Browsing by Subject "Protein Biosynthesis"

Now showing 1 - 7 of 7
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    Cellular metabolism constrains innate immune responses in early human ontogeny
    (Nature Research, 2018-11-16) Kan, Bernard; Michalski, Christina; Fu, Helen; Au, Hilda H.T.; Lee, Kelsey; Marchant, Elizabeth A.; Cheng, Maye F.; Anderson-Baucum, Emily; Aharoni-Simon, Michal; Tilley, Peter; Mirmira, Raghavendra G.; Ross, Colin J.; Luciani, Dan S.; Jan, Eric; Lavoie, Pascal M.; Medicine, School of Medicine
    Pathogen immune responses are profoundly attenuated in fetuses and premature infants, yet the mechanisms underlying this developmental immaturity remain unclear. Here we show transcriptomic, metabolic and polysome profiling and find that monocytes isolated from infants born early in gestation display perturbations in PPAR-γ-regulated metabolic pathways, limited glycolytic capacity and reduced ribosomal activity. These metabolic changes are linked to a lack of translation of most cytokines and of MALT1 signalosome genes essential to respond to the neonatal pathogen Candida. In contrast, they have little impact on house-keeping phagocytosis functions. Transcriptome analyses further indicate a role for mTOR and its putative negative regulator DNA Damage Inducible Transcript 4-Like in regulating these metabolic constraints. Our results provide a molecular basis for the broad susceptibility to multiple pathogens in these infants, and suggest that the fetal immune system is metabolically programmed to avoid energetically costly, dispensable and potentially harmful immune responses during ontogeny.
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    Maintenance of Pdx1 mRNA translation in islet β-cells during the unfolded protein response
    (The Endocrine Society, 2014-11) Templin, Andrew T.; Maier, Bernhard; Tersey, Sarah A.; Hatanaka, Masayuki; Mirmira, Raghavendra G.; Department of Pediatrics, IU School of Medicine
    In type 1 diabetes, proinflammatory cytokines secreted by infiltrating immune cells activate the unfolded protein response (UPR) in islet β-cells, which leads to attenuation of global mRNA translation. Under such conditions, privileged mRNAs required for adaptation to the prevailing stress are maintained in an actively translated state. Pdx1 is a β-cell transcription factor that is required for the adaptive UPR, but it is not known how translation of its mRNA is maintained under these conditions. To study translation, we established conditions in vitro with MIN6 cells and mouse islets and a mixture of proinflammatory cytokines (IL-1β, TNF-α, and IFN-γ) that mimicked the UPR conditions seen in type 1 diabetes. Cell extracts were then subjected to polyribosome profiling to monitor changes to mRNA occupancy by ribosomes. Similar to other privileged mRNAs (Atf4 and Chop), Pdx1 mRNA remained partitioned in actively translating polyribosomes under the UPR, whereas the mRNA encoding a proinsulin-processing enzyme (Cpe) and others partitioned into inactively translating monoribosomes. Bicistronic luciferase reporter analyses revealed that the distal portion of the 5'-untranslated region of mouse Pdx1 (between bp -105 to -280) contained elements that promoted translation under both normal and UPR conditions, and this region exhibited conserved sequences and secondary structure similar to those of other known internal ribosome entry sites. Our findings suggest that Pdx1 protein levels are maintained in the setting of the UPR, in part, through elements in the 5'-untranslated region that confer privileged mRNA translation in a 5'-7-methylguanylate cap-independent manner.
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    Palmitate induces mRNA translation and increases ER protein load in islet β-cells via activation of the mammalian target of rapamycin pathway
    (American Diabetes Association, 2014-10) Hatanaka, Masayuki; Maier, Bernhard; Sims, Emily K.; Templin, Andrew T.; Kulkarni, Rohit N.; Evans-Molina, Carmella; Mirmira, Raghavendra G.; Department of Medicine, IU School of Medicine
    Saturated free fatty acids (FFAs) have complex effects on the islet β-cell, acutely promoting adaptive hyperplasia but chronically impairing insulin release. The acute effects of FFAs remain incompletely defined. To elucidate these early molecular events, we incubated mouse β-cells and islets with palmitate and then studied mRNA translation by polyribosomal profiling and analyzed signaling pathways by immunoblot analysis. We found that palmitate acutely increases polyribosome occupancy of total RNA, consistent with an increase in mRNA translation. This effect on translation was attributable to activation of mammalian target of rapamycin (mTOR) pathways via L-type Ca(2+) channels but was independent of insulin signaling. Longer incubations led to depletion of polyribosome-associated RNA, consistent with activation of the unfolded protein response (UPR). Pharmacologic inhibition of mTOR suppressed both the acute effects of palmitate on mRNA translation and the chronic effects on the UPR. Islets from mice fed a high-fat diet for 7 days showed increases in polyribosome-associated RNA and phosphorylation of S6K, both consistent with activation of mTOR. Our results suggest that palmitate acutely activates mRNA translation and that this increase in protein load contributes to the later UPR.
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    Ribosome Reinitiation Directs Gene-specific Translation and Regulates the Integrated Stress Response
    (American Society for Biochemistry and Molecular Biology, 2015-11-20) Young, Sara K.; Willy, Jeffrey A.; Wu, Cheng; Sachs, Matthew S.; Wek, Ronald C.; Department of Biochemistry & Molecular Biology, IU School of Medicine
    Young, S. K., Willy, J. A., Wu, C., Sachs, M. S., & Wek, R. C. (2015). Ribosome Reinitiation Directs Gene-specific Translation and Regulates the Integrated Stress Response. The Journal of Biological Chemistry, 290(47), 28257–28271. http://doi.org/10.1074/jbc.M115.693184
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    Role of eIF2α Kinases in Translational Control and Adaptation to Cellular Stress
    (Cold Spring Harbor Laboratory Press, 2018-12-12) Wek, Ronald C.; Biochemistry and Molecular Biology, School of Medicine
    A central mechanism regulating translation initiation in response to environmental stress involves phosphorylation of the α subunit of eukaryotic initiation factor 2 (eIF2α). Phosphorylation of eIF2α causes inhibition of global translation, which conserves energy and facilitates reprogramming of gene expression and signaling pathways that help to restore protein homeostasis. Coincident with repression of protein synthesis, many gene transcripts involved in the stress response are not affected or are even preferentially translated in response to increased eIF2α phosphorylation by mechanisms involving upstream open reading frames (uORFs). This review highlights the mechanisms regulating eIF2α kinases, the role that uORFs play in translational control, and the impact that alteration of eIF2α phosphorylation by gene mutations or small molecule inhibitors can have on health and disease.