A novel insight into aging: are there pluripotent very small embryonic-like stem cells (VSELs) in adult tissues overtime depleted in an Igf-1-dependent manner?

Tissue and organ rejuvenation and senescence/aging are closely related to the function of stem cells. Recently, we demonstrated that a population of pluripotent Oct-4+ SSEA-1+Sca-1+Lin-CD45- very small embryonic-like stem cells (VSELs) resides in the adult murine bone marrow (BM) and other murine tissues. We hypothesize that these pluripotent stem cells play an important role in tissue/organ rejuvenation, and have demonstrated that their proliferation and potentially premature depletion is negatively controlled by epigenetic changes of some imprinted genes that regulate insulin factor signaling (Igf2-H19 locus, Igf2R and RasGRF1). Since the attenuation of insulin/insulin growth factor (Ins/Igf) signaling positively correlates with longevity, we propose, based on our experimental data, that gradual decrease in the number of VSELs deposited in adult tissues, which occurs throughout life in an Ins/Igf signaling-dependent manner is an important mechanism of aging. In contrast, a decrease in Ins/Igf stimulation of VSELs that extends the half life of these cells in adult organs would have a beneficial effect on life span. Our preliminary data in long-living Igf-1-signaling-deficient mice show that these animals possess a 3-4 times higher number of VSELs deposited in adult BM, lending support to this novel hypothesis.     

Very small embryonic-like (VSEL) stem cells in adult organs and their potential role in rejuvenation of tissues and longevity

Recently, we purified rare CXC chemokine receptor 4 expressing (CXCR4(+)) small stem cells (SCs) from the murine bone marrow (BM) that express markers characteristic for embryonic (E)SCs, epiblast (EP)SCs, and primordial germ cells (PGCs). We named these primitive cells very small embryonic-like (VSEL) SCs (VSELs). Our data indicate that VSELs are also present in many other organs in mice and that they may differentiate into cells from all three germ layers. Similar SCs were also isolated from human cord blood (CB) and mobilized peripheral blood (mPB). We hypothesize that VSELs are deposited during gastrulation and organogenesis in developing organs/tissues of mammals as a population of pluripotent stem cells (PSCs) that give rise to tissue committed monopotent SCs and that their number decreases with age. Therefore VSELs could play a pivotal role in normal rejuvenation of adult tissues as well as involvement in regeneration of damaged organs. Thus, these cells are potential SCs candidates for regenerative medicine and we envision that the regenerative potential of these cells could be harnessed to decelerate the aging processes.     

Circulating Very Small Embryonic-Like Stem Cells in Cardiovascular Disease

Very small embryonic-like cells (VSELs) are a population of stem cells residing in the bone marrow (BM) and several organs, which undergo mobilization into peripheral blood (PB) following acute myocardial infarction and stroke. These cells express markers of pluripotent stem cells (PSCs), such as Oct-4, Nanog, and SSEA-1, as well as early cardiac, endothelial, and neural tissue developmental markers. VSELs can be effectively isolated from the BM, umbilical cord blood, and PB. Peripheral blood and BM-derived VSELs can be expanded in co-culture with C2C12 myoblast feeder layer and undergo differentiation into cells from all three germ layers, including cardiomyocytes and vascular endothelial cells. Isolation of VSLEs using fluorescence-activated cell sorting multiparameter live cell sorting system is dependent on gating strategy based on their small size and expression of PSC and absence of hematopoietic lineage markers. VSELs express early cardiac and endothelial lineages markers (GATA-4, Nkx2.5/Csx, VE-cadherin, and von Willebrand factor), SDF-1 chemokine receptor CXCR4, and undergo rapid mobilization in acute MI and ischemic stroke. Experiments in mice showed differentiation of BM-derived VSELs into cardiac myocytes and effectiveness of expanded and pre-differentiated VSLEs in improvement of left ventricular ejection fraction after myocardial infarction.     

Bone marrow-derived pluripotent very small embryonic-like stem cells (VSELs) are mobilized after acute myocardial infarction

The adult bone marrow (BM) harbors Sca-1+/Lin−/CD45− pluripotent very small embryonic-like stem cells (VSELs), which can differentiate in vitro into several lineages, including cardiac and vascular lineages. Since mobilization of stem/progenitors from the BM is a prerequisite for their participation in organ repair, we investigated whether VSELs are mobilized into the peripheral blood (PB) after acute myocardial infarction (MI). Wild-type mice (C57BL/6 strain, 6- or 15-wk-old) underwent a 30-min coronary occlusion followed by reperfusion (groups III-V, VIII-X, n = 6-12/group) or a 1-hour open-chest state (sham controls, groups II and VII, n = 8-12/group); mice were sacrificed 24 h, 48 h, or 7 days later and PB samples were harvested. Controls (groups I and VI, n = 6/group) were sacrificed without any intervention. By flow cytometry, VSELs were barely detectable in PB under baseline conditions but their levels increased significantly at 48 h after MI, both in younger (6-wk-old) and older (15-wk-old) mice (3.33 ± 0.37 and 7.10 ± 0.89 cells/µl of blood, respectively). At 48 h after MI, qRT-PCR analysis revealed significantly increased levels of mRNA of markers of pluripotency (Oct-4, Nanog, Rex-1, Rif1, and Dppa1) in PB cells of 6-wk-old (but not 15-wk-old) infarcted mice compared with either controls or sham controls. Confocal microscopy and ImageStream analysis confirmed that mobilized VSELs expressed Oct-4 protein, while Sca-1+/Lin−/CD45+ hematopoietic stem cells did not. This is the first demonstration that Oct-4+ pluripotent stem cells (VSELs) are mobilized from the BM into the PB after acute MI. This phenomenon may have pathophysiological and therapeutic implications for repair of infarcted myocardium.     

Erythrocyte‐derived microvesicles may transfer phosphatidylserine to the surface of nucleated cells and falsely ‘mark’ them as apoptotic

Lysis of erythrocytes using hypotonic solutions is one approach to remove red blood cells (RBCs) from umbilical cord blood (UCB), bone marrow (BM), and peripheral blood (PB) before flow cytometric analysis or sorting of nucleated cells (NCs). Our team employed this separation step to prepare UCB‐, BM‐, or PB‐derived cells to sort very small embryonic‐like stem cells (VSELs). We noticed that depletion of RBCs from UCB by hypotonic lysis resulted in a significant increase in the number of NCs including VSELs that bind Annexin‐V (Ann‐V). Surprisingly, these cells were not apoptotic and displayed normal proliferative potential. To explain this discrepancy, we show that RBC‐derived microvesicles (RMV) released during erythrocyte lysis may transfer phosphatidylserine (PS) to the surface of NCs and ‘mark’ them falsely positive as apoptotic cells. This observation should be considered whenever Ann‐V binding viability assays are employed to evaluate the quality of NCs depleted from erythrocytes via hypotonic lysis.     

Are bone marrow stem cells plastic or heterogenous--that is the question

The concept that bone marrow (BM) may contain heterogeneous populations of stem cells was surprisingly not taken carefully enough into consideration in several recently reported experiments demonstrating so-called plasticity or trans-dedifferentiation of hematopoietic stem cells (HSC). These studies, without including proper controls to exclude this possibility, often lead to wrong interpretations. Accumulated evidence suggests that in addition to hematopoietic stem cells (HSC), bone marrow (BM) also harbors versatile subpopulations of tissue-committed stem cells (TCSC) and perhaps even more primitive pluripotent stem cells (PSC), and that these rare cells accumulate in bone marrow during ontogenesis, and being a mobile population of cells are released from BM into peripheral blood after tissue injury to regenerate damaged organs. Thus, the presence of TCSC/PSC in BM tissue should be considered before experimental evidence is interpreted simply as trans-dedifferentiation/plasticity of HSC. In this review, we will discuss this alternative explanation of plasticity of HSC, providing data from others and our laboratory that supports the concept that BM-derived stem cells are heterogeneous.     

Junctional adhesion molecule-A, JAM-A, is a novel cell-surface marker for long-term repopulating hematopoietic stem cells

Junctional adhesion molecule-A (JAM-A/JAM-1/F11R) is a cell adhesion molecule expressed in epithelial and endothelial cells, and also hematopoietic cells, such as leukocytes, platelets, and erythrocytes. Here, we show that JAM-A is expressed at a high level in the enriched hematopoietic stem cell (HSC) fraction; that is, CD34(+)c-Kit(+) cells in embryonic day 11.5 (E11.5) aorta-gonod-mesonephros (AGM) and E11.5 fetal liver (FL), as well as c-Kit(+)Sca-1(+)Lineage(-) (KSL) cells in E14.5 FL, E18.5FL, and adult bone marrow (BM). Although the percentage of JAM-A(+) cells in those tissues decreases during development, the expression in the HSC fraction is maintained throughout life. Colony-forming assays reveal that multilineage colony-forming activity in JAM-A(+) cells is higher than that in JAM-A(-) cells in the enriched HSC fraction in all of those tissues. Transplantation assays show that long-term reconstituting HSC (LTR-HSC) activity is exclusively in the JAM-A(+) population and is highly enriched in the JAM-A(+) cells sorted directly from whole BM cells by anti-JAM-A antibody alone. Together, these results indicate that JAM-A is expressed on hematopoietic precursors in various hematopoietic tissues and is an excellent marker to isolate LTR-HSCs.     

The negative effect of prolonged somatotrophic/insulin signaling on an adult bone marrow-residing population of pluripotent very small embryonic-like stem cells (VSELs)

It is well known that attenuated insulin/insulin-like growth factor signaling (IIS) has a positive effect on longevity in several animal species, including mice. Here, we demonstrate that a population of murine pluripotent very small embryonic-like stem cells (VSELs) that reside in bone marrow (BM) is protected from premature depletion during aging by intrinsic parental gene imprinting mechanisms and the level of circulating insulin-like growth factor-I (IGF-I). Accordingly, an increase in the circulating level of IGF-I, as seen in short-lived bovine growth hormone (bGH)-expressing transgenic mice, which age prematurely, as well as in wild-type animals injected for 2 months with bGH, leads to accelerated depletion of VSELs from bone marrow (BM). In contrast, long-living GHR-null or Ames dwarf mice, which have very low levels of circulating IGF-I, exhibit a significantly higher number of VSELs in BM than their littermates at the same age. However, the number of VSELs in these animals decreases after GH or IGF-I treatment. These changes in the level of plasma-circulating IGF-I corroborate with changes in the genomic imprinting status of crucial genes involved in IIS, such as Igf-2-H19, RasGRF1, and Ig2R. Thus, we propose that a chronic increase in IIS contributes to aging by premature depletion of pluripotent VSELs in adult tissues.     

Mobilization of very small embryonic-like stem cells in acute coronary syndromes and stroke

The bone marrow (BM) niche contains small heterogenous populations of cells which may contribute to cardiac and endothelial repair, including committed lineages [endothelial progenitor cells (EPCs), multipotent mesenchymal stromal cells (MSCs) and more primitive very small embryonic-like cells (VSELs) expressing pluripotent stem cell (PSC) markers (Oct-4, Nanog, SSEA-1)]. VSELs are present in BM, peripheral blood and some solid organs in mice and were recently identified in peripheral blood in patients with acute coronary syndromes and stroke. VSELs can be expanded in vitro and differentiated into cells from all three germ layers. This population of cells displays the morphology of primitive PSC (small size, open type chromatin, large nucleus, narrow rim of cytoplasm) and express PSC markers. The isolation of human VSELs is based on their size and presence of several surface markers (CXCR4, CD133, CD34) and lack of markers of hematopoietic lineage (lin, CD45). In acute myocardial infarction and ischemic stroke VSELs are rapidly mobilized into peripheral blood, and express increased levels of PSC markers as well as early cardiac (GATA-4, Nkx2.5/Csx), neural (GFAP, nestin, beta-III-tubulin, Olig1, Olig2, Sox2, Musashi) and endothelial lineage markers (VE-cadherin, von Willebrand factor). The number of VSELs mobilized in acute myocardial infarction is inversely correlated with left ventricular ejection fraction and the release of cardiac necrosis markers. Mobilization of these cells is also reduced in patients with diabetes and in the elderly. BM-derived VSELs were expanded and after cardiogenic pre-differentiation injected intramyocardially in mice models of myocardial infarction leading to improved left ventricular contractility. VSELs are probably progeny of epiblast cells which migrated to the BM and developing organs during embryonic development. The cells are present in a quiescent state in the adult BM and solid organs and might serve as a reserve pool of resident stem cells. VSELs are promising candidates for further pre-clinical and clinical studies on cellular cardiovascular therapy.     

Very small embryonic/epiblast-like stem cells (VSELs) and their potential role in aging and organ rejuvenation--an update and comparison to other primitive small stem cells isolated from adult tissues

Very small embryonic-like stem cells (VSELs) are a population of developmentally early stem cells residing in adult tissues. These rare cells, which are slightly smaller than red blood cells, i) become mobilized during stress situations into peripheral blood, ii) are enriched in the Sca1+Lin-CD45- cell fraction in mice and the CD133+ Lin-CD45- cell fraction in humans, iii) express markers of pluripotent stem cells (e.g., Oct4, Nanog, and SSEA), and iv) display a distinct morphology characterized by a high nuclear/cytoplasmic ratio and undifferentiated chromatin. Recent evidence indicates that murine VSELs are kept quiescent in adult tissues and protected from teratoma formation by epigenetic modification of imprinted genes that regulate insulin/insulin like growth factor signaling (IIS). The successful reversal of these epigenetic changes in VSELs that render them quiescent will be crucial for efficient expansion of these cells. The most recent data in vivo from our and other laboratories demonstrated that both murine and human VSELs exhibit some characteristics of long-term repopulating hematopoietic stem cells (LT-HSCs), are at the top of the hierarchy in the mesenchymal lineage, and may differentiate into organ-specific cells (e.g., cardiomyocytes). Moreover, as recently demonstrated the number of these cells positively correlates in several murine models with longevity. Finally, while murine BM-derived VSELs have been extensively characterized more work is needed to better characterize these small cells at the molecular level in humans.     

Mesenchymal stem cells remain of host origin even a long time after allogeneic peripheral blood stem cell or bone marrow transplantation

OBJECTIVE: Plasticity of hematopoietic stem cells (HSC) has gained major interest in stem cell research. In order to investigate whether HSC may differentiate into mesenchymal stem cells (MSC), we assessed chimerism in peripheral blood (PB), mononuclear cell fractions (MNC) of bone marrow, and MSC derived from bone marrow (BM) from 27 up to 4225 days after allogeneic transplantation. PATIENTS AND METHODS: We applied fluorescence in situ hybridization using X/Y gene probes in sex-mismatched and STR-PCR in sex-matched patients. MSC could have been generated in 27 of 55 bone marrow samples derived from 20 patients. Fifteen patients received peripheral blood stem cell transplants (PBSCT), including CD34-selected PBSCT in two. Five patients received bone marrow. RESULTS: While all patients had chimerism in PB and MNC of the BM, in all but one patient BM-derived MSC were of recipient origin. This single patient showed reproducibly MSC of donor origin in a frequency of 1% after having received a CD34-selected PBSCT. Looking at graft collections, MSCs were easily generated from BM specimens, while no MSC could be derived from PBSC samples. CONCLUSION: Even though HSC have been found to differentiate into a variety of nonhematological cell types, they usually do not differentiate into MSC after allogeneic transplantation.     

A strategy for enhancing the engraftment of human hematopoietic stem cells in NOD/SCID mice

To overcome the limitations of allogeneic hematopoietic stem cell transplantation (HSCT), we conducted a study to identify a strategy for enhancing hematopoietic stem cell (HSC) engraftment during HSCT. Co-transplantation experiments with mesenchymal stem cells (MSCs) derived from adult human tissues including bone marrow (BM), adipose tissue (AT), and umbilical cord blood (CB) were conducted. We showed that AT-MSCs and CB-MSCs enhanced the engraftment of HSCs as effectively as BM-MSCs in NOD/SCID mice, suggesting that AT-MSCs and CB-MSCs can be used as alternative stem cell sources for enhancing the engraftment and homing of HSCs. CB-MSCs derived from different donors showed different degrees of efficacy in enhancing the engraftment of HSCs. The most effective CB-MSCs showed higher proliferation rates and secreted more MCP-1, RANTES, EGF, and VEGF. Our results suggest that AT-MSCs and CB-MSCs could be alternative stem cell sources for co-transplantation in HSCT. Furthermore, in terms of MSCs’ heterogeneity, characteristics of each population of MSCs are considerable factors for selecting MSCs suitable for co-transplantation with HSC.     

Rapid and sustained hematopoietic recovery in lethally irradiated mice transplanted with purified Thy-1.1lo Lin-Sca-1+ hematopoietic stem cells

Hematopoietic stem cells (HSCs) are believed to play a critical role in the sustained repopulation of all blood cells after bone marrow transplantation (BMT). However, understanding the role of HSCs versus other hematopoietic cells in the quantitative reconstitution of various blood cell types has awaited methods to isolate HSCs. A candidate population of mouse HSCs, Thy-1.1lo Lin-Sca-1+ cells, was isolated several years ago and, recently, this population has been shown to be the only population of BM cells that contains HSCs in C57BL/Ka-Thy-1.1 mice. As few as 100 of these cells can radioprotect 95% to 100% of irradiated mice, resulting long-term multilineage reconstitution. In this study, we examined the reconstitution potential of irradiated mice transplanted with purified Thy-1.1lo Lin-Sca-1+ BM cells. Donor-derived peripheral blood (PB) white blood cells were detected as early as day 9 or 10 when 100 to 1,000 Thy-1.1lo Lin-Sca-1+ cells were used, with minor dose-dependent differences. The reappearance of platelets by day 14 and thereafter was also seen at all HSC doses (100 to 1,000 cells), with a slight dose-dependence. All studied HSC doses also allowed RBC levels to recover, although at the 100 cell dose a delay in hematocrit recovery was observed at day 14. When irradiated mice were transplanted with 500 Thy-1.1lo Lin-Sca-1+ cells compared with 1 x 10(6) BM cells (the equivalent amount of cells that contain 500 Thy-1.1lo Lin-Sca-1+ cells as well as progenitor and mature cells), very little difference in the kinetics of recovery of PB, white blood cells, platelets, and hematocrit was observed. Surprisingly, even when 200 Thy1.1lo Lin-Sca- 1+ cells were mixed with 4 x 10(5) Sca-1- BM cells in a competitive repopulation assay, most of the early (days 11 and 14) PB myeloid cells were derived from the HSC genotype, indicating the superiority of the Thy-1.1lo Lin-Sca-1+ cells over Sca-1- cells even in the early phases of myeloid reconstitution. Within the Thy-1.1lo Lin-Sca-1+ population, the Rhodamine 123 (Rh123)hi subset dominates in PB myeloid reconstitution at 10 to 14 days, only to be overtaken by the Rh123lo subset at 3 weeks and thereafter. These findings indicate that HSCs can account for the early phase of hematopoietic recovery, as well as sustained hematopoiesis, and raise questions about the role of non-HSC BM populations in the setting of BMT.     

Delayed administration of carrier marrow can decrease competition on donor stem cells during engraftment and maintain radioprotection of the host

OBJECTIVE: The goal of this study was to determine if competitive pressure was placed on hematopoietic stem cells (HSC) by a coinjected "carrier" population that maintains short-term survival of the host. Our hypothesis was that delayed introduction of "carrier" cells would increase engraftment of donor HSC. MATERIALS AND METHODS: Competitive repopulation assays were performed using genetically distinguishable whole bone marrow (BM) populations. Donor BM was competed against carrier BM that was coinjected or injected 3 or 4 days later. Radioprotection with delayed carrier injection also was examined by performing the initial HSC transplantation with Hoechst(lo) side population (SP) cells. SP HSC incubated with cytokines and BM stroma to stimulate cell cycling before transplantation also were tested using coinjection or delayed carrier administration. RESULTS: Delayed introduction of carrier whole BM increased peripheral expansion of donor whole BM, freshly isolated HSC, or cytokine-stimulated HSC compared to coinjection with carrier cells. A 3-day delay in carrier administration maintained radioprotection in 100% of lethally irradiated recipients of highly enriched HSC, whereas a 4-day delay did not rescue these recipients from death. When recipients are rescued, recovering host marrow can compete against donor HSC unless sufficient donor cells are injected. CONCLUSIONS: Delayed introduction of carrier BM significantly increases donor HSC engraftment and peripheral expansion by reducing competition in the host. Competition by a coinjected carrier cell population or recovery of host marrow significantly reduces the therapeutic efficacy of normal or in vitro manipulated donor HSC.     

Who is hematopoietic stem cell: CD34+ or CD34-?

Hematopoietic stem cells (HSC) possess multipotentiality, enabling them to self-renew and also to produce mature blood cells, such as erythrocytes, leukocytes, platelets, and lymphocytes. CD34 is a marker of human HSC, and all colony-forming activity of human bone marrow (BM) cells is found in the CD34+ fraction. Clinical transplantation studies that used enriched CD34+ BM cells indicated the presence of HSC with long-term BM reconstitutional ability within this fraction. But recent studies in NOD/SCID mice, rhesus monkeys, and human/sheep competitive engraftment models have provided evidence for the presence of a rare cell population that contains progenitors capable of producing CD34+ cells in vitro. These progenitors are highly enriched in HSC and have competitive long-term in vivo repopulating potential devoid of both CD34 and lineage-marker expression. These new findings add to the growing evidence that some stem cells in the BM do not express the CD34 marker, which is currently used to select stem cells for transplantation.     

Multipotent progenitor cells can be isolated from postnatal murine bone marrow,muscle, and brain

OBJECTIVE: Recent studies have shown that cells from bone marrow (BM), muscle, and brain may have greater plasticity than previously known. We have identified multipotent adult progenitor cells (MAPC) in postnatal human and rodent BM that copurify with mesenchymal stem cells (MSC). BM MAPC proliferate without senescence and differentiate into mesodermal, neuroectodermal, and endodermal cell types. We hypothesized that cells with characteristics similar to BM MAPC can be selected and cultured from tissues other than BM. MATERIALS AND METHODS: BM, whole brain, and whole muscle tissue was obtained from mice. Cells were plated on Dulbecco modified Eagle medium supplemented with 2% fetal calf serum and 10 ng/mL epidermal growth factor (EGF), 10 ng/mL platelet-derived growth factor (PDGF-BB), and 1000 units/mL leukemia inhibitory factor (LIF) for more than 6 months. Cells were maintained between 0.5 and 1.5 x 10(3) cells/cm(2). At variable time points, we tested cell phenotype by FACS and evaluated their differentiation into endothelial cells, neuroectodermal cells, and endodermal cells in vitro. We also compared the expressed gene profile in BM, muscle, and brain MAPC by Affimetrix gene array analysis. RESULTS: Cells could be cultured from BM, muscle, and brain that proliferated for more than 70 population doublings (PDs) and were negative for CD44, CD45, major histocompatibility complex class I and II, and c-kit. Cells from the three tissues differentiated to cells with morphologic and phenotypic characteristics of endothelium, neurons, glia, and hepatocytes. The expressed gene profile of cells derived from the three tissues was identical (r(2) > 0.975). CONCLUSIONS: This study shows that cells with MAPC characteristics can be isolated not only from BM, but also from brain and muscle tissue. Whether MAPC originally derived from BM are circulating or all organs contain stem cells with MAPC characteristics currently is being studied. Presence of MAPC in multiple tissues may help explain the "plasticity" found in multiple adult tissues.     

Connexin-43 in the osteogenic BM niche regulates its cellular composition and the bidirectional traffic of hematopoietic stem cells and progenitors

Connexin-43 (Cx43), a gap junction protein involved in control of cell proliferation, differentiation and migration, has been suggested to have a role in hematopoiesis. Cx43 is highly expressed in osteoblasts and osteogenic progenitors (OB/P). To elucidate the biologic function of Cx43 in the hematopoietic microenvironment (HM) and its influence in hematopoietic stem cell (HSC) activity, we studied the hematopoietic function in an in vivo model of constitutive deficiency of Cx43 in OB/P. The deficiency of Cx43 in OB/P cells does not impair the steady state hematopoiesis, but disrupts the directional trafficking of HSC/progenitors (Ps) between the bone marrow (BM) and peripheral blood (PB). OB/P Cx43 is a crucial positive regulator of transstromal migration and homing of both HSCs and progenitors in an irradiated microenvironment. However, OB/P Cx43 deficiency in nonmyeloablated animals does not result in a homing defect but induces increased endosteal lodging and decreased mobilization of HSC/Ps associated with proliferation and expansion of Cxcl12-secreting mesenchymal/osteolineage cells in the BM HM in vivo. Cx43 controls the cellular content of the BM osteogenic microenvironment and is required for homing of HSC/Ps in myeloablated animals.     

Differential homing and engraftment properties of hematopoietic progenitor cells from murine bone marrow, mobilized peripheral blood, and fetal liver

The rate of reconstitution following hematopoietic stem cell (HSC) transplantation differs widely depending on the tissue source of the cells infused. To test the hypothesis that variability in engraftment kinetics is related to differences in the efficiency with which intravenously transplanted HSCs "home" to the bone marrow (BM), the homing properties of murine fetal liver (FL), adult BM, and mobilized peripheral blood (MPB) cells were compared. Lethally irradiated mice transplanted with 2 x 10(6) FL, BM, or MPB cells exhibited sequentially slower recovery of circulating leukocytes and platelets that correlates with the progressively lower frequency of colony-forming cells (CFCs) in these tissues. However, differences in the rate and degree of early and long-term reconstitution were maintained even after infusing equal numbers of CFCs derived from FL, BM, and MPB. To compare the homing of progenitors from these tissues, cells were labeled with fluorescent PKH26 dye and injected into lethally irradiated hosts. Three hours later, PKH26(+) cells were reisolated from the BM and spleen by fluorescence-activated cell sorting and assayed for in vitro CFCs. Despite the higher level of very late antigen (VLA)-2, VLA-4, and VLA-5 on Sca-1(+)c-kit(+) cells from FL compared to BM, 10-fold fewer FL CFCs homed to hematopoietic organs than those from BM. MPB cells homed slightly better, but still less efficiently than BM cells. Therefore, clonogenic cells from different tissues exhibit striking variations in homing efficiency that does not necessarily correlate with engraftment kinetics. Homing is likely counterbalanced by intrinsic differences in proliferative potential that ultimately determine the rate of hematopoietic reconstitution.     

粒细胞集落刺激因子动员对CD34^＋细胞黏附分子表达的影响

目的探讨粒细胞集落刺激因子（G—CSF）动员对CD34^＋细胞黏附分子表达的影响。方法应用流式细胞仪检测健康供者稳态及G—CSF动员过程中骨髓、外周血CD34^＋细胞的黏附分子表达变化，并应用结晶紫染色测定CD34^＋细胞的黏附功能。结果G-CSF动员后CD34^＋CD49d^＋细胞比例无显著下降，外周血CD34^＋CD621．^＋、CD34^＋CD54^＋和CD34^＋CDlla^＋细胞比例增高。动员后CD34^＋细胞表面CD49d的平均荧光强度显著减弱，但CD49e、CD62L、CDlla、CD54的平均荧光强度虽呈减弱趋势，却无统计学差异。动员后CD34^＋细胞黏附纤连蛋白能力下降。结论G—CSF通过降低造血干细胞与骨髓基质的黏附而产生动员效应。     

Bone marrow Schwann cells induce hematopoietic stem cell hibernation

Hematopoietic stem cells (HSCs) are clonogenic cells capable of both self-renewal and multilineage differentiation. In adult mouse bone marrow (BM), most HSCs remain in the non-dividing G₀-phase of cell cycle, in close contact with supporting cells known as the HSC “niche”. In the present study, we focused on signaling mechanisms that regulate stem cell dormancy in the BM niche. We show that TGF-β type II receptor deficiency causes reduced phosphorylation of Smad2/3 and impairs long-term repopulating activity in HSCs, suggesting a significant role for TGF-β/Smad signaling in hematopoiesis. Furthermore, we aimed at defining the candidate BM niche responsible for homeostasis of hematopoiesis, and revealed that non-myelinating Schwann cells sustain HSC hibernation by converting TGF-β from its latent to its active form.