Lymphocytes with aberrant expression of Fas or Fas ligand attenuate immune bone marrow failure in a mouse model.

Bone marrow (BM) and lymphocyte samples from aplastic anemia patients show up-regulated Fas and Fas-ligand (FasL) expression, respectively, supporting a relationship between immune-mediated BM destruction and the Fas apoptotic pathway. Mice with spontaneous lymphoproliferation (lpr) and generalized lymphoproliferative disease (gld) mutations exhibit abnormal expression of Fas and FasL, serving as potential models to elucidate underlying mechanisms of BM failure. We examined cellular and functional characteristics of lpr and gld mutants on the C57BL/6 (B6) background. Lymph node (LN) cells from lpr and gld mice produced less apoptosis when coincubated with C.B10-H2(b)/LilMcd (C.B10) BM cells in vitro. This functional difference was confirmed by infusing lpr, gld, and B6 LN cells into sublethally irradiated CB10 mice. All donor LN cells showed significant T cell expansion and activation, but only B6 LN cells caused severe BM destruction. Mice infused with gld LN cells developed mild to moderate BM failure despite receiving FasL-deficient effectors, thus suggesting the existence of alternative pathways or incomplete penetrance of the mutation. Paradoxically, mice that received Fas-deficient lpr LN cells also had reduced BM failure, likely due to down-regulation of proapoptotic genes, an effect that can be overcome by higher doses of lpr LN cells. Our model demonstrates that abnormal Fas or FasL expression interferes with the development of pancytopenia and marrow hypoplasia, validating a major role for the Fas/FasL cytotoxic pathway in immune-mediated BM failure, although disruption of this pathway does not completely abolish marrow destruction.

Enrichment of hematopoietic stem cells with SLAM and LSK markers for the detection of hematopoietic stem cell function in normal and Trp53 null mice.

OBJECTIVE: To test function of hematopoietic stem cells (HSCs) in vivo in C57BL/6 (B6) and Trp53-deficient (Trp53 null) mice by using two HSC enrichment schemes. MATERIALS AND METHODS: Bone marrow (BM) Lin-CD41-CD48-CD150+ (signaling lymphocyte activation molecules [SLAM]), Lin-CD41-CD48-CD150- (SLAM-) and Lin-Sca1+CD117+ (LSK) cells were defined by fluorescence-activated cell staining (FACS). Cellular reactive oxygen species (ROS) level was also analyzed by FACS. Sorted SLAM, SLAM-, and LSK cells were tested in vivo in the competitive repopulation (CR) and serial transplantation assays. RESULTS: SLAM cell fraction was 0.0078%+/-0.0010% and 0.0135%+/-0.0010% of total BM cells in B6 and Trp53 null mice, and was highly correlated (R2=0.7116) with LSK cells. CD150+ BM cells also contained more ROSlow cells than did CD150- cells. B6 SLAM cells repopulated recipients much better than B6 SLAM- cells, showing high HSC enrichment. B6 SLAM cells also engrafted recipients better than Trp53 null SLAM cells in the CR and the follow-up serial transplantation assays. Similarly, LSK cells from B6 donors also had higher repopulating ability than those from Trp53 null donors. However, whole BM cells from the same B6 and Trp53 null donors showed the opposite functional trend in recipient engraftment. CONCLUSION: Both SLAM and LSK marker sets can enrich HSCs from B6 and Trp53 mice. Deficiency of Trp53 upregulates HSC self-renewal but causes no gain of HSC function.

Minor antigen h60-mediated aplastic anemia is ameliorated by immunosuppression and the infusion of regulatory T cells.

Human bone marrow (BM) failure mediated by the immune system can be modeled in mice. In the present study, infusion of lymph node (LN) cells from C57BL/6 mice into C.B10-H2(b)/LilMcd (C.B10) recipients that are mismatched at multiple minor histocompatibility Ags, including the immunodominant Ag H60, produced fatal aplastic anemia. Declining blood counts correlated with marked expansion and activation of CD8 T cells specific for the immunodominant minor histocompatibility Ag H60. Infusion of LN cells from H60-matched donors did not produce BM failure in C.B10 mice, whereas isolated H60-specific CTL were cytotoxic for normal C.B10 BM cells in vitro. Treatment with the immunosuppressive drug cyclosporine abolished H60-specific T cell expansion and rescued animals from fatal pancytopenia. The development of BM failure was associated with a significant increase in activated CD4+CD25+ T cells that did not express intracellular FoxP3, whereas inclusion of normal CD4+CD25+ regulatory T cells in combination with C57BL/6 LN cells aborted H60-specific T cell expansion and prevented BM destruction. Thus, a single minor histocompatibility Ag H60 mismatch can trigger an immune response leading to massive BM destruction. Immunosuppressive drug treatment or enhancement of regulatory T cell function abrogated this pathophysiology and protected animals from the development of BM failure.

Age-dependent accumulation of mtDNA mutations in murine hematopoietic stem cells is modulated by the nuclear genetic background.

Alterations in mitochondrial DNA (mtDNA) and consequent loss of mitochondrial function underlie the mitochondrial theory of aging. In this study, we systematically analyzed the mtDNA control region somatic mutation pattern in 2864 single hematopoietic stem cells (HSCs) and progenitors, isolated by flow cytometry sorting on Lin(-)Kit(+)CD34(-) parameters from young and old C57BL/6 (B6) and BALB/cBy (BALB) mice, to test the hypothesis that the accumulated mtDNA mutations in HSCs were strain-correlated and associated with HSC functional senescence during aging. An increased level of mtDNA mutations in single HSCs was observed in old B6 when compared with young B6 mice (P=0.003); in contrast, no significant age-dependent accumulation of mutations was observed in BALB mice (old versus young, P=0.202) and the level of mutations in both young and old BALB mice was close to that of old B6 mice (P>0.280). Cellular reactive oxygen species (ROS) in mouse HSCs could not be correlated with the level of mtDNA mutations in these cells, although B6 mice had a higher proportion of ROS(-) cells when compared with the BALB mice. Propagation assays of single HSCs showed B6 cells form larger colonies compared with cells from BALB mice, irrespective of age and mtDNA mutation load. We infer from our data that age-related mtDNA somatic mutation accumulation in mouse HSCs is influenced by the nuclear genetic background and that these mutations may not obviously correlate to either cellular ROS content or HSC senescence.

Defective stromal cell function in a mouse model of infusion-induced bone marrow failure.

OBJECTIVE: To study bone marrow (BM) stromal damage in a mouse model of infusion-induced BM failure. MATERIALS AND METHODS: Sublethally irradiated CByB6F1 mice were infused with 5 x 10(6) C57BL/6 (B6) lymph node (LN) cells. Recipient BM cells were taken at 3, 7, 10, and 14 days following LN infusion and were cultured in vitro in alpha-modified Eagle media for 2-3 weeks. Peripheral blood and was analyzed by complete blood counts while BM lymphocyte infiltration/expansion was analyzed by flow cytometry. Marrow cells from affected and control mice were mixed and cultured in vitro to test nonspecific stromal damage. RESULTS: Donor lymphocytes infiltrated host BM within 3-7 days and expanded significantly between 7 and 10 days, concurrent with the development of leukopenia, thrombocytopenia, and marrow hypoplasia. BM cells from mice at 7, 10, and 14 days after B6-LN cell infusion were progressively defective in forming stromal feeder layers. A 1:1 mixture of BM cells from affected CByB6F1 mice and normal B6 mice failed to form an effective stromal feeder layer that could support cobblestone colony formation, indicating that lymphocytes in the BM of affected CByB6F1 mice were able to damage stromal cells in the normal B6 BM. CONCLUSION: Activated lymphocytes destroy both hematopoietic and stromal cells as innocent bystanders in the infusion-induced BM failure model.

c-Kit expression and stem cell factor-induced hematopoietic cell proliferation are up-regulated in aged B6D2F1 mice.

Expression of c-Kit (CD117) and stem cell factor/c-Kit-mediated cell proliferation were tested in vitro in young and old B6D2F1 mice to study the role of c-Kit signaling in hematopoietic stem cell (HSC) senescence. Increasing age is associated with a significant increase in bone marrow (BM) cells without affecting mature blood cells. The number of c-Kit-expressing BM cells increased significantly in old mice when compared to young controls, to 201% in total BM cells, 261% in Lin(-) cells, 517% in Lin(-)CD34(+)Sca1(+) progenitor cells, and 1272% in Lin(-)CD34(-)Sca1(+) HSCs. Sorted Lin(-)Sca1(+)CD117(+) BM cells from an old mouse expanded 5-fold when cultured in vitro for 72 hours with stem cell factor at 25 ng/ml, which was significantly higher than a 2.5-fold expansion of the same cells from a young donor. HSCs and progenitor cells from B6D2F1 mice maintain extremely high proliferative potentials and do not reach proliferative arrest at old age during a normal life span.

Bystander destruction of hematopoietic progenitor and stem cells in a mouse model of infusion-induced bone marrow failure.

Infusion of parental lymph node (LN) cells into sublethally irradiated hybrid F1 recipients created a murine model for bone marrow (BM) failure. Affected animals developed fatal pancytopenia within 2 to 3 weeks, accompanied by BM oligoclonal T-cell infiltration and severe marrow hypoplasia indicated by approximately 10-fold declines in total BM cellularity, 15-fold declines in BM Lin(-)Sca1(+)c-Kit(+) cells, 100-fold declines in spleen colony-forming units, and 100-fold declines in hematopoietic progenitor and stem cells as estimated by irradiation protection in vivo. LN cells of both H2(b/b) and H2(d/d) haplotypes were effectors. Serum interferon-gamma (IFN-gamma) concentration increased 2- to 3-fold. Marrow cells were severely apoptotic, with high proportions of Fas(+) and annexin V(+) cells. Cotransplantation of 5 x 10(5) BM cells from clinically affected donors and 10(6) BM cells from H2 identical healthy mice could not rescue lethally irradiated recipients. Recipients had significantly lower cellularity in peripheral blood and BM, and cell mixtures failed to produce a stromal feeder layer to support marrow cell growth in vitro. Pathogenic T cells from donors after BM failure appeared capable of destroying hematopoietic progenitor, stem, and stromal cells from fully compatible healthy donors as "innocent bystanders." This effect can be partially abrogated by anti-IFN-gamma antibody.