Abstract
BackgroundMost genes introduced into phototrophic eukaryotes during the process of endosymbiosis are either lost or relocated into the host nuclear genome. In contrast, groEL homologues are found in different genome compartments among phototrophic eukaryotes. Comparative sequence analyses of recently available genome data, have allowed us to reconstruct the evolutionary history of these genes and propose a hypothesis that explains the unusual genome distribution of groEL homologues.ResultsOur analyses indicate that while two distinct groEL genes were introduced into eukaryotes by a progenitor of plastids, these particular homologues have not been maintained in all evolutionary lineages. This is of significant interest, because two chaperone proteins always co-occur in oxygenic photosynthetic organisms. We infer strikingly different lineage specific processes of evolution involving deletion, duplication and targeting of groEL proteins.ConclusionThe requirement of two groEL homologues for chaperon function in phototrophs has provided a constraint that has shaped convergent evolutionary scenarios in divergent evolutionary lineages. GroEL provides a general evolutionary model for studying gene transfers and convergent evolutionary processes among eukaryotic lineages.
Highlights
Most genes introduced into phototrophic eukaryotes during the process of endosymbiosis are either lost or relocated into the host nuclear genome
PCC 6803 and on plastid chromosomes of eukaryotes has highlighted a surprisingly varied distribution of genome locations for GroEL homologues amongst photosynthetic taxa [5,6]
Genes encoding GroEL have not been located within the sequenced genomes of chloroplasts in green algae and land plants, but two nuclear homologs of groEL, the cpn60s, have been detected in the nuclear genome of Chlamydomonas reinhardii and some land plants
Summary
Most genes introduced into phototrophic eukaryotes during the process of endosymbiosis are either lost or relocated into the host nuclear genome. The solar powered energy factories of phototrophic eukaryotes, either translate mRNAs for their organelle-encoded genes or import nuclear-encoded proteins. In both cases, correct folding of proteins is managed by chaperones such as those of the GroEL family. We develop here a hypothesis for differential transfer and gene duplication that explains the distribution of groEL homologues amongst the mulitple genomes of photosynthetic taxa. We discuss how these proteins may act as an important regulator for plastid functions
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