Myeloid-committed Progenitors Research Articles

Nucleoporin Nup358 drives the differentiation of myeloid-biased multipotent progenitors by modulating HDAC3 nuclear translocation.

Nucleoporins, the components of nuclear pore complexes (NPCs), can play cell type- and tissue-specific functions. Yet, the physiological roles and mechanisms of action for most NPC components have not yet been established. We report that Nup358, a nucleoporin linked to several myeloid disorders, is required for the developmental progression of early myeloid progenitors. We found that Nup358 ablation in mice results in the loss of myeloid-committed progenitors and mature myeloid cells and the accumulation of myeloid-primed multipotent progenitors (MPPs) in bone marrow. Accumulated MPPs in Nup358 knockout mice are greatly restricted to megakaryocyte/erythrocyte-biased MPP2, which fail to progress into committed myeloid progenitors. Mechanistically, we found that Nup358 is required for histone deacetylase 3 (HDAC3) nuclear import and function in MPP2 cells and established that this nucleoporin regulates HDAC3 nuclear translocation in a SUMOylation-independent manner. Our study identifies a critical function for Nup358 in myeloid-primed MPP2 differentiation and uncovers an unexpected role for NPCs in the early steps of myelopoiesis.

Loss of Nudt15 thiopurine detoxification increases direct DNA damage in hematopoietic stem cells

Thiopurines, such as 6-mercaptopurine (6-MP), are widely used as cytotoxic agents and immunosuppressants for leukemia and autoimmune or inflammatory diseases. A nonsynonymous single nucleotide polymorphism (p.Arg139Cys; R139C) of the nucleoside diphosphate-linked moiety X-type motif 15 (NUDT15) gene causes the loss of thiopurine detoxification, inducing myelosuppression. To understand such hematotoxicity, we investigate the effects of NUDT15 R139C on hematopoietic stem cells (HSCs) upon thiopurine administration. Using previously established Nudt15R138C knock-in mice, which mimic myelosuppression in NUDT15R139C homozygous or heterozygous patients following thiopurine administration, we investigated the numerical changes of HSCs and hematopoietic progenitor cells following 6-MP administration using in vivo flowcytometry and ex vivo HSC expansion. Genes differentially expressed between Nudt15+/+ HSCs and Nudt15R138C/R138C HSCs were identified using RNA-sequencing before the emergence of 6-MP-induced HSC-damage. Gene Ontology (GO) and Transcriptional Regulatory Relationships Unraveled by Sentence-based Text Mining (TRRUST) analyses were performed to elucidate the molecular effects of 6-MP on HSCs. In Nudt15R138C/R138C mice, 6-MP induced exhaustion of HSCs faster than that of multipotent progenitors and as fast as that of myeloid-committed progenitors. Ex vivo-expanded Nudt15R138C/R138C HSCs were dose- and time-dependently damaged by 6-MP. GO analysis identified the DNA damage response and cell cycle process as the most strongly influenced processes in Nudt15R138C/R138C HSCs. TRRUST analysis revealed that the Trp53-regulated transcriptional regulatory network is influenced prior to HSC exhaustion in Nudt15R138C/R138C HSCs. The loss of NUDT15 thiopurine detoxification enhances thiopurine-mediated DNA damage via the Trp53 networks in HSCs. Therefore, caution is required in long-term thiopurine use in patients with NUDT15 R139C in view of its adverse effects on HSCs in the form of DNA damage.

Elucidating Lineage-Specific Myelotoxicity and Chromosomal Aberration Status in Hydroquinone- Exposed Hematopoietic Stem / Progenitor cells

Benzene exposure has been associated with hematotoxicity and leukemogenicity. However, the impact of benzene exposure on complex microenvironment of Hematopoetic Stem Cells (HSCs) niche, comprising of HSCs and lineage-specific progenitors remains elusive. Thus, a study on benzene-targeting HSCs niche could uncover mechanism linking benzene to HSCs niche alteration. This study evaluates the lineage-specific responses following exposure to a benzene metabolite, namely hydroquinone (HQ) in targeting HSCs and myeloid-committed progenitors. Freshly isolated murine bone marrow cells (BMCs) were exposed to HQ at series of concentrations (0 – 50 µM) for 24 hours; followed by cell viability analysis using MTT assay. Chromosomal aberration (CA) status was determined using karyotyping analysis. Expression of surface antigen for HSCs (Sca-1) was confirmed by flow cytometer. Lineage-specific myelotoxicity was studied using the colony-forming unit (CFU) assay for the following myeloid progenitors: CFU granulocyte /erythrocyte /macrophage /megakaryocyte (CFU-GEMM), CFU-granulocyte/macrophage (CFU-GM), CFU-granulocyte (CFU-G), CFU-macrophage (CFU-M), CFU-erythroid (CFU-E) and Burst-forming unit erythroid (BFU-E). HQ reduced (p<0.05) viability of BMCs at 25 µM and 50 µM with the IC10, IC25, and IC50 were at 17 µM, 23 µM and 35 µM, respectively. Increased (p<0.05) frequency of CA was observed in HQ-treated group as compared to control. Reduced (p<0.05) Sca-1+ cells at 17 µM, 23 µM and 35 µM indicates cytotoxic effect of HQ targeting HSCs population. Reduced (p<0.05) total colony counts were noted following HQ exposure at 6.25 µM and a complete inhibition of colony growth were observed at higher concentration (12.5 µM). HQ reduced (p<0.05) the growth of CFU-GEMM, CFU-GM and CFU-G at 6.25 µM, while the growth of CFU-M, CFU-E and BFU-E were not remarkably affected at lower concentrations (1.56 µM and 6.25 µM). Conclusively, HQ induces chromosomal aberration and cytotoxicity on HSCs with notable lineage-specific responses in governing benzene-mediated myelotoxicity targeting HSCs niche.

Abstract 736: Cell lineage-oriented clinical sequencing unveils distinct clonal ontogeny of acute myeloid leukemia with myelodysplasia-related changes

Abstract Acute myeloid leukemia (AML) is characterized by unregulated clonal expansion and maturation arrest of myeloid committed progenitors (MP). AML generally represents de novo onset or evolves from preceding myelodysplastic syndrome (MDS), which is defined by refractory cytopenias, clonal hematopoiesis, and/or multi-lineage dysplasia. The WHO classification 2008 includes this entity as “AML with myelodysplasia-related changes (AML-MRC)”, and currently, diagnosis of AML-MRC is based on either previous history of MDS, multi-lineage dysplasia, or MDS-related cytogenetic abnormality. However, AML-MRC often represents de novo onset without these MDS-compatible clinical features. Considering that AML-MRC exhibits rather poor prognosis with refractoriness to conventional chemotherapy against AML, more accurate and objective diagnostic approach is requisite to unveil hidden “MDS signatures” in patients with apparently de novo AML. A certain set of gene mutations is specific and recurrent in MDS. Given the pre-existing “MDS signatures”, the founder gene mutations might be detected in not only blast cells but also neutrophils and/or T cells in AML-MRC. To test this hypothesis, we performed FACS sorting of neutrophils, T cells, and blasts fractions, respectively, followed by mutation screening using targeted deep sequencing, namely, cell lineage-oriented sequencing (CLS). Genomic DNA both from each cell fraction and buccal swab was subjected to screening mutations in 54 genes which are tightly involved in MDS and AML. Pair-end deep sequencing was performed on an Illumina MiSeq, using library prepared by TruSight Myeloid Panel (Illumina, San Diego, CA). Bioinformatic analysis was performed by in-house pipeline. We performed CLS of clinically diagnosed AML-MRC (n=7), suspected AML-MRC (n=2), de novo AML (AML with t(15;17) or AML with inv16, n=4), MDS (RAEB-1 and RAEB-II, n=3), and familial MDS (n=1). As expected, in a familial MDS case, overlapping germline RUNX1 driver mutation was demonstrated in granulocytes, blast cells and T cells, supporting that it would be originated from a hematopoietic stem cell. Notably, in MDS, AML-MRC, and suspected AML-MRC cases with no germ-line mutations, the founder mutations present in neutrophils were also retained in the AML blast cells, irrespective of a history of MDS, suggesting that these are derived from a myeloid progenitor cell. In marked contrast, there were no overlapping driver mutations between blast cell and neutrophil fractions in de novo AML characterized by recurrent chromosomal abnormalities. In summary, CLS revealed that founder mutations are shared by neutrophils and AML blast cells in AML-MRC, but not in de novo AML. Although our data should be validated in a larger cohort of AML cases, CLS is a promising approach to molecular diagnosis of latent AML-MRC which require distinct therapeutic options from de novo AML. Citation Format: Kazuaki Yokoyama, Nozomi Yusa, Sousuke Nakamura, Mika Ito, Asako Kobayashi, Masayuki Kobayashi, Rika Kasajima, Hiroaki Yui, Eigo Shimizu, Atushi Niida, Rui Yamaguti, Tsuneo Ikenoue, Seiya Imoto, Yoichi Frukawa, Satoru Miyano, Arinobu Tojo. Cell lineage-oriented clinical sequencing unveils distinct clonal ontogeny of acute myeloid leukemia with myelodysplasia-related changes [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2017; 2017 Apr 1-5; Washington, DC. Philadelphia (PA): AACR; Cancer Res 2017;77(13 Suppl):Abstract nr 736. doi:10.1158/1538-7445.AM2017-736

Lineage-related and particle size-dependent cytotoxicity of chitosan nanoparticles on mouse bone marrow-derived hematopoietic stem and progenitor cells

Chitosan nanoparticles (CSNPs) have potential applications in stem cell research. In this study, exvivo cytotoxicity of CSNPs on mouse bone marrow-derived (MBMCs) hematopoietic stem and progenitor cells (HSPCs) was determined. MBMCs were exposed to CSNPs of different particle sizes at various concentrations for up to 72h. Cytotoxicity effect of CSNPs on MBMCs was determined using MTT, Live/Dead Viability/Cytotoxicity assays and flow cytometry analysis of surface antigens on HSCs (Sca-1(+)), myeloid-committed progenitors (CD11b(+), Gr-1(+)), and lymphoid-committed progenitors (CD45(+), CD3e(+)). At 24h incubation, MBMCs' viability was not affected by CSNPs. At 48 and 72h, significant reduction was detected at higher CSNPs concentrations. Small CSNPs (200nm) significantly reduced MBMCs' viability while medium-sized particle (∼400nm) selectively promoted MBMCs growth. Surface antigen assessment demonstrated lineage-dependent effect. Significant decrease in Sca-1(+) cells percentage was observed for medium-sized particle at the lowest CSNPs concentration. Meanwhile, reduction of CD11b(+) and Gr-1(+) cells percentage was detected at high and intermediate concentrations of medium-sized and large CSNPs. Percentage of CD45(+) and CD3e(+) cells along with ROS levels were not significantly affected by CSNPs. In conclusion, medium-sized and large CSNPs were relatively non-toxic at lower concentrations. However, further investigations are necessary for therapeutic applications.

Extramedullary Myelopoiesis in Malaria Depends on Mobilization of Myeloid-Restricted Progenitors by IFN-γ Induced Chemokines

Resolution of a variety of acute bacterial and parasitic infections critically relies on the stimulation of myelopoiesis leading in cases to extramedullary hematopoiesis. Here, we report the isolation of the earliest myeloid-restricted progenitors in acute infection with the rodent malaria parasite, Plasmodium chabaudi. The rapid disappearance of these infection-induced myeloid progenitors from the bone marrow (BM) equated with contraction of the functional myeloid potential in that organ. The loss of BM myelopoiesis was not affected by the complete genetic inactivation of toll-like receptor signaling. De-activation of IFN-γ signaling completely abrogated the contraction of BM myeloid progenitors. Radiation chimeras of Ifngr1-null and control BM revealed that IFN-γ signaling in an irradiation-resistant stromal compartment was crucial for the loss of early myeloid progenitors. Systemic IFN-γ triggered the secretion of C-C motif ligand chemokines CCL2 and CCL7 leading to the egress of early, myeloid-committed progenitors from the bone marrow mediated by their common receptor CCR2. The mobilization of myeloid progenitors initiated extramedullary myelopoiesis in the spleen in a CCR2-dependent manner resulting in augmented myelopoiesis during acute malaria. Consistent with the lack of splenic myelopoiesis in the absence of CCR2 we observed a significant persistence of parasitemia in malaria infected CCR2-deficient hosts. Our findings reveal how the activated immune system mobilizes early myeloid progenitors out of the BM thereby transiently establishing myelopoiesis in the spleen in order to contain and resolve the infection locally.

Dicer1 deletion in myeloid-committed progenitors causes neutrophil dysplasia and blocks macrophage/dendritic cell development in mice

MicroRNAs (miRNAs) have the potential to regulate cellular differentiation programs; however, miRNA deficiency in primary hematopoietic stem cells (HSCs) results in HSC depletion in mice, leaving the question of whether miRNAs play a role in early-lineage decisions un-answered. To address this issue, we deleted Dicer1, which encodes an essential RNase III enzyme for miRNA biogenesis, in murine CCAAT/enhancer-binding protein α (C/EBPA)-positive myeloid-committed progenitors in vivo. In contrast to the results in HSCs, we found that miRNA depletion affected neither the number of myeloid progenitors nor the percentage of C/EBPA-positive progenitor cells. Analysis of gene-expression profiles from wild-type and Dicer1-deficient granulocyte-macrophage progenitors (GMPs) revealed that 20 miRNA families were active in GMPs. Of the derepressed miRNA targets in Dicer1-null GMPs, 27% are normally exclusively expressed in HSCs or are specific for multipotent progenitors and erythropoiesis, indicating an altered gene-expression landscape. Dicer1-deficient GMPs were defective in myeloid development in vitro and exhibited an increased replating capacity, indicating the regained self-renewal potential of these cells. In mice, Dicer1 deletion blocked monocytic differentiation, depleted macrophages, and caused myeloid dysplasia with morphologic features of Pelger-Huët anomaly. These results provide evidence for a miRNA-controlled switch for a cellular program of self-renewal and expansion toward myeloid differentiation in GMPs.

All Hematopoietic Cells Develop from Hematopoietic Stem Cells through Flk2/Flt3-Positive Progenitor Cells

While it is clear that a single hematopoietic stem cell(HSC) is capable of giving rise to all other hematopoietic cell types, the differentiation paths beyond HSC remain controversial. Contradictory reports onthe lineage potential of progenitor populations have questioned their physiological contribution of progenitor populations to multilineage differentiation. Here, we established a lineage tracing mouse model that enabled direct assessment of differentiation pathways invivo. We provide definitive evidence that differentiation into all hematopoietic lineages, including megakaryocyte/erythroid cell types, involves Flk2-expressing non-self-renewing progenitors. A Flk2+ stage was used during steady-state hematopoiesis, after irradiation-induced stress and upon HSC transplantation. In contrast, HSC origin and maintenance do not include a Flk2+ stage. These data demonstrate that HSC specification and maintenance are Flk2 independent, and that hematopoietic lineage separation occurs downstream of Flk2 upregulation.

Loss of Tafazzin (TAZ) Function and Accelerated Apoptosis of Human Bone Marrow Stem and Myeloid Progenitors in Barth Syndrome.

Abstract Abstract 549 Barth syndrome (BTHS) is a severe X-linked stem cell disorder characterized by neutropenia, cardio- and skeletal myopathies, and growth retardation. Barth patients have a high rate of mortality due to progressive cardiomyopathy and/or overwhelming bacterial infections. Majority of Barth patients have mutations in the tafazzin (G4.5 or TAZ) gene that appear to truncate the tafazzin protein resulting in the loss of TAZ function. Based on protein homology, tafazzin is a phospholipid acyltransferase involved in remodeling cardiolipin (CL), the main lipid of the inner mitochondrial membrane. Therefore, BTHS patients exhibit reduced levels of total CL and accumulation of monolysocardiolipin. However, the function of TAZ protein and how these metabolic defects are triggered by TAZ mutations in BTHS remain largely unknown. The cellular or mouse models of this disorder are not availabel yet, and thus, the link between TAZ mutations and severe neutropenia in Barth syndrome remains elusive. Earlier study reported increased annexin V staining but absence of apoptosis in peripheral blood neutrophils. However, the patients' bone marrow stem and myeloid progenitor cells have not been examined. We hypothesized that TAZ mutations trigger accelerated apoptosis of bone marrow stem/progenitor cells, which in turn leads to reduced production of neutrophils in the bone marrow and severe neutropenia in Barth patients. To test this hypothesis, we used TAZ-specific shRNA to knock down the expression of the tafazzin gene in human myeloid progenitor HL60 cells and examined its effect on cell survival. Transfection of human myeloid progenitor cells with two different TAZ-specific but not control scrambled shRNA results in substantial down-regulation in the tafazzin expression level as determined by Western blot and confirmed by RT-PCR using TAZ and GAPDH-specific primers. Human myeloid progenitor cells with knocked down TAZ expression exhibit significantly elevated dissipation of mitochondrial membrane potential compared with control cells with scrambled shRNA as evidenced by flow cytometry analysis of DIOC6-labeled cells ((p&lt;0.0009, n=3). A remarkably significant increase in proportion of apoptotic annexin-positive cells was also observed in response to knock-down of TAZ expression in myeloid progenitor cells compared with control cells with scrambled shRNA (p&lt;0.0002, n=6). The observed increase in apoptosis in response to TAZ knock-down was caspase-3 dependent as evidenced by Western blot analysis. Treatment of the cells with caspase-specific inhibitor zVAD-fmk significantly improved cell survival characteristics to near normal level as determined by flow cytometry (p&lt;0.02, n=4). Interestingly, knock-down of TAZ expression in human lymphoid cells failed to affect their cell survival or mitochondrial membrane potential, indicating that the loss of TAZ function exhibits lineage-specific effect. Analysis of bone marrow-derived CD34+ stem cells from a Barth patient positive for TAZ mutation cultured 24h in the presence of 10% autologous serum revealed nearly 3-fold increase in proportion of apoptotic annexin V positive CD34+ cells compared with the same cell subpopulation from a healthy volunteer (36% in Barth vs 13% in ctrl). More differentiated CD15+ neutrophil precursors also exhibit substantially increased rate of apoptosis compared with control (Barth 27% vs ctrl 17%). CD33+ myeloid-committed progenitor cells from Barth patient do not show increased annexin V binding compared with corresponding cell subpopulation from a healthy volunteer, but demonstrate approximately 2-fold increase in dissipation of mitochondrial membrane potential compared with control donor cells. Thus, these data demonstrate that tafazzin functions as an anti-apoptotic protein, the loss of function of the TAZ gene is cytotoxic to hematopoietic cells, and that severe neutropenia in patients with Barth syndrome is due to accelerated apoptosis of bone marrow myeloid progenitor cells. Our data also reveal that caspase-specific inhibitors may represent potentially therapeutic agents capable of restoring normal production of myeloid cells in Barth Syndrome. Disclosures: No relevant conflicts of interest to declare.

A New Role for the Human Placenta as a Hematopoietic Site Throughout Gestation

We investigated whether the human placenta contributes to embryonic and fetal hematopoietic development. Two cell populations--CD34(++)CD45(low) and CD34( +)CD45(low)--were found in chorionic villi. CD34(++) CD45(low) cells display many markers that are characteristic of multipotent primitive hematopoietic progenitors and hematopoietic stem cells. Clonogenic in vitro assays showed that CD34(++)CD45( low) cells contained colony-forming units-culture with myeloid and erythroid potential and differentiated into CD56(+) natural killer cells and CD19(+) B cells in culture. CD34(+)CD45(low) cells were mostly enriched in erythroid- and myeloid-committed progenitors. While the number of CD34(++)CD45(low) cells increased throughout gestation in parallel with placental mass. However, their density (cells per gram of tissue) reached its peak at 5 to 8 weeks, decreasing more than 7-fold from the ninth week onward. In addition to multipotent progenitors, the placenta contained intermediate progenitors, indicative of active hematopoiesis. Together, these data suggest that the human placenta is potentially an important hematopoietic organ, opening the possibility of banking placental hematopoietic stem cells along with cord blood for transplantation.

Toll-like Receptors on Hematopoietic Progenitor Cells Stimulate Innate Immune System Replenishment

Toll-like receptors (TLRs) are best known for their ability to recognize microbial or viral components and initiate innate immune responses. We showed here that TLRs and their coreceptors were expressed by multipotential hematopoietic stem cells, whose cell cycle entry was triggered by TLR ligation. TLR expression also extended to some of the early hematopoietic progenitors, although not the progenitor cells dedicated to megakaryocyte and erythroid differentiation. TLR signaling via the Myd88 adaptor protein drove differentiation of myeloid progenitors, bypassing some normal growth and differentiation requirements, and also drove lymphoid progenitors to become dendritic cells. CD14 contributed to the efficiency of lipopolysaccharide (LPS) recognition by stem and progenitor cells, and LPS interacted directly with the TLR4/MD-2 complex on these cells in bone marrow. Thus, the preferential pathogen-mediated stimulation of myeloid differentiation pathways may provide a means for rapid replenishment of the innate immune system during infection.

Gene Expression Profiles for Normal Human Bone Marrow-Derived CD34+ Stem Cells and CD34−/CD33+ Myeloid-Committed Progenitor Cells in Response to Daily Granulocyte-Colony-Stimulating Factor (G-CSF) Treatment.

Abstract G-CSF is widely used to accelerate marrow recovery after cancer chemotherapy, to facilitate collection of hematopoietic progenitor cells, and to treat severe chronic neutropenia. Although G-CSF was originally defined as a stimulus for myeloid cell proliferation, it has potent anti-apoptotic properties, affects synthesis of proteins stored in neutrophil granules, and has many other effects on cells of the myeloid lineage. To improve understanding of the molecular and cellular effects of G-CSF, particularly related to its use for the treatment of severe chronic neutropenia, we performed gene expression profile studies using Affymetrix oligonucleotide arrays and purified bone marrow cell sub-populations from normal volunteers treated with daily subcutaneous G-CSF (300 mcg/sc/qd) for five days. Under local anaesthesia, paired marrow aspirates were obtained from the posterior iliac crest before and after 5 daily doses of G-CSF. CD34+ and CD34−/CD33+ cells were purified using Miltenyi immunomagnetic beads. Two rounds of amplification of total RNA isolated from purified CD34+ or CD33+cells was used to obtain sufficient cRNA for hybridization. Expression data from scanned chips were first analyzed using the RMA algorithm. The limma package of the Bioconductor project was used to identify differentially expressed genes. Limma uses an empirical Bayes method to moderate the standard errors of the estimated log-fold changes. The statistical analysis of CD33+ cells revealed that 150 of more than 12,000 genes examined were up- or down-regulated &amp;gt;2-fold in response to G-CSF treatment. The top 10 genes with up- or down-regulated level of expression include clusterin, neutrophil elastase, two transcription factors, gelsolin, Grb2, phospholipase D3, protein kinase C, the major vault protein, and serine-threonine kinase. In the myeloid-committed CD34-/CD33+ progenitor cells, genes with altered expression level represent those with gene products involved in the cell cycle, regulation of apoptosis, the cytoskeleton, the inflammatory response, or serine proteases and transcription factors. Most of the genes up-regulated in CD33+ cells (e.g. neutrophil elastase, phospholipase D, protein kinase C) were down-regulated in CD34-positive cells in response to G-CSF. The results of the comparative analyses revealed the normal signature gene expression profiles for CD34+ and CD34−/CD33+ cells and identified genes that may mediate specific G-CSF effects.

Flt3 ligand regulates dendritic cell development from Flt3+ lymphoid and myeloid-committed progenitors to Flt3+ dendritic cells in vivo.

Stimulation of Flt3 receptor tyrosine kinase through its cognate ligand expands early hematopoietic progenitor and dendritic cells (DCs) in humans and mice. The exact developmental stages at which hematopoietic progenitors express Flt3, are responsive to its ligand, and subsequently develop to DCs, are not known. Here we show that common lymphoid and common myeloid progenitors, as well as steady state DCs in thymus, spleen, and epidermis, express Flt3. The receptor is down-regulated once definitive B cell, T cell, and megakaryocyte/erythrocyte commitment occurs, and Flt3 is not detectable on other steady state hematopoietic cell populations. Upon in vivo Flt3 ligand (Flt3L) administration, Flt3+ progenitor cells and their progeny DCs are expanded, whereas Flt3− downstream progenitors are not, or are only slightly increased. Transplantation of common lymphoid and common myeloid progenitors and subsequent Flt3L injection increases progeny DCs of both precursor populations. These findings provide a definitive map of Flt3 expression in the hematopoietic hierarchy and directly demonstrate that Flt3L can drive DC development along both the lymphoid and myeloid developmental pathways from Flt3+ progenitors to Flt3+ DCs.

Mutant elastase in pathogenesis of cyclic and severe congenital neutropenia.

Severe neutropenia is characterized by maturation arrest of myeloid cells at the promyelocyte stage of hematopoiesis. We reported that accelerated apoptosis of bone marrow myeloid progenitor cells was observed in both cyclic (CN) and severe congenital neutropenia (SCN). Short and long-term cultures of bone marrow CD34+ cells revealed reduced production of multipotent progenitors in SCN. In contrast, production of these cells was slightly elevated in CN compared with CD34+ cells from healthy volunteers. Production of myeloid-committed progenitor cells was significantly reduced in both CN and SCN. FACS analysis of CD34+ cells revealed G /G cell cycle arrest in SCN but not in CN.(0) (1) All CN patients and more than 90% of SCN patients have mutation in the neutrophil elastase (NE) gene. Molecular modeling of NE tertiary structure indicates that mutations observed in SCN are primarily located around the glycosylation sites, whereas CN mutations affect predominantly the active site. Transient expression of CN- or SCN-specific mutant NE cDNA results in impaired survival of human myeloid progenitor cells compared with control cells transfected with intact NE cDNA. We hypothesize that abnormal processing and subcellular localization of mutant NE might predetermine the etiology of cyclic or severe congenital neutropenia.

Increased generation of dendritic cells from myeloid progenitors in autoimmune-prone nonobese diabetic mice.

Aberrant dendritic cell (DC) development and function may contribute to autoimmune disease susceptibility. To address this hypothesis at the level of myeloid lineage-derived DC we compared the development of DC from bone marrow progenitors in vitro and DC populations in vivo in autoimmune diabetes-prone nonobese diabetic (NOD) mice, recombinant congenic nonobese diabetes-resistant (NOR) mice, and unrelated BALB/c and C57BL/6 (BL/6) mice. In GM-CSF/IL-4-supplemented bone marrow cultures, DC developed in significantly greater numbers from NOD than from NOR, BALB/c, and BL/6 mice. Likewise, DC developed in greater numbers from sorted (lineage(-)IL-7Ralpha(-)SCA-1(-)c-kit(+)) NOD myeloid progenitors in either GM-CSF/IL-4 or GM-CSF/stem cell factor (SCF)/TNF-alpha. [(3)H]TdR incorporation indicated that the increased generation of NOD DC was due to higher levels of myeloid progenitor proliferation. Generation of DC with the early-acting hematopoietic growth factor, flt3 ligand, revealed that while the increased DC-generative capacity of myeloid-committed progenitors was restricted to NOD cells, early lineage-uncommitted progenitors from both NOD and NOR had increased DC-generative capacity relative to BALB/c and BL/6. Consistent with these findings, NOD and NOR mice had increased numbers of DC in blood and thymus and NOD had an increased proportion of the putative myeloid DC (CD11c(+)CD11b(+)) subset within spleen. These findings demonstrate that diabetes-prone NOD mice exhibit a myeloid lineage-specific increase in DC generative capacity relative to diabetes-resistant recombinant congenic NOR mice. We propose that an imbalance favoring development of DC from myeloid-committed progenitors predisposes to autoimmune disease in NOD mice.

Dendritic cell potentials of early lymphoid and myeloid progenitors

It has been proposed that there are at least 2 classes of dendritic cells (DCs), CD8alpha(+) DCs derived from the lymphoid lineage and CD8alpha(-) DCs derived from the myeloid lineage. Here, the abilities of lymphoid- and myeloid-restricted progenitors to generate DCs are compared, and their overall contributions to the DC compartment are evaluated. It has previously been shown that primitive myeloid-committed progenitors (common myeloid progenitors [CMPs]) are efficient precursors of both CD8alpha(+) and CD8alpha(-) DCs in vivo. Here it is shown that the earliest lymphoid-committed progenitors (common lymphoid progenitors [CLPs]) and CMPs and their progeny granulocyte-macrophage progenitors (GMPs) can give rise to functional DCs in vitro and in vivo. CLPs are more efficient in generating DCs than their T-lineage descendants, the early thymocyte progenitors and pro-T cells, and CMPs are more efficient DC precursors than the descendant GMPs, whereas pro-B cells and megakaryocyte-erythrocyte progenitors are incapable of generating DCs. Thus, DC developmental potential is preserved during T- but not B-lymphoid differentiation from CLP and during granulocyte-macrophage but not megakaryocyte-erythrocyte development from CMP. In vivo reconstitution experiments show that CLPs and CMPs can reconstitute CD8alpha(+) and CD8alpha(-) DCs with similar efficiency on a per cell basis. However, CMPs are 10-fold more numerous than CLPs, suggesting that at steady state, CLPs provide only a minority of splenic DCs and approximately half the DCs in thymus, whereas most DCs, including CD8alpha(+) and CD8alpha(-) subtypes, are of myeloid origin. (Blood. 2001;97:3333-3341)

Stroma-dependent maintenance of cytokine responsive hematopoietic progenitor cells derived from long-term bone marrow culture.

Hematopoietic cells maintained for long periods on primary cultures of bone marrow stromal cells formed cobblestone colonies (Dexter's long-term bone marrow culture, LTBC). These stably maintained hematopoietic cells (for 4 months) were transferred to a coculture on an established spleen stromal cell line (MSS62), and maintained under stromal cell layer, where they retained their invasive ability in the restricted space between the stromal cell layer and culture substratum (DFC culture). DFC contained lineage-negative (Lin-), c-Kit+, Sca-1- cells and spontaneously produced Mac-1+, Gr-1+ cells. DFC could not grow in the absence of MSS62 stromal cells, although, GM-CSF, IL-3, or IL-7 stimulated its growth. Production of granulocyte and monocytic cells was maintained by GM-CSF or IL-3 while it was decreased by IL-7. RT-PCR analysis showed that the IL-7 responsive cell population expressed early lymphoid markers (Ikaros, Pax-5, Oct-2, Rag-1, TdT, IL-7R and Imu), while lacking expression of receptors for G-CSF (G-CSFR) and for M-CSF (M-CSFR), or myeloperoxidase (MPO). These results suggested that DFC simultaneously contained lymphoid-committed progenitors and myeloid-committed progenitors, and that cytokines may expand their responding progenitor cells under the influence of signals provided by the stromal cells. Such a stromal cell-dependent culture system may be useful to analyze the switching mechanism from constitutive to inducible hematopoiesis in vitro.

Myelokathexis, a congenital disorder of severe neutropenia characterized by accelerated apoptosis and defective expression ofbcl-x in neutrophil precursors

Myelokathexis is a congenital disorder that causes severe chronic leukopenia and neutropenia. Characteristic findings include degenerative changes and hypersegmentation of mature neutrophils and hyperplasia of bone marrow myeloid cells. The associated neutropenia can be partially corrected by treatment with granulocyte colony-stimulating factor (G-CSF) or granulocyte–macrophage colony-stimulating factor (GM-CSF). These features led us to propose that accelerated apoptosis of neutrophil precursors might account for the neutropenic phenotype. Blood and bone marrow aspirates were obtained from 4 patients (2 unrelated families) with myelokathexis before G-CSF therapy and from 2 of the affected persons after G-CSF therapy (1 μg/kg per day subcutaneously for 3 weeks). Bone marrow was fractionated using immunomagnetic bead cell sorting into CD34+, CD33+/CD34−, and CD15+/CD34−/CD33− cell populations. Examination of these cells by flow cytometry and electron microscopy revealed abundant apoptosis in the CD15+ neutrophil precursor population, characterized by enhanced annexin-V binding, extensive membrane blebbing, condensation of heterochromatin, and cell fragmentation. Colony-forming assays demonstrated significant reduction in a proportion of bone marrow myeloid-committed progenitor cells. Immunohistochemical analysis revealed a selective decrease inbcl-x, but not bcl-2, expression in the CD15+/CD34−/CD33− cell population compared with similar subpopulations of control bone marrow-derived myeloid precursors. After G-CSF therapy, apoptotic features of patients' bone marrow cells were substantially reduced, and the absolute neutrophil counts (ANC) and expression ofbcl-x in CD15+/CD34−/CD33−cells increased. The authors concluded that myelokathexis is a disease characterized by the accelerated apoptosis of granulocytes and the depressed expression of bcl-x in bone marrow-derived granulocyte precursor cells. These abnormalities are partially corrected by the in vivo administration of G-CSF. (Blood. 2000;95:320-327)

Myelokathexis, a congenital disorder of severe neutropenia characterized by accelerated apoptosis and defective expression ofbcl-x in neutrophil precursors

Myelokathexis is a congenital disorder that causes severe chronic leukopenia and neutropenia. Characteristic findings include degenerative changes and hypersegmentation of mature neutrophils and hyperplasia of bone marrow myeloid cells. The associated neutropenia can be partially corrected by treatment with granulocyte colony-stimulating factor (G-CSF) or granulocyte-macrophage colony-stimulating factor (GM-CSF). These features led us to propose that accelerated apoptosis of neutrophil precursors might account for the neutropenic phenotype. Blood and bone marrow aspirates were obtained from 4 patients (2 unrelated families) with myelokathexis before G-CSF therapy and from 2 of the affected persons after G-CSF therapy (1 microg/kg per day subcutaneously for 3 weeks). Bone marrow was fractionated using immunomagnetic bead cell sorting into CD34(+), CD33(+)/CD34(-), and CD15(+)/CD34(-)/CD33(- )cell populations. Examination of these cells by flow cytometry and electron microscopy revealed abundant apoptosis in the CD15(+) neutrophil precursor population, characterized by enhanced annexin-V binding, extensive membrane blebbing, condensation of heterochromatin, and cell fragmentation. Colony-forming assays demonstrated significant reduction in a proportion of bone marrow myeloid-committed progenitor cells. Immunohistochemical analysis revealed a selective decrease in bcl-x, but not bcl-2, expression in the CD15(+)/CD34(-)/CD33(-)cell population compared with similar subpopulations of control bone marrow-derived myeloid precursors. After G-CSF therapy, apoptotic features of patients' bone marrow cells were substantially reduced, and the absolute neutrophil counts (ANC) and expression of bcl-x in CD15(+)/CD34(-)/CD33(-)cells increased. The authors concluded that myelokathexis is a disease characterized by the accelerated apoptosis of granulocytes and the depressed expression of bcl-x in bone marrow-derived granulocyte precursor cells. These abnormalities are partially corrected by the in vivo administration of G-CSF. (Blood. 2000;95:320-327)

High-level expression of the ER-MP58 antigen on mouse bone marrow hematopoietic progenitor cells marks commitment to the myeloid lineage.

Studies on the early events in the differentiation of the nonspecific immune system require the identification and isolation of myeloid-committed progenitor cells. Using the monoclonal antibodies (mAb) ER-MP12 and ER-MP20, generated against immortalized macrophage precursors, we have shown previously that the earliest macrophage colony-stimulating factor (M-CSF)-responsive cells in the bone marrow have the ER-MP12hi 20- phenotype. In addition, we found that the ER-MP12hi 20- subset (comprising about 2 % of total nucleated marrow) contains progenitor cells of all hematopoietic lineages. Aiming at the identification and purification of the myeloid progenitor cells within the ER-MP12hi 20-subset, we used ER-MP58, a marker expressed at high level by all M-CSF-responsive bone marrow progenitors. With this marker the ER-MP12hi 20- cell population could be divided into three subfractions: one with absent or low level ER-MP58 expression, one with intermediate, and one with high ER-MP58 expression. These subfractions were isolated by fluorescence-activated cell sorting and tested in vitro and in vivo for their differentiation capacities. In addition, the expression of ER-MP58 on stem cell subsets was examined in the cobblestone area-forming cell (CAFC) assay. Our data indicate that in the ER-MP12hi 20- subpopulation myeloid-committed progenitors are characterized by high-level expression of the ER-MP58 antigen, whereas cells with other or broader differentiation capacities have an ER-MP58 negative/low or intermediate phenotype. These myeloid-committed progenitors have no significant repopulating ability in vivo, in contrast to the ER-MP58 intermediate cells. Primitive CAFC-28/35, corresponding to cells providing long-term hematopoietic engraftment in vivo, also did not express the ER-MP58 Ag at a high level. Thus, cells committed to the myeloid lineage can be separated from progenitor cells with other differentiation capacities by means of multiparameter cell sorting using ER-MP58 in combination with ER-MP12 and ER-MP20.