Molecular phylogeny of small brown algae,with special reference to the systematic position of Caepidium antarcticum (adenocystaceae,ectocarpales)

Nuclear ribosomal DNA (3′-SSU, ITS, 5′-LSU) and plastid-encoded (rbcL and Rubisco spacer) sequences were determined in Caepidium antarcticum and compared to homologous sequences of relatives from Ectocarpales, Scytothamnales, and other brown algae. Plastidial sequences confirmed a previous conclusions from nuclear ribosomal sequences that some taxa with stellate plastids (Asterocladon and relatives) form the closest outgroup to the Ectocarpales as yet identified. To reconcile nomenclature with the clades resolved in recent molecular studies, we propose a subdivision of the Ectocarpales in five families. Plastidial sequences support the recent proposal of Adenocystaceae, and all sequences suggest that Caepidium should be included in this family. As a further result, Geminocarpus was shown to belong to the same clade as Pylaiella and a number of other brown algae with an isomorphic life history and discoid plastids. We recognise this clade, whose correct name is Acinetosporaceae, as another family in the Ectocarpales. We also propose to unite a number of genetically related taxa, which were formely classified in different families, in an extended Chordariaceae. The remaining species of the Ectocarpales belong to Scytosiphonaceae and to Ectocarpaceae, the latter containing only Ectocarpus and Kuckuckia.     

MOLECULAR EVIDENCE FROM nrDNA ITS SEQUENCES THAT LAMINARIOCOLAX (PHAEOPHYCEAE, ECTOCARPALES SENSU LATO) IS A WORLDWIDE CLADE OF CLOSELY RELATED KELP ENDOPHYTES

Marine brown algae living as endophytes in macroalgae are morphologically simple and their taxonomy is particularly difficult. A molecular phylogeny for endophytic taxa isolated from kelps and red algae, and for putative epiphytic and free-living relatives, was inferred from partial small subunit and complete internal transcribed spacer nuclear ribosomal DNA sequences. It has revealed the following results. (1) Three species of endophytes isolated from members of the Laminariales are closely related. They form a clade together with the epi-endophytic species Laminariocolax tomentosoides (Farlow) Kylin. Members of the clade possess uniseriate plurilocular sporangia, and they may form erect filaments. Laminariocolax eckloniae sp. nov., occurring in the South African host Ecklonia maxima (Osbeck) Papenfuss, is described. The new combinations, Laminariocolax aecidioides (Rosenvinge) comb. nov. and L. macrocystis (Peters) comb. nov., are proposed for two taxa previously classified in Gononema and Streblonema , respectively. (2) The genus Laminariocolax occurs worldwide in temperate areas, and the phylogeny of the taxa studied is in agreement with biogeographic distribution. (3) Laminariocolax belongs to the Ectocarpales sensu lato. The genus is more closely related to Chordaria than to Dictyosiphon, Ectocarpus, or Scytosiphon . (4) Two brown endophytes ( Streblonema spp.), isolated from red algae, are closely related to each other and may form a sister clade to Laminariocolax .     

Circumscription of the order Ectocarpales (Phaeophyceae): bibliographical synthesis and molecular evidence

Phylogenetic analyses of 27 brown algae including the type genera of the orders Chordariales, Dictyosiphonales, Ectocarpales sensu stricto, and Scytosiphonales, using partial SSU + LSU combined rDNA sequence data, supports a broadly circumscribed order Ectocarpales. This order is redefined to include taxa possessing an exserted, pedunculated pyrenoid. Previous then taxa were placed in the Ectocarpales sensu stricto, the Chordariales, the Dictyosiphonales, or the Scytosiphonales. Algae either lacking a pyrenoid, and sometimes included in the Ectocarpales (Tilopteridales, Ralfsiales sensu Nakamura), or which possess a non-pedunculated pyrenoid (such as those placed in the recently proposed order Scytothamnales, as well as Asteronema, Asterocladon and Bachelotia), are excluded from the Ectocarpales.     

Plastid Genome of <Emphasis Type="Italic">Dictyopteris divaricata</Emphasis> (Dictyotales,Phaeophyceae): Understanding the Evolution of Plastid Genomes in Brown Algae

Dictyotophycidae is a subclass of brown algae containing 395 species that are distributed worldwide. A complete plastid (chloroplast) genome (ptDNA or cpDNA) had not previously been sequenced from this group. In this study, the complete plastid genome of Dictyopteris divaricata (Okamura) Okamura (Dictyotales, Phaeophyceae) was characterized and compared to other brown algal ptDNAs. This plastid genome was 126,099 bp in size with two inverted repeats (IRs) of 6026 bp. The D. divaricata IRs contained rpl21, making its IRs larger than representatives from the orders Fucales and Laminariales, but was smaller than that from Ectocarpales. The G + C content of D. divaricata (31.19%) was the highest of the known ptDNAs of brown algae (28.94–31.05%). Two protein-coding genes, rbcR and rpl32, were present in ptDNAs of Laminariales, Ectocarpales (Ectocarpus siliculosus), and Fucales (LEF) but were absent in D. divaricata. Reduced intergenic space (13.11%) and eight pairs of overlapping genes in D. divaricata ptDNA made it the most compact plastid genome in brown algae so far. The architecture of D. divaricata ptDNA showed higher similarity to that of Laminariales compared with Fucales and Ectocarpales. The difference in general features, gene content, and architecture among the ptDNAs of D. divaricata and LEF clade revealed the diversity and evolutionary trends of plastid genomes in brown algae.     

Utility of rbcS gene as a novel target DNA region for brown algal molecular systematics

The usefulness of molecular phylogenetic studies has increased remarkably as the quantity and quality of available DNA sequences has increased. When compared with the progress that has occurred in angiosperms and animals, there have been relatively few target DNA regions identified for use in taxonomic studies of brown algae. Therefore, in this study, we developed a new set of primers to amplify Rubisco small subunit (rbcS) gene sequences and determined the rbcS gene sequences of various species of brown algae including those belonging to Dictyotales, Ectocarpales, Fucales and Sphacelariales. The level of sequence variations in the rbcS gene varied according to the brown algal lineages. When focusing on the relationship of species within the genus Sargassum, the rbcS gene sequences provided useful information regarding the phylogenetic relationship among sections of the subgenus Bactrophycus. Based on the broad applicability and phylogenetic utility of the rbcS gene, we suggest that the sequence be used as a new target region for the molecular systematics of brown algae.     

MACROALGAL CANDIDATES FOR GENOMICS1

Genomes from over 130 organisms have been either sequenced completely or are currently under investigation. These studies include a wide array of Bacteria, a smaller number of Archaea, model‐system eukaryotes, parasitic protists, and even several microalgae. However, no major effort is underway to acquire a complete nuclear genome sequence from a single macroalga or seaweed despite their crucial contribution to the biodiversity and energy economy of oceans and estuaries. Here we examine various macroalgae as potential candidates for a genome project. A set of criteria is presented, followed by a brief discussion of how well different candidates from the principal macroalgae groups, green, brown, and red algae, meet these criteria. Based on our analyses, we conclude that the red seaweed, Porphyra yezoensis Ueda, should be the leading candidate for a macroalgal genomics initiative. We realize, of course, that others in the phycological community might have a different opinion and that a broad consensus among algal researchers is required to make seaweed genomics a reality; thus the primary intention of this review is to initiate and encourage further discussion as to where the phycological community should focus its genomic efforts.     

Plant Proteus: brown algal morphological plasticity and underlying developmental mechanisms

Brown algae are multicellular photosynthetic marine organisms, ubiquitous on rocky intertidal shores at cold and temperate latitudes. Nevertheless, little is known about many aspects of their biology, particularly their development. Given their phylogenetic distance (1.6 billion years) from other plant organisms (land plants, and green and red algae), brown algae harbor a high, as-yet undiscovered diversity of biological mechanisms governing their development. They also show great morphological plasticity, responding to specific environmental constraints, such as sea currents, reduced light availability, grazer attacks, desiccation and UV exposure. Here, we show that brown algal morphogenesis is rather simple and flexible, and review recent genomic data on the cellular and molecular mechanisms known to date that can possibly account for this developmental strategy.     

A MOLECULAR ANALYSIS OF ANALIPUS AND RALFSIA (PHAEOPHYCEAE) SUGGESTS THE ORDER ECTOCARPALES IS POLYPHYLETIC1

We report partial 18S ribosomal DNA sequences of Analipus japonicus (Harvey) Wynne and Ralfsia fungiformis (Grunnerus) Setchell et Gardner. These sequences were compared with the corresponding sequences of 13 brown algae representing six phaeophycean orders: Dictyotales, Ectocarpales, Fucales, Laminariales, Sphacelariales, and Syringodermatales. These 15 brown algae included 10 ectocarpoids representing nine ectocarpacean (sensu Gabrielson et al. 1989) families: Chordariaceae, Dictyosiphonaceae, Ectocarpaceae, Elachistaceae, Heterochordariaceae, Leathesiaceae, Punctariaceae, Ralfsiaceae, and Scytosiphonaceae. We addressed the controversial taxonomic placement of A. japonicus and R. fungiformis in the Ectocarpales by analysis of DNA sequences. Neighbor-joining and maximum parsimony-inferred phylogenies provided evidence that A. japonicus and R. fungiformis are not closely associated with the other representatives of the Ectocarpales. Bootstrap analyses suggest polyphyly of the order Ectocarpales (sensu Gabrielson et al.). However, our analysis failed to resolve the phylogenetic relationship between A. japonicus and R. fungiformis. Our results suggest that the ectocarpoids are just as distantly related to A. japonicus and R. fungiformis as they are to members of the advanced orders Desmarestiales, Dictyotales, Fucales, Laminariales, Sphacelariales, and Syringodermatales.     

18S rDNA gene metabarcoding of microeukaryotes and epi-endophytes in the holobiome of seven species of large brown algae

Brown algae (Phaeophyceae) are habitat-forming species in coastal ecosystems and include kelp forests and seaweed beds that support a wide diversity of marine life. Host-associated microbial communities are an integral part of phaeophyte biology, and whereas the bacterial microbial partners have received considerable attention, the microbial eukaryotes associated with brown algae have hardly been studied. Here, we used broadly targeted “pan-eukaryotic” primers (metabarcoding) to investigate brown algal-associated eukaryotes (the eukaryome). Using this approach, we aimed to investigate the eukaryome of seven large brown algae that are important and common species in coastal ecosystems. We also aimed to assess whether these macroalgae harbor novel eukaryotic diversity and to ascribe putative functional roles to the host-associated eukaryome based on taxonomic affiliation and phylogenetic placement. We detected a significant diversity of microeukaryotic and algal lineages associated with the brown algal species investigated. The operational taxonomic units (OTUs) were taxonomically assigned to 10 of the eukaryotic major supergroups, including taxonomic groups known to be associated with seaweeds as epibionts, endobionts, parasites, and commensals. Additionally, we revealed previously unrecorded sequence types, including novel phaeophyte OTUs, particularly in the Fucus spp. samples, that may represent fucoid genomic variants, sequencing artifacts, or undescribed epi-/endophytes. Our results provide baseline data and technical insights that will be useful for more comprehensive seaweed eukaryome studies investigating the evidently lineage-rich and functionally diverse symbionts of brown algae.     

Phylogeny of the Northeast Pacific brown algal (Phaeophycean) orders as inferred from 18S rRNA gene sequences

Partial 18S rRNA gene sequences have been determined for thirteen brown algae representing nine Northeast Pacific brown algal orders: Chordariales, Desmarestiales, Dictyosiphonales, Dictyotales, Ectocarpales, Fucales, Scytosiphonales, Sphacelariales and Syringodermatales. These sequences were compared with published sequences from a kelp (Laminariales), a xanthophyte and a bacillariophyte. A preliminary phylogeny generated by the neighbor-joining phylogeny inference method indicated that the class Phaeophyceae is a monophyletic group in relation to the xanthophyte and the bacillariophyte. Further, bootstrap analysis of the phylogeny consistently grouped together all the representatives belonging to the orders Ectocarpales, Chordariales, Dictyosiphonales and Scytosiphonales and separated them from the representatives belonging to the other brown algal orders. These results offer valuable insights into the controversial brown algal orders' phylogeny and provide additional data to the phylogenetic relationship study among the chromophyte classes.     

A NEW BROWN ALGAL ORDER,ISHIGEALES (PHAEOPHYCEAE), ESTABLISHED ON THE BASIS OF PLASTID PROTEIN‐CODING rbcL,psaA, AND psbA REGION COMPARISONS1

The brown algal family Ishigeaceae currently includes a single genus, Ishige Yendo, with two species. The relationship of the family to other brown algal lineages is less studied in terms of their plastid ultrastructure and molecular phylogeny. We determined the sequences of rbcL from four samples of the two Ishige species and nine putative relatives and the psaA and psbA sequences from 37 representatives of the brown algae. Analyses of individual and combined data sets resulted in similar trees; however, the concatenated data gave greater resolution and clade support than each individual gene. In all the phylogenies, the Phaeophyceae was well resolved, the Ectocarpales being placed in a terminal position and the Ishigeaceae ending up in a basal position. From our ultrastructural study, we concluded that the pyrenoid is absent in the Ishigeaceae, despite the presence of a rudimentary pyrenoid in I. okamurae. These results suggest that the Ishigeaceae is an early diverging brown lineage. Our molecular and morphological data, therefore, lead us to exclude the Ishigeaceae from the Ectocarpales s.l., which have an elaborate pyrenoid, and to propose its own order Ishigeales ord. nov. The Ishigeales is distinguished by oligostichous structure of thalli, phaeophycean hairs formed within cryptostomata, unilocular sporangia transformed from terminal cortical cells, and plurilocular sporangia lacking sterile terminal cells. This study is the first to document the utility of the psaA and psbA sequences for brown algae and also the first report on the multigene phylogeny of the Phaeophyceae based on three protein‐coding plastid genes.     

The eco-evolutionary importance of reproductive system variation in the macroalgae: Freshwater reds as a case study

The relative frequency of sexual versus asexual reproduction governs the distribution of genetic diversity within and among populations. Most studies on the consequences of reproductive variation focus on the mating system (i.e., selfing vs. outcrossing) of diploid-dominant taxa (e.g., angiosperms), often ignoring asexual reproduction. Although reproductive systems are hypothesized to be correlated with life-cycle types, variation in the relative rates of sexual and asexual reproduction remains poorly characterized across eukaryotes. This is particularly true among the three major lineages of macroalgae (green, brown, and red). The Rhodophyta are particularly interesting, as many taxa have complex haploid–diploid life cycles that influence genetic structure. Though most marine reds have separate sexes, we show that freshwater red macroalgae exhibit patterns of switching between monoicy and dioicy in sister taxa that rival those recently shown in brown macroalgae and in angiosperms. We advocate for the investigation of reproductive system evolution using freshwater reds, as this will expand the life-cycle types for which these data exist, enabling comparative analyses broadly across eukaryotes. Unlike their marine cousins, species in the Batrachospermales have macroscopic gametophytes attached to filamentous, often microscopic sporophytes. While asexual reproduction through monospores may occur in all freshwater reds, the Compsopogonales are thought to be exclusively asexual. Understanding the evolutionary consequences of selfing and asexual reproduction will aid in our understanding of the evolutionary ecology of all algae and of eukaryotic evolution generally.     

PHYLOGENETIC RELATIONSHIPS OF THE BROWN ALGAL ORDERS ECTOCARPALES, CHORDARIALES, DICTYOSIPHONALES, AND TILOPTERIDALES (PHAEOPHYCEAE) BASED ON RUBISCO LARGE SUBUNIT AND SPACER SEQUENCES

Phylogenetic relationships among 23 species of morphologically simple brown algae belonging to the Ectocarpales sensu stricto , Chordariales, Dictyosiphonales, and Tilopteridales sensu stricto , Phaeophyceae (Fucophyceae), were analyzed using chloroplast-encoded RUBISCO large subunit gene sequences ( rbc L) and the associated RUBISCO spacer sequences. Comparison of the observed and expected sequence divergence at the three codon positions of rbc L showed that the level of mutational saturation within the brown algae is minor. Thus, rbc L is well suited for phylogenetic studies in this group. Unweighted parsimony analyses and a neighbor-joining distance analysis were performed using unambiguously aligned rbc L sequences from the above four orders, one marine raphidophyte and two Tribophyceae (Xantophyceae). Polyphyly of Tilopteridales sensu lato (i.e. including Dictyosiphonales) is verified; we therefore recommend the use of Tilopteridales in the strict sense. The Ectocarpales, Chordariales, and Dictyosiphonales are paraphyletic with respect to each other, forming a highly interwoven clade. A separate parsimony analysis of the RUBISCO spacer as well as a combined rbc L and spacer analysis supported the close relationship among the latter three orders, adding to the evidence that they should be subsumed into the Ectocarpales sensu lato.     

The importance of effective sampling for exploring the population dynamics of haploid–diploid seaweeds

The mating system partitions genetic diversity within and among populations and the links between life history traits and mating systems have been extensively studied in diploid organisms. As such most evolutionary theory is focused on species for which sexual reproduction occurs between diploid male and diploid female individuals. However, there are many multicellular organisms with biphasic life cycles in which the haploid stage is prolonged and undergoes substantial somatic development. In particular, biphasic life cycles are found across green, brown and red macroalgae. Yet, few studies have addressed the population structure and genetic diversity in both the haploid and diploid stages in these life cycles. We have developed some broad guidelines with which to develop population genetic studies of haploid‐diploid macroalgae and to quantify the relationship between power and sampling strategy. We address three common goals for studying macroalgal population dynamics, including haploid‐diploid ratios, genetic structure and paternity analyses.     

Ecophysiology of photosynthesis in macroalgae

Macroalgae occur in the marine benthos from the upper intertidal to depths of more than 200?m, contributing up to 1?Pg?C per year to global primary productivity. Freshwater macroalgae are mainly green (Chlorophyta) with some red (Rhodophyta) and a small contribution of brown (Phaeophyceae) algae, while in the ocean all three higher taxa are important. Attempts to relate the depth distribution of three higher taxa of marine macroalgae to their photosynthetic light use through their pigmentation in relation to variations in spectral quality of photosynthetically active radiation (PAR) with depth (complementary chromatic adaptation) and optical thickness (package effect) have been relatively unsuccessful. The presence (Chlorophyta, Phaeophyceae) or absence (Rhodophyta) of a xanthophyll cycle is also not well correlated with depth distribution of marine algae. The relative absence of freshwater brown algae does not seem to be related to their photosynthetic light use. Photosynthetic inorganic carbon acquisition in some red and a few green macroalgae involves entry of CO(2) by diffusion. Other red and green macroalgae, and brown macroalgae, have CO(2) concentrating mechanisms; these frequently involve acid and alkaline zones on the surface of the alga with CO(2) (produced from HCO(3) (-)) entering in the acid zones, while some macroalgae have CCMs based on active influx of HCO(3) (-). These various mechanisms of carbon acquisition have different responses to the thickness of the diffusion boundary layer, which is determined by macroalgal morphology and water velocity. Energetic predictions that macroalgae growing at or near the lower limit of PAR for growth should rely on diffusive CO(2) entry without acid and alkaline zones, and on NH(4) (+) rather than NO(3) (-) as nitrogen source, are only partially borne out by observation. The impact of global environmental change on marine macroalgae mainly relates to ocean acidification and warming with shoaling of the thermocline and decreased nutrient flux to the upper mixed layer. Predictions of the impact on macroalgae requires further experiments on interactions among increased inorganic carbon, increased temperature and decreased nitrogen and phosphorus supply, and, when possible, studies of genetic adaptation to environmental change.     

Recruitment and metamorphosis of Haliotis larvae induced by molecules uniquely available at the surfaces of crustose red algae

Crustose red algae induce substratum-specific settlement, attachment and metamorphosis of the planktonic larvae of Haliotis rufescens Swainson (gastropod mollusc), upon direct contact by the larvae with any of a number of algal species tested. Larvae are not induced by contact with intact foliose red, brown or green macroalgae. Geniculate red algae are only slightly active. Larval settlement and metamorphosis are shown to be triggered by a class of chemical inducers associated with macromolecules and found in extracts of all species of crustose, geniculate, and foliose red algae tested; these inducers are not found in extracts of brown or green macroalgae. The substratum specificity of larval settlement and metamorphosis is shown to result from the unique availability of these inducers at the surfaces of the crustose red algae. Using a newly-developed improved method of purification based upon size-separation by gel-filtration, followed by ion-exchange chromatography over a diethylaminoethyl (DEAE)-acrylamide matrix, the principal inducer of Haliotis larval settlement and metamorphosis has been resolved from the red algal phycobiliproteins. Sensitivity of this inducer to reduction in molecular weight by digestion with trypsin demonstrates that this inducer is associated with protein.     

MACROALGAL CANDIDATES FOR GENOMICS

Waaland, J. R.¹ & Stiller, J. W.^{2 1}Department of Botany, University of Washington, Seattle, WA 98195 USA; ²Department of Biology, East Carolina University, Greenville, NC 27858 USA Macroalgae are important components of aquatic ecosystems. Some are harvested or cultivated for economic uses while others are of interest for their phylogenetic or systematic positions. Although most genes known from macroalgae have been isolated for comparative evolutionary analysis, some have been the subject of more detailed molecular investigations. We examine the current state of knowledge for several macroalgae as candidates for genomic study. Selection criteria for target taxa include features such as a well known sexual life history, availability of established laboratory cultures, mutant strains, basic genetic studies, fossil records, and ecological and economic importance. Among the algae to be considered are: Porphyra, Gracilaria, Ectocarpus, Macrocystis, Laminaria, Fucus, Ulva, Chara and Nitella. A strong case can be made for each of these taxa; however, we will emphasize Porphyra yezoensis because of its importance as a food source, its well-characterized and easily manipulated reproductive biology, its relatively small genome size, and recent technical advances in genetic manipulation that should lead to fruitful exploitation of genomic information as it becomes available. Further, the genome of a red alga is an attractive target for comparison with those of other multicellular eukaryotes that have been the object of sequencing projects thus far.     

Morphological and Taxonomic Interpretation of <Emphasis Type="Italic">Orestovia</Emphasis> and <Emphasis Type="Italic">Schuguria</Emphasis>, Enigmatic Devonian Plants from Russia

A detailed study of the external and internal surfaces of the cuticle of Orestovia and Schuguria using scanning electron microscopy and confocal laser microscopy has shown that the structures formerly interpreted as stomata or reproductive organs are most likely to be gland cells producing mucilage. Each structure represents a single large cell with a complex aperture on the external wall. In addition, a reproductive organ similar to multilocular sporangia known in brown algae of the order Ectocarpales has been found in attachment to a compression fossil of Orestovia. These data suggest similarity of the genera studied with brown algae.     

Development and physiology of the brown alga Ectocarpus siliculosus: two centuries of research

Brown algae share several important features with land plants, such as their photoautotrophic nature and their cellulose-containing wall, but the two groups are distantly related from an evolutionary point of view. The heterokont phylum, to which the brown algae belong, is a eukaryotic crown group that is phylogenetically distinct not only from the green lineage, but also from the red algae and the opisthokont phylum (fungi and animals). As a result of this independent evolutionary history, the brown algae exhibit many novel features and, moreover, have evolved complex multicellular development independently of the other major groups already mentioned. In 2004, a consortium of laboratories, including the Station Biologique in Roscoff and Genoscope, initiated a project to sequence the genome of Ectocarpus siliculosus, a small filamentous brown alga that is found in temperate, coastal environments throughout the globe. The E. siliculosus genome, which is currently being annotated, is expected to be the first completely characterized genome of a multicellular alga. In this review we look back over two centuries of work on this brown alga and highlight the advances that have led to the choice of E. siliculosus as a genomic and genetic model organism for the brown algae.     

RESOLVING EVOLUTIONARY RELATIONSHIPS AMONG THE BROWN ALGAE USING CHLOROPLAST AND NUCLEAR GENES1

The brown algae are one of the largest and most important groups of primary producers in benthic coastal marine environments. Despite their biological importance, consensus regarding their taxonomic or evolutionary relationships remains elusive. Our goal was to produce a taxon‐rich two‐gene (rbcL and LSU rDNA) phylogeny. Key species were sequenced to represent each order and family in the analyses across all 19 orders and ～40 families, including selected outgroups Schizocladiophyceae and Xanthophyceae. Our results are in sharp contrast to traditional phylogenetic concepts; the Ectocarpales are not an early diverging clade, nor do the Fucales diverge early from other brown algae. Rather, Choristocarpus is sister to the remaining brown algae. Other groups traditionally considered to have primitive features are actually recently diverged lineages, turning traditional phylogenetic concepts upside down. Additionally, our results allow for the assessment, in the broadest context, of many of the historical and more recent taxonomic changes, resulting in several emended groups along with proposals for two new orders (Onslowiales, Nemodermatales) and one new family (Phaeosiphoniellaceae).