SOCS3 Is a Critical Physiological Negative Regulator of G-CSF Signaling and Emergency Granulopoiesis

AbstractTo determine the importance of suppressor of cytokine signaling-3 (SOCS3) in the regulation of hematopoietic growth factor signaling generally, and of G-CSF-induced cellular responses specifically, we created mice in which the Socs3 gene was deleted in all hematopoietic cells. Although normal until young adulthood, these mice then developed neutrophilia and a spectrum of inflammatory pathologies. When stimulated with G-CSF in vitro, SOCS3-deficient cells of the neutrophilic granulocyte lineage exhibited prolonged STAT3 activation and enhanced cellular responses to G-CSF, including an increase in cloning frequency, survival, and proliferative capacity. Consistent with the in vitro findings, mutant mice injected with G-CSF displayed enhanced neutrophilia, progenitor cell mobilization, and splenomegaly, but unexpectedly also developed inflammatory neutrophil infiltration into multiple tissues and consequent hind-leg paresis. We conclude that SOCS3 is a key negative regulator of G-CSF signaling in myeloid cells and that this is of particular significance during G-CSF-driven emergency granulopoiesis

Aberrant actin depolymerization triggers the pyrin inflammasome and autoinflammatory disease that is dependent on IL-18, not IL-1beta

Gain-of-function mutations that activate the innate immune system can cause systemic autoinflammatory diseases associated with increased IL-1β production. This cytokine is activated identically to IL-18 by an intracellular protein complex known as the inflammasome; however, IL-18 has not yet been specifically implicated in the pathogenesis of hereditary autoinflammatory disorders. We have now identified an autoinflammatory disease in mice driven by IL-18, but not IL-1β, resulting from an inactivating mutation of the actin-depolymerizing cofactor Wdr1. This perturbation of actin polymerization leads to systemic autoinflammation that is reduced when IL-18 is deleted but not when IL-1 signaling is removed. Remarkably, inflammasome activation in mature macrophages is unaltered, but IL-18 production from monocytes is greatly exaggerated, and depletion of monocytes in vivo prevents the disease. Small-molecule inhibition of actin polymerization can remove potential danger signals from the system and prevents monocyte IL-18 production. Finally, we show that the inflammasome sensor of actin dynamics in this system requires caspase-1, apoptosis-associated speck-like protein containing a caspase recruitment domain, and the innate immune receptor pyrin. Previously, perturbation of actin polymerization by pathogens was shown to activate the pyrin inflammasome, so our data now extend this guard hypothesis to host-regulated actin-dependent processes and autoinflammatory disease.Man Lyang Kim, Jae Jin Chae, Yong Hwan Park, Dominic De Nardo, Roslynn A. Stirzaker ... Benjamin T Kile ... et al

The Transcription Factor PU.1 Controls a Reversible Differentiation Program in Acute Myeloid Leukemia

Abstract Background: Acute myeloid leukemia (AML) is an aggressive malignancy characterized by clonal expansion of transformed myeloid precursors that fail to differentiate into mature cells. Since myeloid lineage maturation curbs self-renewal and is considered irreversible, engaging this process in AML is an attractive therapeutic strategy. Results: Normal myeloid differentiation requires the transcription factor PU.1 (SPI1), which is functionally compromised in several AML subtypes and is directly inhibited by the recurrent fusion oncoproteins AML1-ETO and PML-RARA. To examine the importance of PU.1 suppression in AML maintenance in vivo, we have combined RNAi-mediated PU.1 inhibition with p53 deficiency to drive highly aggressive AML in mice. Using these models we find that restoring endogenous PU.1 activity in established AML in vivo is sufficient to trigger robust transcriptional, immunophenotypic, and morphological differentiation of leukemic blasts, yielding polymorphonuclear, neutrophil-like cells. Maturation of AML is associated with significant loss of cell viability and yields sustained disease clearance in vivo. Although PU.1 restoration is potently anti-leukemic, remarkably we find that subsequent suppression of PU.1 in mature neutrophil-like cells reverts them to a transformed state within several days. While mature AML-derived cells are slower to form blast colonies in methylcellulose cultures, their clonogenic frequency is only reduced four-fold relative to AML blasts suggesting highly efficient de-differentiation. Conclusions: These results demonstrate that triggering myeloid differentiation can effectively resolve a p53-deficient model of treatment resistant AML, but also identify a previously unrecognised ability of AML cells to bidirectionally transition between transformed and differentiated states based on the activity of a single transcription factor. Our findings challenge the concept of 'terminal differentiation' in AML and highlight the importance of therapeutically eradicating leukemia cells at all stages of myeloid lineage maturation. Disclosures No relevant conflicts of interest to declare

Aberrant actin depolymerization triggers the pyrin inflammasome and autoinflammatory disease that is dependent on IL-18, not IL-1β

Gain-of-function mutations that activate the innate immune system can cause systemic autoinflammatory diseases associated with increased IL-1β production. This cytokine is activated identically to IL-18 by an intracellular protein complex known as the inflammasome; however, IL-18 has not yet been specifically implicated in the pathogenesis of hereditary autoinflammatory disorders. We have now identified an autoinflammatory disease in mice driven by IL-18, but not IL-1β, resulting from an inactivating mutation of the actin-depolymerizing cofactor Wdr1. This perturbation of actin polymerization leads to systemic autoinflammation that is reduced when IL-18 is deleted but not when IL-1 signaling is removed. Remarkably, inflammasome activation in mature macrophages is unaltered, but IL-18 production from monocytes is greatly exaggerated, and depletion of monocytes in vivo prevents the disease. Small-molecule inhibition of actin polymerization can remove potential danger signals from the system and prevents monocyte IL-18 production. Finally, we show that the inflammasome sensor of actin dynamics in this system requires caspase-1, apoptosis-associated speck-like protein containing a caspase recruitment domain, and the innate immune receptor pyrin. Previously, perturbation of actin polymerization by pathogens was shown to activate the pyrin inflammasome, so our data now extend this guard hypothesis to host-regulated actin-dependent processes and autoinflammatory disease

An Erg-driven transcriptional program controls B cell lymphopoiesis

B cell development is tightly regulated in a stepwise manner to ensure proper generation of repertoire diversity via somatic gene rearrangements. Here, the authors show that a transcription factor, Erg, functions at the earliest stage to critically control two downstream factors, Ebf1 and Pax5, for modulating this gene rearrangement process