2018
DOI: 10.1093/femsec/fiy039
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Evolution of heterotrophy in chrysophytes as reflected by comparative transcriptomics

Abstract: Shifts in the nutritional mode between phototrophy, mixotrophy and heterotrophy are a widespread phenomenon in the evolution of eukaryotic diversity. The transition between nutritional modes is particularly pronounced in chrysophytes and occurred independently several times through parallel evolution. Thus, chrysophytes provide a unique opportunity for studying the molecular basis of nutritional diversification and of the accompanying pathway reduction and degradation of plastid structures. In order to analyze… Show more

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Cited by 35 publications
(46 citation statements)
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“…Further, numerous authors stated and proved a correlation of cell volume and genome size (e.g., Bennett 1972). Additionally, heterotrophic chrysophytes are generally smaller than phototrophic ones, since they do only host remnants of a plastid (Škaloud et al 2014;Grossmann et al 2016;Graupner et al 2018). Following these, we hypothesize phototrophic taxa to have larger genomes than heterotrophic ones, due to the differences in cell sizes.…”
Section: Introductionmentioning
confidence: 55%
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“…Further, numerous authors stated and proved a correlation of cell volume and genome size (e.g., Bennett 1972). Additionally, heterotrophic chrysophytes are generally smaller than phototrophic ones, since they do only host remnants of a plastid (Škaloud et al 2014;Grossmann et al 2016;Graupner et al 2018). Following these, we hypothesize phototrophic taxa to have larger genomes than heterotrophic ones, due to the differences in cell sizes.…”
Section: Introductionmentioning
confidence: 55%
“…However, the heterotrophic Paraphysomonadida also branch basal indicating that the loss of phototrophy occurred early in some branches of Chrysophyceae . As the basal branching pattern is not yet sufficiently resolved, we cannot fully exclude the possibility of early heterotrophic ancestors within Chrysophyceae even though such a scenario appears highly unlikely as it would require secondary "revival" of the plastid and plastid metabolism (Graupner et al 2018).…”
Section: Discussionmentioning
confidence: 95%
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“…E. longa thus joins the group of recently discovered plastid-bearing eukaryotes lacking the MEP pathway, namely the colourless diatom Nitzschia sp. NIES-3581 (Kamikawa et al 2017) and various colourless chrysophytes (Graupner et al 2018; Dorrell et al 2019). In contrast, the plastid-localized MEP pathway in apicomplexans and related alveolates (i.e.…”
Section: Resultsmentioning
confidence: 99%
“…Many of them have a similar metabolic capacity as the apicoplast (Sanchez-Puerta et al 2007; Slamovits and Keeling 2008; Fernández Robledo et al 2011), and some house an even more complex metabolism that includes amino acid biosynthesis and carbohydrate metabolism pathways (Borza et al 2005; Pombert et al 2014; Smith and Lee 2014). Until recently, IPP synthesis seemed to be a process conserved even in the most reduced relic plastids, such as the genome-lacking plastids of certain alveolates (Matsuzaki et al 2008; Janouškovec et al 2015), but non-photosynthetic plastids lacking the characteristic plastidial (MEP or DOXP) pathway of IPP biosynthesis are now known (Kamikawa et al 2017; Graupner et al 2018; Dorrell et al 2019). Thus, there is generally a metabolic reason for a plastid retention, although the cases of plastid dependency differ between lineages.…”
Section: Introductionmentioning
confidence: 99%