Phylogenetic footprint of the plant clock system in angiosperms: evolutionary processes of pseudo-response regulators.

BACKGROUND: Plant circadian clocks regulate many photoperiodic and diurnal responses that are conserved among plant species. The plant circadian clock system has been uncovered in the model plant, Arabidopsis thaliana, using genetics and systems biology approaches. However, it is still not clear how the clock system had been organized in the evolutionary history of plants. We recently revealed the molecular phylogeny of LHY/CCA1 genes, one of the essential components of the clock system. The aims of this study are to reconstruct the phylogenetic relationships of angiosperm clock-associated PRR genes, the partner of the LHY/CCA1 genes, and to clarify the evolutionary history of the plant clock system in angiosperm lineages. RESULTS: In the present study, to investigate the molecular phylogeny of PRR genes, we performed two approaches: reconstruction of phylogenetic trees and examination of syntenic relationships. Phylogenetic analyses revealed that PRR genes had diverged into three clades prior to the speciation of monocots and eudicots. Furthermore, copy numbers of PRR genes have been independently increased in monocots and eudicots as a result of ancient chromosomal duplication events. CONCLUSIONS: Based on the molecular phylogenies of both PRR genes and LHY/CCA1 genes, we inferred the evolutionary process of the plant clock system in angiosperms. This scenario provides evolutionary information that a common ancestor of monocots and eudicots had retained the basic components required for reconstructing a clock system and that the plant circadian clock may have become a more elaborate mechanism after the speciation of monocots and eudicots because of the gene expansion that resulted from polyploidy events.

Adaptive evolution of the uncoupling protein 1 gene contributed to the acquisition of novel nonshivering thermogenesis in ancestral eutherian mammals.

Homeotherms possess various physiological mechanisms to maintain their body temperature, thus allowing them to adapt to various environments. Under cold conditions, most eutherian mammals upregulate heat production in brown adipose tissue (BAT), and uncoupling protein (UCP) 1 is an essential factor in BAT thermogenesis. The evolutionary origin of UCP1 was believed to have been a specific event occurring in eutherian lineages. Recently, however, the UCP1 ortholog was found in fishes, which uncovers a more ancient origin of this gene than previously believed. Here we investigate the evolutionary process of UCP1 by comparative genomic approach. We found that UCP1 evolved rapidly by positive Darwinian selection in the common ancestor of eutherians, although this gene arose in the ancestral vertebrate, since the orthologous genes were shared among most of the vertebrate species. Adaptive evolution occurred after the divergence between eutherians and marsupials, which is consistent with the fact that BAT has been found only in eutherians. Our findings indicate that positive Darwinian selection acted on UCP1 contributed to the acquisition of an efficient mechanism for body temperature regulation in primitive eutherians. Phylogenetic reconstruction of UCP1 with two paralogs (UCP2 and UCP3) among vertebrate species revealed that the gene duplication events which produced these three genes occurred in the common ancestor of vertebrates much earlier than the emergence of eutherians. Thus, our data demonstrate that novel gene function can evolve without de novo gene duplication event.