Project description:Neutrophils can efficiently trigger cytotoxicity towards tumor cells and other target cells upon engagement of the IgA receptor CD89. However, the cell-intrinsic factors that influence the induction of cell death upon exposure to neutrophil effector mechanisms in vivo remain largely unknown. To uncover genetic regulators that influence target cell sensitivity to IgA-induced neutrophil-mediated killing, we used a human CD89 (hCD89) transgenic mouse model in which IgA-mediated killing of Her2-positive CD47-deficient murine target cells is mediated by neutrophils. Using a genome-wide in vivo screening approach, we demonstrate that deletion of the gene encoding inositol-tetrakisphosphate 1 kinase, ITPK1, increases survival of target cells in anti-Her2 IgA-treated mice. Moreover, we show that this effect depends on neutrophil activity and on the ITPK1 kinase domain. Notably, ITPK1 deficiency did not measurably impact survival of IgA-opsonized target cells in in vitro systems, underscoring the importance of in vivo screening systems to uncover physiologically relevant regulators of neutrophil killing.

Project description:Neutrophils can efficiently trigger cytotoxicity towards tumor cells and other target cells upon engagement of the IgA receptor CD89. However, the cell-intrinsic factors that influence the induction of cell death upon exposure to neutrophil effector mechanisms in vivo remain largely unknown. To uncover genetic regulators that influence target cell sensitivity to IgA-induced neutrophil-mediated killing, we used a human CD89 (hCD89) transgenic mouse model in which IgA-mediated killing of Her2-positive CD47-deficient murine target cells is mediated by neutrophils. Using a genome-wide in vivo screening approach, we demonstrate that deletion of the gene encoding inositol-tetrakisphosphate 1 kinase, ITPK1, increases survival of target cells in anti-Her2 IgA-treated mice. Moreover, we show that this effect depends on neutrophil activity and on the ITPK1 kinase domain. Notably, ITPK1 deficiency did not measurably impact survival of IgA-opsonized target cells in in vitro systems, underscoring the importance of in vivo screening systems to uncover physiologically relevant regulators of neutrophil killing.

Project description:Neutrophils can efficiently trigger cytotoxicity towards tumor cells and other target cells upon engagement of the IgA receptor CD89. However, the cell-intrinsic factors that influence the induction of cell death upon exposure to neutrophil effector mechanisms in vivo remain largely unknown. To uncover genetic regulators that influence target cell sensitivity to IgA-induced neutrophil-mediated killing, we used a human CD89 (hCD89) transgenic mouse model in which IgA-mediated killing of Her2-positive CD47-deficient murine target cells is mediated by neutrophils. Using a genome-wide in vivo screening approach, we demonstrate that deletion of the gene encoding inositol-tetrakisphosphate 1 kinase, ITPK1, increases survival of target cells in anti-Her2 IgA-treated mice. Moreover, we show that this effect depends on neutrophil activity and on the ITPK1 kinase domain. Notably, ITPK1 deficiency did not measurably impact survival of IgA-opsonized target cells in in vitro systems, underscoring the importance of in vivo screening systems to uncover physiologically relevant regulators of neutrophil killing.

Project description:ITPK1 sensitizes tumor cells to IgA-dependent neutrophil killing in vivo

Project description:ITPK1 sensitizes tumor cells to IgA-dependent neutrophil killing in vivo [RNA-seq]

Project description:ITPK1 sensitizes tumor cells to IgA-dependent neutrophil killing in vivo [CRISPR Epistasis]

Project description:ITPK1 sensitizes tumor cells to IgA-dependent neutrophil killing in vivo [CRISPR focused]

Project description:ITPK1 sensitizes tumor cells to IgA-dependent neutrophil killing in vivo [CRISPR genome-wide]

Project description:Mechanisms of neutrophil involvement in severe COVID-19 remain incompletely understood. Here we collect longitudinal blood samples from 306 hospitalized COVID-19+ patients and 86 controls, and perform bulk RNA-sequencing of enriched neutrophils, plasma proteomics, and high-throughput antibody profiling to investigate relationships between neutrophil states and disease severity. We identify dynamic switches between 6 distinct neutrophil subtypes. At days 3 and 7 post-hospitalization, patients with severe disease display a granulocytic myeloid-derived suppressor cell-like gene expression signature, while patients with resolving disease show a neutrophil progenitor-like signature. Humoral responses are identified as potential drivers of neutrophil effector functions, with elevated SARS-CoV-2-specific IgG1-to-IgA1 ratios in plasma of severe patients who survived. In vitro experiments confirm that while patient-derived IgG antibodies induce phagocytosis in healthy donor neutrophils, IgA antibodies predominantly induce neutrophil cell death. Overall, our study demonstrates a dysregulated myelopoietic response in severe COVID-19 and a potential role for IgA-dominant responses contributing to mortality.

Project description:Post-injury dysfunction of humoral immunity accounts for infections and poor outcome in cardiovascular diseases. Immunoglobulin A (IgA), the most abundant mucosal antibody is produced by plasma B cells in intestinal Peyer’s patches (PP) and lamina propria. Here, we show that stroke and myocardial ischemia (MI) patients had strongly reduced IgA blood levels. This was phenocopied in experimental mouse models where decreased plasma and fecal IgA were accompanied by rapid and macroscopic shrinkage of PP caused by substantial B cell loss. Stroke/MI triggered neutrophils to release neutrophil extracellular traps (NETs). Depletion of neutrophils, NET-degradation, or blockade of NET-release inhibited PP shrinkage and loss of B cells and IgA in stroke mice. Also, stroke and MI patients had higher amounts of circulating NETs, correlating with reduced IgA levels. Strikingly, stroke patients treated with DNase-I had reduced circulating NETs and stable IgA levels. Our results unveil how tissue-injury-triggered systemic NET release disrupts physiological IgA secretion and how this can be inhibited in patients.