A preliminary investigation of the order Bangiales (Bangiophycidae, Rhodophyta) based on sequences of nuclear small-subunit ribosomal RNA genes

We investigated phylogenetic relationships among red algae of the order Bangiales by analysis of sequences of the nuclear gene encoding cytosolic small-subunit ribosomal RNA in Bangia atropurpurea (Roth) C. Ag. and eight samples representing seven species of Porphyra. The ssu-rDNA range from 1818 to 1845 nucleotides in length, with guanosine plus cytosine ratios between 47.0% and 48.6%. A group IC1 intron occurs in the B atropurpurea ssu-rDNAs at the same position as in P. spiralis var. amplifolia Oliveira Filho et Coll and several other eukaryote ssu-rDNAs. The nine sequences form a stable monophyletic group upon phylogenetic analysis. The ssu-rDNA from B. atropurpurea nests stably within the Porphyra group and is closely related to P. amplissima (Kjellm.) Setchell et Hus in Hus, making the genus Porphyra paraphyletic. No correlation is seen between phylogenetic position and number of cell layers in the Porphyra thallus. We discuss possible taxonomic and evolutionary implications of these observations.     

Observations on the division characterization of diploid nuclear in <Emphasis Type="Italic">Porphyra</Emphasis> (Bangiales,Rhodophyta)

Nuclear divisions of carpospores, conchocelis and conchospores of Porphyra yezoensis, P. haitanensis, P. katadai var. hemiphylla and P. oligospermatangia from China were investigated. The observations showed diploid chromosome numbers of 2n = 6 for P. yezoensis and P. oligospermatangia, and 2n = 10 for P. haitanensis and P. katadai var. hemiphylla. For all four species, somatic pairing of chromosome sets was observed in late prophase. Sister chromosomes separated at anaphase as mitosis took place in carpospores, conchocelis filamentous cells, conchosporangial branch cells and sporangial cells (conchospore formation). Chromosome configurations of tetrad and ring-shaped in conchospore germination were observed, demonstrating the occurrence of meiosis. The characteristics of diploid nuclear division in 2n = 6 species are the same as those of 2n = 10 species. The influence of somatic pairing on nuclear division of diploid cells in Porphyra was discussed.     

GRACILARIOPSIS MCLACHLANII SP. NOV. AND GRACILARIOPSIS PERSICA SP. NOV. OF THE GRACILARIACEAE (GRACILARIALES,RHODOPHYCEAE) FROM THE INDIAN OCEAN1

Two new species of Gracilariopsis from the Indian Ocean are proposed—Gracilariopsis (Gp.) mclachlanii Buriyo, Bellorin et M. C. Oliveira sp. nov. from Tanzania and Gracilariopsis persica Bellorin, Sohrabipour et E. C. Oliveira sp. nov. from Iran—based on morphology and DNA sequence data (rbcL gene and SSU rDNA). Both species fit the typical features of Gracilariopsis: axes cylindrical throughout, freely and loosely ramified up to four orders, with an abrupt transition in cell size from medulla to cortex, cystocarps lacking tubular nutritive cells and superficial spermatangia. Nucleotide sequence comparisons of rbcL and SSU rDNA placed both species into the Gracilariopsis clade as distinct species from all the accepted species for this genus, forming a deeply divergent lineage together with some species from the Pacific. The new species are very difficult to distinguish on morphological grounds from other species of Gracilariopsis, stressing the importance of homologous molecular marker comparisons for the species recognition in this character‐poor genus.     

REPRODUCTION AND LIFE HISTORY OF THE RED ALGA GALAXAURA OBLONGATA (NEMALIALES,GALAXAURACEAE)1

Culture and morphological studies showed that Galaxaura oblongata (Ellis et Solander) Lamouroux has a triphasic life history with conspicuous gametophytes and small filamentous tetrasporophytes. Development of male and female reproductive structures is very similar and both begin with the enlargement of a terminal cell of a filament branch occupying a normal vegetative position within the apical pit of a thallus branch. In male thalli this modified branch forms a conceptacle in which spermatangia are produced. In female thalli, this modified branch forms a three-celled carpogonial branch consisting of a carpogonium, hypogynous cell and basal cell. Filament branches from the basal cell form a pericarp and the gonimoblast develops directly from the carpogonium. Carposporangia are produced in conceptacles which resemble the male conceptacles. About the time the first carposporangia are produced, the carpogonium, hypogynous cell and basal cell form a large fusion cell. Released carpospores germinate in a unipolar or bipolar manner and form small filamentous thalli. Under short day conditions, cruciate tetrasporangia are produced in small clusters. Tetraspores germinate similarly to carpospores and also form small filamentous thalli. Under low nutrient conditions, small cylindrical thalli develop on the filaments and these appear similar to gametophytes collected in nature.     

CELL DIVISION PATTERNS AND DIURNAL CYCLE OF PORPHYRA ABBOTTAE (RHODOPHYTA,BANGIALES) CARPOGONIAL AND CARPOSPORE DEVELOPMENT1

Post-fertilization development of carpospores in Porphyra is a well-documented phenomenon. Development of the pre-fertilization carpogonial cells from vegetative cells, however, has not been previously described. In Porphyra abbottae Krishn., a rock? intertidal monostromatic species occurring from British Columbia to central California, large cells, designated hue CIS “procarpogonial mother cells” (PMCs), initiated the formation of the carpogonial cells. The PMCs formed during late night mitoses beginning at 0200 h with cytokinesis from 0300-0500 h during short day periods of 10:14 h LD in northern California (38°20′N, 123°03′W and 36°37′N, 121°55′W). The PMC cut off numerous smaller cells which in turn divided equal. Approximately 12 h Inter, at 1500 h (day 1) the Smaller cells were recognizable as carpogonial cells by the presence of trichogynes growing from the cytoplasm out through the cell wall to the thallus surface. In another 24 h (day 2), the fertilized carpogonia had divided into carpospore packets. Spores were released at 1500 h the following day (day 3), their projection creating escape channels through the cell walls.     

Hypnea species (Gigartinales,Rhodophyta) from the southeastern coast of Brazil based on molecular studies complemented with morphological analyses,including descriptions of Hypnea edeniana sp. nov. and H. flava sp. nov.

The red algal genus Hypnea (Gigartinales) has a wide geographical distribution along tropical and subtropical coasts around the world. The relatively simple and plastic morphology, often influenced by the conditions of its habitat, complicates the identification of Hypnea species. Therefore, the number and status of some species remain in doubt. Molecular studies have been performed to supplement traditional studies based on morphology, mainly for Hypnea species occurring in Asia. In the present study, sequence data from the DNA barcode COI-5P for 114 samples from the southeastern coast of Brazil, indicated the occurrence of six taxa. Additionally, sequence data from the UPA and rbcL markers for representatives of each of those taxa confirmed the existence of six different species. After morphological analysis and comparison with sequences available in GenBank, these species were named as follows: H. aspera, H. cervicornis, H. cf. musciformis, H. spinella, and two new species, H. flava Nauer, Cassano & M.C. Oliveira and H. edeniana Nauer, Cassano & M.C. Oliveira. Hypnea cervicornis, often considered as a later synonym of H. spinella, should be considered as a distinct species based on morphology and divergence of the three molecular markers used. Hypnea aspera is a new record for the Atlantic Ocean.     

Random amplified polymorphic DNA (RAPD) identification of genetic variation in three species ofPorphyra (Bangiales,Rhodophyta)

The random amplified polymorphic DNA (RAPD) technique was used to characterize three species ofPorphyra from the western North Atlantic and adjacent Gulf of Mexico. Twenty 10-mer primers were screened for DNA amplification usingPorphyra template DNA. Nine of these oligonucleotide primers, all (G+C)-rich, were positive or band-producing, but yielded poor or variable band resolution. Subsequent use of the universal 20-mer M 13 primer resulted in both clear band resolution with a minimum of secondary bands and a high degree of reproducibility. Amplification products for DNA from six regional isolates ofPorphyra carolinensis Coll et Cox,P. leucosticta Thuret in Le Jolis andP. rosengurttii Coll et Cox were compared to each other and toBangia atropurpurea (Roth) C. Agardh. Results provide evidence of both genetically hetero- and homogeneous populations. Use of the RAPD method with the M 13 primer yields amplification products which can be used to fingerprint specific genotypes. This procedure could be used to discriminate between hetero- and homokaryotic fusion products from previously characterized donor strains.     

An evaluation of species relationships in the Porphyra perforata complex (Bangiales,Rhodophyta) using starch gel electrophoresis

Traditional morphological features have formed the basis for distinguishing species of Porphyra. Among these features are number of cell layers, number of chloroplasts per cell, arrangement of reproductive structures on the thallus, and overall morphology. Chromosome number and chromosome morphology have helped corroborate some species identities. A survey of northeast Pacific species of Porphyra using starch gel electrophoresis of 15 soluble proteins has shown that electrophoretic banding patterns provide a reliable diagnostic tool for species identification. Data from starch gel electrophoresis are presented to confirm the identities of species formerly associated with the Porphyra perforata species-complex in British Columbia and northern Washington. Porphyra abbottae, P. fallax, P. kanakaensis, and P. torta are recognized as distinct species, and Porphyra sanjuanensis is synonymized with P. perforata.     

ALGAE FROM CABO FRIO UPWELLING AREA. 2. GELIDIOCOLAX PUSTULATA (GELIDIACEAE,RHODOPHYTA): AN UNUSUAL NEW PUTATIVE PARASITIC SPECIES1

A new species of Gelidiocolax Gardner, G. pustulata Oliveira and Yoneshigue, is described in the tropical western Atlantic from Brazil. The species usually grows on the basal portion of the main axis of Pterocladia capillacea (Gmelin) Bornet et Thuret. Abundant material was collected mainly from November to March at Cabo Frio Island, in the northeast part of the State of Rio de Janeiro, a marine area well known for its upwelling. Infection by the putative parasite seems to damage the host tissue, stimulating the development of a “gall-like” structure that leads to the outgrowth of adventitious branches. The new species has the vegetative features and reproductive structures of the genus Gelidiocolax. It can be distinguished from the other Gelidiocolax species mainly on the basis of its position on the host, size of pustula, the tetrasporangia and the development of spermatangia. Studies of this new taxon support the placement of Gelidiocolax in the Gelidiaceae and not the Choreocolacaceae, as has been suggested in the literature.     

A new species of Litopeltis Hebard, 1920 from Rio de Janeiro,Brazil (Blattodea,Blaberidae, Epilamprinae) with a key to males and geographical distribution of the remaining species of the genus

This contribution describes a new species of Litopeltis from Brazil, L. teresopolitensis sp. n., which shows similarities with L. paineirensis Lopes & Oliveira, 2010 and L. ribeiropretano Lopes & Oliveira, 2010. It differs in characters of morphology genitalia and configuration, with the median sclerite bearing microspines on the sclerotic apex. A map showing the geographic distribution of the Brazilian species and a key to males of the other species of the genus are also presented.     

<Emphasis Type="Italic">Kerianthera longiflora</Emphasis> (Rubiaceae), a remarkable new species from eastern Brazil,with some observations on <Emphasis Type="Italic">K. preclara</Emphasis>

A new species of Kerianthera, K. longiflora Zappi & C. T. Oliveira (Rubiaceae), has been discovered in relicts of Atlantic Forest in Minas Gerais and Espírito Santo, Brazil. This genus was, until now, thought to be monotypic and to occur only in the Amazon. The morphology, phenology and habitat of the new species are discussed and the IUCN conservation status of this and K. preclara are provided.     

TAXONOMY OF THE FLATTENED SOLIERIACEAE (RHODOPHYTA) IN BRAZIL: AGARDHIELLA AND MERISTIELLA1

Taxonomic studies of an extensive collection of flattened members of the Solieriaceae considered by many authors to be species of Agardhiella, Eucheuma, Meristotheca, and Meristiella lead us to conclude that they represent only two genera in Brazil: Agardhiella, including A. ramosissima (Harvey) Kylin and A. floridana (Kylin) Gabrielson ex Guimarães et Oliveira, and Meristiella, with only one species, M. gelidium (J. Agardh) Cheney et Gabrielson. Accordingly, we propose that 1) Meristotheca gigartinoides Joly et Ugadim be synonymized with Agardhiella floridana, and 2) Meristiella echinocarpa (Areschoug) Cheney et Gabrielson and M. schrammii (P. et H. Crouan) Cheney et Gabrielson be synonymized with Meristiella gelidium.     

Olpidiopsis sp., an oomycete from Madagascar that infects Bostrychia and other red algae: Host species susceptibility

Olpidiopsis sp. (Oomycota) was cultured with its original host Bostrychia moritziana (Sonder ex Kützing) J. Agardh from Madagascar. Bean‐shaped zoospores with two heterokont flagella attached to the host cell wall surface and in 2 days host cells began collapsing and one or more syncytia developed in each infected cell. Zoospores were cleaved and an exit tube with a small plug was formed. Complete development and zoospore discharge occurred in 3 days. Infection occurred in cells of polysiphonous branches, monosiphonous branches, rhizoids and reproductive stichidia. Dead cells of plants treated with microwave were not infected. Susceptibility was variable in other Bostrychia species from different countries. Bostrychia moritziana (Sonder ex Kützing) J. Agardh, and Bostrychia radicans (Montagne) Montagne from Madagascar were susceptible but one Bostrychia tenella (J. V. Lamouroux) J. Agardh isolate from Madagascar was susceptible and two were not. B. radicosa (Itono) J. A. West, G. C. Zuccarello et M. Hommersand isolates from Madagascar, Thailand, Australia and New Caledonia were susceptible but an isolate from Malaysia was not. B. radicans isolates from Mexico and Brazil were non‐susceptible as were Bostrychia flagellifera Post, Bostrychia harveyi Montagne, Bostrychia montagnei Harvey, Bostrychia simpliciuscula Harvey ex J. Agardh, Bostrychia tenuissima R. J. King et Puttock, Stictosiphonia intricata(Bory de Saint‐Vincent) P. C. Silva, Stictosiphonia kelanensis (Grunow) R. J. King et Puttock and Stictosiphonia tangatensis (Post) R. J. King et Puttock, Lophosiphonia sp., Neosiphonia sp. and Polysiphonia spp. isolates were also non‐susceptible. Many non‐susceptible strains showed initial cell‐collapse followed by rapid wound‐repair cell formation without syncytia or sporangia developing. Caloglossa leprieurii (Montagne) G. Martens from Madagascar showed cell‐collapse and wound‐repair in periaxial cells, but wing cells died and became purple without wound‐repair. Caloglossa ogasawaraensis Okamura and Caloglossa postiae M. Kamiya et R. J. King had no symptoms of infection. Dasysiphonia chejuensis I. K. Lee et J. A. West was not infected. Surprisingly, the conchocelis phase but not the blade phase of Porphyra pulchella J. A.West, G. C. Zuccarello and Porphyra suborbiculata Kjellman was infected. The conchocelis of Porphyra tenera Kjellman and Porphyra linearis Greville were infected but no blade stages were tested. Porphyra miniata (C. Agardh) C. Agardh and Porphyra dentata Kjellman conchocelis were not infected. Bangia atropurpurea (Roth) C. Agardh gametophyte filaments were not infected. Other red, brown and green algae were not infected. Time lapse videomicroscopy of development and spore release was done.     

Lotharella vacuolata sp. nov., a new species of chlorarachniophyte algae, and time-lapse video observations on its unique post-cell division behavior

A new species of chlorarachniophyte alga, Lotharella vacuolata Ota et Ishida sp. nov., is described. This alga has been maintained as strain CCMP240 at the Provasoli‐Guillard National Center for Culture of Marine Phytoplankton at Bigelow Laboratory for Ocean Sciences. We examined in detail its morphology, ultrastructure and life cycle, using light microscopy, transmission electron microscopy and time‐lapse videomicroscopy. The dominant stage in the life cycle was represented by coccoid cells; however, amoeboid and flagellated stages were also observed. This alga showed unique post‐cell division behavior: one of the two daughter cells became amoeboid and escaped through a pore on the parental cell wall; the other daughter cell remained within the parental cell wall. Pyrenoid ultrastructure and nucleomorph location, which are used as the main generic criteria of chlorarachniophytes, confirmed that the strain CCMP240 is a member of Lotharella. This alga, however, was clearly distinguished from other known Lotharella species by the presence of large vacuoles, unusual post‐cell division behavior and some unique ultrastructural characters.     

Discovery of a novel type of body scale in the marine dinoflagellate,Amphidinium cupulatisquama sp. nov. (Dinophyceae)

A new species of Amphidinium, A. cupulatisquama Tamura et Horiguchi, from sand samples from Ikei Island, Okinawa Prefecture in subtropical Japan, is described based on light, scanning and transmission electron microscopy and the partial sequencing of the large subunit rDNA gene. The species has a typical morphology for the genus, but is distinguished from previously described species by having a combination of the following characteristics: (i) a relatively large cell (over 30 µm in length); (ii) possessing an eyespot on the dorsal side of the cingulum; (iii) the longitudinal flagellum emerging from a point close to the cingulum; (iv) cell division taking place in the motile phase; and (v) possessing body scales. This is the third species of this genus to possess body scales. The body scales of A. cupulatisquama are uniform and cup‐shaped in side view and elliptical in face view. Their dimensions are 136.4 nm by 91.0 nm by 81.8 nm high. In side view, the scale is seen to have a thick lower half and a thin upper half. This scale type is very different from those of previously reported Amphidinium species (HG114 and HG115). The molecular tree indicated that A. cupulatisquama and the two other strains of body scale‐bearing Amphidinium are distantly related within the Amphidinium clade.     

Deviations in the life-history of Gracilaria sp. (Rhodophyta,Gigartinales), from Coquimbo,Chile, under different culture conditions

Cystocarpic branches of a species of Gracilaria from Coquimbo, Chile, were cultured in vitro. A Polysiphonia-like life history was completed in about 6 months, but some abnormalities were observed: i. carpospores gave rise to plants producing either tetrasporangia and spermatangia, or tetrasporangia only; ii. tetraspores cultured without aeration developed into plants bearing spermatangia only; tetraspores cultured with aeration developed into 1:1 female and male gametophytes; iii. plant originated from tetraspore produced spermatangia and tetrasporangia; one of these tetraspores developed into a male gametophyte; iv. some tetraspores gave rise to spherical bodies instead of the ordinary cylindrical branches; one of them bore spermatangia after three months. The results show that environmental factors seem to be interfering with the mechanism of sex determination and induce the development of spermatangia on putative female gametophytes, or on putative tetrasporophytes. Noted added in proof: The Gracilaria sp. studied here was recently described as a new species, G. chilensis by Bird C. J., McLachlan, J & Oliveira, E. C. de, 1986. Can. J. Bot. 64: 2928–2934. Noted added in proof: The Gracilaria sp. studied here was recently described as a new species, G. chilensis by Bird C. J., McLachlan, J & Oliveira, E. C. de, 1986. Can. J. Bot. 64: 2928–2934.     

TWO MORPHOLOGICALLY SIMILAR BIOLOGICAL SPECIES: CHONDRUS PINNULATUS AND C. ARMATUS (GIGARTINACEAE,RHODOPHYTA)1

The nature of the relationship between Chondrus pinnulatus (Harvey) Okamura f. pinnulatus and C. pinnulatus f. armatus (Harvey) Yamada et Mikami (Gigartinaceae, Rhodophyta) was investigated by comparative analysis of their biogeography, phenologies, life histories, gross and vegetative morphology, crossability, and upper thermal tolerance. The forma pinnulatus has a more northerly distribution in Japan and adjacent waters, exhibiting adaptation to the cooler regions, whereas the forma armatus has a more southerly range. The latter may be the result of a higher thermal tolerance. Both formae have a Polysiphonia-type life history and are similar in their internal vegetative morphology. They can, however, be distinguished by gross morphology: forma pinnulatus has wide, flattened axes, compressed to flattened ultimate segments and proliferations, while forma armatus has narrow, compressed to subterete axes and subterete to terete ultimate segments and proliferations. These differences persist in laboratory culture. All intraformae crosses were positive, with carpospores from the cross developing into fertile F₁ tetrasporophytes releasing tetraspores that developed into dioecious F₁ gametophytes, the female gametophytes of which formed normal cystocarps. This suggests that members of populations of each forma freely interbreed. Among interformae crosses, only some offspring derived from geographically distant strains bore normal cystocarps in the F₁ female gametophytes. Other crosses showed that interbreeding between populations of these two formae was blocked by various isolating mechanisms: incompatibility, hybrid inviability, and hybrid sterility. Reproductive isolation between f. pinnulatus and f. armatus is virtually complete in wild populations, because hybrid populations have not been found in the wild. In addition, these two entities can be considered biological species that are also referred to the taxonomic species, C. armatus and C. pinnulatus, because they do not overlap with regard to the morphology of the ultimate segments and proliferations. Subtle (but significant) gross morphological differences, partial interfertility between the two species, and deleterious hybridization in the area in which they occur sympatrically suggest that their evolutionary divergence was relatively recent.     

Morphological observation,life history and rbcL gene sequence analysis of a new species,Grateloupia variata sp. nov. (Halymeniaceae,Rhodophyta) from Qingdao,China

Grateloupia variata sp. nov. H. W. Wang (Halymeniaceae, Rhodophyta) is newly described from Qingdao, China. The results indicated that: (1) thalli are cartilaginous or gelatinous in texture; (2) thalli are constricted at the base with frequent proliferations; (3) the end portion of branches are irregular, wide, flat or ungulate, split; (4) the cortex is 50–80?μm thick, consisting of four to six layers of cells; the medulla is 10–15?μm long and 1–3?μm wide, consisting of densely and irregularly intertwined filaments; (5) six-celled carpogonial ampullae branched and five-celled auxiliary cell ampullae branched; they are of the typical Grateloupia-type; (6) tetraspores and carpospores grow directly into discoid crusts through initial cell division and are of the immediate discal type; (7) Grateloupia variata sp. nov. shows a typical triphasic life history with homotypic gametophytes, carposporophytes and tetrasporophytes, and a typical homotypic alternation of generations; and (8) the rbcL sequences show no pairwise divergence and the species form a small single monophyletic subclade within the Grateloupia clade. Morphological observations, life history and molecular analysis support G. variata as a new species.