An Oncogenic Role for the Phosphorylated h-Subunit of Human Translation Initiation Factor eIF3

Zhang, Lili; Smit-McBride, Zeljka; Pan, Xiaoyu; Rheinhardt, Jeanette; Hershey, John W.B.

doi:10.1074/jbc.m800956200

Cited by 80 publications

(64 citation statements)

References 36 publications

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“…Further evidence implicating eIF3h levels in cancer comes from experiments that reduce the level of eIF3h in a prostate cell line that exhibits high eIF3h levels. Down-regulation of eIF3h causes the cells to lose their ability for anchorage-independent growth and to become more susceptible to apoptosis (57). The results indicate that elevated levels of eIF3h are required to maintain the cancerous state of these prostate-derived cells.…”

Section: Regulation Of Eif3 Is Important In Controlling Cell Prolifermentioning

confidence: 79%

“…Nor is it clear how overexpression of the 3h or 3i subunit, which does not alter the level of eIF3, stimulates protein synthesis and cell proliferation. Further experiments with a stable cell line where eIF3h synthesis can be induced show that the malignant phenotypes emerge within about 8 h of induction, just as the level of eIF3h and the tightly coupled rate of protein synthesis increase, suggesting that protein synthesis is directly involved (57). However, no malignant transformation occurred with induced overexpression of a mutant form of eIF3h, where Ser-183 is changed to alanine to prevent phosphorylation at that site, indicating that phosphorylation of eIF3h is required for induction of malignancy.…”

Section: Regulation Of Eif3 Is Important In Controlling Cell Prolifermentioning

confidence: 99%

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Regulation of protein synthesis and the role of eIF3 in cancer

Hershey¹

2010

Braz J Med Biol Res

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Section: Regulation Of Eif3 Is Important In Controlling Cell Prolifermentioning

confidence: 79%

Section: Regulation Of Eif3 Is Important In Controlling Cell Prolifermentioning

confidence: 99%

Regulation of protein synthesis and the role of eIF3 in cancer

Hershey¹

2010

Braz J Med Biol Res

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“…18 Two eIF3 core subunits, eIF3A and eIF3H, were chosen, both of which are suggested to be involved in translation of certain mRNAs. 58,59,63,99 Furthermore, eIF3A, the largest and conserved eIF3 subunit, may control the assembly and stability of eIF3 as well as the formation of different sub-complexes with additional functions within the mammalian cells. 64,100 However, differently from the Drosophila homolog, ABCE1 silencing in our system did not reduce the levels of eIF3A and eIF3H (Fig.…”

Section: Discussionmentioning

confidence: 99%

ABCE1 is essential for S phase progression in human cells

et al. 2016

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ABCE1 is a highly conserved protein universally present in eukaryotes and archaea, which is crucial for the viability of different organisms. First identified as RNase L inhibitor, ABCE1 is currently recognized as an essential translation factor involved in several stages of eukaryotic translation and ribosome biogenesis. The nature of vital functions of ABCE1, however, remains unexplained. Here, we study the role of ABCE1 in human cell proliferation and its possible connection to translation. We show that ABCE1 depletion by siRNA results in a decreased rate of cell growth due to accumulation of cells in S phase, which is accompanied by inefficient DNA synthesis and reduced histone mRNA and protein levels. We infer that in addition to the role in general translation, ABCE1 is involved in histone biosynthesis and DNA replication and therefore is essential for normal S phase progression. In addition, we analyze whether ABCE1 is implicated in transcript-specific translation via its association with the eIF3 complex subunits known to control the synthesis of cell proliferation-related proteins. The expression levels of a few such targets regulated by eIF3A, however, were not consistently affected by ABCE1 depletion.

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“…Interestingly, the human ortholog of eIF3h is highly expressed in many cancer cells, and its high levels trigger dysregulation of protein synthesis. This oncogenic potential of eIF3h is strongly enhanced by phosphorylation at the conserved residue Ser-183 (Zhang et al, 2008). Recent research revealed that translation regulation via uORFs contributes to plant development, playing important roles in organogenesis.…”

Section: Role Of Tor In Regulation Of Translation Of Specific Mrnas Mmentioning

confidence: 99%

Recent Discoveries on the Role of TOR (Target of Rapamycin) Signaling in Translation in Plants

Schepetilnikov

Ryabova

2017

Plant Physiol.

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Protein synthesis is an intricate, energy-demanding, and tightly controlled process that plays a fundamental role in cell growth, proliferation, and differentiation. The target of rapamycin (TOR) protein kinase integrates stress-, nutrient-, and energy-related signals to optimize protein synthesis outputs. In mammals, TOR is a main controller of capped mRNA translation; how TOR participates in translation initiation in plants is unclear, but active TOR is required for regulation of translation of mRNA with 59-untranslated region (59-UTR) upstream open reading frames (uORFs)-known translation regulatory elements in eukaryotes. Recent data implicates diverse signals such as stress, hormones, and metabolites in regulation of TOR signal transduction pathways and, thus, in response to environmental stress. Here, we review current knowledge of plant TOR complex composition and activation, and its function in translation, compiling data on downstream processes that are under stringent control of TOR in mammals but not yet investigated in plants.Plants have evolved various adaptation mechanisms to ensure their optimal growth, with plant development and behavior being strongly responsive to various external and internal stimuli. By monitoring their environment, plants trigger signal transduction cascades in order to regulate downstream cellular processes, mainly via protein synthesis-a major energy-consuming process (Buttgereit and Brand, 1995). The TOR protein kinase integrates extracellular signals (hormones, biotic and abiotic stresses, growth factors) together with intracellular nutrient availability and energy status to control protein synthesis and other anabolic processes if conditions are favorable, and represses catabolic processes such as autophagy (Albert and Hall, 2015). The past 10 years has boosted research on plant TOR complex composition, highlighted TOR upstream signals and downstream targets, and revealed an interplay between TOR signaling and hormonal, stress, and other pathways in photosynthetic organisms. We are beginning to understand how TOR is activated, and how it controls many cellular processes, such as transcription, translation, and autophagy. Here, we give an overview of recent results on the role of TOR in plant translation control and draw the reader's attention to future questions to address. In plants, inactivation of TOR correlates with a decrease in total polysomal levels (Deprost et al., 2007;Schepetilnikov et al., 2011Schepetilnikov et al., , 2013, strongly suggesting a role for TOR in plant translation. Although a role for TOR in global translation in plants has been documented, the players and mechanisms used to influence different steps of translation initiation -the step most controlled by TOR in mammals-are only starting to emerge. Here, we summarize the current state of knowledge of specific plant translation initiation mechanisms that are controlled by 59-UTR elements of mRNAs and discuss regulation of these mechanisms by TOR/S6 kinase 1 (S6K1) signaling. Examples where TOR re...

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An Oncogenic Role for the Phosphorylated h-Subunit of Human Translation Initiation Factor eIF3

Cited by 80 publications

References 36 publications

Regulation of protein synthesis and the role of eIF3 in cancer

Regulation of protein synthesis and the role of eIF3 in cancer

ABCE1 is essential for S phase progression in human cells

Recent Discoveries on the Role of TOR (Target of Rapamycin) Signaling in Translation in Plants

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