Project description:Increasing energy expenditure through activation of brown adipose tissue (BAT) thermogenesis is an attractive approach to counteract obesity. Thus, it is essential to understand molecular mechanisms that control BAT functions. Here, we describe signal transducer and activator of transcription (STAT) 5 as key regulator of BAT functionality. We found that STAT5 is necessary for acute cold-induced temperature maintenance and stimulated lipid breakdown in BAT using mice that harbour an adipocyte-specific deletion of Stat5a/b genes. In addition, the mitochondrial respiratory capacity of primary differentiated brown adipocytes from STAT5 deficient mice was diminished. We show that increased sensitivity to cold stress upon STAT5 deficiency was associated with reduced expression of thermogenic key player uncoupling protein 1, while decreased stimulated lipolysis of STAT5-deficient BAT explants was linked to decreased protein kinase A activity. In addition, brown remodeling of white fat was diminished following chronic β-adrenergic stimulation. This impairment was linked to a decrease in mitochondrial functionality. We conclude that STAT5 is essential for the β-adrenergic responsiveness of brown adipose tissue and the physiologic function of thermogenic adipose tissue.

Project description:The signal transducer and activator of transcription 5 (STAT5) is an attractive therapeutic target but successful targeting of STAT5 has proved to be difficult. We report herein the development of AK-2292 as a first, potent and selective small-molecule degrader of both STAT5A and STAT5B isoforms. AK-2292 induces degradation of STAT5A/B proteins with an outstanding selectivity over all other STAT proteins and >6,000 non-STAT proteins, leading to selective inhibition of STAT5 activity in cells. AK-2292 effectively induces STAT5 depletion in normal mouse tissues and human chronic myeloid leukemia (CML) xenograft tissues and achieves tumor regression in two CML xenograft mouse models at well-tolerated dose-schedules. AK-2292 is not only a powerful research tool with which to investigate the biology of STAT5 and therapeutic potential of selective STAT5 protein depletion and inhibition in vitro and in vivo, but also a promising lead compound toward ultimate development of a STAT5-targeted therapy.

Project description:Cytokine signaling via signal transducer and activator of transcription (STAT) proteins is crucial for optimal antiviral responses of natural killer (NK) cells. However, the pleiotropic effects of both cytokine and STAT signaling preclude the ability to precisely attribute molecular changes to either source. In this study, we employ a multi-“omics” approach to deconstruct and rebuild the complex interaction of three major STAT signaling pathways in NK cells. We uncover a global STAT4-STAT5 cooperative axis that is distinct and sometimes antagonistic to the STAT1 axis. We generate a network of STAT targets that highlights an integrated negative feedback loop, and demonstrate distinct STAT modes of epigenetic regulation. Finally, we identify shared signatures between mouse in vitro profiles and profiles from viral infection and humans, highlighting clinically translatable targets. Overall, we begin to unravel the intricate crosstalk between cytokine signaling pathways, and offer a valuable resource for improving cellular immunotherapy.

Project description:Cytokine signaling via signal transducer and activator of transcription (STAT) proteins is crucial for optimal antiviral responses of natural killer (NK) cells. However, the pleiotropic effects of both cytokine and STAT signaling preclude the ability to precisely attribute molecular changes to either source. In this study, we employ a multi-“omics” approach to deconstruct and rebuild the complex interaction of three major STAT signaling pathways in NK cells. We uncover a global STAT4-STAT5 cooperative axis that is distinct and sometimes antagonistic to the STAT1 axis. We generate a network of STAT targets that highlights an integrated negative feedback loop, and demonstrate distinct STAT modes of epigenetic regulation. Finally, we identify shared signatures between mouse in vitro profiles and profiles from viral infection and humans, highlighting clinically translatable targets. Overall, we begin to unravel the intricate crosstalk between cytokine signaling pathways, and offer a valuable resource for improving cellular immunotherapy.

Project description:Cytokine signaling via signal transducer and activator of transcription (STAT) proteins is crucial for optimal antiviral responses of natural killer (NK) cells. However, the pleiotropic effects of both cytokine and STAT signaling preclude the ability to precisely attribute molecular changes to either source. In this study, we employ a multi-“omics” approach to deconstruct and rebuild the complex interaction of three major STAT signaling pathways in NK cells. We uncover a global STAT4-STAT5 cooperative axis that is distinct and sometimes antagonistic to the STAT1 axis. We generate a network of STAT targets that highlights an integrated negative feedback loop, and demonstrate distinct STAT modes of epigenetic regulation. Finally, we identify shared signatures between mouse in vitro profiles and profiles from viral infection and humans, highlighting clinically translatable targets. Overall, we begin to unravel the intricate crosstalk between cytokine signaling pathways, and offer a valuable resource for improving cellular immunotherapy.

Project description:Cytokine signaling via signal transducer and activator of transcription (STAT) proteins is crucial for optimal antiviral responses of natural killer (NK) cells. However, the pleiotropic effects of both cytokine and STAT signaling preclude the ability to precisely attribute molecular changes to either source. In this study, we employ a multi-“omics” approach to deconstruct and rebuild the complex interaction of three major STAT signaling pathways in NK cells. We uncover a global STAT4-STAT5 cooperative axis that is distinct and sometimes antagonistic to the STAT1 axis. We generate a network of STAT targets that highlights an integrated negative feedback loop, and demonstrate distinct STAT modes of epigenetic regulation. Finally, we identify shared signatures between mouse in vitro profiles and profiles from viral infection and humans, highlighting clinically translatable targets. Overall, we begin to unravel the intricate crosstalk between cytokine signaling pathways, and offer a valuable resource for improving cellular immunotherapy.

Project description:Cytokine signaling via signal transducer and activator of transcription (STAT) proteins is crucial for optimal antiviral responses of natural killer (NK) cells. However, the pleiotropic effects of both cytokine and STAT signaling preclude the ability to precisely attribute molecular changes to either source. In this study, we employ a multi-“omics” approach to deconstruct and rebuild the complex interaction of three major STAT signaling pathways in NK cells. We uncover a global STAT4-STAT5 cooperative axis that is distinct and sometimes antagonistic to the STAT1 axis. We generate a network of STAT targets that highlights an integrated negative feedback loop, and demonstrate distinct STAT modes of epigenetic regulation. Finally, we identify shared signatures between mouse in vitro profiles and profiles from viral infection and humans, highlighting clinically translatable targets. Overall, we begin to unravel the intricate crosstalk between cytokine signaling pathways, and offer a valuable resource for improving cellular immunotherapy.

Project description:In several cancer types, STAT (Signal transducer and activator of transcription) transcription factors are constitutively activated. We previously identified a target gene, LPP/miR-28 (LIM domain containing preferred translocation partner in lipoma), induced by constitutive activation of STAT5, but not by transient cytokine-activated STAT5. Here, we demonstrate in transformed hematopoietic cells that binding of both STAT5B and p53 to chromatin is required for transcriptional activity of an alternative LPP/miR-28 promoter. Using a genome-wide approach, we identified 463 genomic positions at promoter regions where STAT5B and p53 are co-localized on the chromatin. At these positions, p53 chromatin binding is dependent on persistent STAT5B activation. The transcriptional activity of selected promoters bound by STAT5B and p53 was significantly changed upon STAT5 or p53 inhibition, and the transcription of these target genes is frequently altered in platelets of myeloproliferative neoplasm patients harboring mutations constitutively activating STAT5. These data suggest that the constitutive STAT5 activation recruits p53 in cancer cells and thereby activates oncogenic transcriptional programs. STAT5B and p53 ChIP-chip with or without JAK2 inhibition (ruxolitinib) to inhibit STAT5 phosphorylation and DNA binding.

Project description:Cytokine-activated STAT proteins dimerize and bind to high-affinity motifs, and N-terminal domain-mediated oligomerization of dimers allows tetramer formation and binding to low-affinity tandem motifs, but the functions of dimers versus tetramers are unknown. We generated Stat5a and Stat5b double knock-in (DKI) N-domain mutant mice that form dimers but not tetramers, identified cytokine-regulated genes whose expression required STAT5 tetramers, and defined consensus motifs for dimers versus tetramers. Whereas Stat5- deficient mice exhibited perinatal lethality, DKI mice were viable, indicating that STAT5 dimers were sufficient for survival. Nevertheless, STAT5 DKI mice had fewer CD4+CD25+ T cells, NK cells, and CD8+ T cells, with impaired cytokine-induced proliferation and homeostatic proliferation of CD8+ T cells. DKI CD8+ T cell proliferation following viral infection was diminished and DKI Treg cells did not efficiently control colitis. Thus, tetramerization of STAT5 is dispensable for survival but is critical for cytokine responses and normal immune function. T cells were extracted from spleen of wt and STAT5 double knocked in mice, and treated with IL-2. The cells were collected from 0h (without treatment), 2h, 6h and 17h, and chipped on Affy mouse 430 2.0 arrays.

Project description:During kidney diseases, diverse tissue-specific pathways can regulate kidney injury and prognosis. In our study, we focused on STAT5, a member of the Janus Kinase/ Signal Transducer and Activator of Transcription (JAK/STAT) pathway, classically described in immune cells which has been recently described in intrinsic kidney cells. STAT5 activation is detected in both human podocytes and tubular cells in FSGS and ATI, respectively. Additionally, STAT5 deficiency in either glomerular or tubular epithelium aggravates the functional and structural alterations in a range of experimental models of glomerular or tubular disease. Using RNA sequencing, we show here that STAT5b inactivation in HEK-293 cells resulted in dysregulation of multiple metabolic pathways, including glycolysis and oxidative phosphorylation. In conclusion, activating renal epithelial STAT5 represents a new therapeutic avenue with the potential for a range of beneficial effects in kidney disease.