafumi ; Ichii, Michiko ; [et al.]

American Society of Hematology ; 2013

In: Blood Vol. 122, No. 21 ( 2013-11-15), p. 2429-2429

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In: Blood, American Society of Hematology, Vol. 122, No. 21 ( 2013-11-15), p. 2429-2429

Abstract: Identification of novel markers associated with hematopoietic stem cells (HSCs) is important to progress basic and clinical research regarding the HSC biology. We previously reported that endothelial cell-selective adhesion molecule (ESAM) marks HSCs throughout life in mice (Yokota et al. Blood, 2009). We also demonstrated that ESAM can be a useful indicator of activated HSCs after bone marrow (BM) injury and that ESAM is functionally important for recovering hematopoiesis by using ESAM knockout mice (Sudo et al. J Immunol, 2012). However, the discrepancy between species has been a long-standing obstacle to apply findings in mice to human. For example, established murine HSC markers such as Sca-1 or CD150 are not expressed on human HSCs. Thus, it is important to know if ESAM marks HSCs beyond species and serves as a functional molecule for the HSC property, but information regarding ESAM expression in human HSCs has been quite limited. In this study, we have examined the ESAM expression pattern on human HSCs derived from diverse sources. In addition, we have performed functional assessment of the ESAM-expressing cells. Cord blood (CB), aspirated BM, and granulocyte-colony stimulating factor-mobilized peripheral blood (GMPB) were obtained from healthy donors. BM was also obtained from head of femora of patients who received the hip replacement surgery. All of the protocols were approved by the Institutional Review Board of Osaka University School of Medicine, and we obtained the written agreement form with informed consent from all participants. Mononuclear cells were separated using Ficoll centrifugation from CB, aspirated BM and GMPB. For preparation of BM cells adjacent to bone tissues, trabecular tissues of femora were treated with 2 mg/ml collagenase IV and DNase and gently agitated for 1 hour at 37 °C. Collected cells were analyzed using flow cytometry for cell surface expression of ESAM and other markers. Further, the CD34+ CD38−cells were fractionated according to the intensity of ESAM expression and evaluated in vivo and in vitro functional assays. Flow cytometry analyses revealed that the majority of CB CD34+ CD38− cells expressed ESAM. According to the expression level, CB CD34+ CD38− cells could be subdivided into three populations, namely ESAM−/Low, ESAMHigh, and ESAMBright. While all CB contained a robust ESAMHigh population in CD34+ CD38− cells, the percentage of ESAMBright cells varied widely among CB samples. The ESAMHigh CD34+ CD38− cells also expressed CD90 and CD133, which are known as HSC markers. Methylcellulose colony-forming assays and limiting dilution assays revealed that ESAMHigh fraction enriches primitive hematopoietic progenitors. Further, ESAMHigh cells also reconstituted the long-term human hematopoiesis in NOD/Shi-scid, IL-2Rγnull (NOG) mice. Therefore, as in mice, ESAMHighmarks authentic HSCs in human. On the other hand, ESAMBright CD34+ CD38− cells showed low colony-forming activities and no reconstitution of human hematopoiesis in NOG mice. These ESAMBright CD34+ CD38− cells expressed CD118/leukemia inhibitor factor receptor and endothelial markers such as VE-Cadherin, Flk-1, and CD146, but not CD45. These results suggested that ESAMBright cells in the CB CD34+ CD38− fraction are non-hematopoietic cells. With respect to the other HSC sources such as aspirated BM and GMPB, almost all CD34+ CD38− cells were ESAMHigh and ESAMBright cells were not found in this fraction. Interestingly, however, ESAMBright cells were found in the CD34+ CD38− fraction isolated from collagenase-treated femora. These BM-derived ESAMBright CD34+ CD38− cells expressed endothelial markers as did the CB-derived cells. They could generate CD31+endothelial cells, but not hematopoietic cells in coculture with MS5 stromal cells with vascular endothelial growth factor, stromal-cell-derived factor, and interleukin 16. In conclusion, ESAM expression serves as a marker to enrich HSCs in human regardless of the HSC sources. In addition, the very high intensity of this marker might be useful to isolate non-hematopoietic progenitors from CD34+ CD38− cells, which has been conventionally used as human HSCs. The common feature of ESAM expression of murine and human HSCs suggests a possibility that functional significance of ESAM expression obtained from mouse studies could be applicable to human. Disclosures: No relevant conflicts of interest to declare.

Type of Medium: Online Resource

ISSN: 0006-4971 , 1528-0020

URL: Article

DOI: 10.1182/blood.V122.21.2429.2429

RVK:

XA 33000

RVK:

XA 10000

Language: English

Publisher: American Society of Hematology

Publication Date: 2013

detail.hit.zdb_id: 1468538-3

detail.hit.zdb_id: 80069-7

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MS4A3 Marks Early Myeloid Differentiation in Human Hematopoiesis

Ishibashi, Tomohiko ; Yokota, Takafumi ; Satoh, Yusuke ; [et al.]

American Society of Hematology ; 2014

In: Blood Vol. 124, No. 21 ( 2014-12-06), p. 4319-4319

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In: Blood, American Society of Hematology, Vol. 124, No. 21 ( 2014-12-06), p. 4319-4319

Abstract: Understanding lineage specific markers contributes to investigation into lineage commitment processes in hematopoiesis. Particularly in the human study, information about hematopoietic lineage divergence is essential to refine hematopoietic lineage tree. Lineage markers are also potentially useful for therapeutic target, such as CD20 in B-cell lymphoma, and CD33 in acute myeloid leukemia. We have recently reported that special AT-rich sequence-binding protein 1 (SATB1), a global chromatin organizer, promotes lymphocyte production from hematopoietic stem cells (HSCs) (Immunity 38;1105, 2013). Expression level of SATB1 increases with early lymphoid differentiation, whereas it is shut off in committed myeloid progenitors. To search a novel cell surface molecule that marks the point of branching lineage along early myeloid and lymphoid differentiation, we performed microarray analyses comparing SATB1-overexpressed HSCs with mock-transduced HSCs. The results drew our attention to membrane-spanning 4-domains, subfamily A, member 3 (MS4A3). MS4A3, also called hematopoietic cell-specific transmembrane 4 (HTm4), is a member of the MS4A family. CD20, encoded by MS4A1 gene, belongs to the same family. We observed that expression level of MS4A3 in SATB1-overexpressed HSCs was decreased almost one tenth of that of mock HSCs. To confirm the relationship of SATB1 and MS4A3 in human hematopoietic cells, we first used chronic myeloid leukemia cell line K562, which was found to clearly express MS4A3 on their cell surface. While SATB1 expression was undetectable in original K562 cells, the exogenous expression of SATB1 significantly reduced their MS4A3 expression level, suggesting that SATB1 negatively regulates MS4A3 expression in human cells. Next, we analyzed MS4A3 expression pattern in primary human hematopoietic stem/progenitor cells. Bone marrow (BM) cells were obtained from healthy donors or patients with acute myeloid leukemia. The Institutional Review Board of Osaka University School of Medicine approved all of protocols, and written informed consents were obtained from all participants. Mononuclear cells were separated from the BM samples by density gradient centrifugation, and subsequently applied to cell sorting for Lineage marker-negative (Lin-) CD34+ CD38- HSCs, Lin- CD34+ CD38+ IL-3 receptor α (IL-3Rα)+ CD45RA- common myeloid progenitors (CMPs), Lin- CD34+ CD38+ IL3-Rα+ CD45RA+ granulocyte-macrophage progenitors (GMPs) and Lin- CD34+ CD38+ IL-3Rα- CD45RA-megakaryocyte-erythroid progenitors (MEPs). MS4A3 expression levels of the sorted cells were analyzed with real-time RT-PCR. We detected more than 10-fold amount of MS4A3 transcripts in CMPs than HSCs. Furthermore, its expression level continuously increased along myeloid lineage differentiation to GMP. On the other hand, megakaryocyte-erythroid lineage differentiation was not accompanied by MS4A3 expression and the amount of MS4A3 transcripts in MEPs was minimum as in HSCs. Flow cytometry analyses confirmed that HSCs and MEPs do not express MS4A3 on their cell surface whereas the MS4A3 expression on CMPs and GMPs is detectable. Further, the Lin- CD34+ CD38+ CD33+ cells could be fractionated according to the intensity of cell surface MS4A3 expression. To investigate the significance of cell surface MS4A3 expression for functional analyses of myeloid progenitor cells, we performed methylcellulose colony-forming assays. We found that MS4A3+ cells in Lin- CD34+ CD38+ CD33+ fraction only produced granulocyte/macrophage colonies, losing erythroid colony- and mixed colony-forming capacity. These results suggest that cell surface expression of MS4A3 is useful to distinguish granulocyte/macrophage lineage-committed progenitors from other lineage-related ones in early human hematopoiesis. We also analyzed MS4A3 expression in BM cells obtained from patients with acute leukemia. Flow cytometry analyses revealed that leukemia cells of some patients expressed substantial amount of cell surface MS4A3. In conclusion, MS4A3 is useful to monitor early stage of myeloid differentiation in human hematopoiesis. In addition, our findings of MS4A3 expression on myeloid leukemia cells, while no expression on normal HSCs, imply that MS4A3 might be a therapeutic target molecule in myelogenous leukemia. Further studies would clarify the application of MS4A3 to anti-leukemia therapy. Disclosures No relevant conflicts of interest to declare.

Type of Medium: Online Resource

ISSN: 0006-4971 , 1528-0020

URL: Article

DOI: 10.1182/blood.V124.21.4319.4319

RVK:

XA 33000

RVK:

XA 10000

Language: English

Publisher: American Society of Hematology

Publication Date: 2014

detail.hit.zdb_id: 1468538-3

detail.hit.zdb_id: 80069-7

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An Anti-Apoptotic Molecule, Anamorsin, Is Essential for Erythropoiesis Through the Regulation of Cellular Labile Iron Pool

Tanimura, Akira ; Hamanaka, Yuri ; Fujita, Natsuko ; [et al.]

American Society of Hematology ; 2012

In: Blood Vol. 120, No. 21 ( 2012-11-16), p. 610-610

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In: Blood, American Society of Hematology, Vol. 120, No. 21 ( 2012-11-16), p. 610-610

Abstract: Abstract 610 Introduction: Iron has crucial roles in many cellular biological processes. Cellular iron uptake and export must be tightly regulated. Insufficient iron concentrations impair the function of numerous iron proteins, whereas excess free iron can oxidize and damage the contents of cells. Anamorsin (AM, also called CIAPIN-1) is an anti-apoptotic factor, which we originally isolated as a molecule that confers factor-independent survival of hematopoietic cells. AM-deficient mice are embryonic lethal at late gestation due to the defect of definitive hematopoiesis. It is thought that AM plays a crucial role in hematopoiesis, however its precise biological mechanisms remain unclear. Recently, it was reported that the yeast AM homolog, Dre2, was implicated in cytosolic iron-sulfur (Fe/S) cluster assembly (Zhang Y., et al. Mol.Cell.Biol. 28:5569–5582, 2008). The AM carries conserved cysteine motifs (CX2CXC and twin CX2C) at its C termini, which may form iron binding sites. In this study, we have focused on the possibility that AM may be involved in the maturation of Fe/S cluster and the cellular iron homeostasis, especially, the regulation of labile iron pool (LIP) and that AM may affect the accumulation of reactive oxygen species (ROS), leading to impaired erythropoiesis. Methods and Results: To analyze the function of Fe/S protein, we established wild-type cell lines (AMWT) and AM-deficient cell lines (AMKO) from wild-type and AM-deficient fetal liver (14.5dpc) respectively by using SV40 large T antigen. Iron regulatory protein 1 (IRP1) is a well-known Fe/S protein with dual functions. In the presence of Fe/S cluster, IRP1 functions as a cytosolic aconitase. While, in the absence of Fe/S cluster, IRP1 stabilizes the transferrin receptor (TfR) mRNA by binding to the iron responsive element (IRE). We compared the aconitase activity and the IRE binding activity of IRP1 between AMWT and AMKO. The results showed that the cytosolic aconitase activity in AMKO decreased approximately 30% compared to AMWT and the IRE binding activity of IRP1 in AMKO increased 3-fold compared to AMWT. Furthermore, we compared the iron homeostasis. In the presence of iron chelator, desferrioxamine, the expression of TfR in AMWT was markedly elevated, while it was hardly elevated in AMKO. The LIP is a pool of chelatable and redox-active iron, which serves as a crossroad of cell iron metabolism. The measurement of LIP with the metal-sensitive sensor calcein acetoxymethyl ester showed that AMKO had 5-fold higher cellular LIP than AMWT. Moreover we evaluated the accumulation of ROS and the induction of apoptosis by extracellular iron uptake between AMWT and AMKO. The results showed the accumulation of ROS and the induction of apoptosis in AMKO were enhanced about twice as much as in AMWT. These enhancements could be restored by transduction of AM expressing retrovirus vector to AMKO. We also evaluated the effects of AM-deficiency on erythroid differentiation. Fetal liver cells from wild-type or AM-deficient embryos (14.5dpc) were divided into primitive and more matured erythroid populations based on their expression of CD71 and Ter119 by FACS analysis. AM-deficient fetal liver cells had a significant increase in the CD71low TER119low population, containing primitive erythroid progenitors, compared to wild-type (9.4±2.1% vs. 5.2±1.1%, P 〈 0.05). Conversely, the CD71lowTER119highpopulation, comprised of late orthochromatophilic erythroblasts and reticulocytes, decreased in AM-deficient fetal liver cells compared to wild-type cells (2.3±0.8% vs. 7.4±1.3%, P 〈 0.05). Moreover we studied LIP in wild-type or AM-deficient embryo fetal liver cells. In accordance with the cell lines, the LIP in AM-deficient fetal liver cells increased 3 to 5-fold more than in wild-type fetal liver cells. The accumulation of ROS and the number of apoptotic cells also increased 2 to 5-fold in AM- deficient fetal liver cells compared to wild-type fetal liver cells. Thus, it was showed that AM deficiency impaired the iron homeostasis and conferred low sensitivity for iron concentration, resulting in the increase of LIP, the accumulation of ROS and the induction of apoptosis. Furthermore, dysregulation of cellular iron homeostasis was thought to be the cause of the embryonic lethal due to AM deficiency. Conclusion: Our current findings indicate that AM functions in cytosolic Fe/S cluster biogenesis and iron homeostasis and is essential for erythropoiesis. Disclosures: Kanakura: Shire: Consultancy.

Type of Medium: Online Resource

ISSN: 0006-4971 , 1528-0020

URL: Article

DOI: 10.1182/blood.V120.21.610.610

RVK:

XA 33000

RVK:

XA 10000

Language: English

Publisher: American Society of Hematology

Publication Date: 2012

detail.hit.zdb_id: 1468538-3

detail.hit.zdb_id: 80069-7

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