Your search keyword '"RrmJ"' showing total 8 results

1. Methyltransferases of Riboviria.

Author

Mushegian, Arcady

Subjects

*PROTEIN domains, *METHYLTRANSFERASES, *PROTEIN structure, *AMINO acid sequence, *RNA modification & restriction, *SEQUENCE alignment

Abstract

Many viruses from the realm Riboviria infecting eukaryotic hosts encode protein domains with sequence similarity to S-adenosylmethionine-dependent methyltransferases. These protein domains are thought to be involved in methylation of the 5′-terminal cap structures in virus mRNAs. Some methyltransferase-like domains of Riboviria are homologous to the widespread cellular FtsJ/RrmJ-like methyltransferases involved in modification of cellular RNAs; other methyltransferases, found in a subset of positive-strand RNA viruses, have been assigned to a separate "Sindbis-like" family; and coronavirus-specific Nsp13/14-like methyltransferases appeared to be different from both those classes. The representative structures of proteins from all three groups belong to a specific variety of the Rossmann fold with a seven-stranded β-sheet, but it was unclear whether this structural similarity extends to the level of conserved sequence signatures. Here I survey methyltransferases in Riboviria and derive a joint sequence alignment model that covers all groups of virus methyltransferases and subsumes the previously defined conserved sequence motifs. Analysis of the spatial structures indicates that two highly conserved residues, a lysine and an aspartate, frequently contact a water molecule, which is located in the enzyme active center next to the methyl group of S-adenosylmethionine cofactor and could play a key role in the catalytic mechanism of the enzyme. Phylogenetic evidence indicates a likely origin of all methyltransferases of Riboviria from cellular RrmJ-like enzymes and their rapid divergence with infrequent horizontal transfer between distantly related viruses. [ABSTRACT FROM AUTHOR]

Published

2022

2. Methyltransferases of Riboviria

Author

Arcady Mushegian

Subjects

Riboviria, methyltransferase, S-adenosylmethionine, Rossmann fold, FtsJ, RrmJ, Microbiology, QR1-502

Abstract

Many viruses from the realm Riboviria infecting eukaryotic hosts encode protein domains with sequence similarity to S-adenosylmethionine-dependent methyltransferases. These protein domains are thought to be involved in methylation of the 5′-terminal cap structures in virus mRNAs. Some methyltransferase-like domains of Riboviria are homologous to the widespread cellular FtsJ/RrmJ-like methyltransferases involved in modification of cellular RNAs; other methyltransferases, found in a subset of positive-strand RNA viruses, have been assigned to a separate “Sindbis-like” family; and coronavirus-specific Nsp13/14-like methyltransferases appeared to be different from both those classes. The representative structures of proteins from all three groups belong to a specific variety of the Rossmann fold with a seven-stranded β-sheet, but it was unclear whether this structural similarity extends to the level of conserved sequence signatures. Here I survey methyltransferases in Riboviria and derive a joint sequence alignment model that covers all groups of virus methyltransferases and subsumes the previously defined conserved sequence motifs. Analysis of the spatial structures indicates that two highly conserved residues, a lysine and an aspartate, frequently contact a water molecule, which is located in the enzyme active center next to the methyl group of S-adenosylmethionine cofactor and could play a key role in the catalytic mechanism of the enzyme. Phylogenetic evidence indicates a likely origin of all methyltransferases of Riboviria from cellular RrmJ-like enzymes and their rapid divergence with infrequent horizontal transfer between distantly related viruses.

Published

2022

3. Loss of a single methylation in 23S rRNA delays 50S assembly at multiple late stages and impairs translation initiation and elongation.

Author

Wei Wang, Wanqiu Li, Xueliang Ge, Kaige Yan, Mandava, Chandra Sekhar, Sanyal, Suparna, and Ning Gao

Subjects

*ORGANELLE formation, *RIBOSOMAL RNA, *METHYLATION, *PEPTIDE bonds, *PROTEIN synthesis

Abstract

Ribosome biogenesis is a complex process, and dozens of factors are required to facilitate and regulate the subunit assembly in bacteria. The 2′-O-methylation of U2552 in 23S rRNA by methyltransferase RrmJ is a crucial step in late-stage assembly of the 50S subunit. Its absence results in severe growth defect and marked accumulation of pre50S assembly intermediates. In the present work, we employed cryoelectron microscopy to characterize a set of late-stage pre50S particles isolated from an Escherichia coli ΔrrmJ strain. These assembly intermediates (solved at 3.2 to 3.8 Å resolution) define a collection of late-stage particles on a progressive assembly pathway. Apart from the absence of L16, L35, and L36, major structural differences between these intermediates and the mature 50S subunit are clustered near the peptidyl transferase center, such as H38, H68-71, and H89-93. In addition, the ribosomal A-loop of the mature 50S subunit from ΔrrmJ strain displays large local flexibility on nucleotides next to unmethylated U2552. Fast kinetics-based biochemical assays demonstrate that the ΔrrmJ 50S subunit is only 50% active and two times slower than the WT 50S subunit in rapid subunit association. While the ΔrrmJ 70S ribosomes show no defect in peptide bond formation, peptide release, and ribosome recycling, they translocate with 20% slower rate than the WT ribosomes in each round of elongation. These defects amplify during synthesis of the full-length proteins and cause overall defect in protein synthesis. In conclusion, our data reveal the molecular roles of U2552 methylation in both ribosome biogenesis and protein translation. [ABSTRACT FROM AUTHOR]

Published

2020

4. Loss of a single methylation in 23S rRNA delays 50S assembly at multiple late stages and impairs translation initiation and elongation

Author

Wang, Li, Wanqiu, Li, Ge, Xueliang, Kaige, Yan, Mandava, Chandra Sekhar, Sanyal, Suparna, Gao, Ning, Wang, Li, Wanqiu, Li, Ge, Xueliang, Kaige, Yan, Mandava, Chandra Sekhar, Sanyal, Suparna, and Gao, Ning

Abstract

Ribosome biogenesis is a complex process, and dozens of factors are required to facilitate and regulate the subunit assembly in bacteria. The 2′-O-methylation of U2552 in 23S rRNA by methyltransferase RrmJ is a crucial step in late-stage assembly of the 50S subunit. Its absence results in severe growth defect and marked accumulation of pre50S assembly intermediates. In the present work, we employed cryoelectron microscopy to characterize a set of late-stage pre50S particles isolated from an Escherichia coli Δ rrmJ strain. These assembly intermediates (solved at 3.2 to 3.8 Å resolution) define a collection of late-stage particles on a progressive assembly pathway. Apart from the absence of L16, L35, and L36, major structural differences between these intermediates and the mature 50S subunit are clustered near the peptidyl transferase center, such as H38, H68-71, and H89-93. In addition, the ribosomal A-loop of the mature 50S subunit from Δ rrmJ strain displays large local flexibility on nucleotides next to unmethylated U2552. Fast kinetics-based biochemical assays demonstrate that the Δ rrmJ 50S subunit is only 50% active and two times slower than the WT 50S subunit in rapid subunit association. While the Δ rrmJ 70S ribosomes show no defect in peptide bond formation, peptide release, and ribosome recycling, they translocate with 20% slower rate than the WT ribosomes in each round of elongation. These defects amplify during synthesis of the full-length proteins and cause overall defect in protein synthesis. In conclusion, our data reveal the molecular roles of U2552 methylation in both ribosome biogenesis and protein translation., Author contributions: N.G. designed research; W.W., W.L., X.G., and C.S.M. performedresearch; K.Y. contributed new reagents/analytic tools; W.W., W.L., X.G., C.S.M., S.S., andN.G. analyzed data; and W.W., W.L., X.G., C.S.M., S.S., and N.G. wrote the paper.

Published

2020

5. MRM2 encodes a novel yeast mitochondrial 21S rRNA methyltransferase.

Author

Pintard, Lionel, Bujnicki, Janusz M., Lapeyre, Bruno, and Bonnerot, Claire

Subjects

*YEAST, *RNA, *METHYLTRANSFERASES, *TRANSFERASES, *ANGIOTENSIN converting enzyme, *ESCHERICHIA coli

Abstract

Mitochondria of the yeast Saccharomyces cerevisiae assemble their ribosomes from ribosomal proteins, encoded by the nuclear genome (with one exception), and rRNAs of 15S and 21S, encoded by the mitochondriat genome. Unlike cytoptasmic rRNA, which is highly modified, mitochondriat rRNA contains only three modified nucteotides: a pseudouridine (&Psi:2918) and two 2'-O-methylated riboses (Gm2270 and Um2791) located at the peptidyl transferase centre of 21S rRNA. We demonstrate here that the yeast nuclear genome encodes a mitochondrial protein, named Mrm2, which is required for methylating U2791 of 21S rRNA, both in vivo and in vitro. Deletion of the MRM2 gene causes thermosensitive respiration and leads to rapid toss of mitochondrial DNA. We propose that Mrm2p belongs to a new class of three eukaryotic RNA-modifying enzymes and is the orthologue of FtsJ/RrmJ, which methylates a nucteotide of the peptidy! transferase centre of Escherichia coli 23S rRNA that is homologous to U2791 of 21S rRNA. Our data suggest that this universally conserved modified nucleotide plays an important function in vivo, possibly by inducing conformationat rearrangement of the peptidyl transferase centre. [ABSTRACT FROM AUTHOR]

Published

2002

6. Loss of a single methylation in 23S rRNA delays 50S assembly at multiple late stages and impairs translation initiation and elongation.

Author

Wang W, Li W, Ge X, Yan K, Mandava CS, Sanyal S, and Gao N

Subjects

Cell Cycle Proteins genetics, Cell Cycle Proteins metabolism, Cryoelectron Microscopy, Gene Knockout Techniques, Methylation, Methyltransferases genetics, Methyltransferases metabolism, Models, Molecular, Ribosome Subunits, Large, Bacterial genetics, Ribosome Subunits, Large, Bacterial ultrastructure, Uridine metabolism, Escherichia coli physiology, Peptide Chain Elongation, Translational, Peptide Chain Initiation, Translational, RNA, Ribosomal, 23S metabolism, Ribosome Subunits, Large, Bacterial metabolism

Abstract

Ribosome biogenesis is a complex process, and dozens of factors are required to facilitate and regulate the subunit assembly in bacteria. The 2'-O-methylation of U2552 in 23S rRNA by methyltransferase RrmJ is a crucial step in late-stage assembly of the 50S subunit. Its absence results in severe growth defect and marked accumulation of pre50S assembly intermediates. In the present work, we employed cryoelectron microscopy to characterize a set of late-stage pre50S particles isolated from an Escherichia coli Δ rrmJ strain. These assembly intermediates (solved at 3.2 to 3.8 Å resolution) define a collection of late-stage particles on a progressive assembly pathway. Apart from the absence of L16, L35, and L36, major structural differences between these intermediates and the mature 50S subunit are clustered near the peptidyl transferase center, such as H38, H68-71, and H89-93. In addition, the ribosomal A-loop of the mature 50S subunit from Δ rrmJ strain displays large local flexibility on nucleotides next to unmethylated U2552. Fast kinetics-based biochemical assays demonstrate that the Δ rrmJ 50S subunit is only 50% active and two times slower than the WT 50S subunit in rapid subunit association. While the Δ rrmJ 70S ribosomes show no defect in peptide bond formation, peptide release, and ribosome recycling, they translocate with 20% slower rate than the WT ribosomes in each round of elongation. These defects amplify during synthesis of the full-length proteins and cause overall defect in protein synthesis. In conclusion, our data reveal the molecular roles of U2552 methylation in both ribosome biogenesis and protein translation., Competing Interests: The authors declare no competing interest.

Published

2020

7. Reläskydd för transformatorer : Funktioneroch Skyddsfilosofier

Author

Danielsson, Jonny

Subjects

rrmj, reläskyddshistoria, reläskyddsfilosofi, inrusningsström, rydsa20, reläskydd, stabiliseringskurva, kopplingsarter, statiskt, transformator, skyddsfilosofi, differentialskydd, elektromekaniskt, överströmsskydd

Abstract

Skyddsfilosofierna gällande reläskyddsinställningar har varit densamma genom åren. En god avvägning mellan tillförlitlighet, selektivitet, enkelhet, hastighet och ekonomi krävs. Hur det görs är ofta ganska individuellt och skyddsfilosofier kan skilja en del mellan olika ingenjörer och därför finns inget exakt svar på hur den optimala lösningen för ett specifikt reläskyddssystem ska se ut. Närmare undersökningar på funktioner och jämförelser har gjorts mellan det elektromekaniska överströmsskyddet RRMJ 4 och det nya numeriska skyddet ABB REF 615. De båda differentialskydden, det statiska RYDSA 20 och det numeriska SPAD 346 har också undersökts och jämförts. Arbetet har visat att de elektromekaniska och statiska reläskydden var enkla i sitt utförande och pålitliga. De äldre skydd som testades fungerade fortfarande bra efter 30-40 år i drift. Som väntat så var REF 615 betydligt snabbare än dess äldre motsvarighet RRMJ 4. Det som var mindre väntat var att det statiska differentialskyddet RYDSA 20 var ca 10 ms snabbare än det det numeriska skyddet SPAD 346. Kompabilititetsproblem av program till enheten upptäcktes vid inställningen av REF 615. Slutsatsen blev att snabbhet och tillförlitlighet har förbättrats med de numeriska skydden, fler funktioner finns också inbyggda i samma burk. Men med mer funktioner blir de mer komplexa också och kräver mer av den person, som ska göra alla inställningar. Rätt inställda så har de numeriska skydden inneburit ett stort steg framåt. De äldre skydden var enkla, vilket är en stor fördel, men uppväger inte de fördelar de nya numeriska skydden har inneburit. Protection philosophies have been the same throughout the years. A good balance between reliability, selectivity, simplicity, speed and economy are required. How it is done is often quite individually and protection philosophies may differ somewhat between different engineers, and therefore there is no exact answer to how the optimal solution for a specific relay protection system should look like. More detailed studies on the features and comparisons have been made between the electromechanical overcurrent protection RRMJ 4 and the new numerical protection ABB REF 615. Both differential protections, the static RYDSA 20 and the numerical SPAD 346 has also been investigated and compared. The work has shown that the electromechanical and static relays guards were simple in its execution and trustworthy. The elderly protection tested still worked fine after 30-40 years of operation. As expected, it was the REF 615 that was significantly faster than its older counterpart RRMJ 4. What was less expected was that the static differential protection RYDSA 20 was about 10 ms faster than the numerical protection SPAD 346. The conclusion was that the speed and reliability have been improved with the numerical protections and more features are also built in. But with more features, they become more complex and also require more of the person who will make all the settings. Set correctly so has the numerical protections meant a great step forward. The older systems were simple, which is a big advantage, but do not outweigh the benefits of what the new numerical protections have meant.

Published

2014

8. Protection relay for transformers : Functions and Protection Philosophies

Author

Danielsson, Jonny

Subjects

rrmj, reläskyddshistoria, reläskyddsfilosofi, inrusningsström, rydsa20, reläskydd, stabiliseringskurva, kopplingsarter, statiskt, transformator, skyddsfilosofi, differentialskydd, elektromekaniskt, överströmsskydd

Abstract

Skyddsfilosofierna gällande reläskyddsinställningar har varit densamma genom åren. En god avvägning mellan tillförlitlighet, selektivitet, enkelhet, hastighet och ekonomi krävs. Hur det görs är ofta ganska individuellt och skyddsfilosofier kan skilja en del mellan olika ingenjörer och därför finns inget exakt svar på hur den optimala lösningen för ett specifikt reläskyddssystem ska se ut. Närmare undersökningar på funktioner och jämförelser har gjorts mellan det elektromekaniska överströmsskyddet RRMJ 4 och det nya numeriska skyddet ABB REF 615. De båda differentialskydden, det statiska RYDSA 20 och det numeriska SPAD 346 har också undersökts och jämförts. Arbetet har visat att de elektromekaniska och statiska reläskydden var enkla i sitt utförande och pålitliga. De äldre skydd som testades fungerade fortfarande bra efter 30-40 år i drift. Som väntat så var REF 615 betydligt snabbare än dess äldre motsvarighet RRMJ 4. Det som var mindre väntat var att det statiska differentialskyddet RYDSA 20 var ca 10 ms snabbare än det det numeriska skyddet SPAD 346. Kompabilititetsproblem av program till enheten upptäcktes vid inställningen av REF 615. Slutsatsen blev att snabbhet och tillförlitlighet har förbättrats med de numeriska skydden, fler funktioner finns också inbyggda i samma burk. Men med mer funktioner blir de mer komplexa också och kräver mer av den person, som ska göra alla inställningar. Rätt inställda så har de numeriska skydden inneburit ett stort steg framåt. De äldre skydden var enkla, vilket är en stor fördel, men uppväger inte de fördelar de nya numeriska skydden har inneburit. Protection philosophies have been the same throughout the years. A good balance between reliability, selectivity, simplicity, speed and economy are required. How it is done is often quite individually and protection philosophies may differ somewhat between different engineers, and therefore there is no exact answer to how the optimal solution for a specific relay protection system should look like. More detailed studies on the features and comparisons have been made between the electromechanical overcurrent protection RRMJ 4 and the new numerical protection ABB REF 615. Both differential protections, the static RYDSA 20 and the numerical SPAD 346 has also been investigated and compared. The work has shown that the electromechanical and static relays guards were simple in its execution and trustworthy. The elderly protection tested still worked fine after 30-40 years of operation. As expected, it was the REF 615 that was significantly faster than its older counterpart RRMJ 4. What was less expected was that the static differential protection RYDSA 20 was about 10 ms faster than the numerical protection SPAD 346. The conclusion was that the speed and reliability have been improved with the numerical protections and more features are also built in. But with more features, they become more complex and also require more of the person who will make all the settings. Set correctly so has the numerical protections meant a great step forward. The older systems were simple, which is a big advantage, but do not outweigh the benefits of what the new numerical protections have meant.

Published

2014