David B. Sykes

Pyocyanin and 1-hydroxyphenazine produced by Pseudomonas aeruginosa inhibit the beating of human respiratory cilia in vitro.

Pseudomonas aeruginosa culture filtrates varied in their ability to slow human ciliary beat frequency (7-71%). This activity did not correlate with known virulence factors. However, a close correlation (r = 0.97) existed between ciliary slowing and pigment content. In a prolonged culture, the increase in activity correlated (r = 0.94) with pigment accumulation. Gel filtration of lyophilized filtrate yielded a single peak of activity corresponding to the pigment fraction. Pyocyanin extracted from an active strain, and 1-hydroxyphenazine were purified by high performance liquid chromatography, and characterized by ultraviolet absorbance spectra and mass spectrometry. Both slowed cilia in a dose-dependent manner, and were synthesized and shown to be indistinguishable from the biological compounds. Pyocyanin caused gradual onset of slowing and ultimate widespread ciliostasis with epithelial disruption. 1-hydroxyphenazine caused rapid onset of ciliary slowing associated with dyskinesia and ciliostasis. Pyocyanin assayed within filtrates accounted for a significant proportion of the bioactivity present.

Quantitative production of macrophages or neutrophils ex vivo using conditional Hoxb8

Differentiation mechanisms and inflammatory functions of neutrophils and macrophages are usually studied by genetic and biochemical approaches that require costly breeding and time-consuming purification to obtain phagocytes for functional analysis. Because Hox oncoproteins enforce self-renewal of factor-dependent myeloid progenitors, we queried whether estrogen-regulated Hoxb8 (ER-Hoxb8) could immortalize macrophage or neutrophil progenitors that would execute normal differentiation and normal innate immune function upon ER-Hoxb8 inactivation. Here we describe methods to derive unlimited quantities of mouse macrophages or neutrophils by immortalizing their respective progenitors with ER-Hoxb8 using different cytokines to target expansion of different committed progenitors. ER-Hoxb8 neutrophils and macrophages are functionally superior to those produced by many other ex vivo differentiation models, have strong inflammatory responses and can be derived easily from embryonic day 13 (e13) fetal liver of mice exhibiting embryonic-lethal phenotypes. Using knockout or small interfering RNA (siRNA) technologies, this ER-Hoxb8 phagocyte maturation system represents a rapid analytical tool for studying macrophage and neutrophil biology.

Hoxa9 immortalizes a granulocyte-macrophage colony-stimulating factor-dependent promyelocyte capable of biphenotypic differentiation to neutrophils or macrophages, independent of enforced meis expression.

ABSTRACT The genes encoding Hoxa9 and Meis1 are transcriptionally coactivated in a subset of acute myeloid leukemia (AML) in mice. In marrow reconstitution experiments, coexpression of both genes produces rapid AML, while neither gene alone generates overt leukemia. Although Hoxa9 and Meis1 can bind DNA as heterodimers, both can also heterodimerize with Pbx proteins. Thus, while their coactivation may result from the necessity to bind promoters as heterodimers, it may also result from the necessity of altering independent biochemical pathways that cooperate to generate AML, either as monomers or as heterodimers with Pbx proteins. Here we demonstrate that constitutive expression of Hoxa9 in primary murine marrow immortalizes a late myelomonocytic progenitor, preventing it from executing terminal differentiation to granulocytes or monocytes in the presence of granulocyte-macrophage colony-stimulating factor (GM-CSF) or interleukin-3. This immortalized phenotype is achieved in the absence of endogenous or exogenous Meis gene expression. The Hoxa9-immortalized progenitor exhibited a promyelocytic transcriptional profile, expressing PU.1, AML1, c-Myb, C/EBP alpha, and C/EBP epsilon as well as their target genes, the receptors for GM-CSF, G-CSF, and M-CSF and the primary granule proteins myeloperoxidase and neutrophil elastase. G-CSF obviated the differentiation block of Hoxa9, inducing neutrophilic differentiation with accompanying expression of neutrophil gelatinase B and upregulation of gp91phox. M-CSF also obviated the differentiation block, inducing monocytic differentiation with accompanying expression of the macrophage acetyl-low-density lipoprotein scavenger receptor and F4/80 antigen. Versions of Hoxa9 lacking the ANWL Pbx interaction motif (PIM) also immortalized a promyelocytic progenitor with intrinsic biphenotypic differentiation potential. Therefore, Hoxa9 evokes a cytokine-selective block in differentiation by a mechanism that does not require Meisgene expression or interaction with Pbx through the PIM.

Nup98-HoxA9 immortalizes myeloid progenitors, enforces expression of Hoxa9, Hoxa7 and Meis1, and alters cytokine-specific responses in a manner similar to that induced by retroviral co-expression of Hoxa9 and Meis1.

The association between acute myeloid leukaemia (AML) and the aberrant expression of Hoxa9 is evidenced by (1) proviral activation of Hoxa9 and Meis1 in BXH-2 murine AML, (2) formation of the chimeric Nup98-HoxA9 transactivator protein as a consequence of the t(7;11) translocation in human AML, and (3) the strong expression of HoxA9 and Meis1 in human AML. In mouse models, enforced retroviral expression of Hoxa9 alone in marrow is not sufficient to cause rapid AML, while co-expression of Meis1 and Hoxa9 induces rapid AML. In contrast, retroviral expression of Nup98-HoxA9 is sufficient to cause rapid AML in the absence of enforced Meis1 expression. Previously, we demonstrated that Hoxa9 could block the differentiation of murine marrow progenitors cultured in granulocyte-macrophage colony-simulating factor (GM–CSF). These progenitors lacked Meis1 expression, could not proliferate in stem cell factor (SCF), but could differentiate into neutrophils when switched into granulocyte colony-simulating factor (G-CSF). Ectopic expression of Meis1 in these Hoxa9 cells suppressed their G-CSF-induced differentiation, permitted proliferation in SCF, and therein offered a potential explanation of cooperative function. Because Meis1 binds N-terminal Hoxa9 sequences that are replaced by Nup98, we hypothesized that Nup98-HoxA9 might consolidate the biochemical functions of both Hoxa9 and Meis1 on target gene promoters and might evoke their same lymphokine-responsive profile in immortalized progenitors. Here we report that Nup98-HoxA9, indeed mimicks Hoxa9 plus Meis1 coexpression – it immortalizes myeloid progenitors, prevents differentiation in response to GM–CSF, IL-3, G-CSF, and permits proliferation in SCF. Unexpectedly, however, Nup98-Hoxa9 also enforced strong transcription of the cellular Hoxa9, Hoxa7 and Meis1 genes at levels similar to those found in mouse AMLs generated by proviral activation of Hoxa9 and Meis1. Using Hoxa9−/− marrow, we demonstrate that expression of Hoxa9 is not required for myeloid immortalization by Nup98-HoxA9. Rapid leukaemogenesis by Nup98-HoxA9 may therefore result from both the intrinsic functions of Nup98-HoxA9, as well as of those of coexpressed HOX and MEIS1 genes.

SIRT1 regulates differentiation of mesenchymal stem cells by deacetylating β‐catenin

Mesenchymal stem cells (MSCs) are multi‐potent cells that can differentiate into osteoblasts, adipocytes, chondrocytes and myocytes. This potential declines with aging. We investigated whether the sirtuin SIRT1 had a function in MSCs by creating MSC specific SIRT1 knock‐out (MSCKO) mice. Aged MSCKO mice (2.2 years old) showed defects in tissues derived from MSCs; i.e. a reduction in subcutaneous fat, cortical bone thickness and trabecular volume. Young mice showed related but less pronounced effects. MSCs isolated from MSCKO mice showed reduced differentiation towards osteoblasts and chondrocytes in vitro, but no difference in proliferation or apoptosis. Expression of β‐catenin targets important for differentiation was reduced in MSCKO cells. Moreover, while β‐catenin itself (T41A mutant resistant to cytosolic turnover) accumulated in the nuclei of wild‐type MSCs, it was unable to do so in MSCKO cells. However, mutating K49R or K345R in β‐catenin to mimic deacetylation restored nuclear localization and differentiation potential in MSCKO cells. We conclude that SIRT1 deacetylates β‐catenin to promote its accumulation in the nucleus leading to transcription of genes for MSC differentiation.

An Induced Ets Repressor Complex Regulates Growth Arrest during Terminal Macrophage Differentiation

Defining the molecular mechanisms that coordinately regulate proliferation and differentiation is a central issue in development. Here, we describe a mechanism in which induction of the Ets repressor METS/PE1 links terminal differentiation to cell cycle arrest. Using macrophages as a model, we provide evidence that METS/PE1 blocks Ras-dependent proliferation without inhibiting Ras-dependent expression of cell type-specific genes by selectively replacing Ets activators on the promoters of cell cycle control genes. Antiproliferative effects of METS require its interaction with DP103, a DEAD box-containing protein that assembles a novel corepressor complex. Functional interactions between the METS/DP103 complex and E2F/ pRB family proteins are also necessary for inhibition of cellular proliferation, suggesting a combinatorial code that directs permanent cell cycle exit during terminal differentiation.

Meis1a suppresses differentiation by G-CSF and promotes proliferation by SCF: Potential mechanisms of cooperativity with Hoxa9 in myeloid leukemia

Hoxa9 and Meis1a are homeodomain transcription factors that heterodimerize on DNA and are down-regulated during normal myeloid differentiation. Hoxa9 and Meis1a cooperate to induce acute myeloid leukemia (AML) in mice, and are coexpressed in human AML. Despite their cooperativity in leukemogenesis, we demonstrated previously that retroviral expression of Hoxa9 alone—in the absence of coexpressed retroviral Meis1 or of expression of endogenous Meis genes—blocks neutrophil and macrophage differentiation of primary myeloid progenitors cultured in granulocyte–macrophage colony-stimulating factor (GM-CSF). Expression of Meis1 alone did not immortalize any factor-dependent marrow progenitor. Because HoxA9-immortalized progenitors still execute granulocytic differentiation in response to granulocyte CSF (G-CSF) and monocyte differentiation in response to macrophage CSF (M-CSF), we tested the possibility that Meis1a cooperates with Hoxa9 by blocking viable differentiation pathways unaffected by Hoxa9 alone. Here we report that Meis1a suppresses G-CSF-induced granulocytic differentiation of Hoxa9-immortalized progenitors, permitting indefinite self-renewal in G-CSF. Meis1a also reprograms Hoxa9-immortalized progenitors to proliferate, rather than die, in response to stem cell factor (SCF) alone. We propose that Meis1a and Hoxa9 are part of a molecular switch that regulates progenitor abundance by suppressing differentiation and maintaining self-renewal in response to different subsets of cytokines during myelopoiesis. The independent differentiation pathways targeted by Hoxa9 and Meis1a prompt a “cooperative differentiation arrest” hypothesis for a subset of leukemia, in which cooperating transcription factor oncoproteins block complementary subsets of differentiation pathways, establishing a more complete differentiation block in vivo.

The hematopoietic stem cell niche

Hematopoietic stem cells (HSCs) possess the ability to self-renew and to differentiate to mature progeny along multiple different hematopoietic lineages. The function of HSCs depends upon the signals from surrounding cells found within the highly specialized microenvironment termed the hematopoietic stem cell niche. Understanding and exploiting the HSC niche is a goal of basic scientists and clinicians alike. Recent studies have focused on defining the cellular components and molecular factors critical to this microenvironment. Here we review recent findings, discuss unresolved questions, and examine the clinical implications of our current knowledge of the HSC niche.

HoxB8 requires its Pbx-interaction motif to block differentiation of primary myeloid progenitors and of most cell line models of myeloid differentiation

HoxB8 was the first homeobox gene identified as a cause of leukemia. In murine WEHI3B acute myeloid leukemia (AML) cells, proviral integration leads to the expression of both HoxB8 and Interleukin (IL-3). Enforced expression of HoxB8 blocks differentiation of factor-dependent myeloid progenitors, while IL-3 co-expression induces autocrine proliferation and overt leukemogenicity. Previously, we demonstrated that HoxB8 binds DNA cooperatively with members of the Pbx family of transcription factors, and that HoxB8 makes contact with the Pbx homeodomain through a hexameric sequence designated the Pbx-interaction motif (PIM). E2a-Pbx1, an oncogenic derivative of Pbx1, both retains its ability to heterodimerize with Hox proteins and arrest myeloid differentiation. This observation prompts the question of whether E2a-Pbx1 and Hox oncoproteins use endogenous Hox and Pbx proteins, respectively, to target a common set of cellular genes. Here, we use four different models of neutrophil and macrophage differentiation to determine whether HoxB8 needs to bind DNA or Pbx cofactors in order to arrest myeloid differentiation. The ability of HoxB8 to bind DNA or to bind Pbx was essential (1) to block differentiation of factor-dependent myeloid progenitors from primary marrow; (2) to block IL-6-induced monocytic differentiation of M1-AML cells; and (3) to block granulocytic differentiation of GM-CSF-dependent ECoM-G cells. However, while DNA-binding was required, the HoxB8 Pbx-interaction motif was unnecessary for preventing macrophage differentiation of ECoM-M cells. We conclude that HoxB8 prevents differentiation by directly influencing cellular gene expression, and that the genetic context within a cell dictates whether the effect of HoxB8 is dependent on a physical interaction with Pbx proteins.

Control of signaling-mediated clearance of apoptotic cells by the tumor suppressor p53

Tumor suppressor p53 linked to immune function We thought we knew all we needed to about the tumor suppressor p53. However, Yoon et al. now describe a previously unrecognized function of p53 (see the Perspective by Zitvogel and Kroemer). p53 induces expression of the gene encoding DD1α, a receptor-like transmembrane protein of the immunoglobulin superfamily. In conditions of stress, p53 activation can lead to cell death. p53-induced expression of DD1α also promotes the clearance of dead cells by promoting engulfment by macrophages. Furthermore, expression of DD1α on T cells inhibits T cell function. Thus, p53 offers protection from inflammatory disease caused by the accumulation of apoptotic cells, and its suppression of T cells might help cancer cells to escape immune detection. Science, this issue 10.1126/science.1261669; see also p. 476 p53 promotes clearance of dead cells and proper immune function. [Also see Perspective by Zitvogel and Kroemer] INTRODUCTION Programmed cell death occurs throughout life in all tissues of the body, and more than a billion cells die every day as part of normal processes. Thus, rapid and efficient clearance of cell corpses is a vital prerequisite for homeostatic maintenance of tissue health. Failure to clear dying cells can lead to the accumulation of autoantigens in tissues that foster diseases, such as chronic inflammation, autoimmunity, and developmental abnormalities. In the normal immune system, phagocytic engulfment of apoptotic cells is accompanied by induction of a certain degree of immune tolerance in order to prevent self-antigen recognition. Over the past few decades, enormous efforts have been made toward understanding various mechanisms of tumor suppressor p53–mediated apoptosis. However, the involvement of p53 in postapoptosis has yet to be addressed. RATIONALE One of the most intriguing, yet enigmatic, questions in studying homeostatic control of efficient dead cell clearance and proper immune tolerance is how these two essential activities are interrelated: The complexity of these processes is demonstrated by the many receptors and signaling pathways involved in the engulfment of apoptotic cells and stringent discrimination of self antigens from nonself antigens. Thus, there must be key connection(s) linking the balance between immune homeostasis and inflammation. In addition to the antitumor functions of p53, p53 has been implicated in immune responses and inflammatory diseases, with various roles in the immune system becoming apparent. We identified a postapoptotic target gene of p53, Death Domain1α (DD1α), that is responsive to genotoxic stresses and expressed in immune cells. DD1α appears to function as an immunoregulator of T cell tolerance. We hypothesized that p53 controls signaling-mediated phagocytosis of apoptotic cells through its target, DD1α. We determined that DD1α functions as an engulfment ligand or receptor that is involved in homophilic intermolecular interaction at intercellular junctions of apoptotic cells and macrophages. We also addressed whether DD1α deficiency caused any defects in dead cell clearance in vivo. RESULTS DD1α has similarity with several members of the immunoglobulin superfamily with the extracellular immunoglobulin V (IgV) domain, such as TIM family proteins and an immune checkpoint regulator, PD-L1. We found that the p53 induction and maintenance of DD1α expression in apoptotic cells and its subsequent functional intercellular homophilic interaction between apoptotic cells and macrophages are required for engulfment of apoptotic cells. DD1α-deficient mice showed less reduction in organ size and cell number after ionizing radiation (IR), owing to defective dead cell clearance. DD1α-null mice are viable and indistinguishable in appearance from wild-type littermates at an early age. However, at a later age, DD1α deficiency resulted in the development of autoimmune phenotypes and prominent formation of immune infiltrates in the skin, lung, and kidney, which indicated an immune dysregulation and breakdown of self-tolerance in DD1α-null mice. We demonstrated that DD1α also plays an important role as an intercellular homophilic receptor on T cells, which suggests that DD1α is a key-connecting molecule linking postapoptotic processes to immune surveillance. We found that DD1α deficiency in T cells impaired DD1α-mediated inhibitory activity of T cell proliferation. These data indicate that potential homophilic DD1α interactions are important for the DD1α-mediated T cell inhibitory role. Therefore, the results indicate a role for p53 in regulating expression of immune checkpoint regulators, including PD-1, PD-L1, and DD1α. CONCLUSION We found that the tumor suppressor p53 controls signaling-mediated phagocytosis of apoptotic cells through its target DD1α, which suggests that p53 promotes both the proapoptotic pathway and postapoptotic events. DD1α functions as an engulfment ligand that engages in homophilic intermolecular interaction at intercellular junctions of apoptotic cells and macrophages. DD1α-deficient mice showed in vivo defects in clearing dying cells that led to damage to multiple organs indicative of immune dysfunction. p53-induced expression of DD1α is a vital phase for the phagocytic engulfment process of dead cells and then facilitates the stepwise priming of immune surveillance. As a downstream target of the tumor suppressor p53, DD1α activation may extend the repertoire of p53 activities to “guardian of the immune integrity.” p53-dependent accumulation of DD1α and its involvement in dead cell clearance and immune tolerance. DD1α functions as an engulfment ligand that participates in homophilic intermolecular interaction at intercellular junctions of apoptotic cells and phagocytes. p53 induction of DD1α is a critical step in ensuring proper clearance of cell corpses to warrant the efficient generation of precise immune responses, leading to immune tolerance. The inefficient clearance of dying cells can lead to abnormal immune responses, such as unresolved inflammation and autoimmune conditions. We show that tumor suppressor p53 controls signaling-mediated phagocytosis of apoptotic cells through its target, Death Domain1α (DD1α), which suggests that p53 promotes both the proapoptotic pathway and postapoptotic events. DD1α appears to function as an engulfment ligand or receptor that engages in homophilic intermolecular interaction at intercellular junctions of apoptotic cells and macrophages, unlike other typical scavenger receptors that recognize phosphatidylserine on the surface of dead cells. DD1α-deficient mice showed in vivo defects in clearing dying cells, which led to multiple organ damage indicative of immune dysfunction. p53-induced expression of DD1α thus prevents persistence of cell corpses and ensures efficient generation of precise immune responses.