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13. Structural and evolutionary bioinformatics of the SPOUT superfamily of methyltransferases

Author

Purta Elzbieta, Dunin-Horkawicz Stanislaw, Tkaczuk Karolina L, and Bujnicki Janusz M

Subjects
Computer applications to medicine. Medical informatics, R858-859.7, Biology (General), QH301-705.5
Abstract

Abstract Background SPOUT methyltransferases (MTases) are a large class of S-adenosyl-L-methionine-dependent enzymes that exhibit an unusual alpha/beta fold with a very deep topological knot. In 2001, when no crystal structures were available for any of these proteins, Anantharaman, Koonin, and Aravind identified homology between SpoU and TrmD MTases and defined the SPOUT superfamily. Since then, multiple crystal structures of knotted MTases have been solved and numerous new homologous sequences appeared in the databases. However, no comprehensive comparative analysis of these proteins has been carried out to classify them based on structural and evolutionary criteria and to guide functional predictions. Results We carried out extensive searches of databases of protein structures and sequences to collect all members of previously identified SPOUT MTases, and to identify previously unknown homologs. Based on sequence clustering, characterization of domain architecture, structure predictions and sequence/structure comparisons, we re-defined families within the SPOUT superfamily and predicted putative active sites and biochemical functions for the so far uncharacterized members. We have also delineated the common core of SPOUT MTases and inferred a multiple sequence alignment for the conserved knot region, from which we calculated the phylogenetic tree of the superfamily. We have also studied phylogenetic distribution of different families, and used this information to infer the evolutionary history of the SPOUT superfamily. Conclusion We present the first phylogenetic tree of the SPOUT superfamily since it was defined, together with a new scheme for its classification, and discussion about conservation of sequence and structure in different families, and their functional implications. We identified four protein families as new members of the SPOUT superfamily. Three of these families are functionally uncharacterized (COG1772, COG1901, and COG4080), and one (COG1756 represented by Nep1p) has been already implicated in RNA metabolism, but its biochemical function has been unknown. Based on the inference of orthologous and paralogous relationships between all SPOUT families we propose that the Last Universal Common Ancestor (LUCA) of all extant organisms contained at least three SPOUT members, ancestors of contemporary RNA MTases that carry out m1G, m3U, and 2'O-ribose methylation, respectively. In this work we also speculate on the origin of the knot and propose possible 'unknotted' ancestors. The results of our analysis provide a comprehensive 'roadmap' for experimental characterization of SPOUT MTases and interpretation of functional studies in the light of sequence-structure relationships.

Published
2007
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14. Positioning Europe for the EPITRANSCRIPTOMICS challenge

Author

Jantsch, Michael F., primary, Quattrone, Alessandro, additional, O'Connell, Mary, additional, Helm, Mark, additional, Frye, Michaela, additional, Macias-Gonzales, Manuel, additional, Ohman, Marie, additional, Ameres, Stefan, additional, Willems, Luc, additional, Fuks, Francois, additional, Oulas, Anastasis, additional, Vanacova, Stepanka, additional, Nielsen, Henrik, additional, Bousquet-Antonelli, Cecile, additional, Motorin, Yuri, additional, Roignant, Jean-Yves, additional, Balatsos, Nikolaos, additional, Dinnyes, Andras, additional, Baranov, Pavel, additional, Kelly, Vincent, additional, Lamm, Ayelet, additional, Rechavi, Gideon, additional, Pelizzola, Mattia, additional, Liepins, Janis, additional, Holodnuka Kholodnyuk, Irina, additional, Zammit, Vanessa, additional, Ayers, Duncan, additional, Drablos, Finn, additional, Dahl, John Arne, additional, Bujnicki, Janusz, additional, Jeronimo, Carmen, additional, Almeida, Raquel, additional, Neagu, Monica, additional, Costache, Marieta, additional, Bankovic, Jasna, additional, Banovic, Bojana, additional, Kyselovic, Jan, additional, Valor, Luis Miguel, additional, Selbert, Stefan, additional, Pir, Pinar, additional, Demircan, Turan, additional, Cowling, Victoria, additional, Schäfer, Matthias, additional, Rossmanith, Walter, additional, Lafontaine, Denis, additional, David, Alexandre, additional, Carre, Clement, additional, Lyko, Frank, additional, Schaffrath, Raffael, additional, Schwartz, Schraga, additional, Verdel, Andre, additional, Klungland, Arne, additional, Purta, Elzbieta, additional, Timotijevic, Gordana, additional, Cardona, Fernando, additional, Davalos, Alberto, additional, Ballana, Ester, additional, O´Carroll, Donal, additional, Ule, Jernej, additional, and Fray, Rupert, additional

Published
2018
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15. Positioning Europe for the EPITRANSCRIPTOMICS challenge

Author

Jantsch, Michael F., Quattrone, Alessandro, O'Connell, Mary, Helm, Mark, Frye, Michaela, Macias-Gonzales, Manuel, Ohman, Marie, Ameres, Stefan, Willems, Luc, Fuks, Francois, Oulas, Anastasis, Vanacova, Stepanka, Nielsen, Henrik, Bousquet-Antonelli, Cecile, Motorin, Yuri, Roignant, Jean-Yves, Balatsos, Nikolaos, Dinnyes, Andras, Baranov, Pavel, Kelly, Vincent, Lamm, Ayelet, Rechavi, Gideon, Pelizzola, Mattia, Liepins, Janis, Kholodnyuk, Irina Holodnuka, Zammit, Vanessa, Ayers, Duncan, Drablos, Finn, Dahl, John Arne, Bujnicki, Janusz, Jeronimo, Carmen, Almeida, Raquel, Neagu, Monica, Costache, Marieta, Banković, Jasna, Banović Đeri, Bojana, Kyselovic, Jan, Valor, Luis Miguel, Selbert, Stefan, Pir, Pinar, Demircan, Turan, Cowling, Victoria, Schaefer, Matthias, Rossmanith, Walter, Lafontaine, Denis, David, Alexandre, Carre, Clement, Lyko, Frank, Schaffrath, Raffael, Schwartz, Schraga, Verdel, Andre, Klungland, Arne, Purta, Elzbieta, Timotijević, Gordana, Cardona, Fernando, Davalos, Alberto, Ballana, Ester, O'Carroll, Donal, Ule, Jernej, Fray, Rupert, Jantsch, Michael F., Quattrone, Alessandro, O'Connell, Mary, Helm, Mark, Frye, Michaela, Macias-Gonzales, Manuel, Ohman, Marie, Ameres, Stefan, Willems, Luc, Fuks, Francois, Oulas, Anastasis, Vanacova, Stepanka, Nielsen, Henrik, Bousquet-Antonelli, Cecile, Motorin, Yuri, Roignant, Jean-Yves, Balatsos, Nikolaos, Dinnyes, Andras, Baranov, Pavel, Kelly, Vincent, Lamm, Ayelet, Rechavi, Gideon, Pelizzola, Mattia, Liepins, Janis, Kholodnyuk, Irina Holodnuka, Zammit, Vanessa, Ayers, Duncan, Drablos, Finn, Dahl, John Arne, Bujnicki, Janusz, Jeronimo, Carmen, Almeida, Raquel, Neagu, Monica, Costache, Marieta, Banković, Jasna, Banović Đeri, Bojana, Kyselovic, Jan, Valor, Luis Miguel, Selbert, Stefan, Pir, Pinar, Demircan, Turan, Cowling, Victoria, Schaefer, Matthias, Rossmanith, Walter, Lafontaine, Denis, David, Alexandre, Carre, Clement, Lyko, Frank, Schaffrath, Raffael, Schwartz, Schraga, Verdel, Andre, Klungland, Arne, Purta, Elzbieta, Timotijević, Gordana, Cardona, Fernando, Davalos, Alberto, Ballana, Ester, O'Carroll, Donal, Ule, Jernej, and Fray, Rupert

Abstract

The genetic alphabet consists of the four letters: C, A, G, and T in DNA and C,A,G, and U in RNA. Triplets of these four letters jointly encode 20 different amino acids out of which proteins of all organisms are built. This system is universal and is found in all kingdoms of life. However, bases in DNA and RNA can be chemically modified. In DNA, around 10 different modifications are known, and those have been studied intensively over the past 20years. Scientific studies on DNA modifications and proteins that recognize them gave rise to the large field of epigenetic and epigenomic research. The outcome of this intense research field is the discovery that development, ageing, and stem-cell dependent regeneration but also several diseases including cancer are largely controlled by the epigenetic state of cells. Consequently, this research has already led to the first FDA approved drugs that exploit the gained knowledge to combat disease. In recent years, the similar to 150 modifications found in RNA have come to the focus of intense research. Here we provide a perspective on necessary and expected developments in the fast expanding area of RNA modifications, termed epitranscriptomics.

Published
2018

16. Positioning Europe for the EPITRANSCRIPTOMICS challenge

Author

Jantsch, Michael F, Quattrone, Alessandro, O'Connell, Mary, Helm, Mark, Frye, Michaela, Macias-Gonzales, Manuel, Ohman, Marie, Ameres, Stefan, Willems, Luc, Fuks, Francois, Oulas, Anastasis, Vanacova, Stepanka, Nielsen, Henrik, Bousquet-Antonelli, Cecile, Motorin, Yuri, Roignant, Jean-Yves, Balatsos, Nikolaos, Dinnyes, Andras, Baranov, Pavel, Kelly, Vincent, Lamm, Ayelet, Rechavi, Gideon, Pelizzola, Mattia, Liepins, Janis, Holodnuka Kholodnyuk, Irina, Zammit, Vanessa, Ayers, Duncan, Drablos, Finn, Dahl, John Arne, Bujnicki, Janusz, Jeronimo, Carmen, Almeida, Raquel, Neagu, Monica, Costache, Marieta, Bankovic, Jasna, Banovic, Bojana, Kyselovic, Jan, Valor, Luis Miguel, Selbert, Stefan, Pir, Pinar, Demircan, Turan, Cowling, Victoria, Schäfer, Matthias, Rossmanith, Walter, Lafontaine, Denis, David, Alexandre, Carre, Clement, Lyko, Frank, Schaffrath, Raffael, Schwartz, Schraga, Verdel, Andre, Klungland, Arne, Purta, Elzbieta, Timotijevic, Gordana, Cardona, Fernando, Davalos, Alberto, Ballana, Ester, O Carroll, Donal, Ule, Jernej, Fray, Rupert, Jantsch, Michael F, Quattrone, Alessandro, O'Connell, Mary, Helm, Mark, Frye, Michaela, Macias-Gonzales, Manuel, Ohman, Marie, Ameres, Stefan, Willems, Luc, Fuks, Francois, Oulas, Anastasis, Vanacova, Stepanka, Nielsen, Henrik, Bousquet-Antonelli, Cecile, Motorin, Yuri, Roignant, Jean-Yves, Balatsos, Nikolaos, Dinnyes, Andras, Baranov, Pavel, Kelly, Vincent, Lamm, Ayelet, Rechavi, Gideon, Pelizzola, Mattia, Liepins, Janis, Holodnuka Kholodnyuk, Irina, Zammit, Vanessa, Ayers, Duncan, Drablos, Finn, Dahl, John Arne, Bujnicki, Janusz, Jeronimo, Carmen, Almeida, Raquel, Neagu, Monica, Costache, Marieta, Bankovic, Jasna, Banovic, Bojana, Kyselovic, Jan, Valor, Luis Miguel, Selbert, Stefan, Pir, Pinar, Demircan, Turan, Cowling, Victoria, Schäfer, Matthias, Rossmanith, Walter, Lafontaine, Denis, David, Alexandre, Carre, Clement, Lyko, Frank, Schaffrath, Raffael, Schwartz, Schraga, Verdel, Andre, Klungland, Arne, Purta, Elzbieta, Timotijevic, Gordana, Cardona, Fernando, Davalos, Alberto, Ballana, Ester, O Carroll, Donal, Ule, Jernej, and Fray, Rupert

Abstract

The genetic alphabet consists of the four letters: C, A, G, and T in DNA and C,A,G, and U in RNA. Triplets of these four letters jointly encode 20 different amino acids out of which proteins of all organisms are built. This system is universal and is found in all kingdoms of life. However, bases in DNA and RNA can be chemically modified. In DNA, around 10 different modifications are known, and those have been studied intensively over the past 20 years. Scientific studies on DNA modifications and proteins that recognize them gave rise to the large field of epigenetic and epigenomic research. The outcome of this intense research field is the discovery that development, ageing, and stem-cell dependent regeneration but also several diseases including cancer are largely controlled by the epigenetic state of cells. Consequently, this research has already led to the first FDA approved drugs that exploit the gained knowledge to combat disease. In recent years, the ~150 modifications found in RNA have come to the focus of intense research. Here we provide a perspective on necessary and expected developments in the fast expanding area of RNA modifications, termed epitranscriptomics.

Published
2018

17. Positioning Europe for the EPITRANSCRIPTOMICS challenge.

Author

Jantsch, Michael MF, Quattrone, Alessandro, O'Connell, Mary, Helm, Mark, Frye, Michaela, Macias-Gonzales, Manuel, Ohman, Marie, Ameres, Stefan, Willems, Lucas, Fuks, François, Oulas, Anastasis, Vanacova, Stepanka, Nielsen, Henrik, Bousquet-Antonelli, C, Motorin, Yuri, Roignant, Jean-Yves, Balatsos, Nikolaos, Dinnyes, Andras, Baranov, Pavel, Kelly, Vincent, Lamm, Ayelet, Rechavi, Gideon, Pelizzola, Mattia, Liepins, Janis, Holodnuka Kholodnyuk, Irina, Zammit, Vanessa, Ayers, Duncan, Drablos, Finn, Dahl, John Arne, Bujnicki, Janusz Marek, Jeronimo, Carmen, Almeida, Raquel, Neagu, Monica, Costache, Marieta, Bankovic, Jasna, Banovic, Bojana, Kyselovic, Jan, Valor, Luis Miguel, Selbert, Stefan, Pir, Pinar, Demircan, Turan, Cowling, Victoria, Schäfer, Matthias, Rossmanith, Walter, Lafontaine, Denis, David, Alexandre, Carre, Clement, Lyko, Frank, Schaffrath, Raffael, Schwartz, Schraga, Verdel, Andre, Klungland, Arne, Purta, Elzbieta, Timotijevic, Gordana, Cardona, F., Davalos, Alberto, Ballana, Ester, O Carroll, Donal, Ule, Jernej, Fray, Rupert, Jantsch, Michael MF, Quattrone, Alessandro, O'Connell, Mary, Helm, Mark, Frye, Michaela, Macias-Gonzales, Manuel, Ohman, Marie, Ameres, Stefan, Willems, Lucas, Fuks, François, Oulas, Anastasis, Vanacova, Stepanka, Nielsen, Henrik, Bousquet-Antonelli, C, Motorin, Yuri, Roignant, Jean-Yves, Balatsos, Nikolaos, Dinnyes, Andras, Baranov, Pavel, Kelly, Vincent, Lamm, Ayelet, Rechavi, Gideon, Pelizzola, Mattia, Liepins, Janis, Holodnuka Kholodnyuk, Irina, Zammit, Vanessa, Ayers, Duncan, Drablos, Finn, Dahl, John Arne, Bujnicki, Janusz Marek, Jeronimo, Carmen, Almeida, Raquel, Neagu, Monica, Costache, Marieta, Bankovic, Jasna, Banovic, Bojana, Kyselovic, Jan, Valor, Luis Miguel, Selbert, Stefan, Pir, Pinar, Demircan, Turan, Cowling, Victoria, Schäfer, Matthias, Rossmanith, Walter, Lafontaine, Denis, David, Alexandre, Carre, Clement, Lyko, Frank, Schaffrath, Raffael, Schwartz, Schraga, Verdel, Andre, Klungland, Arne, Purta, Elzbieta, Timotijevic, Gordana, Cardona, F., Davalos, Alberto, Ballana, Ester, O Carroll, Donal, Ule, Jernej, and Fray, Rupert

Abstract

The genetic alphabet consists of the four letters: C, A, G, and T in DNA and C,A,G, and U in RNA. Triplets of these four letters jointly encode 20 different amino acids out of which proteins of all organisms are built. This system is universal and is found in all kingdoms of life. However, bases in DNA and RNA can be chemically modified. In DNA, around 10 different modifications are known, and those have been studied intensively over the past 20 years. Scientific studies on DNA modifications and proteins that recognize them gave rise to the large field of epigenetic and epigenomic research. The outcome of this intense research field is the discovery that development, ageing, and stem-cell dependent regeneration but also several diseases including cancer are largely controlled by the epigenetic state of cells. Consequently, this research has already led to the first FDA approved drugs that exploit the gained knowledge to combat disease. In recent years, the ~150 modifications found in RNA have come to the focus of intense research. Here we provide a perspective on necessary and expected developments in the fast expanding area of RNA modifications, termed epitranscriptomics., SCOPUS: no.j, info:eu-repo/semantics/published

Published
2018

18. MODOMICS: a database of RNA modification pathways. 2017 update

Author

Boccaletto, Pietro, primary, Machnicka, Magdalena A, additional, Purta, Elzbieta, additional, Piątkowski, Paweł, additional, Bagiński, Błażej, additional, Wirecki, Tomasz K, additional, de Crécy-Lagard, Valérie, additional, Ross, Robert, additional, Limbach, Patrick A, additional, Kotter, Annika, additional, Helm, Mark, additional, and Bujnicki, Janusz M, additional

Published
2017
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21. Identification of potential inhibitors of macrolide resistance methyltransferase ErmC by virtual screening and experimental analysis

Author

Feder, Marcin, Purta, Elzbieta, Koscinski, Lukasz, Čubrilo, Sonja, Maravić Vlahoviček, Gordana, Bujnicki, Janusz M., Strelec, Ivica, and Glavaš-Obrovac, Ljubica

Subjects
macrolide antibiotics, antibiotic resistance, Erm methlytransferases, inhibitors
Abstract

Widespread resistance to clinically important macrolide, lincosamide and streptogramin B antibiotics is often conferred by methyltransferases from the Erm family that catalyze S-adenosyl-L-methionine dependent modification of a specific adenine residue in bacterial 23S rRNA. Despite continuous efforts, thus far no inhibitors of these enzymes have been identified or designed that would effectively abolish this type of bacterial resistance. We used the crystal structure of ErmC' methyltransferase as a target for structure based virtual screening of a database comprising 58679 leadlike compounds. We selected 77 compounds for experimental validation ; 63 of them were predicted to bind to the catalytic pocket and 14 compounds were predicted to bind to the putative RNA binding site. Among them we found several novel inhibitors, which reduce the minimal inhibitory concentration of a macrolide antibiotic erythromycin for Escherichia coli with constitutively expressed ErmC' gene. Four of them have IC50 values in the micromolar range and can be regarded as new lead structures with the potential for further optimization, which would direct the development of clinically useful inhibitors and thus help to fight the macrolide resistance based on rRNA methylation.

Published
2008

22. Novi spojevi kao potencijalni inhibitori metil-transferaze ErmC koja uzrokuje rezistenciju na makrolidne antibiotike

Author

Feder, Marcin, Purta, Elzbieta, Koscinski, Lukasz, Čubrilo, Sonja, Maravić Vlahoviček, Gordana, Bujnicki, Janusz M., Zahradka, Ksenija, Plohl, Miroslav, and Ambriović-Ristov, Andreja

Subjects
makrolidni antibiotici, rezistencija na antibiotike, metil-transferaze Erm, inhibitori
Abstract

Glavni mehanizam rezistencije na klinički važne makrolidne antibiotike temelji se na djelovanju metil-transferaza iz porodice Erm koje modificiraju specifični adenin unutar veznog mjesta za antibiotik u bakterijskoj 23S rRNA. Unatoč opetovanim pokušajima, do danas nije pronađen inhibitor koji bi uspješno spriječio ovaj tip bakterijske rezistencije. Proveli smo strukturno in silico pretraživanje javno dostupne baze podataka s 58679 različitih spojeva, u kojem je kao meta za vezanje spojeva poslužila kristalna struktura metil-transferaze ErmC’ . 77 spojeva odabrano je za eksperimentalnu provjeru ; za 63 spoja predviđeno je da se vežu na katalitičko mjesto, dok je za njih 14 pretpostavljeno da se vežu na vezno mjesto za RNA. Identificirano je nekoliko spojeva koji smanjuju minimalnu inhibitornu koncentraciju eritromicina u bakteriji Escherichia coli koja konstitutivno proizvodi protein ErmC’ . Među njima, četiri spoja pokazivala su IC50 u mikromolarnim vrijednostima te ih možemo smatrati novim kandidatima za inhibitore. Njihova daljnja strukturna optimizacija omogućit će razvoj klinički učinkovitih inhibitora koji bi spriječili rezistenciju na makrolidne antibiotike temeljenu na metilaciji ribosomske RNA.

Published
2008

23. Virtual screening and experimental verification to identify potential inhibitors of the ErmC methyltransferase responsible for bacterial resistance against macrolide antibiotics

Author

Feder, Marcin, Purta, Elzbieta, Maravić Gordana, and Bujnicki, Janusz

Subjects
antibiotic resistance, Erm methlytransferases, inhibitors
Abstract

Methyltransferases from the Erm family catalyze SadenosylLmethioninedependent modification of a specific adenine residue in bacterial 23S rRNA, thereby conferring resistance to clinically important macrolide, lincosamide and streptogramin B antibiotics. Thus far, no inhibitors of these enzymes have been identified or designed that would effectively abolish the resistance in vivo. We used the crystal structure of ErmC' methyltransferase as a target for structurebased virtual screening of a database comprising 58679 leadlike compounds. Among 77 compounds selected for experimental validation (63 predicted to bind to the catalytic pocket and 14 compounds predicted to bind to the putative RNAbinding site) we found several novel inhibitors, which reduce the minimal inhibitory concentration of a macrolide antibiotic erythromycin for Escherichia coli with constitutively expressed ErmC' gene. Four of them have IC50 values in the micromolar range and can be regarded as new lead structures with the potential for further optimization, aiming at the development of clinically useful inhibitors.

Published
2007

27. Sequence-structure-function analysis of the bifunctional enzyme MnmC that catalyses the last two steps in the biosynthesis of hypermodified nucleoside mnm5s2U in tRNA.

Author

Roovers, Martine, Oudjama, Yamina, Kaminska, Katarzyna H, Purta, Elzbieta, Caillet, Joël, Droogmans, Louis, Bujnicki, Janusz Marek, Roovers, Martine, Oudjama, Yamina, Kaminska, Katarzyna H, Purta, Elzbieta, Caillet, Joël, Droogmans, Louis, and Bujnicki, Janusz Marek

Abstract

MnmC catalyses the last two steps in the biosynthesis of 5-methylaminomethyl-2-thiouridine (mnm(5)s(2)U) in tRNA. Previously, we reported that this bifunctional enzyme is encoded by the yfcK open reading frame in the Escherichia coli K12 genome. However, the mechanism of its activity, in particular the potential structural and functional dependence of the domains responsible for catalyzing the two modification reactions, remains unknown. With the aid of the protein fold-recognition method, we constructed a structural model of MnmC in complex with the ligands and target nucleosides and studied the role of individual amino acids and entire domains by site-directed and deletion mutagenesis, respectively. We found out that the N-terminal domain contains residues responsible for binding of the S-adenosylmethionine cofactor and catalyzing the methylation of nm(5)s(2)U to form mnm(5)s(2)U, while the C-terminal domain contains residues responsible for binding of the FAD cofactor. Further, point mutants with compromised activity of either domain can complement each other to restore a fully functional enzyme. Thus, in the conserved fusion protein MnmC, the individual domains retain independence as enzymes. Interestingly, the N-terminal domain is capable of independent folding, while the isolated C-terminal domain is incapable of folding on its own, a situation similar to the one reported recently for the rRNA modification enzyme RsmC., Journal Article, Research Support, Non-U.S. Gov't, SCOPUS: ar.j, FLWIN, info:eu-repo/semantics/published

Published
2008

29. The yfhQ gene of Escherichia coli encodes a tRNA:Cm32/Um32 methyltransferase.

Author

Purta, Elzbieta, Van Vliet, Françoise, Tkaczuk, Karolina L, Dunin-Horkawicz, Stanislaw, Mori, Hirotada, Droogmans, Louis, Bujnicki, Janusz Marek, Purta, Elzbieta, Van Vliet, Françoise, Tkaczuk, Karolina L, Dunin-Horkawicz, Stanislaw, Mori, Hirotada, Droogmans, Louis, and Bujnicki, Janusz Marek

Abstract

BACKGROUND: Naturally occurring tRNAs contain numerous modified nucleosides. They are formed by enzymatic modification of the primary transcripts during the complex RNA maturation process. In model organisms Escherichia coli and Saccharomyces cerevisiae most enzymes involved in this process have been identified. Interestingly, it was found that tRNA methylation, one of the most common modifications, can be introduced by S-adenosyl-L-methionine (AdoMet)-dependent methyltransferases (MTases) that belong to two structurally and phylogenetically unrelated protein superfamilies: RFM and SPOUT. RESULTS: As a part of a large-scale project aiming at characterization of a complete set of RNA modification enzymes of model organisms, we have studied the Escherichia coli proteins YibK, LasT, YfhQ, and YbeA for their ability to introduce the last unassigned methylations of ribose at positions 32 and 34 of the tRNA anticodon loop. We found that YfhQ catalyzes the AdoMet-dependent formation of Cm32 or Um32 in tRNASer1 and tRNAGln2 and that an E. coli strain with a disrupted yfhQ gene lacks the tRNA:Cm32/Um32 methyltransferase activity. Thus, we propose to rename YfhQ as TrMet(Xm32) according to the recently proposed, uniform nomenclature for all RNA modification enzymes, or TrmJ, according to the traditional nomenclature for bacterial tRNA MTases. CONCLUSION: Our results reveal that methylation at position 32 is carried out by completely unrelated TrMet(Xm32) enzymes in eukaryota and prokaryota (RFM superfamily member Trm7 and SPOUT superfamily member TrmJ, respectively), mirroring the scenario observed in the case of the m1G37 modification (introduced by the RFM member Trm5 in eukaryota and archaea, and by the SPOUT member TrmD in bacteria)., Journal Article, Research Support, Non-U.S. Gov't, SCOPUS: ar.j, info:eu-repo/semantics/published

Published
2006

30. Sequence-structure-function relationships of a tRNA (m7G46) methyltransferase studied by homology modeling and site-directed mutagenesis.

Author

Purta, Elzbieta, Van Vliet, Françoise, Tricot, Catherine, De Bie, Lara, Feder, Marcin, Skowronek, Krzysztof, Droogmans, Louis, Bujnicki, Janusz Marek, Purta, Elzbieta, Van Vliet, Françoise, Tricot, Catherine, De Bie, Lara, Feder, Marcin, Skowronek, Krzysztof, Droogmans, Louis, and Bujnicki, Janusz Marek

Abstract

The Escherichia coli TrmB protein and its Saccharomyces cerevisiae ortholog Trm8p catalyze the S-adenosyl-L-methionine-dependent formation of 7-methylguanosine at position 46 (m7G46) in tRNA. To learn more about the sequence-structure-function relationships of these enzymes we carried out a thorough bioinformatics analysis of the tRNA:m7G methyltransferase (MTase) family to predict sequence regions and individual amino acid residues that may be important for the interactions between the MTase and the tRNA substrate, in particular the target guanosine 46. We used site-directed mutagenesis to construct a series of alanine substitutions and tested the activity of the mutants to elucidate the catalytic and tRNA-recognition mechanism of TrmB. The functional analysis of the mutants, together with the homology model of the TrmB structure and the results of the phylogenetic analysis, revealed the crucial residues for the formation of the substrate-binding site and the catalytic center in tRNA:m7G MTases., Comparative Study, Journal Article, Research Support, Non-U.S. Gov't, SCOPUS: ar.j, FLWIN, info:eu-repo/semantics/published

Published
2005

31. MODOMICS: a database of RNA modification pathways—2013 update

Author

Machnicka, Magdalena A., primary, Milanowska, Kaja, additional, Osman Oglou, Okan, additional, Purta, Elzbieta, additional, Kurkowska, Malgorzata, additional, Olchowik, Anna, additional, Januszewski, Witold, additional, Kalinowski, Sebastian, additional, Dunin-Horkawicz, Stanislaw, additional, Rother, Kristian M., additional, Helm, Mark, additional, Bujnicki, Janusz M., additional, and Grosjean, Henri, additional

Published
2012
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40. LEF1/β-Catenin Complex Regulates Transcription of the Cav3.1 Calcium Channel Gene (Cacna1g) in Thalamic Neurons of the Adult Brain.

Author

Wisniewska, Marta B., Misztal, Katarzyna, Michowski, Wojciech, Szczot, Marcin, Purta, Elzbieta, Lesniak, Wieslawa, Klejman, Monika E., Dabrowski, Michal, Filipkowski, Robert K., Nagalski, Andrzej, Mozrzymas, Jerzy W., and Kuznicki, Jacek

Subjects
GENETIC transcription, GENETIC regulation, CALCIUM channels, NEURONS, THALAMUS, CELL adhesion, CADHERINS, PHYSIOLOGY
Abstract

β-Catenin, together with LEF1/TCF transcription factors, activates genes involved in the proliferation and differentiation of neuronal precursor cells. In mature neurons, β-catenin participates in dendritogenesis and synaptic function as a component of the cadherin cell adhesion complex. However, the transcriptional activity of β-catenin in these cells remains elusive. In the present study, we found that in the adult mouse brain, β-catenin and LEF1 accumulate in the nuclei of neurons specifically in the thalamus. The particular electrophysiological properties of thalamic neurons depend on T-type calcium channels. Cav3.1 is the predominant T-type channel subunit in the thalamus, and we hypothesized that the Cacna1g gene encoding Cav3.1 is a target of the LEF1/ β-catenin complex. We demonstrated that the expression of Cacna1g is high in the thalamus and is further increased in thalamic neurons treated in vitro with LiCl or WNT3A, activators of β-catenin. Luciferase reporter assays confirmed that the Cacna1G promoter is activated by LEF1 and β-catenin, and footprinting analysis revealed four LEF1 binding sites in the proximal region of this promoter. Chromatin immunoprecipitation demonstrated that the Cacna1g proximal promoter is occupied by β-catenin in vivo in the thalamus, but not in the hippocampus. Moreover, WNT3Astimulation enhanced T-type current in cultured thalamic neurons. Together, our data indicate that the LEF1/ β-catenin complex regulates transcription of Cacna1g and uncover a novel function for β-catenin in mature neurons. We propose that β-catenin contributes to neuronal excitability not only by a local action at the synapse but also by activating gene expression in thalamic neurons. [ABSTRACT FROM AUTHOR]

Published
2010
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41. Sequence-structure-function analysis of the bifunctional enzyme MnmC that catalyses the last two steps in the biosynthesis of hypermodified nucleoside mnm5s2U in tRNA.

Author

Roovers, Martine, Oudjama, Yamina, Kaminska, Katarzyna H., Purta, Elzbieta, Caillet, Joël, Droogmans, Louis, and Bujnicki, Janusz M.

Abstract

MnmC catalyses the last two steps in the biosynthesis of 5-methylaminomethyl-2-thiouridine (mnm5s2U) in tRNA. Previously, we reported that this bifunctional enzyme is encoded by the yfcK open reading frame in the Escherichia coli K12 genome. However, the mechanism of its activity, in particular the potential structural and functional dependence of the domains responsible for catalyzing the two modification reactions, remains unknown. With the aid of the protein fold-recognition method, we constructed a structural model of MnmC in complex with the ligands and target nucleosides and studied the role of individual amino acids and entire domains by site-directed and deletion mutagenesis, respectively. We found out that the N-terminal domain contains residues responsible for binding of the S-adenosylmethionine cofactor and catalyzing the methylation of nm5s2U to form mnm5s2U, while the C-terminal domain contains residues responsible for binding of the FAD cofactor. Further, point mutants with compromised activity of either domain can complement each other to restore a fully functional enzyme. Thus, in the conserved fusion protein MnmC, the individual domains retain independence as enzymes. Interestingly, the N-terminal domain is capable of independent folding, while the isolated C-terminal domain is incapable of folding on its own, a situation similar to the one reported recently for the rRNA modification enzyme RsmC. Proteins, 2008. © 2008 Wiley-Liss, Inc. [ABSTRACT FROM AUTHOR]

Published
2008
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42. 2'-O-ribose methylation of cap2 in human: function and evolution in a horizontally mobile family.

Author

Werner M, Purta E, Kaminska KH, Cymerman IA, Campbell DA, Mittra B, Zamudio JR, Sturm NR, Jaworski J, and Bujnicki JM

Subjects
Evolution, Molecular, Humans, Methylation, Methyltransferases chemistry, Methyltransferases genetics, Multigene Family, Nuclear Proteins analysis, Protein Structure, Tertiary, RNA Caps chemistry, RNA, Small Nuclear metabolism, Recombinant Proteins metabolism, Methyltransferases metabolism, RNA Caps metabolism
Abstract

The 5' cap of human messenger RNA consists of an inverted 7-methylguanosine linked to the first transcribed nucleotide by a unique 5'-5' triphosphate bond followed by 2'-O-ribose methylation of the first and often the second transcribed nucleotides, likely serving to modify efficiency of transcript processing, translation and stability. We report the validation of a human enzyme that methylates the ribose of the second transcribed nucleotide encoded by FTSJD1, henceforth renamed HMTR2 to reflect function. Purified recombinant hMTr2 protein transfers a methyl group from S-adenosylmethionine to the 2'-O-ribose of the second nucleotide of messenger RNA and small nuclear RNA. Neither N(7) methylation of the guanosine cap nor 2'-O-ribose methylation of the first transcribed nucleotide are required for hMTr2, but the presence of cap1 methylation increases hMTr2 activity. The hMTr2 protein is distributed throughout the nucleus and cytosol, in contrast to the nuclear hMTr1. The details of how and why specific transcripts undergo modification with these ribose methylations remains to be elucidated. The 2'-O-ribose RNA cap methyltransferases are present in varying combinations in most eukaryotic and many viral genomes. With the capping enzymes in hand their biological purpose can be ascertained.

Published
2011
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43. Sequence-structure-function relationships of a tRNA (m7G46) methyltransferase studied by homology modeling and site-directed mutagenesis.

Author

Purta E, van Vliet F, Tricot C, De Bie LG, Feder M, Skowronek K, Droogmans L, and Bujnicki JM

Subjects
Amino Acid Sequence, Computational Biology, Escherichia coli Proteins genetics, Kinetics, Models, Molecular, Mutagenesis, Site-Directed, Phylogeny, Protein Conformation, Protein Structure, Secondary, Recombinant Proteins chemistry, Recombinant Proteins metabolism, Sequence Alignment, Sequence Homology, Amino Acid, tRNA Methyltransferases genetics, Escherichia coli enzymology, Escherichia coli Proteins chemistry, Escherichia coli Proteins metabolism, tRNA Methyltransferases chemistry, tRNA Methyltransferases metabolism
Abstract

The Escherichia coli TrmB protein and its Saccharomyces cerevisiae ortholog Trm8p catalyze the S-adenosyl-L-methionine-dependent formation of 7-methylguanosine at position 46 (m7G46) in tRNA. To learn more about the sequence-structure-function relationships of these enzymes we carried out a thorough bioinformatics analysis of the tRNA:m7G methyltransferase (MTase) family to predict sequence regions and individual amino acid residues that may be important for the interactions between the MTase and the tRNA substrate, in particular the target guanosine 46. We used site-directed mutagenesis to construct a series of alanine substitutions and tested the activity of the mutants to elucidate the catalytic and tRNA-recognition mechanism of TrmB. The functional analysis of the mutants, together with the homology model of the TrmB structure and the results of the phylogenetic analysis, revealed the crucial residues for the formation of the substrate-binding site and the catalytic center in tRNA:m7G MTases., (Copyright 2005 Wiley-Liss, Inc.)

Published
2005
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