Heterotachy Processes in Rhodophyte-Derived Secondhand Plastid Genes: Implications for Addressing the Origin and Evolution of Dinoflagellate Plastids

doi:10.1093/molbev/msl011

MBE Advance Access originally published online on May 12, 2006
Molecular Biology and Evolution 2006 23(8):1504-1515; doi:10.1093/molbev/msl011

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Research Article

Heterotachy Processes in Rhodophyte-Derived Secondhand Plastid Genes: Implications for Addressing the Origin and Evolution of Dinoflagellate Plastids

Kamran Shalchian-Tabrizi^*, Marianne Skånseng^*, Fredrik Ronquist^,1, Dag Klaveness, Tsvetan R. Bachvaroff^,2, Charles F. Delwiche, Andreas Botnen^||, Torstein Tengs^*^,3 and Kjetill S. Jakobsen^*

^* Centre for Ecological and Evolutionary Synthesis, Department of Biology, University of Oslo, Oslo, Norway; Evolutionary Biology Centre, Department of Systematic Zoology, Uppsala University, Uppsala, Sweden; Program for Plankton Biology, Department of Biology, University of Oslo, Oslo, Norway; Cell Biology and Molecular Genetics, University of Maryland, College Park; and ^|| Scientific Computer Group, Center for Information Technology Services, University of Oslo, Oslo, Norway

E-mail: k.s.jakobsen{at}bio.uio.no.

Serial transfer of plastids from one eukaryotic host to anotheris the key process involved in evolution of secondhand plastids.Such transfers drastically change the environment of the plastidsand hence the selection regimes, presumably leading to changesover time in the characteristics of plastid gene evolution andto misleading phylogenetic inferences. About half of the dinoflagellateprotists species are photosynthetic and unique in harboringa diversity of plastids acquired from a wide range of eukaryoticalgae. They are therefore ideal for studying evolutionary processesof plastids gained through secondary and tertiary endosymbioses.In the light of these processes, we have evaluated the originof 2 types of dinoflagellate plastids, containing the peridininor 19'-hexanoyloxyfucoxanthin (19'-HNOF) pigments, by inferringthe phylogeny using "covarion" evolutionary models allowingthe pattern of among-site rate variation to change over time.Our investigations of genes from secondary and tertiary plastidsderived from the rhodophyte plastid lineage clearly reveal "heterotachy"processes characterized as stationary covarion substitutionpatterns and changes in proportion of variable sites acrosssequences. Failure to accommodate covarion-like substitutionpatterns can have strong effects on the plastid tree topology.Importantly, multigene analyses performed with probabilisticmethods using among-site rate and covarion models of evolutionconflict with proposed single origin of the peridinin- and 19'-HNOF–containingplastids, suggesting that analysis of secondhand plastids canbe hampered by convergence in the evolutionary signature ofthe plastid DNA sequences. Another type of sequence convergencewas detected at protein level involving the psaA gene. Excludingthe psaA sequence from a concatenated protein alignment groupedthe peridinin plastid with haptophytes, congruent with all DNAtrees. Altogether, taking account of complex processes involvedin the evolution of dinoflagellate plastid sequences (both atthe DNA and amino acid level), we demonstrate the difficultyof excluding independent, tertiary origin for both the peridininand 19'-HNOF plastids involving engulfment of haptophyte-likealgae. In addition, the refined topologies suggest the red algalorder, Porphyridales, as the endosymbiont ancestor of the secondaryplastids in cryptophytes, haptophytes, and heterokonts.

Key Words: chromalveolates • chromists • covarion • dinoflagellates • heterotachy • plastid evolution

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