RIPK1 regulates RIPK3-MLKL-driven systemic inflammation and emergency hematopoiesis.

Upon ligand binding, RIPK1 is recruited to tumor necrosis factor receptor superfamily (TNFRSF) and Toll-like receptor (TLR) complexes promoting prosurvival and inflammatory signaling. RIPK1 also directly regulates caspase-8-mediated apoptosis or, if caspase-8 activity is blocked, RIPK3-MLKL-dependent necroptosis. We show that C57BL/6 Ripk1(-/-) mice die at birth of systemic inflammation that was not transferable by the hematopoietic compartment. However, Ripk1(-/-) progenitors failed to engraft lethally irradiated hosts properly. Blocking TNF reversed this defect in emergency hematopoiesis but, surprisingly, Tnfr1 deficiency did not prevent inflammation in Ripk1(-/-) neonates. Deletion of Ripk3 or Mlkl, but not Casp8, prevented extracellular release of the necroptotic DAMP, IL-33, and reduced Myd88-dependent inflammation. Reduced inflammation in the Ripk1(-/-)Ripk3(-/-), Ripk1(-/-)Mlkl(-/-), and Ripk1(-/-)Myd88(-/-) mice prevented neonatal lethality, but only Ripk1(-/-)Ripk3(-/-)Casp8(-/-) mice survived past weaning. These results reveal a key function for RIPK1 in inhibiting necroptosis and, thereby, a role in limiting, not only promoting, inflammation.

Reversible growth factor dependency and autonomy during murine myelomonocytic leukemia induced by oncogenes.

When murine fetal liver cells were transduced with either of the human acute myeloid leukemia fusion oncogenes MLL-ENL or MLL-AF9 and then transplanted to irradiated recipient mice, myelomonocyte leukemias rapidly developed from the transplanted cells. Analysis of initial events following transduction showed that both oncogenes immediately induced a wide range of enhanced proliferative states, the most extreme of which could generate continuous lines of cells. Maturation defects accompanied the enhanced proliferative states. At all times, the transformed cells exhibited complete dependency on hematopoietic growth factors, particularly GM-CSF and IL-3. Myelomonocytic leukemic cells from primary or transplanted mice formed colonies in semisolid agar. The large majority were dependent on hematopoietic growth factors, but a low frequency of autonomous colonies was also detected. Unexpectedly, reculture of autonomous leukemic colonies generated large numbers of growth factor-dependent clonogenic progeny. Similarly, transplanted clonal autonomous leukemic cells produced leukemias containing a majority of factor-dependent cells. Conversely, recultures of factor-dependent colonies in vitro always produced small numbers of autonomous colonies among the dependent progeny. The reversible relationship between factor dependency and autonomy is surprising because autonomy would have been presumed to represent the final, irreversible, leukemic state.

Concordant mast cell and basophil production by individual hematopoietic blast colony-forming cells.

Previous studies have shown that mouse bone marrow cells can produce mast cells when stimulated in vitro by stem cell factor (SCF) and interleukin-3 (IL-3). Experiments to define the marrow cells able to generate mast cells showed that the most active subpopulations were the Kit(+) Sca1(-) progenitor cell fraction and the more ancestral Kit(+) Sca1(+) blast colony-forming cell fraction. In clonal cultures, up to 64% of blast colony-forming cells were able to generate mast cells when stimulated by SCF and IL-3, and, of these, the most active were those in the CD34(-) Flt3R(-) long-term repopulating cell fraction. Basophils, identified by the monoclonal antibody mMCP-8 to mouse mast cell serine protease-8, were also produced by 50% of blast colony-forming cells with a strong concordance in the production of both cell types by individual blast colony-forming cells. Enriched populations of marrow-derived basophils were shown to generate variable numbers of mast cells after a further incubation with SCF and IL-3. The data extend the repertoire of lineage-committed cells able to be produced by multipotential hematopoietic blast colony-forming cells and show that basophils and mast cells can have common ancestral cells and that basophils can probably generate mast cells at least under defined in vitro conditions.

Hematopoietic overexpression of the transcription factor Erg induces lymphoid and erythro-megakaryocytic leukemia.

The transcription factor encoded by the E-twenty-six (ETS)-related gene, ERG, is an essential regulator of hematopoietic stem cell function and a potent human oncoprotein. Enforced expression of ERG in murine hematopoietic cells leads to the development of a well-characterized lymphoid leukemia and a less well-defined non lymphoid disease. To clarify the latter, we generated murine bone marrow chimeras with enforced Erg expression in engrafted hematopoietic progenitor cells. As expected, these mice developed lymphoid leukemia. However, the previously reported non lymphoid disease that developed was shown to be a uniform, transplantable leukemia with both erythroid and megakaryocytic characteristics. In vivo, this disease had the overall appearance of an erythroleukemia, with an accumulation of immature erythroblasts that infiltrated the bone marrow, spleen, liver, and lung. However, when stimulated in vitro, leukemic cell clones exhibited both erythroid and megakaryocytic differentiation, suggesting that transformation occurred in a bipotential progenitor. Thus, in mice, Erg overexpression induces the development of not only lymphoid leukemia but also erythro-megakaryocytic leukemia.

Multipotential hematopoietic blast colony-forming cells exhibit delays in self-generation and lineage commitment.

Murine hematopoietic blast colony-forming cells (BL-CFCs) are able to generate up to 30,000 progeny blast cells within 10 d in agar cultures. Contained in these populations are large numbers of lineage-committed progenitor cells in the granulocytic and macrophage lineages. Sequential analyses of blast colonies revealed that self-generation of BL-CFCs occurs but is surprisingly late in clonal expansion, as is the emergence of progenitor cells committed to megakaryocytic and eosinophil lineages. Self-generating BL-CFCs were highly enriched in lineage(-) Kit(+) Sca1(+) CD34(-) Flt3R(-) populations, and colonies generated by such cells contained colony-forming units-spleen and formed erythroid and lymphoid progeny in vivo. The data suggest the existence of a hierarchical structure in BL-CFC populations with at least a subset being cells assayable as colony-forming units-spleen. Because BL-CFCs can self-generate and are able to generate lymphoid and myeloid populations, BL-CFCs appear to be ideal cells in which to analyze the processes of self-generation and lineage commitment in clonal in vitro cultures.

Murine hematopoietic blast colony-forming cells and their progeny have distinctive membrane marker profiles.

Two distinct bone marrow-derived blast colony-forming cells can generate colonies of lineage-restricted progenitor cells in agar cultures of murine bone marrow. Both cell types selectively had a Kit(+) ScaI(+) phenotype distinguishing them from most lineage-restricted progenitor cells. Multicentric blast colony-forming cells stimulated by stem cell factor plus interleukin-6 (IL-6) (BL-CFC-S) were separable from most dispersed blast colony-forming cells stimulated by Flt3 ligand and IL-6 (BL-CFC-F) using CD34 and Flt3R probes. Multicentric BL-CFC-S cofractionated with colony-forming units, spleen (CFU-S) supporting the possibility that the 2 cells may be identical. The colony populations generated by BL-CFC-S were similar in their phenotype and proliferative capacity to progenitor cells in whole bone marrow but the progeny of BL-CFC-F were skewed with an abnormally high proportion of Kit(-) Flt3R(+) cells whose clonogenic cells tended to generate only macrophage progeny. Both blast colony populations had a high percentage of GR1(+) and Mac1(+) cells but BL-CFC-F colonies also contained a significant population of B220(+) and IL-7R(+) cells relevant to the superior ability of BL-CFC-F colony cells to generate B lymphocytes and the known dependency of this process on Flt3 ligand and IL-7. The commitment events and phenotypic changes during the generation of differing progenitor cells in blast colonies can now be clonally analyzed in a convenient in vitro culture system.

PU.1 regulates the commitment of adult hematopoietic progenitors and restricts granulopoiesis.

Although the transcription factor PU.1 is essential for fetal lymphomyelopoiesis, we unexpectedly found that elimination of the gene in adult mice allowed disturbed hematopoiesis, dominated by granulocyte production. Impaired production of lymphocytes was evident in PU.1-deficient bone marrow (BM), but myelocytes and clonogenic granulocytic progenitors that are responsive to granulocyte colony-stimulating factor or interleukin-3 increased dramatically. No identifiable common lymphoid or myeloid progenitor populations were discernable by flow cytometry; however, clonogenic assays suggested an overall increased frequency of blast colony-forming cells and BM chimeras revealed existence of long-term self-renewing PU.1-deficient cells that required PU.1 for lymphoid, but not granulocyte, generation. PU.1 deletion in granulocyte-macrophage progenitors, but not in common myeloid progenitors, resulted in excess granulocyte production; this suggested specific roles of PU.1 at different stages of myeloid development. These findings emphasize the distinct nature of adult hematopoiesis and reveal that PU.1 regulates the specification of the multipotent lymphoid and myeloid compartments and restrains, rather than promotes, granulopoiesis.

Clonogenic mast cell progenitors and their excess numbers in chimeric BALB/c mice with inactivated GATA-1.

In agar cultures of marrow cells from adult female BALB/c chimeric GATA-1(Plt13/+) mice, a high frequency of unusual dispersed colonies was noted. Analysis showed that these were colonies of mast cells and that mast cell colony-forming cells (progenitors) could be detected in clonal cultures of adult marrow, neonatal marrow, or fetal liver if the combined stimulus of stem cell factor and interleukin-3 was used. Mast cell progenitors were in active cell cycle and showed an extensive capacity for self-generation. Mast cell colonies both from control GATA-1(+/+) mice and GATA-1(Plt13/+) mice could generate growth factor-dependent cloned cell lines that grew for >18 months. Surprisingly, the majority of the excessive numbers of mast cell progenitors in chimeric GATA-1(Plt13/+) mice were transcribing the inactive Plt13 allele of GATA-1, suggesting that GATA-1 normally acts to restrict the emergence of committed mast cell progenitors. In sharp contrast, all eosinophil progenitors in these mice were transcribing the normal GATA-1 allele. No excess tissue mast cells were observed in GATA-1(Plt13/+) mice, suggesting that the excess mast cell progenitors in these mice might be generating mast cells with a defective in vivo proliferative or tissue homing capacity.

The preleukemic state of mice reconstituted with Mixl1-transduced marrow cells.

Murine granulocytic cells, in becoming leukemic, need to acquire enhanced self-generation and a capacity for autocrine growth stimulation. Mice transplanted with bone marrow cells transduced with the Mixl1 homeobox gene develop a very high frequency of myeloid leukemia derived from the transduced cells. Preleukemic mice contained a high frequency of transduced clonogenic granulocytic cells. They exhibited an abnormally high capacity for self-replication and could generate immortalized granulocytic cell lines that remained absolutely dependent on either GM-CSF or IL-3 and were not leukemic. Organs from mice repopulated by marrow cells transduced either with Mixl1 or the control murine stem cell virus vector exhibited a capacity to produce IL-3 in vitro, activity being highest with the lungs, marrow, bladder, and thymus. Supporting evidence for the in vivo production of IL-3 was the frequent development of mast cells in the marrow. Overexpression of Mixl1 appears capable of inducing an abnormal self-renewal capacity in granulocytic precursors. Aberrant production of IL-3 was not present in the continuous Mixl cell lines and was therefore not in itself likely to be a leukemogenic change but it could support the enhanced survival and proliferation of the Mixl1 granulocytic populations until a final leukemogenic mutation occurs in them.

An Erg-driven transcriptional program controls B cell lymphopoiesis.

B lymphoid development is initiated by the differentiation of hematopoietic stem cells into lineage committed progenitors, ultimately generating mature B cells. This highly regulated process generates clonal immunological diversity via recombination of immunoglobulin V, D and J gene segments. While several transcription factors that control B cell development and V(D)J recombination have been defined, how these processes are initiated and coordinated into a precise regulatory network remains poorly understood. Here, we show that the transcription factor ETS Related Gene (Erg) is essential for early B lymphoid differentiation. Erg initiates a transcriptional network involving the B cell lineage defining genes, Ebf1 and Pax5, which directly promotes expression of key genes involved in V(D)J recombination and formation of the B cell receptor. Complementation of Erg deficiency with a productively rearranged immunoglobulin gene rescued B lineage development, demonstrating that Erg is an essential and stage-specific regulator of the gene regulatory network controlling B lymphopoiesis.

Inactivation of PU.1 in adult mice leads to the development of myeloid leukemia.

Genetically primed adult C57BL mice were deleted of exon 5 of the gene encoding the transcription factor PU.1 by IFN activation of Cre recombinase. After a 13-week delay, conditionally deleted (PU.1(-/-)) mice began dying of myeloid leukemia, and 95% of the mice surviving from early postinduction death developed transplantable myeloid leukemia whose cells were deleted of PU.1 and uniformly Gr-1 positive. The leukemic cells formed autonomous colonies in semisolid culture with varying clonal efficiency, but colony formation was enhanced by IL-3 and sometimes by granulocyte-macrophage colony-stimulating factor. Nine of 13 tumors analyzed had developed a capacity for autocrine IL-3 or granulocyte-macrophage colony-stimulating factor production, and there was evidence of rearrangement of the IL-3 gene. Acquisition of autocrine growth-factor production and autonomous growth appeared to be major events in the transformation of conditionally deleted PU.1(-/-) cells to fully developed myeloid leukemic populations.

Enforced expression of the homeobox gene Mixl1 impairs hematopoietic differentiation and results in acute myeloid leukemia.

Mixl1, the sole murine homologue of the Xenopus Mix/Bix family of homeobox transcription factors, is essential for the patterning of axial mesendodermal structures during early embryogenesis. Gene targeting and overexpression studies have implicated Mixl1 as a regulator of hematopoiesis arising in differentiating embryonic stem cells. To assess the role of Mixl1 in the regulation of adult hematopoiesis, we overexpressed Mixl1 in murine bone marrow using a retroviral transduction/transplantation model. Enforced expression of Mixl1 profoundly perturbed hematopoietic lineage commitment and differentiation, giving rise to abnormal myeloid progenitors and impairing erythroid and lymphoid differentiation. Moreover, all mice reconstituted with Mixl1-transduced bone marrow developed fatal, transplantable acute myeloid leukemia with a mean latency period of 200 days. These observations establish a link between enforced Mixl1 expression and leukemogenesis in the mouse.

A mutation in the translation initiation codon of Gata-1 disrupts megakaryocyte maturation and causes thrombocytopenia.

We have generated mice from a N-ethyl-N-nitrosourea mutagenesis screen that carry a mutation in the translation initiation codon of Gata-1, termed Plt13, which is equivalent to mutations found in patients with acute megakaryoblastic leukemia and Down syndrome. The Gata-1 locus is present on the X chromosome in humans and in mice. Male mice hemizygous for the mutation (Gata-1Plt13/Y) failed to produce red blood cells and died during embryogenesis at a similar stage to Gata-1-null animals. Female mice that carry the Plt13 mutation are mosaic because of random inactivation of the X chromosome. Adult Gata-1Plt13/+ females were not anemic, but they were thrombocytopenic and accumulated abnormal megakaryocytes without a concomitant increase in megakaryocyte progenitor cells. Gata-1Plt13/+ mice contained large numbers of blast-like colony-forming cells, particularly in the fetal liver, but also in adult spleen and bone marrow, from which continuous mast cells lines were readily derived. Although the equivalent mutation to Gata-1Plt13 in humans results in production of GATA-1s, a short protein isoform initiated from a start codon downstream of the mutated initiation codon, Gata-1s was not detected in Gata-1Plt13/+ mice.

Murine megakaryocyte progenitor cells and their susceptibility to suppression by G-CSF.

In agar cultures of mouse bone marrow cells, mega-karyocyte colony-forming cells exhibited shorter survival times than granulocyte-macrophage progenitor cells when initially cultured in the absence of stimulating factors. Initiation of cultures with G-CSF improved the survival times of granulocyte-macrophage progenitor cells and those of megakaryocyte progenitor cells. Paradoxically, G-CSF was found to consistently inhibit megakaryocyte colony formation stimulated by erythropoietin or by stem cell factor plus interleukin-3 (IL-3) plus erythropoietin. G-CSF was a less-consistent inhibitor of megakaryocyte colonies stimulated by thrombopoietin or IL-3. Analysis of the response of marrow cells from mice with the deletion of the genes encoding CIS, SOCS-1, SOCS-2, SOCS-3, SOCS-5, SOCS-6, or SOCS-7 indicated that the inhibitory SOCS proteins, with the possible exception of SOCS-3, were not involved in the G-CSF-initiated suppression of megakaryocyte colony formation.

Anomalous megakaryocytopoiesis in mice with mutations in the c-Myb gene.

Mpl(-/-) mice bearing the Plt3 or Plt4 mutations in the c-Myb gene exhibit thrombopoietin (TPO)-independent supraphysiological platelet production accompanied by excessive megakaryocytopoiesis and defective erythroid and lymphoid cell production. To better define the cellular basis for the thrombocytosis in these mice, we analyzed the production and characteristics of megakaryocytes and their progenitors. Consistent with thrombocytosis arising from hyperactive production, the high platelet counts in mice carrying the c-Myb(Plt4) allele were not accompanied by any significant alteration in platelet half-life. Megakaryocytes in c-Myb mutant mice displayed reduced modal DNA ploidy and, among the excessive numbers of megakaryocyte progenitor cells, more mature precursors were particularly evident. Megakaryocyte progenitor cells carrying the Plt3 or Plt4 c-Myb mutations, but not granulocyte-macrophage progenitors, exhibited 200-fold enhanced responsiveness to granulocyte-macrophage colony-stimulating factor (GM-CSF), suggesting that altered responses to cytokines may contribute to expanded megakaryocytopoiesis. Mutant preprogenitor (blast colony-forming) cells appeared to have little capacity to form megakaryocyte progenitor cells. In contrast, the spleens of irradiated mice 12 days after transplantation with mutant bone marrow contained abundant megakaryocyte progenitor cells, suggesting that altered c-Myb activity skews differentiation commitment in spleen colony-forming units (CFU-S) in favor of excess megakaryocytopoiesis.

Synergistic and inhibitory interactions in the in vitro control of murine megakaryocyte colony formation.

The formation of megakaryocyte colonies in agar cultures of murine bone marrow or spleen cells can be stimulated by the addition of interleukin-3 (IL-3), erythropoietin (EPO), thrombopoietin (TPO), or IL-6. However, greater numbers of colonies developed if combinations of two or more of these stimuli were used, particularly combinations including stem cell factor, with maximal numbers of colonies developing with the combination of stem cell factor plus IL-3 plus EPO. The data indicate that most committed progenitor cells in the megakaryocyte lineage were unusual in that they required stimulation by two or more hematopoietic growth factors. In tests using a range of growth factors, G-CSF was exceptional in that it consistently specifically inhibited megakaryocyte colony formation stimulated by EPO, TPO, or IL-6 but not that stimulated by IL-3. The mechanisms involved in this inhibitory action of G-CSF are unknown, but the inhibitory action could be of relevance for the dose-dependent lowering of platelet levels observed in some subjects injected with G-CSF.

Stem cell factor can stimulate the formation of eosinophils by two types of murine eosinophil progenitor cells.

There are only three known stimuli for eosinophil formation-GM-CSF, interleukin-5 (IL-5), and IL-3. Because mice with inactivation of the gene encoding the common beta receptor chain for GM-CSF, IL-5, and IL-3 (betac(-/-) mice) cannot respond to GM-CSF or IL-5 and do not produce IL-3, they should lack eosinophils. However, they produce reduced numbers of eosinophils, indicating the existence of at least one additional stimulatory factor. Use of betac(-/-) mouse marrow cells failed to detect a novel eosinophil-stimulating factor in cell line- or organ-conditioned media, but stem cell factor (SCF) was found to have a previously unrecognized ability to stimulate the formation of eosinophil colonies or mixed neutrophil-eosinophil colonies. This action of SCF was also observable with marrow cells from other mouse strains and was enhanced by the addition of G-CSF but no other factor tested. Recloning of SCF-stimulated blast colonies showed that progenitors forming pure eosinophil or mixed neutrophil-eosinophil colonies can have a common ancestor but many appear to arise independently from different preprogenitor cells. The observed activity of SCF in marrow cultures was relatively weak, but its action may be stronger in vivo, and SCF needs to be added to GM-CSF, IL-5, and IL-3 in the list of cytokines able to stimulate eosinophil formation.

Crowding-dependent production of colony-stimulating factors by cultured syngeneic or allogeneic hematopoietic cells.

Mitogenic stimulation in vitro of mouse T lymphocytes induces the production of the hematopoietic cytokines granulocyte-macrophage colony-stimulating factor and IL-3. The present experiments showed that simple crowding of murine spleen or lymph node cells was a sufficient inducing stimulus. Crowding did not have this consequence for thymus or marrow cells or spleen cells from nu/nu or Rag-1-/- mice lacking T lymphocytes. Crowding for as short a period as 24 h was sufficient to allow subsequent cytokine production in sparse cultures. Purified T lymphocytes also exhibited low levels of crowding induction of cytokine production and cytokine production was enhanced by IL-2 and IFN-gamma. However, IFN-gamma-/- spleen cells exhibited similar crowding-induced colony-stimulating factor production to that of control spleen cells. Excess cell crowding inhibited cytokine production. This inhibition was not caused by receptor internalization of cytokines but may contribute to the failure to observe IL-3 production in lymphoid organs in vivo. Coculture of allogeneic spleen or peritoneal cells was a strong inducing signal for colony-stimulating factor production but this parameter was unable to detect autoreactivity of T lymphocytes in mice that lack suppressor of cytokine signaling 1 and exhibit T lymphocyte activation.

The lethal effects of transplantation of Socs1-/- bone marrow cells into irradiated adult syngeneic recipients.

Injection of neonatal bone marrow cells from mice lacking the gene encoding suppressor of cytokine signaling 1 (SOCS1) into irradiated syngeneic 129/Sv or C57BL/6 mice led to a decreased survival, more rapidly occurring in 129/Sv than in C57BL/6 mice. Moribund mice did not exhibit the acute or chronic diseases developed by Socs1-/- mice but developed a pathology characteristic of graft-versus-host disease with typical chronic inflammatory lesions in the liver, skin, lungs, and gut. The results indicate that cells derived from the Socs1-/- bone marrow are autoaggressive but did not identify the cell types involved. Failure of the engrafted Socs1-/- marrow cells to reproduce the tissue damage typical of Socs1-/- disease indicates that loss of SOCS1 from target tissues may also be required for the development of the Socs1-/- diseases, such as fatty degeneration of the liver, polymyositis, or corneal inflammation.

Polycystic kidneys and chronic inflammatory lesions are the delayed consequences of loss of the suppressor of cytokine signaling-1 (SOCS-1).

Mice with inactivation of the gene encoding the suppressor of cytokine signaling-1 (SOCS-1) die in neonatal life with an IFN-gamma-dependent inflammatory disease dominated by fatty degeneration and necrosis of the liver. To establish the long-term pathological consequences of loss of SOCS-1 in mice, where initial survival was made possible by also deleting the IFN-gamma gene, a comparison was made of the lifespan of groups of SOCS-1(-/-) IFN-gamma(-/-), SOCS-1(+/+) IFN-gamma(-/-) and SOCS-1(+/+) IFN-gamma(+/+) mice. Mice lacking the genes for both SOCS-1 and IFN-gamma exhibited an accelerated death rate compared with control groups. Disease states developing selectively in SOCS-1(-/-) IFN-gamma(-/-) mice were polycystic kidneys, pneumonia, chronic skin ulcers, and chronic granulomas in the gut and various other organs. Mice of all three groups developed cataracts, but disease development was accelerated in the groups lacking IFN-gamma. SOCS-1(-/-) IFN-gamma(-/-) mice exhibited a slightly increased predisposition to the development of T lymphoid leukemia, either spontaneous or radiation-induced. The development of polycystic kidneys may be caused by a developmental defect in renal-tubule organization noted in neonatal SOCS-1(-/-) mice. The chronic infections and granulomas of SOCS-1(-/-) IFN-gamma(-/-) mice may be based on autoaggression of SOCS-1(-/-) T lymphoid and related cells or a functional deficiency of these cells when lacking SOCS-1.