Chloroplasts are generally known as eukaryotic organelles whose main function is photosynthesis. They perform other functions, however, such as synthesizing isoprenoids, fatty acids, heme, iron sulphur clusters and other essential compounds. In non-photosynthetic lineages that possess plastids, the chloroplast genomes have been reduced and most (or all) photosynthetic genes have been lost. Consequently, non-photosynthetic plastids have also been reduced structurally. Some of these non-photosynthetic or "cryptic" plastids were overlooked or unrecognized for decades. The number of complete plastid genome sequences and/or transcriptomes from non-photosynthetic taxa possessing plastids is rapidly increasing, thus allowing prediction of the functions of non-photosynthetic plastids in various eukaryotic lineages. In some non-photosynthetic eukaryotes with photosynthetic ancestors, no traces of plastid genomes or of plastids have been found, suggesting that they have lost the genomes or plastids completely. This review summarizes current knowledge of non-photosynthetic plastids, their genomes, structures and potential functions in free-living and parasitic plants, algae and protists. We introduce a model for the order of plastid gene losses which combines models proposed earlier for land plants with the patterns of gene retention and loss observed in protists. The rare cases of plastid genome loss and complete plastid loss are also discussed.
Edited by Ulf-Ingo FlüggeKeywords: Plastid EST Euglenozoa Polyadenylation Quantitative PCR Trans-splicing a b s t r a c t Euglena gracilis possesses secondary plastids of green algal origin. In this study, E. gracilis expressed sequence tags (ESTs) derived from polyA-selected mRNA were searched and several ESTs corresponding to plastid genes were found. PCR experiments failed to detect SL sequence at the 5 0 -end of any of these transcripts, suggesting plastid origin of these polyadenylated molecules. Quantitative PCR experiments confirmed that polyadenylation of transcripts occurs in the Euglena plastids. Such transcripts have been previously observed in primary plastids of plants and algae as low-abundance intermediates of transcript degradation. Our results suggest that a similar mechanism exists in secondary plastids. Ó 2014 Federation of European Biochemical Societies. Published by Elsevier B.V. All rights reserved. IntroductionEuglena gracilis is a fresh-water photosynthetic flagellate belonging to the order Euglenida and to the protist phylum Euglenozoa [1,2]. This phylum includes also the orders Kinetoplastida, Diplonemida and Symbiontida [3,4], which comprise exclusively heterotrophic species. Most euglenid species are free-living heterotrophic flagellates, but some of them possess secondary plastids that arose via secondary endosymbiosis of a green alga [5]. Phylogenetic analysis of plastid genome sequences revealed that euglenid plastids are derived from a Pyramimonas-related prasinophyte alga [6].A common euglenozoan feature is the processing of primary nuclear transcripts by spliced leader (SL) RNA-mediated trans-splicing [7]. This process includes replacement of the 5 0 -end of premRNA by the 5 0 -end of SL-RNA, donating identical 5 0 -termini to the mRNA molecules. Similar to nuclear cis-splicing, trans-splicing process is also mediated by spliceosomes, but a Y-branch intron structure is formed instead of a lariat [8]. The only currently known nuclear mRNA lacking the SL sequence in E. gracilis is that of the fibrillarin gene [9]. Since SL-trans-splicing does not occur in organelles (mitochondria, plastids), the presence (or absence) of an SL sequence at the 5 0 -end of a euglenozoan mRNA is diagnostic for its synthesis in the nucleus (or organelles, respectively).E. gracilis cell possesses approximately eight secondary plastids bounded by three membranes [10,11]. The plastid genome of this species is circular and comprises 143.17 kb. It contains 96 protein and RNA gene loci [12], group II and III introns, and twintrons (i.e. introns within introns) [13].The evolutionary transition from an endosymbiont to the plastid organelle was accompanied by a loss of many genes and gene transfer from the endosymbiont genome(s) to the host genome [14]. Gene transfer from plastids and mitochondria is an ongoing process, as it has been demonstrated in animals, plants, fungi as well as protists [15,16].Nuclear copies of plastid DNA (NUPT) can be found in a variety of species [17]. However, some species, e.g. the ...
Parasitic trypanosomatids and phototrophic euglenids are among the most extensively studied euglenozoans. The phototrophic euglenid lineage arose relatively recently through secondary endosymbiosis between a phagotrophic euglenid and a prasinophyte green alga that evolved into the euglenid secondary chloroplast. The parasitic trypanosomatids (i.e. Trypanosoma spp. and Leishmania spp.) and the freshwater phototrophic euglenids (i.e. Euglena gracilis) are the most evolutionary distant lineages in the Euglenozoa phylogenetic tree. The molecular and cell biological traits they share can thus be considered as ancestral traits originating in the common euglenozoan ancestor. These euglenozoan ancestral traits include common mitochondrial presequence motifs, respiratory chain complexes containing various unique subunits, a unique ATP synthase structure, the absence of mitochondria‐encoded transfer RNAs (tRNAs), a nucleus with a centrally positioned nucleolus, closed mitosis without dissolution of the nuclear membrane and nucleoli, a nuclear genome containing the unusual ‘J’ base (β‐D‐glucosyl‐hydroxymethyluracil), processing of nucleus‐encoded precursor messenger RNAs (pre‐mRNAs) via spliced‐leader RNA (SL‐RNA) trans‐splicing, post‐transcriptional gene silencing by the RNA interference (RNAi) pathway and the absence of transcriptional regulation of nuclear gene expression. Mitochondrial uridine insertion/deletion RNA editing directed by guide RNAs (gRNAs) evolved in the ancestor of the kinetoplastid lineage. The evolutionary origin of other molecular features known to be present only in either kinetoplastids (i.e. polycistronic transcripts, compaction of nuclear genomes) or euglenids (i.e. monocistronic transcripts, huge genomes, many nuclear cis‐spliced introns, polyproteins) is unclear.
Analyses of environmental sequences and two regions of chloroplast genomes revealed the presence of new clades of photosynthetic euglenids in marine environments
Euglenophyceae are unicellular algae with the majority of their diversity known from small freshwater reservoirs. Only two dozen species have been described to occur in marine habitats, but their abundance and diversity remain unexplored. Phylogenetic studies revealed marine prasinophyte green alga, Pyramimonas parkeae, as the closest extant relative of the euglenophytes' plastid, but similarly to euglenophytes, our knowledge about the diversity of Pyramimonadales is limited. Here we explored Euglenophyceae and Pyramimonadales phylogenetic diversity in marine environmental samples. We yielded 18S rDNA and plastid 16S rDNA sequences deposited in public repositories and reconstructed Euglenophyceae reference trees. We searched high-throughput environmental sequences from the TARA Oceans expedition and Ocean Sampling Day initiative for 18S rDNA and 16S rDNA, placed them in the phylogenetic context and estimated their relative abundances. To avoid polymerase chain reaction (PCR) bias, we also exploited metagenomic data from the TARA Oceans expedition for the presence of rRNA sequences from these groups. Finally, we targeted these protists in coastal samples by specific PCR amplification of two parts of the plastid genome uniquely shared between euglenids and Pyramimonadales. All approaches revealed previously undetected, but relatively low-abundant lineages of marine Euglenophyceae. Surprisingly, some of those lineages are branching within the freshwater or brackish genera. ; Tel. (+48) 22 55 266 41. † These authors contributed equally to this work.
An intact plastid genome is essential for the survival of colorless Euglena longa but not Euglena gracilis
Euglena gracilis growth with antibacterial agents leads to bleaching, permanent plastid gene loss. Colorless Euglena (Astasia) longa resembles a bleached E. gracilis. To evaluate the role of bleaching in E. longa evolution, the effect of streptomycin, a plastid protein synthesis inhibitor, and ofloxacin, a plastid DNA gyrase inhibitor, on E. gracilis and E. longa growth and plastid DNA content were compared. E. gracilis growth was unaffected by streptomycin and ofloxacin. Quantitative PCR analyses revealed a time dependent loss of plastid genes in E. gracilis demonstrating that bleaching agents produce plastid gene deletions without affecting cell growth. Streptomycin and ofloxacin inhibited E. longa growth indicating that it requires plastid genes to survive. This suggests that evolutionary divergence of E. longa from E. gracilis was triggered by the loss of a cytoplasmic metabolic activity also occurring in the plastid. Plastid metabolism has become obligatory for E. longa cell growth. A process termed "intermittent bleaching", short term exposure to subsaturating concentrations of reversible bleaching agents followed by growth in the absence of a bleaching agent, is proposed as the molecular mechanism for E. longa plastid genome reduction. Various non-photosynthetic lineages could have independently arisen from their photosynthetic ancestors via a similar process.
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