UNIPROT:P04637 - FACTA Search

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Query: UNIPROT:P04637 (p53)
77,613 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The vaccinia virus (VV) replicates robustly and alters the progression of the cell cycle via an unknown mechanism. Herein, we provide evidence for the existence of a unique VV infection-induced cell cycle control mechanism. The regulation is correlated with the inactivation of p53 and Rb, which are associated with the RNA polymerase III transcription factor B (TFIIIB) subunits, TBP and Brf1 respectively. VV infection induced the expression of Mdm2 and its translocation into the nucleus, thereby resulting in a disruption of p53. VV also stimulated the expression of TFIIIB and TFIIIC, and consequently induced tRNA synthesis. On the other hand, the total level of Rb was not significantly influenced, but the level of hypo-phosphorylated Rb was enhanced, partially due to the VV-induced downregulation of cyclin-dependent kinases 4 and 6. However, the hypo-phosphorylated Rb appeared to be largely sequestered into a complex with Brf1, which resulted in the blockage of Rb function to repress E2F1 transactivation, thereby leading to a moderately higher proportion of cells in the S and G(2) phases. Conversely, the enforced expression of exogenous Rb restored the normally observed cell cycle patterns. Overall, these controls may contribute to the efficient replication of the virus in rapidly growing cells.
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PMID:Vaccinia virus-mediated cell cycle alteration involves inactivation of tumour suppressors associated with Brf1 and TBP. 1787 50

The La protein interacts with a variety of small RNAs as well as certain growth-associated mRNAs such as Mdm2 mRNA. Human La (hLa) phosphoprotein is so highly conserved that it can replace the tRNA processing function of the fission yeast La protein in vivo. We used this system, which is based on tRNA-mediated suppression (TMS) of ade6-704 in S. pombe, to compare the activities of mouse and human La proteins. Prior studies indicate that hLa is activated by phosphorylation of serine-366 by protein kinase CK2, neutralizing a negative effect of a short basic motif (SBM). First, we report the sequence mapping of the UGA stop codon that requires suppressor tRNA for TMS, to an unexpected site in S. pombe ade6-704. Next, we show that, unlike hLa, native mLa is unexpectedly inactive for TMS, although its intrinsic activity is revealed by deletion of its SBM. We then show that mLa is not phosphorylated by CK2, accounting for the mechanistic difference between mLa and hLa. We found a PKA/PKG target sequence in mLa (S199) that is not present in hLa, and show that PKA/PKG efficiently phosphorylates mLa S199 in vitro. A noteworthy conclusion that comes from this work is that this fission yeast system can be used to gain insight into differences in control mechanisms used by La proteins of different mammalian species. Finally, RNA binding assays indicate that while mutation of mLa S199 has little effect on pre-tRNA binding, it substantially decreases binding to a probe derived from Mdm2 mRNA. In closing, we note that species-specific signaling through La may be relevant to the La-dependent Mdm2 pathways of p53 metabolism and cancer progression in mice and humans.
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PMID:Mouse and human La proteins differ in kinase substrate activity and activation mechanism for tRNA processing. 1825 91

Although AIMP3/p18 is normally associated with the multi-tRNA synthetase complex via its specific interaction with methionyl-tRNA synthetase, it also works as a tumor suppressor by interacting with ATM, the upstream kinase of p53. To understand the molecular interactions of AIMP3 and the mechanisms involved, we determined the crystal structure of AIMP3 at 2.0-angstroms resolution and identified its potential sites of interaction with ATM. AIMP3 contains two distinct domains linked by a 7-amino acid (Lys57-Ser63) peptide, which contains a 3(10) helix. The 56-amino acid N-terminal domain consists of two helices into which three antiparallel beta strands are inserted, and the 111-amino acid C-terminal domain contains a bundle of five helices (Thr64-Tyr152) followed by a coiled region (Pro153-Leu169). Structural analyses revealed homologous proteins such as yeast glutamyl-tRNA synthetase, Arc1p, EF1Bgamma, and glutathione S-transferase and suggested two potential molecular binding sites. Moreover, mutations at the C-terminal putative binding site abolished the interaction between AIMP3 and ATM and the ability of AIMP3 to activate p53. Thus, this work identified the two potential molecular interaction sites of AIMP3 and determined the residues critical for its tumor-suppressive activity through the interaction with ATM.
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PMID:Determination of three-dimensional structure and residues of the novel tumor suppressor AIMP3/p18 required for the interaction with ATM. 1834 21

PTEN, a tumor suppressor whose function is frequently lost in human cancers, possesses a lipid phosphatase activity that represses phosphatidylinositol 3-kinase (PI3K) signaling, controlling cell growth, proliferation, and survival. The potential for PTEN to regulate the synthesis of RNA polymerase (Pol) III transcription products, including tRNAs and 5S rRNAs, was evaluated. The expression of PTEN in PTEN-deficient cells repressed RNA Pol III transcription, whereas decreased PTEN expression enhanced transcription. Transcription repression by PTEN was uncoupled from PTEN-mediated effects on the cell cycle and was independent of p53. PTEN acts through its lipid phosphatase activity, inhibiting the PI3K/Akt/mTOR/S6K pathway to decrease transcription. PTEN, through the inactivation of mTOR, targets the TFIIIB complex, disrupting the association between TATA-binding protein and Brf1. Kinetic analysis revealed that PTEN initially induces a decrease in the serine phosphorylation of Brf1, leading to a selective reduction in the occupancy of all TFIIIB subunits on tRNA(Leu) genes, whereas prolonged PTEN expression results in the enhanced serine phosphorylation of Bdp1. Together, these results demonstrate a new class of genes regulated by PTEN through its ability to repress the activation of PI3K/Akt/mTOR/S6K signaling.
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PMID:PTEN represses RNA polymerase III-dependent transcription by targeting the TFIIIB complex. 1839 Oct 23

Elongator, a multi-subunit complex assembled by the IkappaB kinase-associated protein (IKAP)/hELP1 scaffold protein is involved in transcriptional elongation in the nucleus as well as in tRNA modifications in the cytoplasm. However, the biological processes regulated by Elongator in human cells only start to be elucidated. Here we demonstrate that IKAP/hELP1 depleted colon cancer-derived cells show enhanced basal expression of some but not all pro-apoptotic p53-dependent genes such as BAX. Moreover, Elongator deficiency causes increased basal and daunomycin-induced expression of the pro-survival serum- and glucocorticoid-induced protein kinase (SGK) gene through a p53-dependent pathway. Thus, our data collectively demonstrate that Elongator deficiency triggers the activation of p53-dependent genes harbouring opposite functions with respect to apoptosis.
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PMID:Deregulated expression of pro-survival and pro-apoptotic p53-dependent genes upon Elongator deficiency in colon cancer cells. 1843 Apr 10

AIMP2/p38 is a scaffolding protein required for the assembly of the macromolecular tRNA synthetase complex. Here, we describe a previously unknown function for AIMP2 as a positive regulator of p53 in response to genotoxic stresses. Depletion of AIMP2 increased resistance to DNA damage-induced apoptosis, and introduction of AIMP2 into AIMP2-deficient cells restored the susceptibility to apoptosis. Upon DNA damage, AIMP2 was phosphorylated, dissociated from the multi-tRNA synthetase complex, and translocated into the nuclei of cells. AIMP2 directly interacts with p53, thereby preventing MDM2-mediated ubiquitination and degradation of p53. Mutations in AIMP2, affecting its interaction with p53, hampered its ability to activate p53. Nutlin-3 recovered the level of p53 and the susceptibility to UV-induced cell death in AIMP2-deficient cells. This work demonstrates that AIMP2, a component of the translational machinery, functions as proapoptotic factor via p53 in response to DNA damage.
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PMID:AIMP2/p38, the scaffold for the multi-tRNA synthetase complex, responds to genotoxic stresses via p53. 1869 51

A long form (tRNase Z(L)) of tRNA 3' processing endoribonuclease (tRNase Z, or 3' tRNase) can cleave any target RNA at any desired site under the direction of artificial small guide RNA (sgRNA) that mimics a 5'-half portion of tRNA. Based on this enzymatic property, a gene silencing technology has been developed, in which a specific mRNA level can be downregulated by introducing into cells a synthetic 5'-half-tRNA that is designed to form a pre-tRNA-like complex with a part of the mRNA. Recently 5'-half-tRNA fragments have been reported to exist stably in various types of cells, although little is know about their physiological roles. We were curious to know if endogenous 5'-half-tRNA works as sgRNA for tRNase Z(L) in the cells. Here we show that human cytosolic tRNase Z(L) modulates gene expression through 5'-half-tRNA. We found that 5'-half-tRNA(Glu), which co-immunoprecipitates with tRNase Z(L), exists predominantly in the cytoplasm, functions as sgRNA in vitro, and downregulates the level of a luciferase mRNA containing its target sequence in human kidney 293 cells. We also demonstrated that the PPM1F mRNA is one of the genuine targets of tRNase Z(L) guided by 5'-half-tRNA(Glu). Furthermore, the DNA microarray data suggested that tRNase Z(L) is likely to be involved in the p53 signaling pathway and apoptosis.
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PMID:Modulation of gene expression by human cytosolic tRNase Z(L) through 5'-half-tRNA. 1952 60

The tumor suppressor gene TP53 is known to be a key regulator in cancer, and more than half of human cancers exhibit mutations in this gene. Recent evidence shows that point mutations in TP53 not only disrupt its function but also possess gain-of-function and dominant-negative effects on wild-type copies, thus making the mutated gene an oncogene. Hence, this brings about the possibility that TP53 mutations may be under selection for increasing the overall translation efficiency (TE) of defected TP53 in cancerous cells. Here, we perform the first large-scale analysis of TE in human cancer mutated TP53 variants, identifying a significant increase in TE that is correlated with the frequency of TP53 mutations. Furthermore, mutations with a known oncogenic effect significantly increase their TE compared with the other TP53 mutations. Further analysis shows that TE may have influence both on selecting the location of the mutation and on its outcome: codons with lower TE show stronger selection toward nonsynonymous mutations and, for each codon, frequent mutations show stronger increase in TE compared with less frequent mutations. Additionally, we find that TP53 mutations have significantly higher TE increase in progressive versus primary tumors. Finally, an analysis of TP53 NCI-60 cell lines points to a coadaptation between the mutations and the tRNA pool, increasing the overall TP53 TE. Taken together, these results show that TE plays an important role in the selection of TP53 cancerous mutations.
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PMID:TP53 cancerous mutations exhibit selection for translation efficiency. 1988 6

Bacterial RNases are promising tools for the development of anticancer drugs. Neoplastic transformation leads to enhanced accumulation of rRNA and tRNA, and altered expression of regulatory noncoding RNAs. Cleavage of RNA in cancer cells is the main reason for the cytotoxic effects of exogenic RNases. We have shown that binase, a cytotoxic ribonuclease from Bacillus intermedius, affects the total amount of intracellular RNA and the expression of proapoptotic and antiapoptotic mRNAs. For four cell lines, we visualized cellular RNA by fluorescence microscopy, and determined RNA levels, viability and apoptosis by flow cytometry. We found that the level of cellular RNA was decreased in cells that were sensitive to the cytotoxic effects of binase. The RNA level was lowered by 44% in HEK cells transfected with the hSK4 gene of the Ca(2+)-activated potassium channels (HEKhSK4) and by 20% in kit-transformed myeloid progenitor FDC-P1iR1171 cells. The most significant decrease in RNA levels was registered in the subpopulations of apoptotic cells. However, the binase-induced RNA decrease did not correlate with apoptosis. Kit-transformed cells with binase-induced RNA decrease retained viability if the interleukin-dependent proliferation pathway was activated. Using quantitative RT-PCR with RNA samples isolated from the binase-treated HEKhSK4 cells, we found that the amount of mRNA of the antiapoptotic bcl-2 gene in vivo was reduced about two-fold. In contrast, expression of the proapoptotic genes p53 and hSK4 was increased 1.5-fold and 4.3-fold, respectively. These results show that binase is a regulator of RNA-dependent processes of cell proliferation and apoptosis.
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PMID:Binase cleaves cellular noncoding RNAs and affects coding mRNAs. 1996 15

Precise photochemical control of protein function can be achieved through the site-specific introduction of caging groups. Chemical and enzymatic methods, including in vitro translation and chemical ligation, have been used to photocage proteins in vitro. These methods have been extended to allow the introduction of caged proteins into cells by permeabilization or microinjection, but cellular delivery remains challenging. Since lysine residues are key determinants for nuclear localization sequences, the target of key post-translational modifications (including ubiquitination, methylation, and acetylation), and key residues in many important enzyme active sites, we were interested in photocaging lysine to control protein localization, post-translational modification, and enzymatic activity. Photochemical control of these important functions mediated by lysine residues in proteins has not previously been demonstrated in living cells. Here we synthesized 1 and evolved a pyrrolysyl-tRNA synthetase/tRNA pair to genetically encode the incorporation of this amino acid in response to an amber codon in mammalian cells. To exemplify the utility of this amino acid, we caged the nuclear localization sequences (NLSs) of nucleoplasmin and the tumor suppressor p53 in human cells, thus mislocalizing the proteins in the cytosol. We triggered protein nuclear import with a pulse of light, allowing us to directly quantify the kinetics of nuclear import.
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PMID:Genetically encoded photocontrol of protein localization in mammalian cells. 2021

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