The hematopoietic stem-cell niche in health and leukemia

被引:72
作者
Sanchez-Aguilera, Abel [1 ]
Mendez-Ferrer, Simon [1 ,2 ,3 ,4 ]
机构
[1] CNIC, Stem Cell Niche Pathophysiol Grp, Melchor Fernandez Almagro 3, Madrid 28029, Spain
[2] Univ Cambridge, Wellcome Trust Med Res Council Cambridge Stem Cel, Cambridge Biomed Campus, Cambridge CB2 0PT, England
[3] Univ Cambridge, Dept Haematol, Cambridge Biomed Campus, Cambridge CB2 0PT, England
[4] Natl Hlth Serv Blood & Transplant, Cambridge Biomed Campus, Cambridge CB2 0PT, England
来源
CELLULAR AND MOLECULAR LIFE SCIENCES | 2017年 / 74卷 / 04期
基金
英国惠康基金;
关键词
Hematopoietic stem cell; Stem cell niche; Bone marrow microenvironment; Leukemia; Leukemia stem cell; BONE-MARROW NICHE; CHRONIC MYELOGENOUS LEUKEMIA; MESENCHYMAL STROMAL CELLS; ACUTE MYELOID-LEUKEMIA; IN-VIVO; PROGENITOR CELLS; ENDOTHELIAL NICHES; SELF-RENEWAL; MOUSE MODEL; MICROENVIRONMENT;
D O I
10.1007/s00018-016-2306-y
中图分类号
Q5 [生物化学]; Q7 [分子生物学];
学科分类号
071010 ; 081704 ;
摘要
Research in the last decade has shown that hematopoietic stem cells (HSCs) interact with and are modulated by a complex multicellular microenvironment in the bone marrow, which includes both the HSC progeny and multiple non-hematopoietic cell types. Intense work is gradually throwing light on the composition of the HSC niche and the molecular cues exchanged between its components, which has implications for HSC production, maintenance and expansion. In addition, it has become apparent that bidirectional interactions between leukemic cells and their niche play a previously unrecognized role in the initiation and development of hematological malignancies. Consequently, targeting of the malignant niche holds considerable promise for more specific antileukemic therapies. Here we summarize the latest insights into HSC niche biology and recent work showing multiple connections between hematological malignancy and alterations in the bone marrow microenvironment.
引用
收藏
页码:579 / 590
页数:12
相关论文
共 83 条
  • [31] Tracking single hematopoietic stem cells in vivo using high-throughput sequencing in conjunction with viral genetic barcoding
    Lu, Rong
    Neff, Norma F.
    Quake, Stephen R.
    Weissman, Irving L.
    [J]. NATURE BIOTECHNOLOGY, 2011, 29 (10) : 928 - U229
  • [32] Monocytes-macrophages that express α-smooth muscle actin preserve primitive hematopoietic cells in the bone marrow
    Ludin, Aya
    Itkin, Tomer
    Gur-Cohen, Shiri
    Mildner, Alexander
    Shezen, Elias
    Golan, Karin
    Kollet, Orit
    Kalinkovich, Alexander
    Porat, Ziv
    D'Uva, Gabriele
    Schajnovitz, Amir
    Voronov, Elena
    Brenner, David A.
    Apte, Ron N.
    Jung, Steffen
    Lapidot, Tsvee
    [J]. NATURE IMMUNOLOGY, 2012, 13 (11) : 1072 - 1082
  • [33] A robust and high-throughput Cre reporting and characterization system for the whole mouse brain
    Madisen, Linda
    Zwingman, Theresa A.
    Sunkin, Susan M.
    Oh, Seung Wook
    Zariwala, Hatim A.
    Gu, Hong
    Ng, Lydia L.
    Palmiter, Richard D.
    Hawrylycz, Michael J.
    Jones, Allan R.
    Lein, Ed S.
    Zeng, Hongkui
    [J]. NATURE NEUROSCIENCE, 2010, 13 (01) : 133 - U311
  • [34] Osteoblast Precursors, but Not Mature Osteoblasts, Move into Developing and Fractured Bones along with Invading Blood Vessels
    Maes, Christa
    Kobayashi, Tatsuya
    Selig, Martin K.
    Torrekens, Sophie
    Roth, Sanford I.
    Mackem, Susan
    Carmeliet, Geert
    Kronenberg, Henry M.
    [J]. DEVELOPMENTAL CELL, 2010, 19 (02) : 329 - 344
  • [35] Increased skeletal VEGF enhances β-catenin activity and results in excessively ossified bones
    Maes, Christa
    Goossens, Steven
    Bartunkova, Sonia
    Drogat, Benjamin
    Coenegrachts, Lieve
    Stockmans, Ingrid
    Moermans, Karen
    Nyabi, Omar
    Haigh, Katharina
    Naessens, Michael
    Haenebalcke, Lieven
    Tuckermann, Jan P.
    Tjwa, Marc
    Carmeliet, Peter
    Mandic, Vice
    David, Jean-Pierre
    Behrens, Axel
    Nagy, Andras
    Carmeliet, Geert
    Haigh, Jody J.
    [J]. EMBO JOURNAL, 2010, 29 (02) : 424 - 441
  • [36] Osteoclasts promote the formation of hematopoietic stem cell niches in the bone marrow
    Mansour, Anna
    Abou-Ezzi, Grazia
    Sitnicka, Ewa
    Jacobsen, Sten Eirik W.
    Wakkach, Abdelilah
    Blin-Wakkach, Claudine
    [J]. JOURNAL OF EXPERIMENTAL MEDICINE, 2012, 209 (03) : 537 - 549
  • [37] Unexpectedly efficient homing capacity of purified murine hematopoietic stem cells
    Matsuzaki, Y
    Kinjo, K
    Mulligan, RC
    Okano, H
    [J]. IMMUNITY, 2004, 20 (01) : 87 - 93
  • [38] Individual stem cells with highly variable proliferation and self-renewal properties comprise the human hematopoietic stem cell compartment
    McKenzie, Joby L.
    Gan, Olga I.
    Doedens, Monica
    Wang, Jean C. Y.
    Dick, John E.
    [J]. NATURE IMMUNOLOGY, 2006, 7 (11) : 1225 - 1233
  • [39] Myelodysplastic Cells in Patients Reprogram Mesenchymal Stromal Cells to Establish a Transplantable Stem Cell Niche Disease Unit
    Medyouf, Hind
    Mossner, Maximilian
    Jann, Johann-Christoph
    Nolte, Florian
    Raffel, Simon
    Herrmann, Carl
    Lier, Amelie
    Eisen, Christian
    Nowak, Verena
    Zens, Bettina
    Muedder, Katja
    Klein, Corinna
    Oblaender, Julia
    Fey, Stephanie
    Vogler, Jovita
    Fabarius, Alice
    Riedl, Eva
    Roehl, Henning
    Kohlmann, Alexander
    Staller, Marita
    Haferlach, Claudia
    Mueller, Nadine
    John, Thilo
    Platzbecker, Uwe
    Metzgeroth, Georgia
    Hofmann, Wolf-Karsten
    Trumpp, Andreas
    Nowak, Daniel
    [J]. CELL STEM CELL, 2014, 14 (06) : 824 - 837
  • [40] Haematopoietic stem cell release is regulated by circadian oscillations
    Mendez-Ferrer, Simon
    Lucas, Daniel
    Battista, Michela
    Frenette, Paul S.
    [J]. NATURE, 2008, 452 (7186) : 442 - U4
123456789