Cells in multicellular organisms do not live in a vacuum. Coordinated responses of individual cells to challenges at the level of the organism are instructed by integrated prompts from their environment. This environmental signaling determines the cells’ properties and behavior to a considerable degree. Tissue stem cells, in particular, are dependent on environmental signaling to rapidly process indicators of stress to exert their regenerative functions while restricting their proliferative potential during homeostasis. Studies in both invertebrate and vertebrate systems indicate that this is achieved in a specialized, anatomically defined, regulatory environment referred to as the ‘stem cell niche’. The capacity of the niche to shape a cell’s behavior has been powerfully illustrated in Drosophila, in which the niche can impose stem-cell like properties upon other cell types.1
In the hematopoietic system, the endosteal surface has been recognized as such an anatomically defined regulatory environment for tissue stem cells. Although sometimes referred to as the ‘osteoblastic niche’, the endosteal surface comprises a broader range of components. These include osteolineage cells at various developmental stages, vascular endothelium, osteoclasts, neurogenic cells, ‘stromal’ bone lining cells, CXCL12-expressing reticular cells and extracellular matrix proteins. Some of these components, including osteolineage cells, have been established in genetic models to have a regulatory role in determining hematopoietic stem cell (HSC) behavior, but it is likely that the orchestrated (direct and indirect) action of most cellular components as a ‘functional unit’ is required for all aspects of stem cell control under conditions of both homeostasis and stress.2
HSC are not statically positioned within their niches but are known to migrate and are found at distinct locations throughout the bone marrow, blood and peripheral tissues. While the physiological significance of their migratory behavior has remained relatively obscure in post-natal hematopoiesis, this capacity is exploited in stem cell mobilization to harvest these cells for regenerative purposes. Granulocyte colony-stimulating factor (G-CSF)-mediated mobilization has thus been used as a powerful means to obtain mechanistic insights into the process of HSC trafficking. Trafficking occurs through an intricate process of de-adhesion, chemoattraction and lodging into a new location.3 In diverse stem cells systems, including the hematopoietic system, the CXCL12-CXCR4 axis has emerged as a major determinant of these processes. Deficiency of the ligand or receptor results in embryonic death and impaired colonization of bone marrow by hematopoietic progenitors, including HSC, during ontogeny while conditional ablation of CXCR4 in hematopoietic cells results in loss of HSC from the marrow environment. CXCL12 gradients are established through the coordinated interaction of several degrading enzymes that can cleave the cytokine, its receptor or both.
In this issue of Haematologica, Staudt et al. provide additional insights into this process.4 Through a series of elaborate and detailed biochemical analyses, the cysteine protease cathepsin X was indicated to be a novel molecular player in HSC migration and trafficking. The authors demonstrated that cathepsin X is expressed by and secreted from human stromal cell lines and primary ‘osteoblastic’ cells (defined as bone-derived colony-forming units-fibroblast (CFU-F) differentiated towards the osteoblastic lineage). The protease was detected on the cell surface of primary osteoblasts, predominantly in the immature form, but also in the mature form. The secreted protein retrieved from supernatants was proteolytically active, as demonstrated by the cleavage of fluorescent substrates. Exogenous mature cathepsin X and shRNA-mediated knock-down of the gene disrupted pre-existing adhesion of CD34 cord blood cells to primary osteoblastic cells in vitro which suggests a role of cathepsin X in proteolytic attenuation of adhesive interactions between HSC and the osteoblasts, although the proteolytic substrate remains to be identified. Furthermore, cathepsin X was capable of degrading both isoforms of CXCL12 (SDF1αand β) which impaired the chemotactic properties of SDF1α on CD34 cells.
While elucidation of the relevance of cathepsin X in HSC mobilization and trafficking will have to await (targeted) knockdown of the protein in genetic in vivo models, a working hypothesis of its functional role can be formulated on the basis of the authors’ findings (Figure 1). In this model, cathepsin X promotes HSC trafficking from the endosteal niche through the degradation of CXCL12 and proteolytic interference with, yet to be specifically defined, HSC-osteoblastic interactions. It has previously been shown that other enzymes, including other cathepsins (K and G)5 and matrix-metalloproteinase-9 (MMP9),6 have similar capacity to cleave CXCL12 and receptor-ligand interactions. Cathepsin X thus represents the latest addition to a rapidly expanding dynamic network of chemoattractant-degrading proteases involved in HSC localization and trafficking towards, away and perhaps along the endosteal surface.
The significance of elucidating molecular determinants in this network is of obvious relevance to stem cell transplantation biology. The niche is increasingly recognized as a potential target to facilitate donor cell mobilization and engraftment after transplantation. Pharmacological manipulation of the niche size has been proven successful in pre-clinical models of stem cell mobilization,7 and promoting migration of HSC from their niches through pharmacological stimulation of degrading proteases may be beneficial. In retrospect, the clinical success of G-CSF as a mobilizing agent relies, partly, on creating a proteolytic microenvironment facilitating de-adhesion and migration of HSC.8 While exploiting our expanding knowledge in optimizing cell replacement strategies is of obvious importance, key questions remain.
Why do hematopoietic stem cells migrate during post-natal hematopoiesis?
The answer to this question remains largely speculative to date, but recent findings have begun to create a conceptional framework in which HSC migration may have its place in stress response and immunosurveillance. Emerging evidence suggests that HSC trafficking between distinct niches in the bone marrow may be required for switching between homeostatic hematopoiesis and conditions of increased demand during hematopoietic stress.9 HSC can reversibly acquire several states, including a dormant state (in which the cells are maintained long-term in the G0 stage of the cell cycle), a homeostatic state (in which the cells are occasionally cycling) and an injury-activated state (in which the cells are continuously cycling). HSC switch from dormancy to self-renewal under conditions of hematopoietic stress, such as bleeding and G-CSF mobilization. Similarly, activation of HSC cycling during chronic infection has recently been demonstrated.10
Figure 1.A speculative working model of the role of cathepsin X in hematopoietic stem/progenitor cell trafficking in the endosteal niche based on in vitro observations by Staudt et al. Cathepsin X is active in a network of degrading proteases promoting trafficking of HSC from the endosteal niche through cleavage of CXCL12 and ligand-receptor interactions at the endosteal surface. The nature of the adhesive interaction remains to be identified. Whether direct cell-cell contact is required for niche-induced signaling, as well established in invertebrates, remains controversial in the mammalian hematopoietic system.
Given that several heterologous cell types can contribute to the HSC microenvironment and that functional heterogeneity may be present within each of them, it seems reasonable to propose that these distinct HSC states are associated with specific extrinsic signals that emanate from diverse and unique microenvironmental niches,11 although this awaits experimental confirmation. HSC might migrate upon (neuro-adrenergic) stress signaling from a niche at the endosteal surface guarding its quiescence and longevity towards niches receptive or supportive of increased proliferation (Figure 1). The observation that mobilization strategies promote both HSC cycling and exit to the bloodstream supports the mechanistic link between cell cycle progression and interaction with the niche.
In addition to migration between bone marrow niches, it has long been recognized that HSC periodically enter the peripheral blood, where they are constitutively present.12 Recent studies have further defined the circuit of hematopoietic stem/progenitor cell recirculation through peripheral tissues where they may provide a recruitable source of immune and inflammatory effector cells.13 The observations point towards hematopoietic stem/progenitor cells having an immunosurveillance role, a view that may be supported by the observation that exit of HSC into the blood is governed by a circadian rhythm under adrenergic control and involving down-regulation of cxcl12.14 Finally, it has been proposed that circulating HSC are required to occupy newly generated niches during (circadian) bone remodeling, both precluding the occupation of niches by non-stem cell types and providing a ‘fitness’ test for the recirculating stem cells.15 Although a definitive answer to the question of why HSC migrate will have to await information from in vivo models in which this trafficking is blocked, the emerging data support a view in which HSC trafficking endows the organism with a adaptable system allowing it to meet the demands of supporting durable hematopoiesis and to be nimble enough to meet increased demand under conditions of hematopoietic stress. Deregulation of this process would be anticipated to result in mitigated responses to various hematopoietic challenges which may be reflected in the delayed hematopoietic recovery of MMP9 mice following 5-fluoruracil treatment.6 Evolution, however, has likely provided the system with ample functional redundancy, as further documented by the work of Staudt et al. in this issue.
Can defective hematopoietic stem cell trafficking and localization play a role in hematopoietic disease?
As indicated, stem cell trafficking is a continuous, reversible process which involves de-adhesion and chemoattraction (where cathepsin X likely exerts its actions), but also re-attachment to the niche. Trafficking implies the eventual return of HSC to their (dormant) niches and there is evidence from murine models that failure of this to occur may result in hematopoietic abnormalities during homeostasis. Mice with a deficiency of functional receptors for key ligands determining lodgment at the endosteal surface (such as cxcl12,16 calcium,17 and stem cell factor18) display aberrant HSC localization away from the endosteal surface, which is associated with increased cycling and progressive loss due to replicative exhaustion and results in hypocellularity of the bone marrow. It has been hypothesized that interference with niche-induced quiescence, either by altered niche signaling or detachment from the niche, may result in increased cycling of cells that have the inherent machinery of self-renewal, thus poising these cells ready for the acquisition of somatic mutations and malignant transformation. Recently experimental evidence introduced the concept of niche-induced oncogenesis in the hematopoietic system, showing that specific genetic abnormalities in osteoprogenitor cells can induce myelodysplasia and acute myeloid leukemia in mice.19 Whether leukemic transformation in this system was associated with impaired trafficking or aberrant localization of HSC in their niche remains to be determined. It is noteworthy, however, that aberrant localization of hematopoietic stem/progenitor cells in human disease is not unprecedented, as atypical localization of immature progenitors is a common finding in myelodysplastic syndromes.20 Indeed, recent findings in mouse models warrant reconsideration of a possible involvement of the dynamic interaction between HSC and their niche in the pathogenesis of certain hematopoietic diseases, including bone marrow failure syndromes and myelodysplastic syndromes. Studies such as the one published by Staudt et al. in this issue of the Journal, identifying determinants of this interaction, will greatly facilitate such investigations.
Footnotes
- Marc H.G.P. Raaijmakers is a hematologist in the Department of Hematology at the Erasmus Medical Center in Rotterdam, The Netherlands.
- ( Related Original Article on page 1452)
- Financial and other disclosures provided by the author using the ICMJE (www.icmje.org) Uniform Format for Disclosure of Competing Interests are available with the full text of this paper at www.haematologica.org.
References
- Kai T, Spradling A. Differentiating germ cells can revert into functional stem cells in Drosophila melanogaster ovaries. Nature. 2004; 428(6982):564-9. Google Scholar
- Raaijmakers MH, Scadden DT. Evolving concepts on the microenvironmental niche for hematopoietic stem cells. Curr Opin Hematol. 2008; 15(4):301-6. Google Scholar
- Mendez-Ferrer S, Frenette PS. Hematopoietic stem cell trafficking: regulated adhesion and attraction to bone marrow microenvironment. Ann NY Acad Sci. 2007; 1116:392-413. Google Scholar
- Staudt ND, Aicher WK, Kalbacher H, Stevanovic S, Carmona AK, Bogyo M, Klein G. Cathepsin X is secreted by human osteoblasts, digests CXCL-12 and impairs adhesion of hematopoietic stem and progenitor cells to osteoblasts. Haematologica. 2010; 95(9):1452-1460. Google Scholar
- Kollet O, Dar A, Shivtiel S, Kalinkovich A, Lapid K, Sztainberg Y. Osteoclasts degrade endosteal components and promote mobilization of hematopoietic progenitor cells. Nat Med. 2006; 12(6):657-64. Google Scholar
- Heissig B, Hattori K, Dias S, Friedrich M, Ferris B, Hackett NR. Recruitment of stem and progenitor cells from the bone marrow niche requires MMP-9 mediated release of kit-ligand. Cell. 2002; 109(5):625-37. Google Scholar
- Adams GB, Martin RP, Alley IR, Chabner KT, Cohen KS, Calvi LM. Therapeutic targeting of a stem cell niche. Nat Biotechnol. 2007; 25(2):238-43. Google Scholar
- Levesque JP, Takamatsu Y, Nilsson SK, Haylock DN, Simmons PJ. Vascular cell adhesion molecule-1 (CD106) is cleaved by neutrophil proteases in the bone marrow following hematopoietic progenitor cell mobilization by granulocyte colony-stimulating factor. Blood. 2001; 98(5):1289-97. Google Scholar
- Wilson A, Laurenti E, Oser G, van der Wath RC, Blanco-Bose W, Jaworski M. Hematopoietic stem cells reversibly switch from dormancy to self-renewal during homeostasis and repair. Cell. 2008; 135(6):1118-29. Google Scholar
- Baldridge MT, King KY, Boles NC, Weksberg DC, Goodell MA. Quiescent haematopoietic stem cells are activated by IFN-gamma in response to chronic infection. Nature. 2010; 465(7299):793-7. Google Scholar
- Trumpp A, Essers M, Wilson A. Awakening dormant haematopoietic stem cells. Nat Rev Immunol. 2010; 10(3):201-9. Google Scholar
- Wright DE, Wagers AJ, Gulati AP, Johnson FL, Weissman IL. Physiological migration of hematopoietic stem and progenitor cells. Science. 2001; 294(5548):1933-6. Google Scholar
- Massberg S, Schaerli P, Knezevic-Maramica I, Kollnberger M, Tubo N, Moseman EA. Immunosurveillance by hematopoietic progenitor cells trafficking through blood, lymph, and peripheral tissues. Cell. 2007; 131(5):994-1008. Google Scholar
- Mendez-Ferrer S, Lucas D, Battista M, Frenette PS. Haematopoietic stem cell release is regulated by circadian oscillations. Nature. 2008; 452(7186):442-7. Google Scholar
- Scadden DT. Circadian rhythms: stem cells traffic in time. Nature. 2008; 452(7186):416-7. Google Scholar
- Sugiyama T, Kohara H, Noda M, Nagasawa T. Maintenance of the hematopoietic stem cell pool by CXCL12-CXCR4 chemokine signaling in bone marrow stromal cell niches. Immunity. 2006; 25(6):977-88. Google Scholar
- Adams GB, Chabner KT, Alley IR, Olson DP, Szczepiorkowski ZM, Poznansky MC. Stem cell engraftment at the endosteal niche is specified by the calcium-sensing receptor. Nature. 2006; 439(7076):599-603. Google Scholar
- Barker JE. Sl/Sld hematopoietic progenitors are deficient in situ. Exp Hematol. 1994; 22(2):174-7. Google Scholar
- Raaijmakers MH, Mukherjee S, Guo S, Zhang S, Kobayashi T, Schoonmaker JA. Bone progenitor dysfunction induces myelodysplasia and secondary leukaemia. Nature. 2010; 464(7290):852-7. Google Scholar
- Mangi MH, Mufti GJ. Primary myelodysplastic syndromes: diagnostic and prognostic significance of immunohistochemical assessment of bone marrow biopsies. Blood. 1992; 79(1):198-205. Google Scholar