dc.contributor.author | Růžička, Petr | |
dc.date.accessioned | 2021-12-06T13:45:19Z | |
dc.date.available | 2021-12-06T13:45:19Z | |
dc.date.issued | 2011 | |
dc.date.submitted | 2011-05-20 | |
dc.identifier.uri | https://dspace.jcu.cz/handle/123456789/24120 | |
dc.description.abstract | Many eukaryotic genes do not follow simple vertical inheritance. Elongation factor 1? (EF-1?)
and methionine adenosyl transferase (MAT) are enzymes with complicated evolutionary histories
and, interestingly, the two cases have several features in common. These essential enzymes occur
as two relatively divergent paralogs (EF-1?/EFL, MAT/MATX) that have patchy distributions in
eukaryotic lineages that are nearly mutually exclusive. To explain such distributions, we must
invoke either multiple eukaryote-to-eukaryote horizontal gene transfers (HGTs) followed by
functional replacement, or presence of both paralogs in the common ancestor followed by longterm
co-existence and differential losses in various eukaryotic lineages. To understand the
evolution of these paralogs, we have performed in vivo experiments in Trypanosoma brucei
addressing the consequences of long-term co-expression and functional replacement. In the first
experiment of its kind, we have demonstrated that EF-1? and MAT can be simultaneously
expressed with EFL and MATX, respectively, without affecting the growth of the flagellates.
After the endogenous MAT or EF-1? was down-regulated by RNA interference, MATX
immediately substituted for its paralog, while EFL was not able to substitute for EF-1?, leading
to mortality. We conclude that MATX is naturally capable of evolving patchy paralog
distribution via HGTs and/or long term co-expression and differential losses. The capability of
EFL to spread by HGT is lower and so the patchy distribution of EF-1?/EFL paralogs was
probably shaped mainly by deep paralogy followed by long term co-existence and differential
losses. | cze |
dc.format | 29 | |
dc.format | 29 | |
dc.language.iso | eng | |
dc.publisher | Jihočeská univerzita | cze |
dc.rights | Bez omezení | |
dc.subject | EFL | cze |
dc.subject | MATX | cze |
dc.subject | horizontal gene transfer | cze |
dc.subject | functional rescue | cze |
dc.subject | RNAi | cze |
dc.subject | Trypanosoma | cze |
dc.subject | EFL | eng |
dc.subject | MATX | eng |
dc.subject | horizontal gene transfer | eng |
dc.subject | functional rescue | eng |
dc.subject | RNAi | eng |
dc.subject | Trypanosoma | eng |
dc.title | Experimental examination of EFL and MATX
eukaryotic horizontal gene transfers: co-existence of
mutually exclusive transcripts predates functional
rescue | cze |
dc.title.alternative | Experimental examination of EFL and MATX
eukaryotic horizontal gene transfers: co-existence of
mutually exclusive transcripts predates functional
rescue | eng |
dc.type | rigorózní práce | cze |
dc.identifier.stag | 24910 | |
dc.description.abstract-translated | Many eukaryotic genes do not follow simple vertical inheritance. Elongation factor 1? (EF-1?)
and methionine adenosyl transferase (MAT) are enzymes with complicated evolutionary histories
and, interestingly, the two cases have several features in common. These essential enzymes occur
as two relatively divergent paralogs (EF-1?/EFL, MAT/MATX) that have patchy distributions in
eukaryotic lineages that are nearly mutually exclusive. To explain such distributions, we must
invoke either multiple eukaryote-to-eukaryote horizontal gene transfers (HGTs) followed by
functional replacement, or presence of both paralogs in the common ancestor followed by longterm
co-existence and differential losses in various eukaryotic lineages. To understand the
evolution of these paralogs, we have performed in vivo experiments in Trypanosoma brucei
addressing the consequences of long-term co-expression and functional replacement. In the first
experiment of its kind, we have demonstrated that EF-1? and MAT can be simultaneously
expressed with EFL and MATX, respectively, without affecting the growth of the flagellates.
After the endogenous MAT or EF-1? was down-regulated by RNA interference, MATX
immediately substituted for its paralog, while EFL was not able to substitute for EF-1?, leading
to mortality. We conclude that MATX is naturally capable of evolving patchy paralog
distribution via HGTs and/or long term co-expression and differential losses. The capability of
EFL to spread by HGT is lower and so the patchy distribution of EF-1?/EFL paralogs was
probably shaped mainly by deep paralogy followed by long term co-existence and differential
losses. | eng |
dc.date.accepted | 2011-05-25 | |
dc.description.department | Přírodovědecká fakulta | cze |
dc.thesis.degree-discipline | Experimentální biologie | cze |
dc.thesis.degree-grantor | Jihočeská univerzita. Přírodovědecká fakulta | cze |
dc.thesis.degree-name | RNDr. | |
dc.thesis.degree-program | Biologie | cze |
dc.description.grade | Dokončená práce s úspěšnou obhajobou | cze |