Your search keyword '"Mekhedov Sergei L"' showing total 16 results

1. The COG database: an updated version includes eukaryotes

Author

Sverdlov Alexander V, Smirnov Sergei, Rao B Sridhar, Nikolskaya Anastasia N, Mekhedov Sergei L, Mazumder Raja, Krylov Dmitri M, Koonin Eugene V, Kiryutin Boris, Jacobs Aviva R, Jackson John D, Fedorova Natalie D, Tatusov Roman L, Vasudevan Sona, Wolf Yuri I, Yin Jodie J, and Natale Darren A

Subjects

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

Abstract

Abstract Background The availability of multiple, essentially complete genome sequences of prokaryotes and eukaryotes spurred both the demand and the opportunity for the construction of an evolutionary classification of genes from these genomes. Such a classification system based on orthologous relationships between genes appears to be a natural framework for comparative genomics and should facilitate both functional annotation of genomes and large-scale evolutionary studies. Results We describe here a major update of the previously developed system for delineation of Clusters of Orthologous Groups of proteins (COGs) from the sequenced genomes of prokaryotes and unicellular eukaryotes and the construction of clusters of predicted orthologs for 7 eukaryotic genomes, which we named KOGs after eukaryotic orthologous groups. The COG collection currently consists of 138,458 proteins, which form 4873 COGs and comprise 75% of the 185,505 (predicted) proteins encoded in 66 genomes of unicellular organisms. The eukaryotic orthologous groups (KOGs) include proteins from 7 eukaryotic genomes: three animals (the nematode Caenorhabditis elegans, the fruit fly Drosophila melanogaster and Homo sapiens), one plant, Arabidopsis thaliana, two fungi (Saccharomyces cerevisiae and Schizosaccharomyces pombe), and the intracellular microsporidian parasite Encephalitozoon cuniculi. The current KOG set consists of 4852 clusters of orthologs, which include 59,838 proteins, or ~54% of the analyzed eukaryotic 110,655 gene products. Compared to the coverage of the prokaryotic genomes with COGs, a considerably smaller fraction of eukaryotic genes could be included into the KOGs; addition of new eukaryotic genomes is expected to result in substantial increase in the coverage of eukaryotic genomes with KOGs. Examination of the phyletic patterns of KOGs reveals a conserved core represented in all analyzed species and consisting of ~20% of the KOG set. This conserved portion of the KOG set is much greater than the ubiquitous portion of the COG set (~1% of the COGs). In part, this difference is probably due to the small number of included eukaryotic genomes, but it could also reflect the relative compactness of eukaryotes as a clade and the greater evolutionary stability of eukaryotic genomes. Conclusion The updated collection of orthologous protein sets for prokaryotes and eukaryotes is expected to be a useful platform for functional annotation of newly sequenced genomes, including those of complex eukaryotes, and genome-wide evolutionary studies.

Published

2003

2. Myosin-driven transport network in plants

Author

Kurth, Elizabeth G., Peremyslov, Valera V., Turner, Hannah L., Makarova, Kira S., Iranzo, Jaime, Mekhedov, Sergei L., Koonin, Eugene V., and Dolja, Valerian V.

Published

2017

3. Mammalian retrovirus-like protein PEG10 packages its own mRNA and can be pseudotyped for mRNA delivery

Author

Howard Hughes Medical Institute, McGovern Institute for Brain Research at MIT, Massachusetts Institute of Technology. Department of Brain and Cognitive Sciences, Massachusetts Institute of Technology. Department of Biological Engineering, Massachusetts Institute of Technology. Department of Biology, Segel, Michael, Lash, Blake, Song, Jingwei, Ladha, Alim, Liu, Catherine C, Jin, Xin, Mekhedov, Sergei L, Macrae, Rhiannon K, Koonin, Eugene V, Zhang, Feng, Howard Hughes Medical Institute, McGovern Institute for Brain Research at MIT, Massachusetts Institute of Technology. Department of Brain and Cognitive Sciences, Massachusetts Institute of Technology. Department of Biological Engineering, Massachusetts Institute of Technology. Department of Biology, Segel, Michael, Lash, Blake, Song, Jingwei, Ladha, Alim, Liu, Catherine C, Jin, Xin, Mekhedov, Sergei L, Macrae, Rhiannon K, Koonin, Eugene V, and Zhang, Feng

Abstract

Hitching a ride with a retroelement Retroviruses and retroelements have inserted their genetic code into mammalian genomes throughout evolution. Although many of these integrated virus-like sequences pose a threat to genomic integrity, some have been retooled by mammalian cells to perform essential roles in development. Segel et al . found that one of these retroviral-like proteins, PEG10, directly binds to and secretes its own mRNA in extracellular virus–like capsids. These virus-like particles were then pseudotyped with fusogens to deliver functional mRNA cargos to mammalian cells. This potentially provides an endogenous vector for RNA-based gene therapy. —DJ

Published

2022

4. Mammalian retrovirus-like protein PEG10 packages its own mRNA and can be pseudotyped for mRNA delivery

Author

Segel, Michael, primary, Lash, Blake, additional, Song, Jingwei, additional, Ladha, Alim, additional, Liu, Catherine C., additional, Jin, Xin, additional, Mekhedov, Sergei L., additional, Macrae, Rhiannon K., additional, Koonin, Eugene V., additional, and Zhang, Feng, additional

Published

2021

5. Mitochondria-rough-ER contacts in the liver regulate systemic lipid homeostasis

Author

Anastasia, Irene, primary, Ilacqua, Nicolò, additional, Raimondi, Andrea, additional, Lemieux, Philippe, additional, Ghandehari-Alavijeh, Rana, additional, Faure, Guilhem, additional, Mekhedov, Sergei L., additional, Williams, Kevin J., additional, Caicci, Federico, additional, Valle, Giorgio, additional, Giacomello, Marta, additional, Quiroga, Ariel D., additional, Lehner, Richard, additional, Miksis, Michael J., additional, Toth, Katalin, additional, de Aguiar Vallim, Thomas Q., additional, Koonin, Eugene V., additional, Scorrano, Luca, additional, and Pellegrini, Luca, additional

Published

2021

6. Genomic determinants of sporulation in Bacilli and Clostridia: towards the minimal set of sporulation-specific genes

Author

Galperin, Michael Y., Mekhedov, Sergei L., Puigbo, Pere, Smirnov, Sergey, Wolf, Yuri I., and Rigden, Daniel J.

Published

2012

7. Prevalence of intron gain over intron loss in the evolution of paralogous gene families

Author

Babenko, Vladimir N., Rogozin, Igor B., Mekhedov, Sergei L., and Koonin, Eugene V.

Published

2004

8. A comprehensive evolutionary classification of proteins encoded in complete eukaryotic genomes

Author

Koonin, Eugene V, Fedorova, Natalie D, Jackson, John D, Jacobs, Aviva R, Krylov, Dmitri M, Makarova, Kira S, Mazumder, Raja, Mekhedov, Sergei L, Nikolskaya, Anastasia N, Rao, B Sridhar, Rogozin, Igor B, Smirnov, Sergei, Sorokin, Alexander V, Sverdlov, Alexander V, Vasudevan, Sona, Wolf, Yuri I, Yin, Jodie J, and Natale, Darren A

Published

2004

9. The complex domain architecture of SAMD9 family proteins, predicted STAND-like NTPases, suggests new links to inflammation and apoptosis

Author

Mekhedov, Sergei L., primary, Makarova, Kira S., additional, and Koonin, Eugene V., additional

Published

2017

10. The complex domain architecture of SAMD9 family proteins, predicted STANDlike NTPases, suggests new links to inflammation and apoptosis.

Author

Mekhedov, Sergei L., Makarova, Kira S., and Koonin, Eugene V.

Subjects

*INFLAMMATION, *APOPTOSIS, *VIRUS inhibitors, *ANTINEOPLASTIC agents, *ACTINOBACTERIA

Abstract

We report a comprehensive computational dissection of the domain architecture of the SAMD9 family proteins that are involved in antivirus and antitumor response in humans. We show that the SAMD9 protein family is represented in most animals and also, unexpectedly, in bacteria, in particular actinomycetes. From the N to C terminus, the core SAMD9 family architecture includes DNA/RNA-binding AlbA domain, a variant Sir2-like domain, a STAND-like P-loop NTPase, an array of TPR repeats and an OB-fold domain with predicted RNA-binding properties. Vertebrate SAMD9 family proteins contain the eponymous SAM domain capable of polymerization, whereas some family members from other animals instead contain homotypic adaptor domains of the DEATH superfamily, known as dedicated components of apoptosis networks. Such complex domain architecture is reminiscent of the STAND superfamily NTPases that are involved in various signaling processes, including programmed cell death, in both eukaryotes and prokaryotes. These findings suggest that SAMD9 is a hub of a novel, evolutionarily conserved defense network that remains to be characterized. [ABSTRACT FROM AUTHOR]

Published

2017

11. Genomic determinants of sporulation inBacilliandClostridia: towards the minimal set of sporulation‐specific genes

Author

Galperin, Michael Y., primary, Mekhedov, Sergei L., additional, Puigbo, Pere, additional, Smirnov, Sergey, additional, Wolf, Yuri I., additional, and Rigden, Daniel J., additional

Published

2012

12. Selection for short introns in highly expressed genes

Author

Castillo-Davis, Cristian I., primary, Mekhedov, Sergei L., additional, Hartl, Daniel L., additional, Koonin, Eugene V., additional, and Kondrashov, Fyodor A., additional

Published

2002

13. Gibberellin promotes histone H1 kinase activity and the expression of cdc2 and cyclin genes during the induction of rapid growth in deepwater rice internodes

Author

Sauter, Margret, primary, Mekhedov, Sergei L., additional, and Kende, Hans, additional

Published

1995

14. The COG database: an updated version includes eukaryotes.

Author

Tatusov, Roman L., Fedorova, Natalie D., Jackson, John D., Jacobs, Aviva R., Kiryutin, Boris, Koonin, Eugene V., Krylov, Dmitri M., Mazumder, Raja, Mekhedov, Sergei L., Nikolskaya, Anastasia N., Rao, B. Sridhar, Smirnov, Sergei, Sverdlov, Alexander V., Vasudevan, Sona, Wolf, Yuri I., Yin, Jodie J., and Natale, Darren A.

Subjects

DATABASES, PROTEINS, PROKARYOTES, GENOMES, GENES

Abstract

Background: The availability of multiple, essentially complete genome sequences of prokaryotes and eukaryotes spurred both the demand and the opportunity for the construction of an evolutionary classification of genes from these genomes. Such a classification system based on orthologous relationships between genes appears to be a natural framework for comparative genomics and should facilitate both functional annotation of genomes and large-scale evolutionary studies. Results: We describe here a major update of the previously developed system for delineation of Clusters of Orthologous Groups of proteins (COGs) from the sequenced genomes of prokaryotes and unicellular eukaryotes and the construction of clusters of predicted orthologs for 7 eukaryotic genomes, which we named KOGs after eukaryotic orthologous groups. The COG collection currently consists of 138,458 proteins, which form 4873 COGs and comprise 75% of the 185,505 (predicted) proteins encoded in 66 genomes of unicellular organisms. The eukaryotic orthologous groups (KOGs) include proteins from 7 eukaryotic genomes: three animals (the nematode Caenorhabditis elegans, the fruit fly Drosophila melanogaster and Homo sapiens), one plant, Arabidopsis thaliana, two fungi (Saccharomyces cerevisiae and Schizosaccharomyces pombe), and the intracellular microsporidian parasite Encephalitozoon cuniculi. The current KOG set consists of 4852 clusters of orthologs, which include 59,838 proteins, or ~54% of the analyzed eukaryotic 110,655 gene products. Compared to the coverage of the prokaryotic genomes with COGs, a considerably smaller fraction of eukaryotic genes could be included into the KOGs; addition of new eukaryotic genomes is expected to result in substantial increase in the coverage of eukaryotic genomes with KOGs. Examination of the phyletic patterns of KOGs reveals a conserved core represented in all analyzed species and consisting of ~20% of the KOG set. This conserved portion of the KOG set is much greater than the ubiquitous portion of the COG set (~1% of the COGs). In part, this difference is probably due to the small number of included eukaryotic genomes, but it could also reflect the relative compactness of eukaryotes as a clade and the greater evolutionary stability of eukaryotic genomes. Conclusion: The updated collection of orthologous protein sets for prokaryotes and eukaryotes is expected to be a useful platform for functional annotation of newly sequenced genomes, including those of complex eukaryotes, and genome-wide evolutionary studies. [ABSTRACT FROM AUTHOR]

Published

2003

15. Submergence Enhances Expression of a Gene Encoding 1-Aminocyclopropane-1-Carboxylate Oxidase in Deepwater Rice.

Author

Mekhedov, Sergei L. and Kende, Hans

Subjects

*AMINOCYCLOPROPANECARBOXYLATE synthase, *DEEPWATER rice, *CARBOXYLIC acids, *ETHYLENE, *GENE expression in plants, *MOLECULAR cloning, *MESSENGER RNA, *PLANT enzymes

Abstract

Partial submergence greatly stimulates internodal growth in deepwater rice (Oryza sativa L.). Previous work has shown that the effect of submergence is, at least in part, mediated by ethylene, which accumulates in the air spaces of submerged internodes. To investigate the expression of the genes encoding ethylene biosynthetic enzymes during accelerated growth of deepwater rice, we cloned a 1-aminocyclopropane- 1-carboxylate (ACC) oxidase cDNA (OSACO1) from internodes of submerged plants and measured the activity of the enzyme in tissue extracts with an improved assay. We found an increase in ACC oxidase mRNA levels and enzyme activity after 4 to 24 h of submergence. Thus, it is likely that ethylene biosynthesis in internodes of deepwater rice is controlled, at least in part, at the level of ACC oxidase. [ABSTRACT FROM AUTHOR]

Published

1996

16. The COG database: An updated version includes eukaryotes

Author

Tatusov, Roman L., Natalie Abrams, Jackson, John D., Jacobs, Aviva R., Kiryutin, Boris, Koonin, Eugene V., Krylov, Dmitri M., Mazumder, Raja, Mekhedov, Sergei L., Nikolskaya, Anastasia N., Rao, B. Sridhar, Smirnov, Sergei, Sverdlov, Alexander V., Vasudevan, Sona, Wolf, Yuri I., Yin, Jodie J., and Natale, Darren A.

Subjects

fungi, Proteins, lcsh:Computer applications to medicine. Medical informatics, United States, Evolution, Molecular, Eukaryotic Cells, National Institutes of Health (U.S.), lcsh:Biology (General), Terminology as Topic, Animals, Humans, lcsh:R858-859.7, Databases, Nucleic Acid, Databases, Protein, lcsh:QH301-705.5, Research Article

Abstract

Background The availability of multiple, essentially complete genome sequences of prokaryotes and eukaryotes spurred both the demand and the opportunity for the construction of an evolutionary classification of genes from these genomes. Such a classification system based on orthologous relationships between genes appears to be a natural framework for comparative genomics and should facilitate both functional annotation of genomes and large-scale evolutionary studies. Results We describe here a major update of the previously developed system for delineation of Clusters of Orthologous Groups of proteins (COGs) from the sequenced genomes of prokaryotes and unicellular eukaryotes and the construction of clusters of predicted orthologs for 7 eukaryotic genomes, which we named KOGs after eukaryotic orthologous groups. The COG collection currently consists of 138,458 proteins, which form 4873 COGs and comprise 75% of the 185,505 (predicted) proteins encoded in 66 genomes of unicellular organisms. The eukaryotic orthologous groups (KOGs) include proteins from 7 eukaryotic genomes: three animals (the nematode Caenorhabditis elegans, the fruit fly Drosophila melanogaster and Homo sapiens), one plant, Arabidopsis thaliana, two fungi (Saccharomyces cerevisiae and Schizosaccharomyces pombe), and the intracellular microsporidian parasite Encephalitozoon cuniculi. The current KOG set consists of 4852 clusters of orthologs, which include 59,838 proteins, or ~54% of the analyzed eukaryotic 110,655 gene products. Compared to the coverage of the prokaryotic genomes with COGs, a considerably smaller fraction of eukaryotic genes could be included into the KOGs; addition of new eukaryotic genomes is expected to result in substantial increase in the coverage of eukaryotic genomes with KOGs. Examination of the phyletic patterns of KOGs reveals a conserved core represented in all analyzed species and consisting of ~20% of the KOG set. This conserved portion of the KOG set is much greater than the ubiquitous portion of the COG set (~1% of the COGs). In part, this difference is probably due to the small number of included eukaryotic genomes, but it could also reflect the relative compactness of eukaryotes as a clade and the greater evolutionary stability of eukaryotic genomes. Conclusion The updated collection of orthologous protein sets for prokaryotes and eukaryotes is expected to be a useful platform for functional annotation of newly sequenced genomes, including those of complex eukaryotes, and genome-wide evolutionary studies.