Nucleus-encoded, plastid-targeted acetolactate synthase genes in two closely related chlorophytes, Chlamydomonas reinhardtii and Volvox carteri: phylogenetic origins and recent insertion of introns

Acetolactate synthase (ALS) catalyzes the first committed step in the synthesis of branched-chain amino acids. In green plants and fungi, ALS is encoded by a nuclear gene whose product is targeted to plastids (in plants) or to mitochondria (in fungi). In red algae, the gene is plastid-encoded. We have determined the complete sequence of nucleus-encoded ALS genes from the green algae Chlamydomonas reinhardtii and Volvox carteri. Phylogenetic analyses of the ALS gene family indicate that the ALS genes of green algae and plants are closely related, sharing a recent common ancestor. Furthermore, although these genes are clearly of eubacterial origin, a relationship to the ALS genes of red algae and cyanobacteria (endosymbiotic precursors of plastids) is only weakly indicated. The algal ALS genes are distinguished from their homologs in higher plants by the fact that they are interrupted by numerous spliceosomal introns; plant ALS genes completely lack introns. The restricted phylogenetic distribution of these introns suggests that they were inserted recently, after the divergence of these green algae from plants. Two introns in the Volvox ALS gene, not found in the Chlamydomonas gene, are positioned precisely at sites which resemble “proto-splice” sequences in the Chlamydomonas gene.     

Cloning and characterization of chloroplast ribosomal protein-encoding genes, rpl16 and rps3, of the marine macro-algae, Gracilaria tenuistipitata

In Gracilaria tenuistipitata, a highly differentiated multicellular member of the marine red algae, Rhodophyta, chloroplast (cp) DNA can be separated as a satellite band from the nuclear DNA in a CsCl gradient. Using a heterologous probe from Chlamydomonas, the ribosomal protein-encoding gene, rpl16, was located on a 4.5-kb EcoRI fragment of cp DNA. The fragment was cloned and a 1365-bp region around rpl16 was sequenced. The gene order around rpl16, 5′ rpl22-rps3-rpl16, is identical to that detected in the chloroplast DNA of liverwort, tobacco and maize. Both the nucleotide sequence and the amino-acid sequence of rpl16 are more conserved than that of rps3. The rpl16 gene contains no intron, a feature which shows more similarity to the unicellular green algae, Chlamydomonas, than the other land plants. Sequences that may form a stable stem-loop structure were detected within the coding sequence of rpl16.     

The phylogenetic position of red algae revealed by multiple nuclear genes from mitochondria-containing eukaryotes and an alternative hypothesis on the origin of plastids

Abstract Red algae are one of the main photosynthetic eukaryotic lineages and are characterized by primitive features, such as a lack of flagella and the presence of phycobiliproteins in the chloroplast. Recent molecular phylogenetic studies using nuclear gene sequences suggest two conflicting hypotheses (monophyly versus non-monophyly) regarding the relationships between red algae and green plants. Although kingdom-level phylogenetic analyses using multiple nuclear genes from a wide-range of eukaryotic lineages were very recently carried out, they used highly divergent gene sequences of the cryptomonad nucleomorph (as the red algal taxon) or incomplete red algal gene sequences. In addition, previous eukaryotic phylogenies based on nuclear genes generally included very distant archaebacterial sequences (designated as the outgroup) and/or amitochondrial organisms, which may carry unusual gene substitutions due to parasitism or the absence of mitochondria. Here, we carried out phylogenetic analyses of various lineages of mitochondria-containing eukaryotic organisms using nuclear multigene sequences, including the complete sequences from the primitive red alga Cyanidioschyzon merolae. Amino acid sequence data for two concatenated paralogous genes (α- and β-tubulin) from mitochondria-containing organisms robustly resolved the basal position of the cellular slime molds, which were designated as the outgroup in our phylogenetic analyses. Phylogenetic analyses of 53 operational taxonomic units (OTUs) based on a 1525-amino-acid sequence of four concatenated nuclear genes (actin, elongation factor-1α, α-tubulin, and β-tubulin) reliably resolved the phylogeny only in the maximum parsimonious (MP) analysis, which indicated the presence of two large robust monophyletic groups (Groups A and B) and the basal eukaryotic lineages (red algae, true slime molds, and amoebae). Group A corresponded to the Opisthokonta (Metazoa and Fungi), whereas Group B included various primary and secondary plastid-containing lineages (green plants, glaucophytes, euglenoids, heterokonts, and apicomplexans), Ciliophora, Kinetoplastida, and Heterolobosea. The red algae represented the sister lineage to Group B. Using 34 OTUs for which essentially the entire amino acid sequences of the four genes are known, MP, distance, quartet puzzling, and two types of maximum likelihood (ML) calculations all robustly resolved the monophyly of Group B, as well as the basal position of red algae within eukaryotic organisms. In addition, phylogenetic analyses of a concatenated 4639-amino-acid sequence for 12 nuclear genes (excluding the EF-2 gene) of 12 mitochondria-containing OTUs (including C. merolae) resolved a robust non-sister relationship between green plants and red algae within a robust monophyletic group composed of red algae and the eukaryotic organisms belonging to Group B. A new scenario for the origin and evolution of plastids is suggested, based on the basal phylogenetic position of the red algae within the large clade (Group B plus red algae). The primary plastid endosymbiosis likely occurred once in the common ancestor of this large clade, and the primary plastids were subsequently lost in the ancestor(s) of the Discicristata (euglenoids, Kinetoplastida, and Heterolobosea), Heterokontophyta, and Alveolata (apicomplexans and Ciliophora). In addition, a new concept of “Plantae” is proposed for phototrophic and nonphototrophic organisms belonging to Group B and red algae, on the basis of the common history of the primary plastid endosymbiosis. The Plantae include primary plastid-containing phototrophs and nonphototrophic eukaryotes that possibly contain genes of cyanobacterial origin acquired in the primary endosymbiosis.     

A “Green” Phosphoribulokinase in Complex Algae with Red Plastids: Evidence for a Single Secondary Endosymbiosis Leading to Haptophytes, Cryptophytes, Heterokonts, and Dinoflagellates

Phosphoribulokinase (PRK) is an essential enzyme of photosynthetic eukaryotes which is active in the plastid-located Calvin cycle and regenerates the substrate for ribulose-bisphosphate carboxylase/oxygenase (Rubisco). Rhodophytes and chlorophytes (red and green algae) recruited their nuclear-encoded PRK from the cyanobacterial ancestor of plastids. The plastids of these organisms can be traced back to a single primary endosymbiosis, whereas, for example, haptophytes, dinoflagellates, and euglenophytes obtained their “complex” plastids through secondary endosymbioses, comprising the engulfment of a unicellular red or green alga by a eukaryotic host cell. We have cloned eight new PRK sequences from complex algae as well as a rhodophyte in order to investigate their evolutionary origin. All available PRK sequences were used for phylogenetic analyses and the significance of alternative topologies was estimated by the approximately unbiased test. Our analyses led to several astonishing findings. First, the close relationship of PRK genes of haptophytes, heterokontophytes, cryptophytes, and dinophytes (complex red lineage) supports a monophyletic origin of their sequences and hence their plastids. Second, based on PRK genes the complex red lineage forms a highly supported assemblage together with chlorophytes and land plants, to the exclusion of the rhodophytes. This green affinity is in striking contrast to the expected red algal origin and our analyses suggest that the PRK gene was acquired once via lateral transfer from a green alga. Third, surprisingly the complex green lineages leading to Bigelowiella and Euglena probably also obtained their PRK genes via lateral gene transfers from a red alga and a complex alga with red plastids, respectively. Electronic Supplementary Material Electronic Supplementary material is available for this article at and accessible for authorised users. [Reviewing Editor: Dr. Patrick Keeling ] The nucleotide sequence data will appear in the DDBJ/EMBL/GenBank International Nucleotide Sequence Database under the following accession numbers. cDNA clones: AY772245 (Pavlova lutheri); AY772246 (Guillardia theta); AY772247 (Lingulodinium polyedrum); AY772248 and AY772249 (Pyrocystis lunula); AY772250 (Euglena gracilis); AY772251 (Chondrus crispus). Genomic clone: AY772252 (Prymnesium parvum). Genomic PCR clone: AY772253 (Bigelowiella natans).     

The Complete Mitochondrial Genome Sequence of the Hornwort <Emphasis Type="Italic">Megaceros</Emphasis><Emphasis Type="Italic">aenigmaticus</Emphasis> Shows a Mixed Mode of Conservative Yet Dynamic Evolution in Early Land Plant Mitochondrial Genomes

Land plants possess some of the most unusual mitochondrial genomes among eukaryotes. However, in early land plants these genomes resemble those of green and red algae or early eukaryotes. The question of when during land plant evolution the dramatic change in mtDNAs occurred remains unanswered. Here we report the first completely sequenced mitochondrial genome of the hornwort, Megaceros aenigmaticus, a member of the sister group of vascular plants. It is a circular molecule of 184,908 base pairs, with 32 protein genes, 3 rRNA genes, 17 tRNA genes, and 30 group II introns. The genome contains many genes arranged in the same order as in those of a liverwort, a moss, several green and red algae, and Reclinomonas americana, an early-branching eukaryote with the most ancestral form of mtDNA. In particular, the gene order between mtDNAs of the hornwort and Physcomitrella patens (moss) differs by only 8 inversions and translocations. However, the hornwort mtDNA possesses 4 derived features relative to green alga mtDNAs—increased genome size, RNA editing, intron gains, and gene losses—which were all likely acquired during the origin and early evolution of land plants. Overall, this genome and those of other 2 bryophytes show that mitochondrial genomes in early land plants, unlike their seed plant counterparts, exhibit a mixed mode of conservative yet dynamic evolution. Electronic supplementary material  The online version of this article (doi:) contains supplementary material, which is available to authorized users. Libo Li and Bin Wang contributed equally to this work.     

Evolution of fragmented mitochondrial ribosomal RNA genes inChlamydomonas

The fragmented mitochondrial ribosomal RNAs (rRNAs) of the green algaeChlamydomonas eugametos andChlamydomonas reinhardtii are discontinuously encoded in subgenic modules that are scrambled in order and interspersed with protein coding and tRNA genes. The mitochondrial rRNA genes of these two algae differ, however, in both the distribution and organization of rRNA coding information within their respective genomes. The objectives of this study were (1) to examine the phylogenetic relationships between the mitochondrial rRNA gene sequences ofC. eugametos andC. reinhardtii and those of the conventional mitochondrial rRNA genes of the green alga,Prototheca wickerhamii, and land plants and (2) to attempt to deduce the evolutionary pathways that gave rise to the unusual mitochondrial rRNA gene structures in the genusChlamydomonas. Although phylogenetic analysis revealed an affiliation between the mitochondrial rRNA gene sequences of the twoChlamydomonas taxa to the exclusion of all other mitochondrial rRNA gene sequences tested, no specific affiliation was noted between theChlamydomonas sequences andP. wickerhamii or land plants. Calculations of the minimal number of transpositions required to convert hypothetical ancestral rRNA gene organizations to the arrangements observed forC. eugametos andC. reinhardtii mitochondrial rRNA genes, as well as a limited survey of the size of mitochondrial rRNAs in other members of the genus, lead us to propose that the last common ancestor ofChlamydomonas algae contained fragmented mitochondrial rRNA genes that were nearly co-linear with conventional rRNA genes.     

Characterization of genes encoding the light-harvesting proteins in diatoms: biogenesis of the fucoxanthin chlorophylla/c protein complex

In chromophytic algae the major light-harvesting complex is the fucoxanthin chlorophylla/c protein complex. Recently, we have cloned several highly related cDNA and genomic sequences encoding the fucoxanthin chlorophylla/c proteins from the diatomPhaeodactylum tricornutum. These genes are clustered on the nuclear genome. The sequences of the fucoxanthin chlorophylla/c proteins as deduced from the gene sequences have some similarity to the chlorophylla/b proteins associated with light-harvesting complexes of higher plants and green algae. Like the chlorophylla/b proteins of higher plants, the fucoxanthin chlorophylla/c proteins are synthesized as higher-molecular weight precursors in the cytoplasm of the cell and are transported into the plastids. However, the mode of transport into diatom plastids is very different from the mechanism involved in transporting proteins into the chloroplasts of higher plants and green algae. We focus here on the characteristics of the fucoxanthin chlorophylla/c proteins, the mode of transport of these proteins into plastids, the arrangement of the genes encoding these proteins, and efforts to utilize these genes to develop a DNA transformation system for diatoms.     

Phylogeny and Self-Splicing Ability of the Plastid tRNA-Leu Group I Intron

Group I introns are mobile RNA enzymes (ribozymes) that encode conserved primary and secondary structures required for autocatalysis. The group I intron that interrupts the tRNA-Leu gene in cyanobacteria and plastids is remarkable because it is the oldest known intervening sequence and may have been present in the common ancestor of the cyanobacteria (i.e., 2.7–3.5 billion years old). This intron entered the eukaryotic domain through primary plastid endosymbiosis. We reconstructed the phylogeny of the tRNA-Leu intron and tested the in vitro self-splicing ability of a diverse collection of these ribozymes to address the relationship between intron stability and autocatalysis. Our results suggest that the present-day intron distribution in plastids is best explained by strict vertical transmission, with no intron losses in land plants or a subset of the Stramenopiles (xanthophyceae/phaeophyceae) and frequent loss among green algae, as well as in the red algae and their secondary plastid derivatives (except the xanthophyceae/phaeophyceae lineage). Interestingly, all tested land plant introns could not self-splice in vitro and presumably have become dependent on a host factor to facilitate in vivo excision. The host dependence likely evolved once in the common ancestor of land plants. In all other plastid lineages, these ribozymes could either self-splice or complete only the first step of autocatalysis. The first two authors (Dawn Simon and David Fewer) have contributed equally to this work. Present address (David Fewer): Department of Applied Chemistry and Microbiology, Viikki Biocenter, P.O. Box 56, Viikinkaari 9, 00014 University of Helsinki, Helsinki, Finland     

Plastome mutants

Summary Since the first reports seventy-five years ago on the non-Mendelian inheritance of variegation in plants, chloroplast gene mutations have been useful for genetical and physiological investigations. The mutations have been shown to affect the chloroplast translational apparatus, photosystem I, photosystem II, the cytochrome f/b₆ complex, carbon fixation, or the ATP synthase. They arose spontaneously or were induced by mutagens or by the action of nuclear mutator genes. Alterations of chloroplast DNA include point mutations, deletions, duplications, and inversions. In 1909, Correns discovered uniparental transmission of chloroplasts when he observed the maternal inheritance of a chlorophyll deficiency inMirabilis jalapa. At the same time, Baur (1909) reported crosses ofPelargonium zonale in which the offspring inherited chloroplasts from both parents (biparental transmission) with variegated leaves resulting as the green and white plastids sorted out. since the experiments of Baur and Correns, many non-Mendelian mutants have been isolated in both higher plants and algae (for reviews see Hagemann, 1964; Kirk and Tilney-Bassett, 1978; Gillham, 1978). Some of these are mitochondrial traits, including cytoplasmic male sterility in maize and several other plants (Hanson and Conde, 1985; Pring and Lonsdale, 1985). Several other traits have been tentatively identified as mitochondrial since their inheritance pattern differs from that of both nuclear and chloroplast genes, including the deformed leaf (“falsifolia”) syndrome ofOenothera (Stubbe, 1970), non-chromosomal stripe of maize (Coe, 1983), and inChlamydomonas, photoautotropism (Wiseman et al., 1977) and a minute colony phenotype (Alexander et al., 1974). A far larger number of extranuclear mutations affect the plastome (plastid genome). Among the algae,Euglena gracilis (Russell and Lyman, 1982),Scenedesmus obliquus (Bishop, 1982) andChlorella (Galling, 1982) have yielded interesting mutants, but unlikeChlamydomonas, they are not known to undergo sexual reproduction, and thus the Mendelian or non-Mendelian nature of the mutations has not been determined. Most of the plastome mutations which have been characterized have been isolated in higher plant lines or fromChlamydomonas.     

Taxonomy, molecular phylogeny, and ultrastructural morphology of Olpidiopsis porphyrae sp. nov. (Oomycetes, straminipiles), a unicellular obligate endoparasite of Bangia and Porphyra spp. (Bangiales, Rhodophyta)

Olpidiopsis porphyrae sp. nov., a marine oomycete endoparasite that infects the commercially cultivated red alga Porphyra yezoensis, is described and its phylogenetic position based on molecular data and ultrastructural morphology is discussed. O. porphyrae infects the host Porphyra by means of encysted zoospores. Spherical-shaped holocarpic thalli develop within the cytoplasm of its algal host, which produce monoplanetic, subapically biflagellate zoospores. The characteristic features of this isolate are the ellipsoidal, unicellular thallus and simple holocarpic zoosporangial development, which show morphological similarity with the genus Olpidiopsis. Laboratory infection experiments with a wide range of green, brown, and red algae revealed that O. porphyrae infects several stages of the bangialean red algae (the genera Bangia and Porphyra). Molecular phylogenetic analyses inferred from both SSU rRNA and cox2 genes showed O. porphyrae branched before the main saprolegnian and peronosporalean lineages within the monophyletic oomycete clade, indicating its phylogenetic separation from them. A single or double K-body-like organelle, which contains tubular inclusions, is found located to one side of the zoospore nucleus and shows similarities to homologous organelles previously described in O. saprolegniae. The ultrastructural morphology of O. porphyrae with zoospore initials containing K-bodies and tubular mitochondrial cristae is characteristic of oomycetes. Group I intron-like multiple insertions were found in the SSU rRNA gene of O. porphyrae. This is the first report of SSU group I introns in the class Oomycetes.     

Phylogeny of Plastids Based on Cladistic Analysis of Gene Loss Inferred from Complete Plastid Genome Sequences

Based on the recent hypothesis on the origin of eukaryotic phototrophs, red algae, green plants, and glaucophytes constitute the primary photosynthetic eukaryotes (whose plastids may have originated directly from a cyanobacterium-like prokaryote via primary endosymbiosis), whereas the plastids of other lineages of eukaryotic phototrophs appear to be the result of secondary or tertiary endosymbiotic events (involving a phototrophic eukaryote and a host cell). Although phylogenetic analyses using multiple plastid genes from a wide range of eukaryotic lineages have been carried out, some of the major phylogenetic relationships of plastids remain ambiguous or conflict between different phylogenetic methods used for nucleotide or amino acid substitutions. Therefore, an alternative methodology to infer the plastid phylogeny is needed. Here, we carried out a cladistic analysis of the loss of plastid genes after primary endosymbiosis using complete plastid genome sequences from a wide range of eukaryotic phototrophs. Since it is extremely unlikely that plastid genes are regained during plastid evolution, we used the irreversible Camin-Sokal model for our cladistic analysis of the loss of plastid genes. The cladistic analysis of the 274 plastid protein-coding genes resolved the 20 operational taxonomic units representing a wide range of eukaryotic lineages (including three secondary plastid-containing groups) into two large monophyletic groups with high bootstrap values: one corresponded to the red lineage and the other consisted of a large clade composed of the green lineage (green plants and Euglena) and the basal glaucophyte plastid. Although the sister relationship between the green lineage and the Glaucophyta was not resolved in recent phylogenetic studies using amino acid substitutions from multiple plastid genes, it is consistent with the rbcL gene phylogeny and with a recent phylogenetic study using multiple nuclear genes. In addition, our analysis robustly resolved the conflicting/ambiguous phylogenetic positions of secondary plastids in previous phylogenetic studies: the Euglena plastid was sister to the chlorophycean (Chlamydomonas) lineage, and the secondary plastids from the diatom (Odontiella) and cryptophyte (Guillardia) were monophyletic within the red lineage.     

Origins of the secondary plastids of Euglenophyta and Chlorarachniophyta as revealed by an analysis of the plastid‐targeting,nuclear‐encoded gene psbO1

Because the secondary plastids of the Euglenophyta and Chlorarachniophyta are very similar to green plant plastids in their pigment composition, it is generally considered that ancestral green algae were engulfed by other eukaryotic host cells to become the plastids of these two algal divisions. Recent molecular phylogenetic studies have attempted to resolve the phylogenetic positions of these plastids; however, almost all of the studies analyzed only plastid‐encoded genes. This limitation may affect the results of comparisons between genes from primary and secondary plastids, because genes in endosymbionts have a higher mutation rate than the genes of their host cells. Thus, the phylogeny of these secondary plastids must be elucidated using other molecular markers. Here, we compared the plastid‐targeting, nuclear‐encoded, oxygen‐evolving enhancer (psbO) genes from various green plants, the Euglenophyta and Chlorarachniophyta. A phylogenetic analysis based on the PsbO amino acid sequences indicated that the chlorarachniophyte plastids are positioned within the Chlorophyta (including Ulvophyceae, Chlorophyceae, and Prasinophyceae, but excluding Mesostigma). In contrast, plastids of the Euglenophyta and Mesostigma are positioned outside the Chlorophyta and Streptophyta. The relationship of these three phylogenetic groups was consistent with the grouping of the primary structures of the thylakoid‐targeting domain and its adjacent amino acids in the PsbO N‐terminal sequences. Furthermore, the serine‐X‐alanine (SXA) motif of PsbO was exactly the same in the Chlorarachniophyta and the prasinophycean Tetraselmis. Therefore, the chlorarachniophyte secondary plastids likely evolved from the ancestral Tetraselmis‐like alga within the Chlorophyta, whereas the Euglenophyte plastids may have originated from the unknown basal lineage of green plants.     

124 Evidence for Lateral Transfer of a IE Intron between Fungal and Red Algal Small Subunit Ribosomal RNA Genes

In a recent study of the North American biogeography of the red algae genus Hildenbrandia, the presence of group I introns were noted in the nuclear SSU rRNA gene of the marine species H. rubra (Hildenbrandiales). Group I introns in the nuclear encoded rRNAs have been previously reported in the Hildenbrandiales as well as the Bangiales. All reported introns within the red algae have been identified as belonging to the IC1 subclass and occur at two insertion sites in the nuclear small subunit rRNA (516 and 1506). However, an unclassified intron was discovered at position 989 in the nuclear SSU rRNA gene of a collection of H. rubra from British Columbia, Canada. We have determined that the intron is a member of the IE subclass and this is the first report of an IE intron and an intron in position 989 in the red algae. Phylogenetic analyses of the intron sequences reveal a close relationship between this group IE intron and similar ascomycete and basidiomycete fungal IE introns in the nuclear SSU rRNA genes at positions 989 and 1199. In addition, a common unique helix (structural signature) in the P13 domain of the Hildenbrandia intron and those of the fungi at the 989 and 1199 IE positions in the nuclear SSU rRNA gene also indicates a close relationship. Hence, this study provides evidence for a possible lateral transfer of the IE intron in position 989 between fungal and red algal nuclear SSU rRNA genes.     

Sequence analysis and phylogenetic reconstruction of the genes encoding the large and small subunits of ribulose-1,5-bisphosphate carboxylase/oxygenase from the chlorophyllb-containing prokaryoteProchlorothrix hollandica

Summary Prochlorophytes similar toProchloron sp. andProchlorothrix hollandica have been suggested as possible progenitors of the plastids of green algae and land plants because they are prokaryotic organisms that possess chlorophyllb (chlb). We have sequenced theProchlorothrix genes encoding the large and small subunits of ribulose-1,5-bisphosphate carboxylase/oxygenase (rubisco),rbcL andrbcS, for comparison with those of other taxa to assess the phylogenetic relationship of this species. Length differences in the large subunit polypeptide among all sequences compared occur primarily at the amino terminus, where numerous short gaps are present, and at the carboxy terminus, where sequences ofAlcaligenes eutrophus and non-chlorophyllb algae are several amino acids longer. Some domains in the small subunit polypeptide are conserved among all sequences analyzed, yet in other domains the sequences of different phylogenetic groups exhibit specific structural characteristics. Phylogenetic analyses ofrbcL andrbcS using Wagner parsimony analysis of deduced amino acid sequences indicate thatProchlorothrix is more closely related to cyanobacteria than to the green plastid lineage. The molecular phylogenies suggest that plastids originated by at least three separate primary endosymbiotic events, i.e., once each leading to green algae and land plants, to red algae, and toCyanophora paradoxa. TheProchlorothrix rubisco genes show a strong GC bias, with 68% of the third codon positions being G or C. Factors that may affect the GC content of different genomes are discussed.     

The largest subunit of RNA polymerase II from the Glaucocystophyta: functional constraint and short-branch exclusion in deep eukaryotic phylogeny

Background  

Evolutionary analyses of the largest subunit of RNA polymerase II (RPB1) have yielded important and at times provocative results. One particularly troublesome outcome is the consistent inference of independent origins of red algae and green plants, at odds with the more widely accepted view of a monophyletic Plantae comprising all eukaryotes with primary plastids. If the hypothesis of a broader kingdom Plantae is correct, then RPB1 trees likely reflect a persistent phylogenetic artifact. To gain a better understanding of RNAP II evolution, and the presumed artifact relating to green plants and red algae, we isolated and analyzed RPB 1 from representatives of Glaucocystophyta, the third eukaryotic group with primary plastids.     

Cyanobacterial Genes Transmitted to the Nucleus Before Divergence of Red Algae in the Chromista

The plastids of red algae, green plants, and glaucophytes may have originated directly from a cyanobacterium-like prokaryote via primary endosymbiosis. In contrast, the plastids of other lineages of eukaryotic phototrophs appear to be the result of secondary or tertiary endosymbiotic events involving a phototrophic eukaryote and a eukaryotic host cell. Although phylogenetic analyses of multiple plastid genes from a wide range of eukaryotic lineages have been carried out, the phylogenetic positions of the secondary plastids of the Chromista (Heterokontophyta, Haptophyta and Cryptophyta) are ambiguous in a range of different analyses. This ambiguity may be the result of unusual substitutions or bias in the plastid genes established by the secondary endosymbiosis. In this study, we carried out phylogenetic analyses of five nuclear genes of cyanobacterial origin (6-phosphogluconate dehydrogenase [gnd], oxygen-evolving-enhancer [psbO], phosphoglycerate kinase [pgk], delta-aminolevulinic acid dehydratase [aladh], and ATP synthase gamma [atpC] genes), using the genome sequence data from the primitive red alga Cyanidioschyzon merolae 10D. The sequence data robustly resolved the origin of the cyanobacterial genes in the nuclei of the Chromista (Heterokontophyta and Haptophyta) and Dinophyta, before the divergence of the extant red algae (including Porphyra [Rhodophyceae] and Cyanidioschyzon [Cyadidiophyceae]). Although it is likely that gnd genes in the Chromista were transmitted from the cyanobacterium-like ancestor of plastids in the primary endosymbiosis, other genes might have been transferred from nuclei of a red algal ancestor in the secondary endosymbiosis. Therefore, the results indicate that the Chromista might have originated from the ancient secondary endosymbiosis before the divergence of extant red algae.     

An update on carotenoid biosynthesis in algae: phylogenetic evidence for the existence of two classes of phytoene synthase

Carotenoids play crucial roles in structure and function of the photosynthetic apparatus of bacteria, algae, and higher plants. The entry-step reaction to carotenoid biosynthesis is catalyzed by the phytoene synthase (PSY), which is structurally and functionally related in all organisms. A comparative genomic analysis regarding the PSY revealed that the green algae Ostreococcus and Micromonas possess two orthologous copies of the PSY genes, indicating an ancient gene duplication event that produced two classes of PSY in algae. However, some other green algae (Chlamydomonas reinhardtii, Chlorella vulgaris, and Volvox carteri), red algae (Cyanidioschyzon merolae), diatoms (Thalassiosira pseudonana and Phaeodactylum tricornutum), and higher plants retained only one class of the PSY gene whereas the other gene copy was lost in these species. Further, similar to the situation in higher plants recent gene duplications of PSY have occurred for example in the green alga Dunaliella salina/bardawil. As members of the PSY gene families in some higher plants are differentially regulated during development or stress, the discovery of two classes of PSY gene families in some algae suggests that carotenoid biosynthesis in these algae is differentially regulated in response to development and environmental stress as well.     

Structural features of the plastid ribosomal RNA operons of two red algae: Antithamnion sp. and Cyanidium caldarium

The nucleotide sequences of the plastid 16S rDNA of the multicellular red alga Antithamnion sp. and the 16S rDNA/23S rDNA intergenic spacers of the plastid DNAs of the unicellular red alga Cyanidium caldarium and of Antithamnion sp. were determined. Sequence comparisons support the idea of a polyphyletic origin of the red algal and the higher-plant chloroplasts. Both spacer regions include the unsplit tRNA^Ile (GAU) and tRNA^Ala (UGC) genes and so the plastids of both algae form a homogeneous group with those of chromophytic algae and Cyanophora paradoxa characterized by small-sized rDNA spacers in contrast to green algae and higher plants. Nevertheless, remarkable sequence differences within the rRNA and the tRNA genes give the plastids of Cyanidium caldarium a rather isolated position.