%0 Journal Article %1 pmid18621711 %A Kroiss, M. %A Schultz, J. %A Wiesner, J. %A Chari, A. %A Sickmann, A. %A Fischer, U. %D 2008 %J Proc. Natl. Acad. Sci. U.S.A. %K imported myown protein_evolution %P 10045--10050 %T Evolution of an RNP assembly system: a minimal SMN complex facilitates formation of UsnRNPs in Drosophila melanogaster %V 105 %X In vertebrates, assembly of spliceosomal uridine-rich small nuclear ribonucleoproteins (UsnRNPs) is mediated by the SMN complex, a macromolecular entity composed of the proteins SMN and Gemins 2-8. Here we have studied the evolution of this machinery using complete genome assemblies of multiple model organisms. The SMN complex has gained complexity in evolution by a blockwise addition of Gemins onto an ancestral core complex composed of SMN and Gemin2. In contrast to this overall evolutionary trend to more complexity in metazoans, orthologs of most Gemins are missing in dipterans. In accordance with these bioinformatic data a previously undescribed biochemical purification strategy elucidated that the dipteran Drosophila melanogaster contains an SMN complex of remarkable simplicity. Surprisingly, this minimal complex not only mediates the assembly reaction in a manner very similar to its vertebrate counterpart, but also prevents misassembly onto nontarget RNAs. Our data suggest that only a minority of Gemins are required for the assembly reaction per se, whereas others may serve additional functions in the context of UsnRNP biogenesis. The evolution of the SMN complex is an interesting example of how the simplification of a biochemical process contributes to genome compaction.

@article{pmid18621711, abstract = {In vertebrates, assembly of spliceosomal uridine-rich small nuclear ribonucleoproteins (UsnRNPs) is mediated by the SMN complex, a macromolecular entity composed of the proteins SMN and Gemins 2-8. Here we have studied the evolution of this machinery using complete genome assemblies of multiple model organisms. The SMN complex has gained complexity in evolution by a blockwise addition of Gemins onto an ancestral core complex composed of SMN and Gemin2. In contrast to this overall evolutionary trend to more complexity in metazoans, orthologs of most Gemins are missing in dipterans. In accordance with these bioinformatic data a previously undescribed biochemical purification strategy elucidated that the dipteran Drosophila melanogaster contains an SMN complex of remarkable simplicity. Surprisingly, this minimal complex not only mediates the assembly reaction in a manner very similar to its vertebrate counterpart, but also prevents misassembly onto nontarget RNAs. Our data suggest that only a minority of Gemins are required for the assembly reaction per se, whereas others may serve additional functions in the context of UsnRNP biogenesis. The evolution of the SMN complex is an interesting example of how the simplification of a biochemical process contributes to genome compaction.}, added-at = {2011-07-21T16:10:59.000+0200}, author = {Kroiss, M. and Schultz, J. and Wiesner, J. and Chari, A. and Sickmann, A. and Fischer, U.}, biburl = {https://www.bibsonomy.org/bibtex/28f6b70400b57dda1c9d44ae28e80426e/jschultz}, interhash = {bd0b2b867d0db1836a07d218da2f8294}, intrahash = {8f6b70400b57dda1c9d44ae28e80426e}, journal = {Proc. Natl. Acad. Sci. U.S.A.}, keywords = {imported myown protein_evolution}, month = jul, pages = {10045--10050}, timestamp = {2017-06-09T10:29:47.000+0200}, title = {{{E}volution of an {R}{N}{P} assembly system: a minimal {S}{M}{N} complex facilitates formation of {U}sn{R}{N}{P}s in {D}rosophila melanogaster}}, volume = 105, year = 2008 }