Vadim V. Goremykin scite author profile

Photosynthetic eukaryotes, particularly unicellular forms, possess a fossil record that is either wrought with gaps or difficult to interpret, or both. Attempts to reconstruct their evolution have focused on plastid phylogeny, but were limited by the amount and type of phylogenetic information contained within single genes. Among the 210 different protein-coding genes contained in the completely sequenced chloroplast genomes from a glaucocystophyte, a rhodophyte, a diatom, a euglenophyte and five land plants, we have now identified the set of 45 common to each and to a cyanobacterial outgroup genome. Phylogenetic inference with an alignment of 11,039 amino-acid positions per genome indicates that this information is sufficient--but just rarely so--to identify the rooted nine-taxon topology. We mapped the process of gene loss from chloroplast genomes across the inferred tree and found that, surprisingly, independent parallel gene losses in multiple lineages outnumber phylogenetically unique losses by more that 4:1. We identified homologues of 44 different plastid-encoded proteins as functional nuclear genes of chloroplast origin, providing evidence for endosymbiotic gene transfer to the nucleus in plants.

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A genome‐wide phylogenetic reconstruction of family 1 UDP‐glycosyltransferases revealed the expansion of the family during the adaptation of plants to life on land

Caputi

et al. 2011

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). † These authors equally contributed to this work. SUMMARYFor almost a decade, our knowledge on the organisation of the family 1 UDP-glycosyltransferases (UGTs) has been limited to the model plant A. thaliana. The availability of other plant genomes represents an opportunity to obtain a broader view of the family in terms of evolution and organisation. Family 1 UGTs are known to glycosylate several classes of plant secondary metabolites. A phylogeny reconstruction study was performed to get an insight into the evolution of this multigene family during the adaptation of plants to life on land. The organisation of the UGTs in the different organisms was also investigated. More than 1500 putative UGTs were identified in 12 fully sequenced and assembled plant genomes based on the highly conserved PSPG motif. Analyses by maximum likelihood (ML) method were performed to reconstruct the phylogenetic relationships existing between the sequences. The results of this study clearly show that the UGT family expanded during the transition from algae to vascular plants and that in higher plants the clustering of UGTs into phylogenetic groups appears to be conserved, although gene loss and gene gain events seem to have occurred in certain lineages. Interestingly, two new phylogenetic groups, named O and P, that are not present in A. thaliana were discovered.

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Mitochondrial DNA of Vitis vinifera and the Issue of Rampant Horizontal Gene Transfer

Goremykin

Salamini

Velasco

et al. 2008

Molecular Biology and Evolution

258

223

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The mitochondrial genome of grape (Vitis vinifera), the largest organelle genome sequenced so far, is presented. The genome is 773,279 nt long and has the highest coding capacity among known angiosperm mitochondrial DNAs (mtDNAs). The proportion of promiscuous DNA of plastid origin in the genome is also the largest ever reported for an angiosperm mtDNA, both in absolute and relative terms. In all, 42.4% of chloroplast genome of Vitis has been incorporated into its mitochondrial genome. In order to test if horizontal gene transfer (HGT) has also contributed to the gene content of the grape mtDNA, we built phylogenetic trees with the coding sequences of mitochondrial genes of grape and their homologs from plant mitochondrial genomes. Many incongruent gene tree topologies were obtained. However, the extent of incongruence between these gene trees is not significantly greater than that observed among optimal trees for chloroplast genes, the common ancestry of which has never been in doubt. In both cases, we attribute this incongruence to artifacts of tree reconstruction, insufficient numbers of characters, and gene paralogy. This finding leads us to question the recent phylogenetic interpretation of Bergthorsson et al. (2003, 2004) and Richardson and Palmer (2007) that rampant HGT into the mtDNA of Amborella best explains phylogenetic incongruence between mitochondrial gene trees for angiosperms. The only evidence for HGT into the Vitis mtDNA found involves fragments of two coding sequences stemming from two closteroviruses that cause the leaf roll disease of this plant. We also report that analysis of sequences shared by both chloroplast and mitochondrial genomes provides evidence for a previously unknown gene transfer route from the mitochondrion to the chloroplast.

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Genomes of Stigonematalean Cyanobacteria (Subsection V) and the Evolution of Oxygenic Photosynthesis from Prokaryotes to Plastids

Dagan¹,

Roettger²,

Stucken³

et al. 2012

224

211

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Cyanobacteria forged two major evolutionary transitions with the invention of oxygenic photosynthesis and the bestowal of photosynthetic lifestyle upon eukaryotes through endosymbiosis. Information germane to understanding those transitions is imprinted in cyanobacterial genomes, but deciphering it is complicated by lateral gene transfer (LGT). Here, we report genome sequences for the morphologically most complex true-branching cyanobacteria, and for Scytonema hofmanni PCC 7110, which with 12,356 proteins is the most gene-rich prokaryote currently known. We investigated components of cyanobacterial evolution that have been vertically inherited, horizontally transferred, and donated to eukaryotes at plastid origin. The vertical component indicates a freshwater origin for water-splitting photosynthesis. Networks of the horizontal component reveal that 60% of cyanobacterial gene families have been affected by LGT. Plant nuclear genes acquired from cyanobacteria define a lower bound frequency of 611 multigene families that, in turn, specify diazotrophic cyanobacterial lineages as having a gene collection most similar to that possessed by the plastid ancestor.

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