Primary EBV+ nodal T/NK-cell lymphoma (PTCL-EBV) is a poorly understood disease which shows features resembling extranodal NK/T-cell lymphoma (ENKTL) and is currently not recognized as a distinct entity but categorized as a variant of PTCL-NOS. Herein, we analyzed copy-number aberrations (n=77) with focus on global measures of genomic instability (GI) and homologous recombination deficiency (HRD) and performed gene expression (n=84) and EBV miRNA expression profiling (n=24) and targeted mutational analysis (n=16) to further characterize PTCL-EBV in relation to ENKTL and PTCL-NOS. Multivariate analysis revealed a significantly worse outcome of PTCL-EBV compared to PTCL-NOS (P=0.002) but not ENKTL. Remarkably, PTCL-EBV exhibited significantly lower GI and HRD scores compared to ENKTL and PTCL-NOS. Gene Set Enrichment Analysis revealed many immune-related pathways, interferon alpha/gamma response, and IL6_JAK_STAT3 signaling to be significantly upregulated in PTCL-EBV and correlated with lower GI-scores. We also identified NFκB-associated genes, BIRC3, NFκB1 (p50) and CD27, and their proteins to be upregulated in PTCLEBV. PTCL-EBV demonstrated mostly type 2 EBV latency pattern and, strikingly, exhibited downregulated expression of most EBV miRNAs compared to ENKTL and their target genes were also enriched in immune-related pathways. PTCL-EBV also showed frequent mutations of TET2, PIK3CD and STAT3, and are microsatellite stable. Overall, the poor outcome, low genomic instability, upregulation of immune pathways and downregulation of EBV miRNAs are distinctive features of PTCL-EBV. Our data support the consideration of PTCL-EBV as a distinct entity, provide novel insights into the disease pathogenesis and offer potential new therapeutic targets for this tumor.
The differentiation of human pluripotent stem cells into pancreatic cells involves cellular proliferation and apoptosis during cell fate transitions. However, their implications for establishing cellular identity are unclear. Here, we profiled the expression of BCL-2 family of proteins during pancreatic specification and observed an upregulation of BCL-xL, downregulation of BAK and corresponding downregulation of cleaved CASP3 representative of apoptosis. Experimental inhibition of BCL-xL reciprocally increased apoptosis and resulted in a decreased gene expression of pancreatic markers despite a compensatory increase in anti-apoptotic protein BCL-2. RNA-Seq analyses then revealed a downregulation of multiple metabolic genes upon inhibition of BCL-xL. Follow-up bioenergetics assays revealed broad downregulation of both glycolysis and oxidative phosphorylation when BCL-xL was inhibited. Early perturbation of BCL-xL during pancreatic specification also had subsequent detrimental effects on the formation of INS + pancreatic beta-like cells. In conclusion, the more differentiated pancreatic progenitors are dependent on anti-apoptotic BCL-xL for survival, whereas the less differentiated pancreatic progenitors that survived after WEHI-539 treatment would exhibit a more immature phenotype. Therefore, modulation of the expression level of BCL-xL can potentially increase the survival and robustness of pancreatic progenitors that ultimately define human pancreatic beta cell mass and function.
Cell cycle progression and lipid metabolism are well-coordinated processes required for proper cell proliferation. In liver diseases that arise from dysregulated lipid metabolism, proliferation is diminished. To study the outcome of CDK1 loss and blocked hepatocyte proliferation on lipid metabolism and the consequent impact on whole-body physiology, we performed lipidomics, metabolomics, and RNA-seq analyses on a mouse model. We observed reduced triacylglycerides in liver of young mice, caused by oxidative stress that activated FOXO1 to promote expression of Pnpla2/ATGL. Additionally, we discovered that hepatocytes displayed malfunctioning β-oxidation, reflected by increased acylcarnitines (ACs) and reduced β-hydroxybutyrate. This led to elevated plasma free fatty acids (FFAs), which were transported to the adipose tissue for storage and triggered greater insulin secretion. Upon aging, chronic hyperinsulinemia resulted in insulin resistance and hepatic steatosis through activation of LXR. Here, we demonstrate that loss of hepatocyte proliferation is not only an outcome but also possibly a causative factor for liver pathology.
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