Project description:<p>Natural killer (NK) cells are forced to cope with different oxygen environments even under resting conditions. The adaptation to low oxygen is regulated by oxygen-sensitive transcription factors, the hypoxia-inducible factors (HIFs). The function of HIFs for NK cell activation and metabolic rewiring remains controversial. Activated NK cells are predominantly glycolytic, but the metabolic programs that ensure the maintenance of resting NK cells are enigmatic. By combining <em>in situ</em> metabolomic and transcriptomic analyses in resting murine NK cells, our study defines HIF-1a as a regulator of tryptophan metabolism and cellular nicotinamide adenine dinucleotide (NAD+) levels. The HIF-1a/NAD+ axis prevents ROS production during oxidative phosphorylation (OxPhos) and thereby blocks DNA damage and NK cell apoptosis under steadystate conditions. In contrast, in activated NK cells under hypoxia, HIF-1a is required for glycolysis, and forced HIF-1a expression boosts glycolysis and NK cell performance <em>in vitro</em> and <em>in vivo</em>. Our data highlight two distinct pathways by which HIF-1a interferes with NK cell metabolism. While HIF-1a-driven glycolysis is essential for NK cell activation, resting NK cell homeostasis relies on HIF-1a-dependent tryptophan/NAD+ metabolism.</p><p><br></p><p><strong>Linked cross omic data sets:</strong></p><p>RNA-seq data associated with this study are available in ArrayExpress (BioStudies): accession <a href='https://www.ebi.ac.uk/biostudies/arrayexpress/studies/E-MTAB-12082' rel='noopener noreferrer' target='_blank'>E-MTAB-12082</a>.</p>

Project description:NK cells are a promising cellular therapy for cancer, with challenges in the field including persistence, functional activity, and tumor recognition. Briefly priming blood NK cells with rhIL-12, rhIL-15, and rhIL-18 (12/15/18) results in memory-like NK cell differentiation and enhanced responses against cancer. We developed a novel platform centered upon an inert tissue factor scaffold for production of heteromeric fusion protein complexes (HFPC). The first use of this platform combined IL-12, IL-15 and IL-18 receptor engagement (HCW9201) and the second adds CD16 engagement (HCW9207). HCW9201 and HCW9207 stimulated activation and proliferation signals in NK cells, but HCW9207 had decreased IL-18 receptor signaling. RNAseq and multidimensional mass cytometry revealed strong parallels between HCW9201 and 12/15/18. Moreover, HCW9201 stimulation improved NK cell metabolic fitness, and resulted in the DNA methylation remodeling characteristic of memory-like differentiation. HCW9201- and 12/15/18-primed similar increases in short-term and memory-like NK cell cytotoxicity and IFN-g production against leukemia targets, as well as equivalent control of leukemia in NSG mice. Thus, HFPCs represent a protein engineering approach that solves many problems associated with multi-signal receptor engagement on immune cells, and HCW9201-primed NK cells will be advanced as an ideal approach for clinical GMP-grade memory-like NK cell production for cancer therapy.erm and memory-like NK cell cytotoxicity and IFN-g production against leukemia targets, as well as equivalent control of leukemia in NSG mice. Thus, HFPCs represent a protein engineering approach that solves many problems associated with multi-signal receptor engagement on immune cells, and HCW9201-primed NK cells will be advanced as an ideal approach for clinical GMP-grade memory-like NK cell production for cancer therapy.

Project description:Short-term hypoxia synergizes with interleukin 15 priming in driving glycolytic gene transcription and supports human natural killer cell activities.

Project description:IL-15 priming alters IFN-g regulation in murine NK cells.

Project description:NK cells are innate lymphoid cells that protect the host against malignant and infected cells. Activation with the cytokines IL-12, IL-15, and IL-18 induces NK cells to differentiate into memory-like NK cells that have enhanced function compared to conventional NK (cNK) cells. However, mechanisms governing their biology and whether all cNK cells become memory-like are unclear. We identified that IL-12/15/18 activation results in two main fates: reprogramming into enriched memory-like (eML) or priming into effector (eff)cNK cells. eML NK cells have distinct epigenetics, phenotype, and enhanced function (IFNγ, cytotoxicity) compared to cNK and effcNK cells. In contrast, effcNK cells transcriptionally and epigenetically resemble cNK cells. Furthermore, we identify that within cNK cells CD56bright and CD56dim NK cells are the origin of distinct subsets of eML NK cells. Moreover, these two subsets of eML NK cells persist within patients receiving ML NK cell therapy for several months. Thus, IL-12/15/18 activation of NK cells results in multiple cell fates, with epigenetic and transcriptional mechanisms orchestrating eML NK cell differentiation and function. These mechanistic insights provide new strategies to enhance NK cellular therapy.

Project description:NK cells are innate lymphoid cells that protect the host against malignant and infected cells. Activation with the cytokines IL-12, IL-15, and IL-18 induces NK cells to differentiate into memory-like NK cells that have enhanced function compared to conventional NK (cNK) cells. However, mechanisms governing their biology and whether all cNK cells become memory-like are unclear. We identified that IL-12/15/18 activation results in two main fates: reprogramming into enriched memory-like (eML) or priming into effector (eff)cNK cells. eML NK cells have distinct epigenetics, phenotype, and enhanced function (IFNγ, cytotoxicity) compared to cNK and effcNK cells. In contrast, effcNK cells transcriptionally and epigenetically resemble cNK cells. Furthermore, we identify that within cNK cells CD56bright and CD56dim NK cells are the origin of distinct subsets of eML NK cells. Moreover, these two subsets of eML NK cells persist within patients receiving ML NK cell therapy for several months. Thus, IL-12/15/18 activation of NK cells results in multiple cell fates, with epigenetic and transcriptional mechanisms orchestrating eML NK cell differentiation and function. These mechanistic insights provide new strategies to enhance NK cellular therapy.

Project description:NK cells are innate lymphoid cells that protect the host against malignant and infected cells. Activation with the cytokines IL-12, IL-15, and IL-18 induces NK cells to differentiate into memory-like NK cells that have enhanced function compared to conventional NK (cNK) cells. However, mechanisms governing their biology and whether all cNK cells become memory-like are unclear. We identified that IL-12/15/18 activation results in two main fates: reprogramming into enriched memory-like (eML) or priming into effector (eff)cNK cells. eML NK cells have distinct epigenetics, phenotype, and enhanced function (IFNγ, cytotoxicity) compared to cNK and effcNK cells. In contrast, effcNK cells transcriptionally and epigenetically resemble cNK cells. Furthermore, we identify that within cNK cells CD56bright and CD56dim NK cells are the origin of distinct subsets of eML NK cells. Moreover, these two subsets of eML NK cells persist within patients receiving ML NK cell therapy for several months. Thus, IL-12/15/18 activation of NK cells results in multiple cell fates, with epigenetic and transcriptional mechanisms orchestrating eML NK cell differentiation and function. These mechanistic insights provide new strategies to enhance NK cellular therapy.

Project description:As the principal effector cell population of the innate immune system, NK cells may make critical contributions to natural, immune-mediated control of HIV-1 replication. Using genome-wide assessments of activating and inhibitory epigenetic chromatin features, we here demonstrate that cytotoxic NK (cNK) cells from elite controllers (ECs) frequently display elevated activating histone modifications at the IL-2/IL-15 receptor β chain and the BCL-2 gene loci. These epigenetic changes translated into increased responsiveness of cNK cells to paracrine IL-15 secretion, which coincided with higher levels of IL-15 transcription by myeloid dendritic cells in ECs. The distinct immune crosstalk between these two innate immune cell populations resulted in improved IL-15-dependent cNK cell survival, paired with a metabolic profile biased towards IL-15-mediated glycolytic activities. Together, these results suggest that cNK cells from ECs display an epigenetically-programmed IL-15 response signature, and support the emerging role of innate immune pathways in natural, drug-free control of HIV-1.

Project description:As the principal effector cell population of the innate immune system, NK cells may make critical contributions to natural, immune-mediated control of HIV-1 replication. Using genome-wide assessments of activating and inhibitory epigenetic chromatin features, we here demonstrate that cytotoxic NK (cNK) cells from elite controllers (ECs) frequently display elevated activating histone modifications at the IL-2/IL-15 receptor β chain and the BCL-2 gene loci. These epigenetic changes translated into increased responsiveness of cNK cells to paracrine IL-15 secretion, which coincided with higher levels of IL-15 transcription by myeloid dendritic cells in ECs. The distinct immune crosstalk between these two innate immune cell populations resulted in improved IL-15-dependent cNK cell survival, paired with a metabolic profile biased towards IL-15-mediated glycolytic activities. Together, these results suggest that cNK cells from ECs display an epigenetically-programmed IL-15 response signature, and support the emerging role of innate immune pathways in natural, drug-free control of HIV-1.

Project description:Limited oxygen in solid tumors poses a challenge to successful immunotherapy with NK cells. NK cells have impaired cytotoxicity when cultured in hypoxia (1% oxygen), but not physiologic or atmospheric oxygen (>5%). We sought to analyze the impact of oxygen concentrations on human NK cell biology to determine what factors were driving loss of cytotoxicity and where there were opportunities to overcome hypoxia-induced dysfunction in NK cells.