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42 results on '"Polevoda, Bogdan"'

5. THUMPD1 bi-allelic variants cause loss of tRNA acetylation and a syndromic neurodevelopmental disorder

Author

Broly, Martin, primary, Polevoda, Bogdan V., additional, Awayda, Kamel M., additional, Tong, Ning, additional, Lentini, Jenna, additional, Besnard, Thomas, additional, Deb, Wallid, additional, O’Rourke, Declan, additional, Baptista, Julia, additional, Ellard, Sian, additional, Almannai, Mohammed, additional, Hashem, Mais, additional, Abdulwahab, Ferdous, additional, Shamseldin, Hanan, additional, Al-Tala, Saeed, additional, Alkuraya, Fowzan S., additional, Leon, Alberta, additional, van Loon, Rosa L.E., additional, Ferlini, Alessandra, additional, Sanchini, Mariabeatrice, additional, Bigoni, Stefania, additional, Ciorba, Andrea, additional, van Bokhoven, Hans, additional, Iqbal, Zafar, additional, Al-Maawali, Almundher, additional, Al-Murshedi, Fathiya, additional, Ganesh, Anuradha, additional, Al-Mamari, Watfa, additional, Lim, Sze Chern, additional, Pais, Lynn S., additional, Brown, Natasha, additional, Riazuddin, Saima, additional, Bézieau, Stéphane, additional, Fu, Dragony, additional, Isidor, Bertrand, additional, Cogné, Benjamin, additional, and O’Connell, Mitchell R., additional

Published
2022
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13. Effects of an unusual poison identify a lifespan role for Topoisomerase 2 in Saccharomyces cerevisiae

Author

Tombline, Gregory, primary, Millen, Jonathan I., additional, Polevoda, Bogdan, additional, Rapaport, Matan, additional, Baxter, Bonnie, additional, Van Meter, Michael, additional, Gilbertson, Matthew, additional, Madrey, Joe, additional, Piazza, Gary A., additional, Rasmussen, Lynn, additional, Wennerberg, Krister, additional, White, E. Lucile, additional, Nitiss, John L., additional, and Goldfarb, David S., additional

Published
2017
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32. The diversity of acetylated proteins

Author

Polevoda, Bogdan and Sherman, Fred

Subjects
Eukaryotic Cells, Bacterial Proteins, Acetyltransferases, Lysine, Animals, Genetic Variation, Humans, Proteins, Acetylation, Review, Peptides, Protein Processing, Post-Translational
Abstract

Amino-terminal acetylation occurs on the bulk of eukaryotic acetylated proteins and on regulatory peptides, whereas lysine acetylation occurs at different positions on a variety of proteins, including histones, transcription factors, nuclear import factors, and α-tubulin., Acetylation of proteins, either on various amino-terminal residues or on the ε-amino group of lysine residues, is catalyzed by a wide range of acetyltransferases. Amino-terminal acetylation occurs on the bulk of eukaryotic proteins and on regulatory peptides, whereas lysine acetylation occurs at different positions on a variety of proteins, including histones, transcription factors, nuclear import factors, and α-tubulin.

Published
2002

34. A synopsis of eukaryotic Nα-terminal acetyltransferases: nomenclature, subunits and substrates.

Author

Polevoda, Bogdan, Arnesen, Thomas, and Sherman, Fred

Subjects
*YEAST, *LEAVENING agents, *ACETYLTRANSFERASES, *NAMES, *HUMAN beings, *EUKARYOTIC cells, *CELLS, *ACYLTRANSFERASES, *ENZYMES
Abstract

We have introduced a consistent nomenclature for the various subunits of the NatA-NatE Nterminal acetyltransferases from yeast, humans and other eukaryotes. [ABSTRACT FROM AUTHOR]

Published
2009
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35. Yeast N.

Author

Polevoda, Bogdan, Brown, Steven, Cardillo, Thomas S., Rigby, Sean, and Sherman, Fred

Published
2008
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36. The Yeast Translation Release Factors Mrf1 p and Sup45p (eRF1) Are Methylated, Respectively, by the Methyltransferases Mtq1 p and Mtq2p.

Author

Polevoda, Bogdan, Span, Lisa, and Sherman, Fred

Subjects
*YEAST, *ENZYMES, *CATALYSTS, *METHYLATION, *METHYLTRANSFERASES, *TRANSMETHYLATION, *ESCHERICHIA coli
Abstract

The translation release factors (RFs) RF1 and RF2 of Escherichia coli are methylated at the N5-glutamine of the GGQ motif by PrmC methyltransferase. This motif is conserved in organisms from bacteria to higher eukaryotes. The Saccharomyces cerevisiae RFs, mitochondrial Mrf1p and cytoplasmic Sup45p (eRF1), have sequence similarities to the bacterial RFs, including the potential site of glutamine methylation in the GGQ motif. A computational analysis revealed two yeast proteins, Mtq1p and Mtq2p, that have strong sequence similarity to PrmC. Mass spectrometric analysis demonstrated that Mtq1p and Mtq2p methylate Mrf1p and Sup45p, respectively, in vivo. A tryptic peptide of Mrf1p, GGQHVNTTDSAVR, containing the GGQ motif was found to be ∼50% methylated at the glutamine residue in the normal strain but completely unmodified in the peptide from mtq1-Δ. Moreover, Mtq1p methyltransferase activity was observed in an in vitro assay. In similar experiments, it was determined that Mtq2p methylates Sup45p. The Sup45p methylation by Mtq2p was recently confirmed independently (Heurgue-Hamard, V., Champ, S., Mora, L., Merkulova-Rainon, T., Kisselev, L. L., and Buckingham, R. H. (2005) J. Biol. Chem. 280, 2439–2445). Analysis of the deletion mutants showed that although mtq1-Δ had only moderate growth defects on nonfermentable carbon sources, the mtq2-A had multiple phenotypes, including cold sensitivity and sensitivity to translation fidelity antibiotics paromomycin and geneticin, to high salt and calcium concentrations, to polymyxin B, and to caffeine. Also, the mitochondrial mit- mutation, cox2-V25, containing a premature stop mutation, was suppressed by mtq1-Δ. Most interestingly, the mtq2-Δ was significantly more resistant to the anti-microtubule drugs thiabendazole and benomyl, suggesting that Mtq2p may also methylate certain microtubule-related proteins. [ABSTRACT FROM AUTHOR]

Published
2006
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37. Identification and specificities of N-terminal acetyltransferases from Saccharomyces cerevisiae.

Author

Polevoda, Bogdan, Norbeck, Joakim, Takakura, Hikaru, Blomberg, Anders, and Sherman, Fred

Subjects
*ACETYLATION, *METHIONINE, *ACETYLTRANSFERASES, *ACYLTRANSFERASES, *AMINO acids, *ACYLATION
Abstract

N-terminal acetylation can occur cotranslationally on the initiator methionine residue or on the penultimate residue if the methionine is cleaved. We investigated the three N-terminal acetyltransferases (NATs), Ard1p/ Nat1p, Nat3p and Mak3p. Ard1p and Mak3p are significantly related to each other by amino acid sequence, as is Nat3p, which was uncovered in this study using programming alignment procedures. Mutants deleted in any one of these NAT genes were viable, but some exhibited diminished mating efficiency and reduced growth at 37??°C, and on glycerol and NaCl-containing media. The three NATs had the following substrate specificities as determined in vivo by examining acetylation of 14 altered forms of iso-1-cytochrome c and 55 abundant normal proteins in each of the deleted strains: Ard1p/Nat1p, subclasses with Ser-, Ala-, Gly- and Thr-termini; Nat3p, Met-Glu- and Met- Asp- and a subclass of Met-Asn-termini; and Mak3p subclasses with Met-Ile- and Met-Leu-termini. In addition, a special subclass of substrates with Ser-Glu-Phe-, Ala-Glu-Phe- and Gly-Glu-Phe-termini required all three NATs for acetylation. [ABSTRACT FROM AUTHOR]

Published
1999
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38. Cytochrome cMethyltransferase, Ctm1p, of Yeast*

Author

Polevoda, Bogdan, Martzen, Mark R., Das, Biswadip, Phizicky, Eric M., and Sherman, Fred

Abstract

Cytochromes cfrom plants and fungi, but not higher animals, contain methylated lysine residues at specific positions, including for example, the trimethylated lysine at position 72 in iso-1-cytochrome cof the yeast Saccharomyces cerevisiae. Testing of 6,144 strains of S. cerevisiae, each overproducing a different open reading frame fused to glutathione S-transferase, previously revealed that YHR109w was associated with an activity that methylated horse cytochrome c. We show here that this open reading frame, denoted Ctm1p, is specifically responsible for trimethylating lysine 72 of iso-1-cytochrome c. Unmethylated forms of cytochromecbut not other proteins or nucleic acids are methylatedin vitroby Ctm1p produced in S. cerevisiaeorEscherichia coli. Iso-1-cytochrome cpurified from a ctm1-Δ strain is not trimethylated in vivo, whereas the K72R mutant form, or the trimethylated Lys-72 form of iso-1-cytochrome c, are not significantly methylated by Ctm1p in vitro. Like apocytochromec, but in contrast to holocytochrome c, Ctm lp is located in the cytosol, consistent with the view that the natural substrate is apocytochrome c. The ctm1-Δ strain lacking the methyltransferase did not exhibit any growth defect on a variety of media and growth conditions, and the unmethylated iso-1-cytochrome cwas produced at the normal level and exhibited the normal activity in vivo. Ctm1p and cytochrome cwere coordinately regulated during anaerobic to aerobic transition, a finding consistent with the view that this methyltransferase evolved to act on cytochrome c.

Published
2000
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39. Nα-Acetylation and Proteolytic Activity of the Yeast 20 S Proteasome*

Author

Kimura, Yayoi, Takaoka, Motoko, Tanaka, Sono, Sassa, Hidenori, Tanaka, Keiji, Polevoda, Bogdan, Sherman, Fred, and Hirano, Hisashi

Abstract

Nα-Acetylation, catalyzed co-translationally with Nα-acetyltransferase (NAT), is the most common modifications of eukaryotic proteins. In yeast, there are at least three NATs: NAT1, MAK3, and NAT3. The 20 S proteasome subunits were purified from the normal strain and each of the deletion mutants,nat1, mak3, and nat3. The electrophoretic mobility of these subunits was compared by two-dimensional gel electrophoresis. Shifts toward the alkaline side of the gel and unblocking of the N terminus of certain of the subunits in one or another of the mutants indicated that the α1, α2, α3, α4, α7, and β3 subunits were acetylated with NAT1, the α5 and α6 subunits were acetylated with MAK3, and the β4 subunit was acetylated with NAT3. Furthermore, the Ac-Met-Phe-Leu and Ac-Met-Phe-Arg termini of the α5 and α6 subunits, respectively, extended the known types of MAK3 substrates. Thus, nine subunits were Nα-acetylated, whereas the remaining five were processed, resulting in the loss of the N-terminal region. The 20 S proteasomes derived from either the nat1mutant or the normal strain were similar in respect to chymotrypsin-like, trypsin-like, and peptidylglutamyl peptide hydrolyzing activitiesin vitro, suggesting thatNα-acetylation does not play a major functional role in these activities. However, the chymotrypsin-like activity in the absence of sodium dodecyl sulfate was slightly higher in the nat1mutant than in the normal strain.

Published
2000
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40. Nα-Acetylation of yeast ribosomal proteins and its effect on protein synthesis

Author

Kamita, Masahiro, Kimura, Yayoi, Ino, Yoko, Kamp, Roza M., Polevoda, Bogdan, Sherman, Fred, and Hirano, Hisashi

Subjects
*ACETYLATION, *YEAST, *RIBOSOMES, *RNA, *PROTEIN synthesis, *ACETYLTRANSFERASES, *GEL electrophoresis, *MASS spectrometry
Abstract

Abstract: Nα-Acetyltransferases (NATs) cause the Nα-acetylation of the majority of eukaryotic proteins during their translation, although the functions of this modification have been largely unexplored. In yeast (Saccharomyces cerevisiae), four NATs have been identified: NatA, NatB, NatC, and NatD. In this study, the Nα-acetylation status of ribosomal protein was analyzed using NAT mutants combined with two-dimensional difference gel electrophoresis (2D-DIGE) and mass spectrometry (MS). A total of 60 ribosomal proteins were identified, of which 17 were Nα-acetylated by NatA, and two by NatB. The Nα-acetylation of two of these, S17 and L23, by NatA was not previously observed. Furthermore, we tested the effect of ribosomal protein Nα-acetylation on protein synthesis using the purified ribosomes from each NAT mutant. It was found that the protein synthesis activities of ribosomes from NatA and NatB mutants were decreased by 27% and 23%, respectively, as compared to that of the normal strain. Furthermore, we have shown that ribosomal protein Nα-acetylation by NatA influences translational fidelity in the presence of paromomycin. These results suggest that ribosomal protein Nα-acetylation is necessary to maintain the ribosome''s protein synthesis function. [Copyright &y& Elsevier]

Published
2011
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41. Transfer RNA acetylation regulates in vivo mammalian stress signaling.

Author

Gamage ST, Khoogar R, Manage SH, Crawford MC, Georgeson J, Polevoda BV, Sanders C, Lee KA, Nance KD, Iyer V, Kustanovich A, Perez M, Thu CT, Nance SR, Amin R, Miller CN, Holewinski RJ, Meyer T, Koparde V, Yang A, Jailwala P, Nguyen JT, Andresson T, Hunter K, Gu S, Mock BA, Edmondson EF, Difilippantonio S, Chari R, Schwartz S, O'Connell MR, Chih-Chien Wu C, and Meier JL

Abstract

Transfer RNA (tRNA) modifications are crucial for protein synthesis, but their position-specific physiological roles remain poorly understood. Here we investigate the impact of N4-acetylcytidine (ac 4 C), a highly conserved tRNA modification, using a Thumpd1 knockout mouse model. We find that loss of Thumpd1-dependent tRNA acetylation leads to reduced levels of tRNA Leu , increased ribosome stalling, and activation of eIF2α phosphorylation. Thumpd1 knockout mice exhibit growth defects and sterility. Remarkably, concurrent knockout of Thumpd1 and the stress-sensing kinase Gcn2 causes penetrant postnatal lethality, indicating a critical genetic interaction. Our findings demonstrate that a modification restricted to a single position within type II cytosolic tRNAs can regulate ribosome-mediated stress signaling in mammalian organisms, with implications for our understanding of translation control as well as therapeutic interventions., Competing Interests: DECLARATION OF INTERESTS The authors have no positions or financial interests to declare.

Published
2024
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42. Yeast N(alpha)-terminal acetyltransferases are associated with ribosomes.

Author

Polevoda B, Brown S, Cardillo TS, Rigby S, and Sherman F

Subjects
Acetyltransferases genetics, Acetyltransferases isolation & purification, Amino-Acid N-Acetyltransferase genetics, Amino-Acid N-Acetyltransferase isolation & purification, Arylamine N-Acetyltransferase genetics, Arylamine N-Acetyltransferase isolation & purification, Gene Deletion, N-Terminal Acetyltransferase B, N-Terminal Acetyltransferase C, N-Terminal Acetyltransferases, Polyribosomes chemistry, Polyribosomes metabolism, Protein Binding, Protein Subunits, Ribosomal Proteins isolation & purification, Ribosomal Proteins metabolism, Ribosomes chemistry, Saccharomyces cerevisiae chemistry, Saccharomyces cerevisiae genetics, Saccharomyces cerevisiae Proteins genetics, Saccharomyces cerevisiae Proteins isolation & purification, Acetyltransferases metabolism, Amino-Acid N-Acetyltransferase metabolism, Arylamine N-Acetyltransferase metabolism, Protein Interaction Mapping, Ribosomes metabolism, Saccharomyces cerevisiae metabolism, Saccharomyces cerevisiae Proteins metabolism
Abstract

N-terminal acetylation is one of the most common modifications, occurring on the vast majority of eukaryotic proteins. Saccharomyces cerevisiae contains three major NATs, designated NatA, NatB, and NatC, with each having catalytic subunits Ard1p, Nat3p, and Mak3p, respectively. Gautschi et al. (Gautschi et al. [2003] Mol Cell Biol 23: 7403) previously demonstrated with peptide crosslinking experiments that NatA is bound to ribosomes. In our studies, biochemical fractionation in linear sucrose density gradients revealed that all of the NATs are associated with mono- and polyribosome fractions. However only a minor portion of Nat3p colocalized with the polyribosomes. Disruption of the polyribosomes did not cause dissociation of the NATs from ribosomal subparticles. The NAT auxiliary subunits, Nat1p and Mdm20p, apparently are required for efficient binding of the corresponding catalytic subunits to the ribosomes. Deletions of the genes corresponding to auxiliary subunits significantly diminish the protein levels of the catalytic subunits, especially Nat3p, while deletions of the catalytic subunits produced less effect on the stability of Nat1p and Mdm20p. Also two ribosomal proteins, Rpl25p and Rpl35p, were identified in a TAP-affinity purified NatA sample. Moreover, Ard1p copurifies with Rpl35p-TAP. We suggest that these two ribosomal proteins, which are in close proximity to the ribosomal exit tunnel, may play a role in NatA attachment to the ribosome., ((c) 2007 Wiley-Liss, Inc.)

Published
2008
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