V. I. Dubovaya scite author profile

To unravel the region of human eukaryotic release factor 1 (eRF1) that is close to stop codons within the ribosome, we used mRNAs containing a single photoactivatable 4-thiouridine (s 4 U) residue in the ®rst position of stop or control sense codons. Accurate phasing of these mRNAs onto the ribosome was achieved by the addition of tRNA Asp . Under these conditions, eRF1 was shown to crosslink exclusively to mRNAs containing a stop or s 4 UGG codon. A procedure that yielded 32 P-labeled eRF1 deprived of the mRNA chain was developed; analysis of the labeled peptides generated after speci®c cleavage of both wild-type and mutant eRF1s maps the crosslink in the tripeptide KSR (positions 63±65 of human eRF1) and points to K63 located in the conserved NIKS loop as the main crosslinking site. These data directly show the interaction of the N-terminal (N) domain of eRF1 with stop codons within the 40S ribosomal subunit and provide strong support for the positioning of the eRF1 middle (M) domain on the 60S subunit. Thus, the N and M domains mimic the tRNA anticodon and acceptor arms, respectively.

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Role of the individual domains of translation termination factor eRF1 in GTP binding to eRF3

Кононенко¹,

Mitkevich²,

Dubovaya³

et al. 2007

Proteins

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Eukaryotic translational termination is triggered by polypeptide release factors eRF1, eRF3, and one of the three stop codons at the ribosomal A-site. Isothermal titration calorimetry shows that (i) the separated MC, M, and C domains of human eRF1 bind to eRF3; (ii) GTP binding to eRF3 requires complex formation with either the MC or M + C domains; (iii) the M domain interacts with the N and C domains; (iv) the MC domain and Mg2+ induce GTPase activity of eRF3 in the ribosome. We suggest that GDP binding site of eRF3 acquires an ability to bind gamma-phosphate of GTP if altered by cooperative action of the M and C domains of eRF1. Thus, the stop-codon decoding is associated with the N domain of eRF1 while the GTPase activity of eRF3 is controlled by the MC domain of eRF1 demonstrating a substantial structural uncoupling of these two activities though functionally they are interrelated.

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GTP-dependent structural rearrangement of the eRF1:eRF3 complex and eRF3 sequence motifs essential for PABP binding

Кононенко

Mitkevich

Atkinson

et al. 2009

Nucleic Acids Research

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Translation termination in eukaryotes is governed by the concerted action of eRF1 and eRF3 factors. eRF1 recognizes the stop codon in the A site of the ribosome and promotes nascent peptide chain release, and the GTPase eRF3 facilitates this peptide release via its interaction with eRF1. In addition to its role in termination, eRF3 is involved in normal and nonsense-mediated mRNA decay through its association with cytoplasmic poly(A)-binding protein (PABP) via PAM2-1 and PAM2-2 motifs in the N-terminal domain of eRF3. We have studied complex formation between full-length eRF3 and its ligands (GDP, GTP, eRF1 and PABP) using isothermal titration calorimetry, demonstrating formation of the eRF1:eRF3:PABP:GTP complex. Analysis of the temperature dependence of eRF3 interactions with G nucleotides reveals major structural rearrangements accompanying formation of the eRF1:eRF3:GTP complex. This is in contrast to eRF1:eRF3:GDP complex formation, where no such rearrangements were detected. Thus, our results agree with the established active role of GTP in promoting translation termination. Through point mutagenesis of PAM2-1 and PAM2-2 motifs in eRF3, we demonstrate that PAM2-2, but not PAM2-1 is indispensible for eRF3:PABP complex formation.

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Detection of Abundantly Transcribed Genes and Gene Translocation in Human Immunodeficiency Virus-Associated Non—Hodgkin's Lymphoma

et al. 2001

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Several novel, differentially transcribed genes were identified in one centroblastic and one immunoblastic HIV-associated B-cell non-Hodgkin's lymphoma (B-NHL) by subtractive cloning. In both lymphomas, we detected an upregulated transcription of several mitochondrial genes. In the centroblastic B-NHL, we found a high level transcription of nuclear genes including the interferon-inducible gene (INF-ind), the immunoglobulin light chain gene (IgL), the set oncogene, and several unknown genes. The data obtained on upregulated expression of the genes in human B-NHL of HIV-infected patients considerably overlap with those obtained earlier for the B-NHL of simian immunodeficiency virus-infected monkeys. In the centroblastic lymphoma, one transcript revealed a fusion of the 3'-untranslated region of the set gene and the C-terminal region of the IgL gene. This chimeric sequence was confirmed by a site-directed polymerase chain reaction performed with total cDNA and genomic DNA. The expected amplification product was obtained in both cases pointing to a genomic rearrangement. The IgL-set fusion sequence was not found in cDNA preparations and genomic DNA of the immunoblastic HIV-associated B-NHL. Further studies are necessary to determine whether these genes contribute to lymphoma development or can be used as therapeutic targets.

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Transcription of TIMP3, DAPK1, and AKR1B10 in squamous-cell lung cancer

et al. 2006

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Transcription factor AP-1 is a dimer complex composed by DNA-binding proteins of Jun, Fos, and ATF families. AP-1 mediates cell response on growth factors, cytokines, neurotransmitters and other intercellular signaling molecules. AP-1 activity is mediated by G-proteins, adapter proteins, MAP kinases and other elements of cellular signaling systems. AP-1 dependent genes play a pivotal role in regulation of cell proliferation, morphogenesis, apoptosis, and differentiation.

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V. I. Dubovaya

The invariant uridine of stop codons contacts the conserved NIKSR loop of human eRF1 in the ribosome

Role of the individual domains of translation termination factor eRF1 in GTP binding to eRF3

GTP-dependent structural rearrangement of the eRF1:eRF3 complex and eRF3 sequence motifs essential for PABP binding

Detection of Abundantly Transcribed Genes and Gene Translocation in Human Immunodeficiency Virus-Associated Non—Hodgkin's Lymphoma

Transcription of TIMP3, DAPK1, and AKR1B10 in squamous-cell lung cancer

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