Your search keyword '"Stefan Moisyadi"' showing total 2 results

1. Upregulated ethanolamine phospholipid synthesis via selenoprotein I is required for effective metabolic reprogramming during T cell activation

Author

Chi Ma, FuKun W. Hoffmann, Michael P. Marciel, Kathleen E. Page, Melodie A. Williams-Aduja, Ellis N.L. Akana, Greg S. Gojanovich, Mariana Gerschenson, Johann Urschitz, Stefan Moisyadi, Vedbar S. Khadka, Sharon Rozovsky, Youping Deng, F. David Horgen, and Peter R. Hoffmann

Subjects

Selenium, Selenoprotein, Phosphatidylethanolamine, Ethanolamine phosphotransferase, Metabolic sensing, AMPK, Internal medicine, RC31-1245

Abstract

Objective: T cell activation triggers metabolic reprogramming to meet increased demands for energy and metabolites required for cellular proliferation. Ethanolamine phospholipid synthesis has emerged as a regulator of metabolic shifts in stem cells and cancer cells, which led us to investigate its potential role during T cell activation. Methods: As selenoprotein I (SELENOI) is an enzyme participating in two metabolic pathways for the synthesis of phosphatidylethanolamine (PE) and plasmenyl PE, we generated SELENOI-deficient mouse models to determine loss-of-function effects on metabolic reprogramming during T cell activation. Ex vivo and in vivo assays were carried out along with metabolomic, transcriptomic, and protein analyses to determine the role of SELENOI and the ethanolamine phospholipids synthesized by this enzyme in cell signaling and metabolic pathways that promote T cell activation and proliferation. Results: SELENOI knockout (KO) in mouse T cells led to reduced de novo synthesis of PE and plasmenyl PE during activation and impaired proliferation. SELENOI KO did not affect T cell receptor signaling, but reduced activation of the metabolic sensor AMPK. AMPK was inhibited by high [ATP], consistent with results showing SELENOI KO causing ATP accumulation, along with disrupted metabolic pathways and reduced glycosylphosphatidylinositol (GPI) anchor synthesis/attachment Conclusions: T cell activation upregulates SELENOI-dependent PE and plasmenyl PE synthesis as a key component of metabolic reprogramming and proliferation.

Published

2021

2. Effective Targeted Gene Knockdown in Mammalian Cells Using the piggyBac Transposase-based Delivery System

Author

Jesse B Owens, Juanita Mathews, Philip Davy, Ilko Stoytchev, Stefan Moisyadi, and Rich Allsopp

Subjects

cell line, piggyBac transposase, pmGENIE-3, RNA interference, telomerase, Therapeutics. Pharmacology, RM1-950

Abstract

Nonviral gene delivery systems are rapidly becoming a desirable and applicable method to overexpress genes in various types of cells. We have recently developed a piggyBac transposase-based, helper-independent and self-inactivating delivery system (pmGENIE-3) capable of high-efficiency transfection of mammalian cells including human cells. In the following study, we have assessed the potential of this delivery system to drive the expression of short hairpin RNAs to knock down genes in human cells. Two independent pmGENIE-3 vectors were developed to specifically target knockdown of an endogenous gene, telomerase reverse transcriptase (TERT), in telomerase-positive human immortalized cell lines. As compared with a transposase-deficient vector, pmGENIE-3 showed significantly improved short-term transfection efficiency (~4-fold enhancement, 48 hours posttransfection) and long-term integration efficiency (~5-fold enhancement) following antibiotic selection. We detected a significant reduction of both TERT expression and telomerase activity in both HEK293 and MCF-7 breast carcinoma cells transfected with two pmGENIE-3 construct targeting distinct regions of TERT. Importantly, this knockdown of expression was sufficient to abrogate telomerase function since telomeres were significantly shortened (3–4 Kb, P < 0.001) in both TERT-targeted cell lines following antibiotic selection of stable integrants. Together, these data show the capacity of the piggyBac nonviral delivery system to stably knockdown gene expression in mammalian cells and indicate the potential to develop novel tumor-targeting therapies.

Published

2013