Komarekiella atlantica gen. et sp. nov. (Nostocaceae, Cyanobacteria): a new subaerial taxon from the Atlantic Rainforest and Kauai, Hawaii

Six strains of Cyanobacteria sampled in the Brazilian Atlantic rainforest and one strain from Kauai, Hawaii, were studied using morphological and molecular approaches, including 16S rRNA gene phylogenies and 16S–23S ITS secondary structures, and are herein described as Komarekilla atlantica gen. et sp. nov.. Morphologically they are similar to Nostoc, Desmonostoc, Halotia, and Mojavia and indistinguishable from Chlorogloeopsis. The parsimony and Bayesian phylogenies of the 16S rDNA show that these strains are close to nostocacean strains, in strongly supported clades and separated from all other genera. The secondary structures of the 16S–23S ITS were very consistent between strains of K. atlantica, but distinctly different from structures in other close taxa. Of special note, the Hawaiian strain of K. atlantica had 16S sequence identities of 99.5– 100% to the Brazilian strains, and 16S–23S ITS sequence identities of 99.4–99.8% to the Brazilian strains, and consequently likely represents a very recent introduction of the species to Kauai from South America, the geographic source of many of the non–native plants in the Hawaiian Archipelago

Genomic and Metabolomic Analyses of Natural Products in Nodularia spumigena Isolated from a Shrimp Culture Pond

The bloom-forming cyanobacterium Nodularia spumigena CENA596 encodes the biosynthetic gene clusters (BGCs) of the known natural products nodularins, spumigins, anabaenopeptins/namalides, aeruginosins, mycosporin-like amino acids, and scytonemin, along with the terpenoid geosmin. Targeted metabolomics confirmed the production of these metabolic compounds, except for the alkaloid scytonemin. Genome mining of N. spumigena CENA596 and its three closely related Nodularia strains—two planktonic strains from the Baltic Sea and one benthic strain from Japanese marine sediment—revealed that the number of BGCs in planktonic strains was higher than in benthic one. Geosmin—a volatile compound with unpleasant taste and odor—was unique to the Brazilian strain CENA596. Automatic annotation of the genomes using subsystems technology revealed a related number of coding sequences and functional roles. Orthologs from the Nodularia genomes are involved in the primary and secondary metabolisms. Phylogenomic analysis of N. spumigena CENA596 based on 120 conserved protein sequences positioned this strain close to the Baltic Nodularia. Phylogeny of the 16S rRNA genes separated the Brazilian CENA596 strain from those of the Baltic Sea, despite their high sequence identities (99% identity, 100% coverage). The comparative analysis among planktic Nodularia strains showed that their genomes were considerably similar despite their geographically distant origin

The compositionally distinct cyanobacterial biocrusts from brazilian savanna and their environmental drivers of community diversity

Machado de Lima, Náthali Maria. São Paulo State University (UNESP). Microbiology Graduation Program. Department of Zoology and Botany. São Paulo, Brazil.Cámara Fernandes, Vanessa Moreira. Arizona State University. Center for Fundamental and Applied Microbiomics. Biodesign Institute. Tempe, Arizona, United States.Roush, Daniel. Arizona State University. Center for Fundamental and Applied Microbiomics. Biodesign Institute. Tempe, Arizona, United States.Velasco Ayuso, Sergio. Universidad de Buenos Aires. Facultad de Agronomía. Instituto de Investigaciones Fisiológicas y Ecológicas Vinculadas a la Agricultura (IFEVA). Buenos Aires, Argentina.Rigonato, Janaina. University of São Paulo (USP). Center for Nuclear Energy in Agriculture (CENA). Piracicaba, Brazil.Garcia Pichel, Ferran. Arizona State University. Center for Fundamental and Applied Microbiomics. Biodesign Institute. Tempe, Arizona, United States.Zanini Branco, Luis Henrique. São Paulo State University (UNESP). Microbiology Graduation Program. Department of Zoology and Botany. São Paulo, Brazil.10The last decade was marked by efforts to define and identify the main cyanobacterial players in biological crusts around the world. However, not much is known about biocrusts in Brazil’s tropical savanna (cerrado), despite the existence of environments favorable to their development and ecological relevance. We examined the community composition of cyanobacteria in biocrusts from six sites distributed in the Southeast of the country using high throughput sequencing of 16S rRNA and phylogenetic placement in the wider context of biocrusts from deserts. Sequences ascribable to 22 genera of cyanobacteria were identified. Although a significant proportion of sequences did not match those of known cyanobacteria, several clades of Leptolyngbya and Porphyrosiphon were found to be the most abundant. We identified significant differences in dominance and overall composition among the cerrado sites, much larger than within-site variability. The composition of cerrado cyanobacterial communities was distinct from those known in biocrusts from North American deserts. Among several environmental drivers considered, the opposing trend of annual precipitation and mean annual temperature best explained the variability in community composition within Brazilian biocrusts. Their compositional uniqueness speaks of the need for dedicated efforts to study the ecophysiology of tropical savanna biocrust and their roles in ecosystem function for management and preservation

Global Trends in Marine Plankton Diversity across Kingdoms of Life

35 pages, 18 figures, 1 table, supplementary information https://doi.org/10.1016/j.cell.2019.10.008.-- Raw reads of Tara Oceans are deposited at the European Nucleotide Archive (ENA). In particular, newly released 18S rRNA gene metabarcoding reads are available under the number ENA: PRJEB9737. ENA references for the metagenomics reads corresponding to the size fraction < 0.22 μm (for prokaryotic viruses) analyzed in this study are included in Gregory et al. (2019); see their Table S3. ENA references for the metagenomics reads corresponding to the size fraction 0.22-1.6/3 μm (for prokaryotes and giruses) correspond to Salazar et al. (2019) (see https://zenodo.org/record/3473199). Imaging datasets from the nets are available through the collaborative web application and repository EcoTaxa (Picheral et al., 2017) under the address https://ecotaxa.obs-vlfr.fr/prj/412 for regent data, within the 3 projects https://ecotaxa.obs-vlfr.fr/prj/397, https://ecotaxa.obs-vlfr.fr/prj/398, https://ecotaxa.obs-vlfr.fr/prj/395 for bongo data, and within the 2 projects https://ecotaxa.obs-vlfr.fr/prj/377 and https://ecotaxa.obs-vlfr.fr/prj/378 for WP2 data. A table with Shannon values and multiple samples identifiers, plus a table with flow cytometry data split in six groups are available (https://doi.org/10.17632/p9r9wttjkm.1). Contextual data from the Tara Oceans expedition, including those that are newly released from the Arctic Ocean, are available at https://doi.org/10.1594/PANGAEA.875582The ocean is home to myriad small planktonic organisms that underpin the functioning of marine ecosystems. However, their spatial patterns of diversity and the underlying drivers remain poorly known, precluding projections of their responses to global changes. Here we investigate the latitudinal gradients and global predictors of plankton diversity across archaea, bacteria, eukaryotes, and major virus clades using both molecular and imaging data from Tara Oceans. We show a decline of diversity for most planktonic groups toward the poles, mainly driven by decreasing ocean temperatures. Projections into the future suggest that severe warming of the surface ocean by the end of the 21st century could lead to tropicalization of the diversity of most planktonic groups in temperate and polar regions. These changes may have multiple consequences for marine ecosystem functioning and services and are expected to be particularly significant in key areas for carbon sequestration, fisheries, and marine conservationTara Oceans (which includes both the Tara Oceans and Tara Oceans Polar Circle expeditions) would not exist without the leadership of the Tara Ocean Foundation and the continuous support of 23 institutes (https://oceans.taraexpeditions.org/). We further thank the commitment of the following sponsors: CNRS (in particular Groupement de Recherche GDR3280 and the Research Federation for the Study of Global Ocean Systems Ecology and Evolution FR2022/Tara Oceans-GOSEE), the European Molecular Biology Laboratory (EMBL), Genoscope/CEA, the French Ministry of Research, and the French Government “Investissements d’Avenir” programs OCEANOMICS (ANR-11-BTBR-0008), FRANCE GENOMIQUE (ANR-10-INBS-09-08), MEMO LIFE (ANR-10-LABX-54), the PSL∗ Research University (ANR-11-IDEX-0001-02), as well as EMBRC-France (ANR-10-INBS-02). Funding for the collection and processing of the Tara Oceans data set was provided by NASA Ocean Biology and Biogeochemistry Program under grants NNX11AQ14G, NNX09AU43G, NNX13AE58G, and NNX15AC08G (to the University of Maine); the Canada Excellence research chair on remote sensing of Canada’s new Arctic frontier; and the Canada Foundation for Innovation. We also thank agnès b. and Etienne Bourgois, the Prince Albert II de Monaco Foundation, the Veolia Foundation, Region Bretagne, Lorient Agglomeration, Serge Ferrari, Worldcourier, and KAUST for support and commitment. The global sampling effort was enabled by countless scientists and crew who sampled aboard the Tara from 2009–2013, and we thank MERCATOR-CORIOLIS and ACRI-ST for providing daily satellite data during the expeditions. We are also grateful to the countries who graciously granted sampling permission. We thank Stephanie Henson for providing ocean carbon export data and are also grateful to the other researchers who kindly made their data available. We thank Juan J. Pierella-Karlusich for advice regarding single-copy genes. C.d.V. and N.H. thank the Roscoff Bioinformatics platform ABiMS (http://abims.sb-roscoff.fr) for providing computational resources. C.B. acknowledges funding from the European Research Council (ERC) under the European Union’s Horizon 2020 Research and Innovation Program (grant agreement 835067) as well as the Radcliffe Institute of Advanced Study at Harvard University for a scholar’s fellowship during the 2016-2017 academic year. M.B.S. thanks the Gordon and Betty Moore Foundation (award 3790) and the National Science Foundation (awards OCE#1536989 and OCE#1829831) as well as the Ohio Supercomputer for computational support. S.G.A. thanks the Spanish Ministry of Economy and Competitiveness (CTM2017-87736-R), and J.M.G. is grateful for project RT2018-101025-B-100. F.L. thanks the Institut Universitaire de France (IUF) as well as the EMBRC platform PIQv for image analysis. M.C.B., D.S., and J.R. received financial support from the French Facility for Global Environment (FFEM) as part of the “Ocean Plankton, Climate and Development” project. M.C.B. also received financial support from the Coordination for the Improvement of Higher Education Personnel of Brazil (CAPES 99999.000487/2016-03)Peer Reviewe

Cyanobacterial diversity from São Paulo State mangroves

Os micro-organismos desempenham importante papel na reciclagem dos elementos em ecossistemas de manguezais, uma vez que como produtores primários podem controlar reações químicas. O grupo particular das cianobactérias atua promovendo a entrada de carbono e nitrogênio por meio da sua capacidade de realizar fotossíntese oxigênica e fixação de nitrogênio atmosférico. No Brasil, as florestas de manguezais ocupam uma área de aproximadamente 25.000 km2 e no Estado de São Paulo, 240 km2 da área total está coberta por este ecossistema. O objetivo deste trabalho foi avaliar a diversidade de cianobactérias que colonizam as folhas de Avicennia schaueriana, Rhizophora mangle e Laguncularia racemosa do manguezal da Ilha do Cardoso, um ambiente pristino, bem como acessar e comparar a população de cianobactérias dos solos dos manguezais da Ilha do Cardoso e de Bertioga, este último contaminado com óleo bruto. Para este propósito, as técnicas de DGGE e biblioteca de clone do gene RNAr 16S, ARISA e TRFLP do gene nifH foram utilizadas. Os resultados da filosfera evidenciaram uma sutil influência do gênero de árvore na colonização das cianobactérias, entretanto, um forte efeito da localização destas dentro do manguezal foi observado. As folhas das árvores do meio da área de manguezal apresentaram uma maior diversidade de gêneros de cianobactérias. No geral, foram identificados 19 gêneros e várias sequências de cianobactérias não cultiváveis. Uma predominância de sequências com alta similaridade com representantes das ordens Nostocales e Oscillatoriales foi observada. Sequências com identidade com o gênero Symphyonemopsis (ordem Stigonematales) foram recuperadas em maiores quantidade. Com relação à diversidade no solo, os resultados de DGGE e ARISA demonstraram que a população de cianobactérias é distinta entre os manguezais estudados, porém os perfis eletroforéticos das amostras coletadas próximo ao mar se agruparam, sugerindo que a colonização é influenciada pelas condições de inundação. O perfil mais diferente foi obtido no ponto próximo à floresta no manguezal de Bertioga, local mais afetado pela contaminação de óleo. As bibliotecas de clones claramente indicaram diferenças das sequências do gene RNAr 16S entre os pontos amostrados. Um total de 99 UTOs foi obtido, com 61 "singletons". Na localidade próxima ao mar os gêneros Procholorococcus e Synechococcus foram dominantes em ambos os manguezais. A maioria das sequências de RNAr 16S encontradas nos outros pontos foram relacionadas com cianobactérias não cultiváveis. A diversidade alfa sugeriu que o local com menor diversidade foi o meio do manguezal de Bertioga, e o maior foi em Bertioga próximo à floresta, os demais pontos tiveram valores similares. Os maiores índices de riqueza foram encontrados nos pontos próximos à floresta, enquanto menores valores foram observados nos pontos próximos ao mar. A maioria das sequências de RNAr 16S obtidas em Bertioga no meio do manguezal e próximo à floresta tiveram identidades menores do que 90% com as disponíveis no GenBank. Estas sequências podem representar novos táxons ou cianobactérias conhecidas, porém ainda não sequenciadas. O TRFLP do gene nifH indicou que os locais próximos ao mar e meio do manguezal na Ilha do Cardoso abrigaram populações de diazotróficos semelhantes, enquanto que em Bertioga estes pontos apresentaram diferenças nos perfis de TRFLP. As maiores diferenças estavam nos locais próximos à floresta em ambos os manguezais.Microorganisms play important role in the recycling of elements in mangrove ecosystems, since as primary producers they can control chemical reactions. The particular cyanobacteria group act promoting the input of carbon and nitrogen through their ability to realize oxygenic photosynthesis and fixing atmospheric nitrogen. In Brazil, the mangrove forests occupy an area of approximately 25.000 km2, and in the total area of São Paulo State, 240 km2 are covered by this ecosystem. The aim of this work was to evaluate the cyanobacterial diversity that colonize Avicennia schaueriana, Rhizophora mangle and Laguncularia racemosa leaves from Cardoso Island mangrove, a pristine site, as well as to assess and compare the soil cyanobacterial population from both Cardoso Island and Bertioga mangroves, this last one contaminated with crude oil. For this purpose, the techniques of DGGE and clone library of 16S rRNA gene, ARISA, and TRFLP of nifH gene were used. The phyllosphere results evidenced a subtle difference of the genus of tree on the colonization of cyanobacteria, however a strong effect from trees location within the mangrove was observed. The tree leaves from the middle of mangrove area showed a greater diversity of cyanobacterial genera. In geral, 19 genera and several uncultivated cyanobacteria were identified. A predominance of sequences with high similarities to representatives of the order Nostocales and Oscillatoriales were observed. Sequences with similarities to the genus Symphyonemopsis (order Stigonematales) were recovered in higher quantity. Regarding to the soil diversity, DGGE and ARISA results showed that the cyanobacterial population is distinct among both mangroves studied, however the electrophoretic profiles from samples collected near to the sea grouped together, suggesting that colonization is influenced by flood conditions. The most different profile was obtained in the site near to the forest in Bertioga mangrove, location more affected by the oil contamination. Clone libraries clearly showed 16S rRNA sequences differences among sites sampled. A total of 99 OTUs were obtained, with 61 singletons. In the site near to the sea the Procholorococcus and Synechococcus genera were dominant in both mangroves. The majority of 16S rRNA sequences found in the other sites were related to uncultured cyanobacteria. Alpha diversity suggested that the site with lowest diversity was middle of the Bertioga mangrove, and the highest was Bertioga near to the forest, the remainder sites had similar values. The highest richness indices were found in the sites near to the forest, while lower values were observed in the sites near to the sea. The majority of the 16S rRNA sequences obtained from the middle of the mangrove and near to the forest in Bertioga showed identities lower than 90% with that available in the GenBank. These sequences may represent novel cyanobacterial taxa or known cyanobacteria not yet sequenced. The TRFLP of nifH gene indicated that the sites near to the sea and middle of the Cardoso Island mangrove harbored similar diazotrophic populations, while in Bertioga these sites presented differences in TRFLP profiles. The greatest differences were in the sites near to the forest in both mangroves

Ocean-wide comparisons of plankton composition clarify differences in the structure and regulation of mesopelagic communities: Ocean-wide comparisons of plankton composition clarify differences in the structure and regulation of mesopelagic communities

International audienc

Ocean-wide comparisons of plankton composition clarify differences in the structure and regulation of mesopelagic communities: Ocean-wide comparisons of plankton composition clarify differences in the structure and regulation of mesopelagic communities

International audienc