Project description:Natural killer (NK) cells are critical for the immune response to cancer. However, solid tumor-infiltrating NK cells display reduced persistence and effector functions, limiting their clinical efficacy. To understand the mechanisms that induce Mouse NK cell dysfunction in solid tumors, we compared single-cell gene expression in patient-matched tumor-infiltrating compared to tumor-adjacent NK cells to identify unfolded protein response (UPR) genes associated with worse cancer patient survival. Primary Mouse NK cells accumulated unfolded proteins and induced a chronic UPR response to nutrient stress from the tumor microenvironment metabolome (TMM), sufficient to cause pronounced dysfunction and decreased persistence. Mechanistically, the transcription factor Fli1 epigenetically repressed UPR genes to limit Mouse NK cell proteostasis in the presence of the TMM. CRISPR-mediated Fli1 deletion enhanced unfolded protein clearance, persistence, and tumor control in vivo. Thus, our results suggest that the TMM is sufficient to induce Mouse NK cell dysfunction in solid tumors through the regulation of proteostasis.

Project description:Natural killer (NK) cells are critical for the immune response to cancer. However, solid tumor-infiltrating NK cells display reduced persistence and effector functions, limiting their clinical efficacy. To understand the mechanisms that induce human NK cell dysfunction in solid tumors, we compared single-cell gene expression in patient-matched tumor-infiltrating compared to tumor-adjacent NK cells to identify unfolded protein response (UPR) genes associated with worse cancer patient survival. Primary human NK cells accumulated unfolded proteins and induced a chronic UPR response to nutrient stress from the tumor microenvironment metabolome (TMM), sufficient to cause pronounced dysfunction and decreased persistence. Mechanistically, the transcription factor Fli1 epigenetically repressed UPR genes to limit human NK cell proteostasis in the presence of the TMM. CRISPR-mediated Fli1 deletion enhanced unfolded protein clearance, persistence, and tumor control in vivo. Thus, our results suggest that the TMM is sufficient to induce human NK cell dysfunction in solid tumors through the regulation of proteostasis.

Project description:Natural killer (NK) cells are critical for the immune response to cancer. However, solid tumor-infiltrating NK cells display reduced persistence and effector functions, limiting their clinical efficacy. To understand the mechanisms that induce Mouse NK cell dysfunction in solid tumors, we compared single-cell gene expression in patient-matched tumor-infiltrating compared to tumor-adjacent NK cells to identify unfolded protein response (UPR) genes associated with worse cancer patient survival. Primary Mouse NK cells accumulated unfolded proteins and induced a chronic UPR response to nutrient stress from the tumor microenvironment metabolome (TMM), sufficient to cause pronounced dysfunction and decreased persistence. Mechanistically, the transcription factor Fli1 epigenetically repressed UPR genes to limit Mouse NK cell proteostasis in the presence of the TMM. CRISPR-mediated Fli1 deletion enhanced unfolded protein clearance, persistence, and tumor control in vivo. Thus, our results suggest that the TMM is sufficient to induce Mouse NK cell dysfunction in solid tumors through the regulation of proteostasis.

Project description:Natural killer (NK) cells are critical for the immune response to cancer. However, solid tumor-infiltrating NK cells display reduced persistence and effector functions, limiting their clinical efficacy. To understand the mechanisms that induce human NK cell dysfunction in solid tumors, we compared single-cell gene expression in patient-matched tumor-infiltrating compared to tumor-adjacent NK cells to identify unfolded protein response (UPR) genes associated with worse cancer patient survival. Primary human NK cells accumulated unfolded proteins and induced a chronic UPR response to nutrient stress from the tumor microenvironment metabolome (TMM), sufficient to cause pronounced dysfunction and decreased persistence. Mechanistically, the transcription factor Fli1 epigenetically repressed UPR genes to limit human NK cell proteostasis in the presence of the TMM. CRISPR-mediated Fli1 deletion enhanced unfolded protein clearance, persistence, and tumor control in vivo. Thus, our results suggest that the TMM is sufficient to induce human NK cell dysfunction in solid tumors through the regulation of proteostasis.

Project description:Natural killer (NK) cells are critical for the immune response to cancer. However, solid tumor-infiltrating NK cells display reduced persistence and effector functions, limiting their clinical efficacy. To understand the mechanisms that induce human NK cell dysfunction in solid tumors, we compared single-cell gene expression in patient-matched tumor-infiltrating compared to tumor-adjacent NK cells to identify unfolded protein response (UPR) genes associated with worse cancer patient survival. Primary human NK cells accumulated unfolded proteins and induced a chronic UPR response to nutrient stress from the tumor microenvironment metabolome (TMM), sufficient to cause pronounced dysfunction and decreased persistence. Mechanistically, the transcription factor Fli1 epigenetically repressed UPR genes to limit human NK cell proteostasis in the presence of the TMM. CRISPR-mediated Fli1 deletion enhanced unfolded protein clearance, persistence, and tumor control in vivo. Thus, our results suggest that the TMM is sufficient to induce human NK cell dysfunction in solid tumors through the regulation of proteostasis.

Project description:Natural killer (NK) cells are critical for the immune response to cancer. However, solid tumor-infiltrating NK cells display reduced persistence and effector functions, limiting their clinical efficacy. To understand the mechanisms that induce human NK cell dysfunction in solid tumors, we compared single-cell gene expression in patient-matched tumor-infiltrating compared to tumor-adjacent NK cells to identify unfolded protein response (UPR) genes associated with worse cancer patient survival. Primary human NK cells accumulated unfolded proteins and induced a chronic UPR response to nutrient stress from the tumor microenvironment metabolome (TMM), sufficient to cause pronounced dysfunction and decreased persistence. Mechanistically, the transcription factor Fli1 epigenetically repressed UPR genes to limit human NK cell proteostasis in the presence of the TMM. CRISPR-mediated Fli1 deletion enhanced unfolded protein clearance, persistence, and tumor control in vivo. Thus, our results suggest that the TMM is sufficient to induce human NK cell dysfunction in solid tumors through the regulation of proteostasis.

Project description:Imbalances in endoplasmic reticulum (ER) proteostasis are associated with etiologically-diverse degenerative diseases linked to excessive extracellular protein misfolding and aggregation. Reprogramming of the ER proteostasis environment through genetic activation of the Unfolded Protein Response (UPR)-associated transcription factor ATF6 attenuates secretion and extracellular aggregation of amyloidogenic proteins. Here, we employed a screening approach that included complementary arm-specific UPR reporters and medium-throughput transcriptional profiling to identify non-toxic small molecules that phenocopy the ATF6-mediated reprogramming of the ER proteostasis environment. Comprehensive transcriptome analysis was employed to validate the capacity of three prioritized compounds to remodel the ER proteostasis environment, and to assess the prefential activation of ATF6 transcriptional targets relative to targets of the IRE1/XBP1s and PERK arms of the UPR. HEK293T-Rex and HEK293-DAX cells were treated for 6 hr with vehicle (DMSO), 1 µM Tg, 10 mM TMP (in HEK293DAX), or 10 µM 132, 147 or 263 in biological triplicate at 37 ̊C

Project description:The unfolded protein response (UPR) maintains endoplasmic reticulum (ER) proteostasis through the activation of transcription factors such as XBP1s and ATF6. The functional consequences of these transcription factors for ER proteostasis remain poorly defined. Here, we describe methodology that enables orthogonal, small molecule-mediated activation of the UPR-associated transcription factors XBP1s and/or ATF6 in the same cell independent of stress. We employ transcriptomics and quantitative proteomics to evaluate ER proteostasis network remodeling owing to the XBP1s and/or ATF6 transcriptional programs. Furthermore, we demonstrate that the three ER proteostasis environments accessible by activating XBP1s and/or ATF6 differentially influence the folding, trafficking, and degradation of destabilized ER client proteins without globally affecting the endogenous proteome. Our data reveal how the ER proteostasis network is remodeled by the XBP1s and/or ATF6 transcriptional programs at the molecular level and demonstrate the potential for selectively restoring aberrant ER proteostasis of pathologic, destabilized proteins through arm-selective UPR-activation. The unfolded protein response adapts endoplasmic reticulum (ER) proteostasis via stress-responsive transcription factors including XBP1s and ATF6. Here, R. Luke Wiseman and colleagues implement technology for the orthogonal, ligand-dependent activation of XBP1s and/or ATF6 in a single cell. They characterize how XBP1s and/or ATF6 activation impacts ER proteostasis pathway composition and function. Adapted ER environments influence the proteostasis of destabilized protein variants without affecting the endogenous proteome. The work informs the development of proteostasis environment-adapting therapeutics for protein misfolding-related diseases. In order to activate both XBP1s and ATF6 in the same cell, we incorporated DHFR.ATF6 and tet-inducible XBP1s into a HEK293T-REx cell line stably expressing the tet-repressor. The HEK293DYG control cell line expresses tet-inducible eGFP and DHFR.YFP and is used as a control to demonstrate that the addition of doxycycline (dox) and trimethoprim (TMP) do not induce UPR genes. HEK293DYG cells were treated for 12 h with vehicle or 1 μg/mL dox and 10 μM TMP in biological triplicate. Cells were harvested and RNA was extracted using the RNeasy Mini Kit (Qiagen). Genomic DNA was removed by on-column digestion using the RNase-free DNase Set (Qiagen). Data from HEK293DYG cells showed no significant overlap in the ligand-treated transcriptomes obtained from HEK293DAX cells.

Project description:The unfolded protein response (UPR) maintains endoplasmic reticulum (ER) proteostasis through the activation of transcription factors such as XBP1s and ATF6. The functional consequences of these transcription factors for ER proteostasis remain poorly defined. Here, we describe methodology that enables orthogonal, small molecule-mediated activation of the UPR-associated transcription factors XBP1s and/or ATF6 in the same cell independent of stress. We employ transcriptomics and quantitative proteomics to evaluate ER proteostasis network remodeling owing to the XBP1s and/or ATF6 transcriptional programs. Furthermore, we demonstrate that the three ER proteostasis environments accessible by activating XBP1s and/or ATF6 differentially influence the folding, trafficking, and degradation of destabilized ER client proteins without globally affecting the endogenous proteome. Our data reveal how the ER proteostasis network is remodeled by the XBP1s and/or ATF6 transcriptional programs at the molecular level and demonstrate the potential for selectively restoring aberrant ER proteostasis of pathologic, destabilized proteins through arm-selective UPR-activation. The unfolded protein response adapts endoplasmic reticulum (ER) proteostasis via stress-responsive transcription factors including XBP1s and ATF6. Here, R. Luke Wiseman and colleagues implement technology for the orthogonal, ligand-dependent activation of XBP1s and/or ATF6 in a single cell. They characterize how XBP1s and/or ATF6 activation impacts ER proteostasis pathway composition and function. Adapted ER environments influence the proteostasis of destabilized protein variants without affecting the endogenous proteome. The work informs the development of proteostasis environment-adapting therapeutics for protein misfolding-related diseases. In order to activate both XBP1s and ATF6 in the same cell, we incorporated DHFR.ATF6 and tet-inducible XBP1s into a HEK293T-REx cell line stably expressing the tet-repressor. Selection of a single colony resulted in the HEK293DAX cell line in which XBP1s is induced by doxycycline and DHFR.ATF6 is activated by trimethoprim (TMP; TMP-dependent DHFR.ATF6 activation in HEK293DAX cells will henceforth be referred to as ATF6 activation for simplicity). HEK293DAX cells were treated for 12 h with vehicle, 1 ?g/mL dox, 10 ?M TMP, or both in biological triplicate. Cells were harvested and RNA was extracted using the RNeasy Mini Kit (Qiagen). Genomic DNA was removed by on-column digestion using the RNase-free DNase Set (Qiagen). Data from HEK293DYG cells showed no significant overlap in the ligand-treated transcriptomes obtained from the control HEK293DYG cells.

Project description:Imbalances in endoplasmic reticulum (ER) proteostasis are associated with etiologically-diverse degenerative diseases linked to excessive extracellular protein misfolding and aggregation. Reprogramming of the ER proteostasis environment through genetic activation of the Unfolded Protein Response (UPR)-associated transcription factor ATF6 attenuates secretion and extracellular aggregation of amyloidogenic proteins. Here, we employed a screening approach that included complementary arm-specific UPR reporters and medium-throughput transcriptional profiling to identify non-toxic small molecules that phenocopy the ATF6-mediated reprogramming of the ER proteostasis environment. Comprehensive transcriptome analysis was employed to validate the capacity of three prioritized compounds to remodel the ER proteostasis environment, and to assess the prefential activation of ATF6 transcriptional targets relative to targets of the IRE1/XBP1s and PERK arms of the UPR.