Your search keyword '"Edgcomb, V"' showing total 106 results

1. Studying the In Situ Role of Protistan Communities in Hydrocarbon Contaminated Water Samples via Community Profiling and CARD-FISH

Author

Behnke, A., Engel, M., Edgcomb, V., Stoeck, T., and Timmis, Kenneth N., editor

Published

2010

2. Role of Protists in Microbial Interactions with Hydrocarbons

Author

Stoeck, T., Edgcomb, V., and Timmis, Kenneth N., editor

Published

2010

3. A genomic catalog of Earth’s microbiomes

Author

Nayfach, S., Roux, S., Seshadri, R., Udwary, D., Varghese, N., Schulz, F., Wu, D., Paez-Espino, D., Chen, I., Huntemann, M., Palaniappan, K., Ladau, J., Mukherjee, S., Reddy, T., Nielsen, T., Kirton, E., Faria, J., Edirisinghe, J., Henry, C., Jungbluth, S., Chivian, D., Dehal, P., Wood-Charlson, E., Arkin, A., Tringe, S., Visel, A., Abreu, H., Acinas, S., Allen, E., Allen, M., Alteio, L., Andersen, G., Anesio, A., Attwood, G., Avila-Magaña, V., Badis, Y., Bailey, J., Baker, B., Baldrian, P., Barton, H., Beck, D., Becraft, E., Beller, H., Beman, J., Bernier-Latmani, R., Berry, T., Bertagnolli, A., Bertilsson, S., Bhatnagar, J., Bird, J., Blanchard, J., Blumer-Schuette, S., Bohannan, B., Borton, M., Brady, A., Brawley, S., Brodie, J., Brown, S., Brum, J., Brune, A., Bryant, D., Buchan, A., Buckley, D., Buongiorno, J., Cadillo-Quiroz, H., Caffrey, S., Campbell, A., Campbell, B., Carr, S., Carroll, J., Cary, S., Cates, A., Cattolico, R., Cavicchioli, R., Chistoserdova, L., Coleman, M., Constant, P., Conway, J., Mac Cormack, W., Crowe, S., Crump, B., Currie, C., Daly, R., DeAngelis, K., Denef, V., Denman, S., Desta, A., Dionisi, H., Dodsworth, J., Dombrowski, N., Donohue, T., Dopson, M., Driscoll, T., Dunfield, P., Dupont, C., Dynarski, K., Edgcomb, V., Edwards, E., Elshahed, M., Figueroa, I., Flood, B., Fortney, N., Fortunato, C., Francis, C., Gachon, C., Garcia, S., Gazitua, M., Gentry, T., Gerwick, L., Gharechahi, J., Girguis, P., Gladden, J., Gradoville, M., Grasby, S., Gravuer, K., Grettenberger, C., Gruninger, R., Guo, J., Habteselassie, M., Hallam, S., Hatzenpichler, R., Hausmann, B., Hazen, T., Hedlund, B., Henny, C., Herfort, L., Hernandez, M., Hershey, O., Hess, M., Hollister, E., Hug, L., Hunt, D., Jansson, J., Jarett, J., Kadnikov, V., Kelly, C., Kelly, R., Kelly, W., Kerfeld, C., Kimbrel, J., Klassen, J., Konstantinidis, K., Lee, L., Li, W., Loder, A., Loy, A., Lozada, M., MacGregor, B., Magnabosco, C., Maria da Silva, A., McKay, R., McMahon, K., McSweeney, C., Medina, M., Meredith, L., Mizzi, J., Mock, T., Momper, L., Moran, M., Morgan-Lang, C., Moser, D., Muyzer, G., Myrold, D., Nash, M., Nesbø, C., Neumann, A., Neumann, R., Noguera, D., Northen, T., Norton, J., Nowinski, B., Nüsslein, K., O’Malley, M., Oliveira, R., Maia de Oliveira, V., Onstott, T., Osvatic, J., Ouyang, Y., Pachiadaki, M., Parnell, J., Partida-Martinez, L., Peay, K., Pelletier, D., Peng, X., Pester, M., Pett-Ridge, J., Peura, S., Pjevac, P., Plominsky, A., Poehlein, A., Pope, P., Ravin, N., Redmond, M., Reiss, R., Rich, V., Rinke, C., Rodrigues, J., Rodriguez-Reillo, W., Rossmassler, K., Sackett, J., Salekdeh, G., Saleska, S., Scarborough, M., Schachtman, D., Schadt, C., Schrenk, M., Sczyrba, A., Sengupta, A., Setubal, J., Shade, A., Sharp, C., Sherman, D., Shubenkova, O., Sierra-Garcia, I., Simister, R., Simon, H., Sjöling, S., Slonczewski, J., Correa de Souza, R., Spear, J., Stegen, J., Stepanauskas, R., Stewart, F., Suen, G., Sullivan, M., Sumner, D., Swan, B., Swingley, W., Tarn, J., Taylor, G., Teeling, H., Tekere, M., Teske, A., Thomas, T., Thrash, C., Tiedje, J., Ting, C., Tully, B., Tyson, G., Ulloa, O., Valentine, D., Van Goethem, M., VanderGheynst, J., Verbeke, T., Vollmers, J., Vuillemin, A., Waldo, N., Walsh, D., Weimer, B., Whitman, T., van der Wielen, P., Wilkins, M., Williams, T., Woodcroft, B., Woolet, J., Wrighton, K., Ye, J., Young, E., Youssef, N., Yu, F., Zemskaya, T., Ziels, R., Woyke, T., Mouncey, N., Ivanova, N., Kyrpides, N., Eloe-Fadrosh, E., Consortium, I., and Agencia Estatal de Investigación (España)

Subjects

Resource, Life sciences, biology, Biomedical Engineering, FILOGENIA, Bioengineering, Genomics, Biology, Microbiology, Applied Microbiology and Biotechnology, Genome, purl.org/becyt/ford/1 [https], 03 medical and health sciences, ddc:570, EARTH MICROBIOME PROJECT, Microbiome, purl.org/becyt/ford/1.6 [https], 030304 developmental biology, 2. Zero hunger, 0303 health sciences, 030306 microbiology, Phylum, 15. Life on land, biology.organism_classification, Computational biology and bioinformatics, Phylogenetic diversity, Evolutionary biology, Earth Microbiome Project, Molecular Medicine, Evolutionary ecology, MAGS, GENOMICS, Biotechnology, Archaea, MICROBIAL DIVERSITY

Abstract

13 pages, 5 figures, supplementary information https://doi.org/10.1038/s41587-020-0718-6.-- Data availability: All available metagenomic data, bins and annotations are available through the IMG/M portal (https://img.jgi.doe.gov/). Bulk download for the 52,515 MAGs is available at https://genome.jgi.doe.gov/GEMs and https://portal.nersc.gov/GEM. Genome-scale metabolic models for the nonredundant, high-quality GEMs are summarized at https://doi.org/10.25982/53247.64/1670777 and available in KBase (https://narrative.kbase.us/#org/jgimags). IMG/M identifiers of all metagenomes binned, including detailed information for each metagenome, are available in Supplementary Table 1.-- The pipeline used to generate the metagenome bins is available at https://bitbucket.org/berkeleylab/metabat/src/master/, Publisher Correction: A genomic catalog of Earth’s microbiomes; Nature Biotechnology 39: 520 (2021); https://doi.org/10.1038/s41587-020-00769-4, The reconstruction of bacterial and archaeal genomes from shotgun metagenomes has enabled insights into the ecology and evolution of environmental and host-associated microbiomes. Here we applied this approach to >10,000 metagenomes collected from diverse habitats covering all of Earth’s continents and oceans, including metagenomes from human and animal hosts, engineered environments, and natural and agricultural soils, to capture extant microbial, metabolic and functional potential. This comprehensive catalog includes 52,515 metagenome-assembled genomes representing 12,556 novel candidate species-level operational taxonomic units spanning 135 phyla. The catalog expands the known phylogenetic diversity of bacteria and archaea by 44% and is broadly available for streamlined comparative analyses, interactive exploration, metabolic modeling and bulk download. We demonstrate the utility of this collection for understanding secondary-metabolite biosynthetic potential and for resolving thousands of new host linkages to uncultivated viruses. This resource underscores the value of genome-centric approaches for revealing genomic properties of uncultivated microorganisms that affect ecosystem processes, This work was conducted by the US DOE Joint Genome Institute, a DOE Office of Science User Facility (contract no. DE-AC02–05CH11231), and used resources of the National Energy Research Scientific Computing Center, which is supported by the Office of Science of the US DOE (contract no. DE-AC02–05CH11231). This work was also supported as part of the Genomic Sciences Program DOE Systems Biology KBase (award nos. DE-AC02-05CH11231, DE-AC02-06CH11357, DE-AC05-00OR22725, and DE-AC02-98CH10886).-- With the funding support of the ‘Severo Ochoa Centre of Excelle

Published

2020

4. A genomic catalog of Earth’s microbiomes

Author

Nayfach, S, Roux, S, Seshadri, R, Udwary, D, Varghese, N, Schulz, F, Wu, D, Paez-Espino, D, Chen, IM, Huntemann, M, Palaniappan, K, Ladau, J, Mukherjee, S, Reddy, TBK, Nielsen, T, Kirton, E, Faria, JP, Edirisinghe, JN, Henry, CS, Jungbluth, SP, Chivian, D, Dehal, P, Wood-Charlson, EM, Arkin, AP, Tringe, SG, Visel, A, Abreu, H, Acinas, SG, Allen, E, Allen, MA ; https://orcid.org/0000-0002-8852-1454, Alteio, LV, Andersen, G, Anesio, AM, Attwood, G, Avila-Magaña, V, Badis, Y, Bailey, J, Baker, B, Baldrian, P, Barton, HA, Beck, DAC, Becraft, ED, Beller, HR, Beman, JM, Bernier-Latmani, R, Berry, TD, Bertagnolli, A, Bertilsson, S, Bhatnagar, JM, Bird, JT, Blanchard, JL, Blumer-Schuette, SE, Bohannan, B, Borton, MA, Brady, A, Brawley, SH, Brodie, J, Brown, S, Brum, JR, Brune, A, Bryant, DA, Buchan, A, Buckley, DH, Buongiorno, J, Cadillo-Quiroz, H, Caffrey, SM, Campbell, AN, Campbell, B, Carr, S, Carroll, JL, Cary, SC, Cates, AM, Cattolico, RA, Cavicchioli, R ; https://orcid.org/0000-0001-8989-6402, Chistoserdova, L, Coleman, ML, Constant, P, Conway, JM, Mac Cormack, WP, Crowe, S, Crump, B, Currie, C, Daly, R, DeAngelis, KM, Denef, V, Denman, SE, Desta, A, Dionisi, H, Dodsworth, J, Dombrowski, N, Donohue, T, Dopson, M, Driscoll, T, Dunfield, P, Dupont, CL, Dynarski, KA, Edgcomb, V, Edwards, EA, Elshahed, MS, Figueroa, I, Williams, Timothy, Thomas, Torsten ; https://orcid.org/0000-0001-9557-3001, Nayfach, S, Roux, S, Seshadri, R, Udwary, D, Varghese, N, Schulz, F, Wu, D, Paez-Espino, D, Chen, IM, Huntemann, M, Palaniappan, K, Ladau, J, Mukherjee, S, Reddy, TBK, Nielsen, T, Kirton, E, Faria, JP, Edirisinghe, JN, Henry, CS, Jungbluth, SP, Chivian, D, Dehal, P, Wood-Charlson, EM, Arkin, AP, Tringe, SG, Visel, A, Abreu, H, Acinas, SG, Allen, E, Allen, MA ; https://orcid.org/0000-0002-8852-1454, Alteio, LV, Andersen, G, Anesio, AM, Attwood, G, Avila-Magaña, V, Badis, Y, Bailey, J, Baker, B, Baldrian, P, Barton, HA, Beck, DAC, Becraft, ED, Beller, HR, Beman, JM, Bernier-Latmani, R, Berry, TD, Bertagnolli, A, Bertilsson, S, Bhatnagar, JM, Bird, JT, Blanchard, JL, Blumer-Schuette, SE, Bohannan, B, Borton, MA, Brady, A, Brawley, SH, Brodie, J, Brown, S, Brum, JR, Brune, A, Bryant, DA, Buchan, A, Buckley, DH, Buongiorno, J, Cadillo-Quiroz, H, Caffrey, SM, Campbell, AN, Campbell, B, Carr, S, Carroll, JL, Cary, SC, Cates, AM, Cattolico, RA, Cavicchioli, R ; https://orcid.org/0000-0001-8989-6402, Chistoserdova, L, Coleman, ML, Constant, P, Conway, JM, Mac Cormack, WP, Crowe, S, Crump, B, Currie, C, Daly, R, DeAngelis, KM, Denef, V, Denman, SE, Desta, A, Dionisi, H, Dodsworth, J, Dombrowski, N, Donohue, T, Dopson, M, Driscoll, T, Dunfield, P, Dupont, CL, Dynarski, KA, Edgcomb, V, Edwards, EA, Elshahed, MS, Figueroa, I, Williams, Timothy, and Thomas, Torsten ; https://orcid.org/0000-0001-9557-3001

Abstract

The reconstruction of bacterial and archaeal genomes from shotgun metagenomes has enabled insights into the ecology and evolution of environmental and host-associated microbiomes. Here we applied this approach to >10,000 metagenomes collected from diverse habitats covering all of Earth’s continents and oceans, including metagenomes from human and animal hosts, engineered environments, and natural and agricultural soils, to capture extant microbial, metabolic and functional potential. This comprehensive catalog includes 52,515 metagenome-assembled genomes representing 12,556 novel candidate species-level operational taxonomic units spanning 135 phyla. The catalog expands the known phylogenetic diversity of bacteria and archaea by 44% and is broadly available for streamlined comparative analyses, interactive exploration, metabolic modeling and bulk download. We demonstrate the utility of this collection for understanding secondary-metabolite biosynthetic potential and for resolving thousands of new host linkages to uncultivated viruses. This resource underscores the value of genome-centric approaches for revealing genomic properties of uncultivated microorganisms that affect ecosystem processes.

Published

2021

5. Author Correction: A genomic catalog of Earth’s microbiomes (Nature Biotechnology, (2021), 39, 4, (499-509), 10.1038/s41587-020-0718-6)

Author

Nayfach, S, Roux, S, Seshadri, R, Udwary, D, Varghese, N, Schulz, F, Wu, D, Paez-Espino, D, Chen, IM, Huntemann, M, Palaniappan, K, Ladau, J, Mukherjee, S, Reddy, TBK, Nielsen, T, Kirton, E, Faria, JP, Edirisinghe, JN, Henry, CS, Jungbluth, SP, Chivian, D, Dehal, P, Wood-Charlson, EM, Arkin, AP, Tringe, SG, Visel, A, Abreu, H, Acinas, SG, Allen, E, Allen, MA ; https://orcid.org/0000-0002-8852-1454, Alteio, LV, Andersen, G, Anesio, AM, Attwood, G, Avila-Magaña, V, Badis, Y, Bailey, J, Baker, B, Baldrian, P, Barton, HA, Beck, DAC, Becraft, ED, Beller, HR, Beman, JM, Bernier-Latmani, R, Berry, TD, Bertagnolli, A, Bertilsson, S, Bhatnagar, JM, Bird, JT, Blanchard, JL, Blumer-Schuette, SE, Bohannan, B, Borton, MA, Brady, A, Brawley, SH, Brodie, J, Brown, S, Brum, JR, Brune, A, Bryant, DA, Buchan, A, Buckley, DH, Buongiorno, J, Cadillo-Quiroz, H, Caffrey, SM, Campbell, AN, Campbell, B, Carr, S, Carroll, JL, Cary, SC, Cates, AM, Cattolico, RA, Cavicchioli, R, Chistoserdova, L, Coleman, ML, Constant, P, Conway, JM, Mac Cormack, WP, Crowe, S, Crump, B, Currie, C, Daly, R, DeAngelis, KM, Denef, V, Denman, SE, Desta, A, Dionisi, H, Dodsworth, J, Dombrowski, N, Donohue, T, Dopson, M, Driscoll, T, Dunfield, P, Dupont, CL, Dynarski, KA, Edgcomb, V, Edwards, EA, Elshahed, MS, Figueroa, I, Thomas, Torsten ; https://orcid.org/0000-0001-9557-3001, Williams, Timothy, Nayfach, S, Roux, S, Seshadri, R, Udwary, D, Varghese, N, Schulz, F, Wu, D, Paez-Espino, D, Chen, IM, Huntemann, M, Palaniappan, K, Ladau, J, Mukherjee, S, Reddy, TBK, Nielsen, T, Kirton, E, Faria, JP, Edirisinghe, JN, Henry, CS, Jungbluth, SP, Chivian, D, Dehal, P, Wood-Charlson, EM, Arkin, AP, Tringe, SG, Visel, A, Abreu, H, Acinas, SG, Allen, E, Allen, MA ; https://orcid.org/0000-0002-8852-1454, Alteio, LV, Andersen, G, Anesio, AM, Attwood, G, Avila-Magaña, V, Badis, Y, Bailey, J, Baker, B, Baldrian, P, Barton, HA, Beck, DAC, Becraft, ED, Beller, HR, Beman, JM, Bernier-Latmani, R, Berry, TD, Bertagnolli, A, Bertilsson, S, Bhatnagar, JM, Bird, JT, Blanchard, JL, Blumer-Schuette, SE, Bohannan, B, Borton, MA, Brady, A, Brawley, SH, Brodie, J, Brown, S, Brum, JR, Brune, A, Bryant, DA, Buchan, A, Buckley, DH, Buongiorno, J, Cadillo-Quiroz, H, Caffrey, SM, Campbell, AN, Campbell, B, Carr, S, Carroll, JL, Cary, SC, Cates, AM, Cattolico, RA, Cavicchioli, R, Chistoserdova, L, Coleman, ML, Constant, P, Conway, JM, Mac Cormack, WP, Crowe, S, Crump, B, Currie, C, Daly, R, DeAngelis, KM, Denef, V, Denman, SE, Desta, A, Dionisi, H, Dodsworth, J, Dombrowski, N, Donohue, T, Dopson, M, Driscoll, T, Dunfield, P, Dupont, CL, Dynarski, KA, Edgcomb, V, Edwards, EA, Elshahed, MS, Figueroa, I, Thomas, Torsten ; https://orcid.org/0000-0001-9557-3001, and Williams, Timothy

Abstract

In the version of this article initially published, four people were missing from the alphabetical list of IMG/M Data Consortium members: Lauren V. Alteio of the Centre for Microbiology and Environmental Systems Science, University of Vienna, Vienna, Austria; Jeffrey L. Blanchard of the Biology Department, University of Massachusetts Amherst, Amherst, MA, USA; Kristen M. DeAngelis of the Department of Microbiology, University of Massachusetts Amherst, Amherst, MA, USA; and William Rodriguez-Reillo of the Research Computing Division, Harvard Medical School, Boston, MA, USA. The error has been corrected in the PDF and HTML versions of the article.

Published

2021

6. Publisher Correction: A genomic catalog of Earth’s microbiomes (Nature Biotechnology, (2021), 39, 4, (499-509), 10.1038/s41587-020-0718-6)

Author

Nayfach, S, Roux, S, Seshadri, R, Udwary, D, Varghese, N, Schulz, F, Wu, D, Paez-Espino, D, Chen, IM, Huntemann, M, Palaniappan, K, Ladau, J, Mukherjee, S, Reddy, TBK, Nielsen, T, Kirton, E, Faria, JP, Edirisinghe, JN, Henry, CS, Jungbluth, SP, Chivian, D, Dehal, P, Wood-Charlson, EM, Arkin, AP, Tringe, SG, Visel, A, Abreu, H, Acinas, SG, Allen, E, Allen, MA ; https://orcid.org/0000-0002-8852-1454, Andersen, G, Anesio, AM, Attwood, G, Avila-Magaña, V, Badis, Y, Bailey, J, Baker, B, Baldrian, P, Barton, HA, Beck, DAC, Becraft, ED, Beller, HR, Beman, JM, Bernier-Latmani, R, Berry, TD, Bertagnolli, A, Bertilsson, S, Bhatnagar, JM, Bird, JT, Blumer-Schuette, SE, Bohannan, B, Borton, MA, Brady, A, Brawley, SH, Brodie, J, Brown, S, Brum, JR, Brune, A, Bryant, DA, Buchan, A, Buckley, DH, Buongiorno, J, Cadillo-Quiroz, H, Caffrey, SM, Campbell, AN, Campbell, B, Carr, S, Carroll, JL, Cary, SC, Cates, AM, Cattolico, RA, Cavicchioli, R, Chistoserdova, L, Coleman, ML, Constant, P, Conway, JM, Mac Cormack, WP, Crowe, S, Crump, B, Currie, C, Daly, R, Denef, V, Denman, SE, Desta, A, Dionisi, H, Dodsworth, J, Dombrowski, N, Donohue, T, Dopson, M, Driscoll, T, Dunfield, P, Dupont, CL, Dynarski, KA, Edgcomb, V, Edwards, EA, Elshahed, MS, Figueroa, I, Flood, B, Fortney, N, Fortunato, CS, Williams, Timothy, Thomas, Torsten ; https://orcid.org/0000-0001-9557-3001, Nayfach, S, Roux, S, Seshadri, R, Udwary, D, Varghese, N, Schulz, F, Wu, D, Paez-Espino, D, Chen, IM, Huntemann, M, Palaniappan, K, Ladau, J, Mukherjee, S, Reddy, TBK, Nielsen, T, Kirton, E, Faria, JP, Edirisinghe, JN, Henry, CS, Jungbluth, SP, Chivian, D, Dehal, P, Wood-Charlson, EM, Arkin, AP, Tringe, SG, Visel, A, Abreu, H, Acinas, SG, Allen, E, Allen, MA ; https://orcid.org/0000-0002-8852-1454, Andersen, G, Anesio, AM, Attwood, G, Avila-Magaña, V, Badis, Y, Bailey, J, Baker, B, Baldrian, P, Barton, HA, Beck, DAC, Becraft, ED, Beller, HR, Beman, JM, Bernier-Latmani, R, Berry, TD, Bertagnolli, A, Bertilsson, S, Bhatnagar, JM, Bird, JT, Blumer-Schuette, SE, Bohannan, B, Borton, MA, Brady, A, Brawley, SH, Brodie, J, Brown, S, Brum, JR, Brune, A, Bryant, DA, Buchan, A, Buckley, DH, Buongiorno, J, Cadillo-Quiroz, H, Caffrey, SM, Campbell, AN, Campbell, B, Carr, S, Carroll, JL, Cary, SC, Cates, AM, Cattolico, RA, Cavicchioli, R, Chistoserdova, L, Coleman, ML, Constant, P, Conway, JM, Mac Cormack, WP, Crowe, S, Crump, B, Currie, C, Daly, R, Denef, V, Denman, SE, Desta, A, Dionisi, H, Dodsworth, J, Dombrowski, N, Donohue, T, Dopson, M, Driscoll, T, Dunfield, P, Dupont, CL, Dynarski, KA, Edgcomb, V, Edwards, EA, Elshahed, MS, Figueroa, I, Flood, B, Fortney, N, Fortunato, CS, Williams, Timothy, and Thomas, Torsten ; https://orcid.org/0000-0001-9557-3001

Abstract

This paper was originally published under standard Springer Nature copyright (© The Author(s), under exclusive licence to Springer Nature America, Inc.). It is now available as an open-access paper under a Creative Commons Attribution 4.0 International license. The error has been corrected in the print, HTML and PDF versions of the article.

Published

2021

7. Environmental factors shaping bacterial, archaeal and fungal community structure in hydrothermal sediments of Guaymas Basin, Gulf of California

Author

Ramirez, G.A., Paraskevi, M., Sehein, T., Wegener, Gunter, Chambers, C.R., Joye, S.B., Peterson, R.N., Philippe, A., Burgaud, G., Edgcomb, V., Teske, A.P., Ramirez, G.A., Paraskevi, M., Sehein, T., Wegener, Gunter, Chambers, C.R., Joye, S.B., Peterson, R.N., Philippe, A., Burgaud, G., Edgcomb, V., and Teske, A.P.

Abstract

The flanking regions of Guaymas Basin, a young marginal rift basin located in the Gulf of California, are covered with thick sediment layers that are hydrothermally altered due to magmatic intrusions. To explore environmental controls on microbial community structure in this complex environment, we analyzed site- and depth-related patterns of microbial community composition (bacteria, archaea, and fungi) in hydrothermally influenced sediments with different thermal conditions, geochemical regimes, and extent of microbial mats. We compared communities in hot hydrothermal sediments (75-100°C at ~40 cm depth) covered by orange-pigmented Beggiatoaceae mats in the Cathedral Hill area, temperate sediments (25-30°C at ~40 cm depth) covered by yellow sulfur precipitates and filamentous sulfur oxidizers at the Aceto Balsamico location, hot sediments (>115°C at ~40 cm depth) with orange-pigmented mats surrounded by yellow and white mats at the Marker 14 location, and background, non-hydrothermal sediments (3.8°C at ~45 cm depth) overlain with ambient seawater. Whereas bacterial and archaeal communities are clearly structured by site-specific in-situ thermal gradients and geochemical conditions, fungal communities are generally structured by sediment depth. Unexpectedly, chytrid sequence biosignatures are ubiquitous in surficial sediments whereas deeper sediments contain diverse yeasts and filamentous fungi. In correlation analyses across different sites and sediment depths, fungal phylotypes correlate to each other to a much greater degree than Bacteria and Archaea do to each other or to fungi, further substantiating that site-specific in-situ thermal gradients and geochemical conditions that control bacteria and archaea do not extend to fungi.

Published

2021

8. Site U1552.

Author

Teske, A., Lizarralde, D., Höfig, T. W., Aiello, I. W., Ash, J. L., Bojanova, D. P., Buatier, M. D., Edgcomb, V. P., Galerne, C. Y., Gontharet, S., Heuer, V. B., Jiang, S., Kars, M. A. C., Singh, S. Khogenkumar, Kim, J.-H., Koornneef, L. M. T., Marsaglia, K. M., Meyer, N. R., Morono, Y., and Negrete-Aranda, R.

Subjects

SILLS (Geology), PORE water, GAS hydrates, CARBON sequestration, MICROBIAL communities, UNDERWATER drilling, SCIENTIFIC expeditions

Published

2021

9. Sites U1547 and U1548.

Author

Teske, A., Lizarralde, D., Höfig, T. W., Aiello, I. W., Ash, J. L., Bojanova, D. P., Buatier, M. D., Edgcomb, V. P., Galerne, C. Y., Gontharet, S., Heuer, V. B., Jiang, S., Kars, M. A. C., Singh, S. Khogenkumar, Kim, J.-H., Koornneef, L. M. T., Marsaglia, K. M., Meyer, N. R., Morono, Y., and Negrete-Aranda, R.

Subjects

SILLS (Geology), GEOCHEMICAL surveys, MARINE sediments, MICROBIAL communities, UNDERWATER drilling, SCIENTIFIC expeditions

Published

2021

10. Expedition 385 methods.

Author

Teske, A., Lizarralde, D., Höfig, T. W., Aiello, I. W., Ash, J. L., Bojanova, D. P., Buatier, M. D., Edgcomb, V. P., Galerne, C. Y., Gontharet, S., Heuer, V. B., Jiang, S., Kars, M. A. C., Singh, S. Khogenkumar, Kim, J.-H., Koornneef, L. M. T., Marsaglia, K. M., Meyer, N. R., Morono, Y., and Negrete-Aranda, R.

Subjects

UNDERWATER drilling, SCIENTIFIC expeditions, RESEARCH vessels, SCIENCE databases

Published

2021

11. Expedition 385 summary.

Author

Teske, A., Lizarralde, D., Höfig, T. W., Aiello, I. W., Ash, J. L., Bojanova, D. P., Buatier, M. D., Edgcomb, V. P., Galerne, C. Y., Gontharet, S., Heuer, V. B., Jiang, S., Kars, M. A. C., Singh, S. Khogenkumar, Kim, J.-H., Koornneef, L. M. T., Marsaglia, K. M., Meyer, N. R., Morono, Y., and Negrete-Aranda, R.

Subjects

SCIENTIFIC expeditions, UNDERWATER drilling, SPREADING centers (Geology), HEAT flow (Oceanography), MAGMATISM, MARINE sediments

Abstract

International Ocean Discovery Program Expedition 385 drilled organic-rich sediments and intruded sills in the off-axis region and axial graben of the northern spreading segment of Guaymas Basin, a young marginal seafloor spreading system in the Gulf of California. Guaymas Basin is characterized by high heat flow and magmatism in the form of sill intrusions into sediments, which extends tens of kilometers off axis, in contrast with the localized volcanism found at most mid-ocean ridge spreading centers. Sill intrusions provide transient heat sources that mobilize buried sedimentary carbon, in part as methane and other hydrocarbons, and drive hydrothermal circulation. The resulting thermal and geochemical gradients shape abundance, composition, and activity of the deep subsurface biosphere of the basin. Drill sites extend over a broad region of Guaymas Basin. Adjacent Sites U1545 and U1546, located ~52 km northwest of the northern Guaymas Basin axial graben, recovered sediment successions to ~540 meters below seafloor (mbsf) (equivalent to the core depth below seafloor, Method A [CSF-A] scale), including a thin sill (a few meters thick) drilled near the bottom of Site U1545 and a massive sill (~355-430 mbsf) at Site U1546 that chemically and physically affects the surrounding sediments. Sites U1547 and U1548, located ~27 km northwest of the axial graben, were drilled to investigate an active sill-driven hydrothermal system evident at the seafloor as an 800 m wide, circular bathymetric high called Ringvent because of its outline of a ring of active vent sites. Ringvent is underlain by a thick sill at shallow depth (Site U1547). Geothermal gradients steepen toward the Ringvent periphery (Holes U1548A-U1548C), and the zones of authigenic carbonate precipitation and of highest microbial cell abundance correspondingly shallow toward the periphery. The underlying sill was drilled several times and yielded diverse igneous rock textures, sediment/sill interfaces, and alteration minerals in veins and vesicles. The Ringvent sill became the target of an integrated, interdisciplinary sampling and research effort that included geological, geochemical, and microbiological components. The thermal, lithologic, geochemical, and microbiological contrasts between the northwestern sites (U1545 and U1546) and the Ringvent sites (U1547 and U1548) form the core scientific observations informing the direct influence of sillsediment interaction. These observations are supplemented by results from sites that exhibit persistent influence of thermally equilibrated sill intrusions, including supporting long-lived methane cold seeps, as observed at off-axis Sites U1549 and U1552, and the persistent geochemical record of hydrocarbon formation near the sill/sediment contact, as observed at the northern axial trough Site U1550, which confirms observations from Deep Sea Drilling Project (DSDP) Leg 64. Drilling at Site U1551 ~29 km southeast of the axial graben was not successful due to unstable shallow sands, but it confirmed the dominant influence of gravity-flow sedimentation processes southeast of the axial graben. The scientific outcomes of Expedition 385 will (1) revise long-held assumptions about the role of sill emplacement in subsurface carbon mobilization versus carbon retention, (2) comprehensively examine the subsurface biosphere of Guaymas Basin and its responses and adaptations to hydrothermal conditions, (3) redefine hydrothermal controls on authigenic mineral formation in sediments, and (4) yield new insights into the long term influence of sill-sediment interaction on sediments deposited at the earliest stages of seafloor spreading, that is, when spreading centers are proximal to a continental margin. The generally high quality and high degree of completeness of the shipboard data sets present opportunities for inter- and multidisciplinary collaborations during shore-based studies. In comparison to DSDP Leg 64 to Guaymas Basin in 1979, continuous availability of sophisticated drilling strategies (e.g., the advanced piston corer [APC] and halflength APC systems) and numerous analytical innovations greatly improved sample recovery and scientific yield, particularly in the areas of organic geochemistry and microbiology. For example, microbial metagenomics did not exist 40 y ago. However, these technical refinements do not change the fact that Expedition 385 in many respects builds on the foundations of understanding laid by Leg 64 drilling in Guaymas Basin. [ABSTRACT FROM AUTHOR]

Published

2021

12. International Ocean Discovery Program, Expedition 385 Preliminary Report : Guaymas Basin Tectonics and Biosphere ; 15 September–15 November 2019

Author

Teske, A., Lizarralde, D., Höfig, T., Aiello, I., Ash, J., Bojanova, D., Buatier, M., Edgcomb, V., Galerne, C., Gontharet, S., Heuer, V., Jiang, S., Kars, M., Khogenkumar Singh, S., Kim, J., Koornneef, L., Marsaglia, K., Meyer, N., Morono, Y., Negrete-Aranda, R., Neumann, F., Pastor, L., Peña-Salinas, M., Pérez Cruz, L., Ran, L., Riboulleau, A., Sarao, J., Schubert, F., Stock, J., Toffin, L., Xie, W., Yamanaka, T., and Zhuang, G.

Published

2020

13. Expedition 385 Preliminary Report: Guaymas Basin Tectonics and Biosphere

Author

Teske, A. P., Lizarralde, D., Höfig, T. W., Aiello, I. W., Ash, J. L., Bojanova, D. P., Buatier, M. D., Edgcomb, V. P., Galerne, Christophe, Gontharet, S., Heuer, V. B., Jiang, S., Kars, M. A. C., Kim, J., Koorneef, L. M. T., Marsaglia, K. M., Meyer, N. R., Morono, Y., Neumann, F., Negrete-Aranda, R., Pastor, L. C., Penas-Salinas, M. E., Perez Cruz, L. L., Ran, L., Riboulleau, A., Sarao, J. A., Schubert, F., Khogernkumar Singh, S., Stock, J. M., Toffin, L. M. A. A., Xie, W., Yamanaka, T., and Zhuang, G.

Abstract

International Ocean Discovery Program (IODP) Expedition 385 drilled organic-rich sediments with sill intrusions on the flanking regions and in the northern axial graben in Guaymas Basin, a young marginal rift basin in the Gulf of California. Guaymas Basin is characterized by a widely distributed, intense heat flow and widespread off-axis magmatism expressed by a dense network of sill intrusions across the flanking regions, which is in contrast to classical mid-ocean ridge spreading centers. The numerous off-axis sills provide multiple transient heat sources that mobilize buried sedimentary carbon, in part as methane and other hydrocarbons, and drive hydrothermal circulation. The resulting thermal and geochemical gradients shape abundance, composition, and activity of the deep subsurface biosphere of the basin. Drill sites extend over the flanking regions of Guaymas Basin, covering a distance of ~81 km from the from the northwest to the southeast. Adjacent Sites U1545 and U1546 recovered the oldest and thickest sediment successions (to ~540 meters below seafloor [mbsf]; equivalent to the core depth below seafloor, Method A [CSF-A] scale), one with a thin sill (a few meters in thickness) near the drilled bottom (Site U1545), and one with a massive, deeply buried sill (~356–430 mbsf) that chemically and physically affects the surrounding sediments (Site U1546). Sites U1547 and U1548, located in the central part of the northern Guaymas Basin segment, were drilled to investigate a 600 m wide circular mound (bathymetric high) and its periphery. The dome-like structure is outlined by a ring of active vent sites called Ringvent. It is underlain by a remarkably thick sill at shallow depth (Site U1547). Hydrothermal gradients steepen at the Ringvent periphery (Holes U1548A–U1548C), which in turn shifts the zones of authigenic carbonate precipitation and of highest microbial cell abundance toward shallower depths. The Ringvent sill was drilled several times and yielded remarkably diverse igneous rock textures, sediment–sill interfaces, and hydrothermal alteration, reflected by various secondary minerals in veins and vesicles. Thus, the Ringvent sill became the target of an integrated sampling and interdisciplinary research effort that included geological, geochemical, and microbiological specialties. The thermal, lithologic, geochemical, and microbiological contrasts between the two deep northwestern sites (U1545 and U1546) and the Ringvent sites (U1547 and U1548) form the scientific centerpiece of the expedition. These observations are supplemented by results from sites that represent attenuated cold seepage conditions in the central basin (Site U1549), complex and disturbed sediments overlying sills in the northern axial trough (Site U1550), terrigenous sedimentation events on the southeastern flanking regions (Site U1551), and hydrate occurrence in shallow sediments proximal to the Sonora margin (Site U1552). The scientific outcomes of Expedition 385 will (1) revise long-held assumptions about the role of sill emplacement in subsurface carbon mobilization versus carbon retention, (2) comprehensively examine the subsurface biosphere of Guaymas Basin and its responses and adaptations to hydrothermal conditions, (3) redefine hydrothermal controls of authigenic mineral formation in sediments, and (4) yield new insights into many geochemical and geophysical aspects of both architecture and sill–sediment interaction in a nascent spreading center. The generally high quality and high degree of completeness of the shipboard datasets present opportunities for interdisciplinary and multidisciplinary collaborations during shore-based studies. In comparison to Deep Sea Drilling Project Leg 64 to Guaymas Basin in 1979, sophisticated drilling strategies (for example, the advanced piston corer [APC] and half-length APC systems) and numerous analytical innovations have greatly improved sample recovery and scientific yield, particularly in the areas of organic geochemistry and microbiology. For example, microbial genomics did not exist 40 y ago. However, these technical refinements do not change the fact that Expedition 385 will in many respects build on the foundations laid by Leg 64 for understanding Guaymas Basin, regardless of whether adjustments are required in the near future.

Published

2020

14. Dynamic Accretion Beneath a Slow‐Spreading Ridge Segment: IODP Hole 1473A and the Atlantis Bank Oceanic Core Complex

Author

Dick, H. J. B., primary, MacLeod, C. J., additional, Blum, P., additional, Abe, N., additional, Blackman, D. K., additional, Bowles, J. A., additional, Cheadle, M. J., additional, Cho, K., additional, Ciazela, J., additional, Deans, J. R., additional, Edgcomb, V. P., additional, Ferrando, C., additional, France, L., additional, Ghosh, B., additional, Ildefonse, B., additional, John, B., additional, Kendrick, M. A., additional, Koepke, J., additional, Leong, J. A. M., additional, Liu, C., additional, Ma, Q., additional, Morishita, T., additional, Morris, A., additional, Natland, J. H., additional, Nozaka, T., additional, Pluemper, O., additional, Sanfilippo, A., additional, Sylvan, J. B., additional, Tivey, M. A., additional, Tribuzio, R., additional, and Viegas, G., additional

Published

2019

15. Molecular evolution inferred from small subunit rRNA sequences: what does it tell us about phylogenetic relationships and taxonomy of the parabasalids?

Author

Viscogliosi, E, Edgcomb, V. P, Gerbod, D, Noel, C, Delgado-Viscogliosi, P, and Sogin, M. L

Subjects

Exobiology

Abstract

The Parabasala are a primitive group of protists divided into two classes: the trichomonads and the hypermastigids. Until recently, phylogeny and taxonomy of parabasalids were mainly based on the comparative analysis of morphological characters primarily linked to the development of their cytoskeleton. Recent use of molecular markers, such as small subunit (SSU) rRNA has led to now insights into the systematics of the Parabasala and other groups of prolists. An updated phylogeny based on SSU rRNA is provided and compared to that inferred from ultrastructural data. The SSU rRNA phylogeny contradicts the dogma equating simple characters with pumitive characters. Hypermastigids, possessing a hyperdeveloped cytoskeleton, exhibit the most basal emergence in the parabasalid lineage. Other observations emerge from the SSU rRNA analysis, such as the secondary loss of some cytoskeleton structures in all representatives of the Monocercomonadidae, the existence of secondarily free living taxa (reversibility of parasitism) and the evidence against the co-evolution of the endobiotic parabasalids and their animal hosts. According to phylogenies based on SSU rRNA, all the trichomonad families are not monophyletic groups, putting into question the validity of current taxonomic assignments. The precise branching order of some taxa remains unclear, but this issue can possibly be addressed by the molecular analysis of additional parabasalids. The goal of such additional analyses would be to propose, in a near future, a revision of the taxonomy of this group of protists that takes into account both molecular and morphological data.

Published

1999

16. Dynamic Accretion Beneath a Slow-Spreading Ridge Segment: IODP Hole 1473A and the Atlantis Bank Oceanic Core Complex

Author

Dick, H. J.B., MacLeod, C. J., Blum, P., Abe, N., Blackman, D. K., Bowles, J. A., Cheadle, M. J., Cho, K., Ciazela, J., Deans, J. R., Edgcomb, V. P., Ferrando, C., France, L., Ghosh, B., Ildefonse, B., John, B., Kendrick, M. A., Koepke, J., Leong, J. A.M., Liu, C., Ma, Q., Morishita, T., Morris, A., Natland, J. H., Nozaka, T., Pluemper, O., Sanfilippo, A., Sylvan, J. B., Tivey, M. A., Tribuzio, R., Viegas, G., Dick, H. J.B., MacLeod, C. J., Blum, P., Abe, N., Blackman, D. K., Bowles, J. A., Cheadle, M. J., Cho, K., Ciazela, J., Deans, J. R., Edgcomb, V. P., Ferrando, C., France, L., Ghosh, B., Ildefonse, B., John, B., Kendrick, M. A., Koepke, J., Leong, J. A.M., Liu, C., Ma, Q., Morishita, T., Morris, A., Natland, J. H., Nozaka, T., Pluemper, O., Sanfilippo, A., Sylvan, J. B., Tivey, M. A., Tribuzio, R., and Viegas, G.

Abstract

809 deep IODP Hole U1473A at Atlantis Bank, SWIR, is 2.2 km from 1,508-m Hole 735B and 1.4 from 158-m Hole 1105A. With mapping, it provides the first 3-D view of the upper levels of a 660-km2 lower crustal batholith. It is laterally and vertically zoned, representing a complex interplay of cyclic intrusion, and ongoing deformation, with kilometer-scale upward and lateral migration of interstial melt. Transform wall dives over the gabbro-peridotite contact found only evolved gabbro intruded directly into the mantle near the transform. There was no high-level melt lens, rather the gabbros crystallized at depth, and then emplaced into the zone of diking by diapiric rise of a crystal mush followed by crystal-plastic deformation and faulting. The residues to mass balance the crust to a parent melt composition lie at depth below the center of the massif—likely near the crust-mantle boundary. Thus, basalts erupted to the seafloor from >1,550 mbsf. By contrast, the Mid-Atlantic Ridge lower crust drilled at 23°N and at Atlantis Massif experienced little high-temperature deformation and limited late-stage melt transport. They contain primitive cumulates and represent direct intrusion, storage, and crystallization of parental MORB in thinner crust below the dike-gabbro transition. The strong asymmetric spreading of the SWIR to the south was due to fault capture, with the northern rift valley wall faults cutoff by a detachment fault that extended across most of the zone of intrusion. This caused rapid migration of the plate boundary to the north, while the large majority of the lower crust to spread south unroofing Atlantis Bank and uplifting it into the rift mountains.

Published

2019

17. Southwest Indian Ridge Lower Crust and Moho. Proceedings of the International Ocean Discovery Program, 360

Author

Macleod, C. J., Dick, H. J. B., Blum, P., Abe, N., Blackman, D. K., Bowles, J. A., Cheadle, M. J., Cho, K., Ciążela, J., Deans, J. R., Edgcomb, V. P., Ferrando, C., France, L., Ghosh, B., Ildefonse, B. M., Kendrick, M. A., Koepke, J. H., Leong, J. A. M., Liu, C., Ma, Q., Morishita, T., Morris, A., Natland, J. H., Nozaka, T., Pluemper, O., Sanfilippo, A., Sylvan, J. B., Tivey, M. A., Tribuzio, R., and Viegas, L. G. F.

Published

2017

18. Insights into the metabolic functioning of a multipartner ciliate symbiosis from oxygen‐depleted sediments

Author

Beinart, R. A., primary, Beaudoin, D. J., additional, Bernhard, J. M., additional, and Edgcomb, V. P., additional

Published

2018

19. IODP Expedition 360: First stage of drilling into Earth's Mantle

Author

Ciazela, J., Dick, H. J. B., Macleod, C. J., Blum, P., Abe, N., Blackman, D. K., Bowles, J. A., Cheadle, M. J., Cho, K., Deans, J. R., Edgcomb, V. P., Ferrando, C., France, L., Ghosh, B., Ildefonse, B. M., Mark, M., Kendrick, A., Koepke, J., Leong, J. A. M., Liu, C., Ma, Q., Morishita, T., Morris, A., Natland, J. H., Nozaka, T., Pluemper, O., Sanfilippo, A., Sylvan, J. B., Tivey, M. A., Tribuzio, R., and Viegas, L. G. F.

Subjects

Expedition 360, Moho, Atlantis bank, Mantle, Lower crust, IODP

Published

2016

20. International Ocean Discovery Program Expedition 360 Preliminary Report: Southwest Indian Ridge Lower Crust and Moho the nature of the lower crust and Moho at slower spreading ridges (SloMo Leg 1)

Author

Dick, H. J. B., Macleod, C. J., Blum, P., Abe, N., Blackman, D. K., Bowles, J. A., Cheadle, M. J., Cho, K., Ciazela, J., Deans, J. R., Edgcomb, V. P., Ferrando, C., France, L., Ghosh, B., Ildefonse, B. M., Kendrick, M. A., Koepke, J. H., Leong, J. A. M., Liu, C., Ma, Q., Morishita, T., Morris, A., Natland, J. H., Nozaka, T., Pluemper, O., Sanfilippo, A., Sylvan, J. B., Tivey, M. A., Tribuzio, R., Viegas, L. G. F., Kavanagh, L., Burgio, M., Martinez, A., Zhang, J., Skinner, T., and Mclelland, J. S.

Published

2016

21. UniEuk : Time to Speak a Common Language in Protistology!

Author

Berney, C, Ciuprina, A, Bender, S, Brodie, J, Edgcomb, V, Kim, E, Rajan, J, Parfrey, LW, Adl, S, Audic, S, Bass, D, Caron, DA, Cochrane, G, Czech, L, Dunthorn, M, Geisen, S, Glöckner, FO, Mahé, F, Quast, C, Kaye, JZ, Simpson, AGB, Stamatakis, A, del Campo, J, Yilmaz, P, de Vargas, C, Berney, C, Ciuprina, A, Bender, S, Brodie, J, Edgcomb, V, Kim, E, Rajan, J, Parfrey, LW, Adl, S, Audic, S, Bass, D, Caron, DA, Cochrane, G, Czech, L, Dunthorn, M, Geisen, S, Glöckner, FO, Mahé, F, Quast, C, Kaye, JZ, Simpson, AGB, Stamatakis, A, del Campo, J, Yilmaz, P, and de Vargas, C

Abstract

Universal taxonomic frameworks have been critical tools to structure the fields of botany, zoology, mycology, and bacteriology as well as their large research communities. Animals, plants, and fungi have relatively solid, stable morpho‐taxonomies built over the last three centuries, while bacteria have been classified for the last three decades under a coherent molecular taxonomic framework. By contrast, no such common language exists for microbial eukaryotes, even though environmental ‘‐omics’ surveys suggest that protists make up most of the organismal and genetic complexity of our planet's ecosystems! With the current deluge of eukaryotic meta‐omics data, we urgently need to build up a universal eukaryotic taxonomy bridging the protist ‐omics age to the fragile, centuries‐old body of classical knowledge that has effectively linked protist taxa to morphological, physiological, and ecological information. UniEuk is an open, inclusive, community‐based and expert‐driven international initiative to build a flexible, adaptive universal taxonomic framework for eukaryotes. It unites three complementary modules, EukRef, EukBank, and EukMap, which use phylogenetic markers, environmental metabarcoding surveys, and expert knowledge to inform the taxonomic framework. The UniEuk taxonomy is directly implemented in the European Nucleotide Archive at EMBL‐EBI, ensuring its broad use and long‐term preservation as a reference taxonomy for eukaryotes.

Published

2017

22. The genome of an endosymbiotic methanogen is very similar to those of its free‐living relatives.

Author

Beinart, R. A., Rotterová, J., Čepička, I., Gast, R. J., and Edgcomb, V. P.

Subjects

ENDOSYMBIOSIS, METHANOGENS, METHANOBACTERIUM, REPRODUCTIVE isolation, LINEAGE

Abstract

Summary: The methanogenic endosymbionts of anaerobic protists represent the only known intracellular archaea, yet, almost nothing is known about genome structure and content in these lineages. Here, an almost complete genome of an intracellular Methanobacterium species was assembled from a metagenome derived from its host ciliate, a Heterometopus species. Phylogenomic analysis showed that the endosymbiont was closely related to free‐living Methanobacterium isolates, and when compared with the genomes of free‐living Methanobacterium, the endosymbiont did not show significant reduction in genome size or GC content. Additionally, the Methanobacterium endosymbiont genome shared the majority of its genes with its closest relative, though it did also contain unique genes possibly involved in interactions with the host via membrane‐associated proteins, the removal of toxic by‐products from host metabolism and the production of small signalling molecules. Though anaerobic ciliates have been shown to transmit their endosymbionts to daughter cells during division, the results presented here could suggest that the endosymbiotic Methanobacterium did not experience significant genetic isolation or drift and/or that this lineage was only recently acquired. Altogether, comparative genomic analysis identified genes potentially involved in the establishment and maintenance of the symbiosis, as well provided insight into the genomic consequences for an intracellular archaeum. [ABSTRACT FROM AUTHOR]

Published

2018

23. Protistan community patterns within the brine and halocline of deep hypersaline anoxic basins in the eastern Mediterranean Sea

Author

Edgcomb V, Orsi W, Leslin C, Epstein SS, Bunge J, Jeon S, Yakimov MM, Behnke A, and Stoeck T.

Published

2009

24. Effects of Dissolved Sulfide, pH, and Temperature on Growth and Survival of Marine Hyperthermophilic Archaea

Author

Molyneaux, S. J., Lloyd, K. G., Teske, A., Atkins, M. S., Edgcomb, V. P., Wirsen, C. O., and Boer, S.

Abstract

The ability of metabolically diverse hyperthermophilic archaea to withstand high temperatures, low pHs, high sulfide concentrations, and the absence of carbon and energy sources was investigated. Close relatives of our study organisms, Methanocaldococcus jannaschii, Archaeoglobus profundus, Thermococcus fumicolans, and Pyrococcus sp. strain GB-D, are commonly found in hydrothermal vent chimney walls and hot sediments and possibly deeper in the subsurface, where highly dynamic hydrothermal flow patterns and steep chemical and temperature gradients provide an ever-changing mosaic of microhabitats. These organisms (with the possible exception of Pyrococcus strain GB-D) tolerated greater extremes of low pH, high sulfide concentration, and high temperature when actively growing and metabolizing than when starved of carbon sources and electron donors/acceptors. Therefore these organisms must be actively metabolizing in the hydrothermal vent chimneys, sediments, and subsurface in order to withstand at least 24 h of exposure to extremes of pH, sulfide, and temperature that occur in these environments.

Published

2005

25. Molecular analysis of deep subsurface microbial communities in Nankai Trough sediments (ODP Leg 190, Site 1176)

Author

Kormas, K.Ar. Smith, D.C. Edgcomb, V. Teske, A.

Abstract

The prokaryotic community inhabiting the deep subsurface sediments in the Forearc Basin of the Nankai Trough southeast of Japan (ODP Site 1176) was analyzed by 16S rDNA sequencing. Sediment samples from 1.15, 51.05, 98.50 and 193.96 m below sea floor (mbsf) harbored highly diverse bacterial communities. The most frequently retrieved clones included members of the Green non-sulfur bacteria whose closest relatives come from deep subsurface environments, a new epsilon-proteobacterial phylotype, and representatives of a cluster of closely related bacterial sequences from hydrocarbon- and methane-rich sediments around the world. Archaeal clones were limited to members of the genus Thermococcus, and were only obtained from the two deepest samples. © 2003 Federation of European Microbiological Societies. Published by Elsevier Science B.V. All rights reserved.

Published

2003

26. Microbial diversity of hydrothermal sediments in the Guaymas Basin: Evidence for anaerobic methanotrophic communities

Author

Edgcomb, V., Sylva, S.P., Kysela, D., De Vera Gomez, A., Jannasch, H.W., Sogin, M.L., Teske, A., and Hinrichs, K.-U.

Abstract

Microbial communities in hydrothermally active sediments of the Guaymas Basin (Gulf of California, Mexico) were studied by using 16S rRNA sequencing and carbon isotopic analysis of archaeal and bacterial lipids. The Guaymas sediments harbored uncultured euryarchaeota of two distinct phylogenetic lineages within the anaerobic methane oxidation 1 (ANME-1) group, ANME-1a and ANME-1b, and of the ANME-2c lineage within the Methanosarcinales, both previously assigned to the methanotrophic archaea. The archaeal lipids in the Guaymas Basin sediments included archaeol, diagnostic for nonthermophilic euryarchaeota, and sn-2-hydroxyarchaeol, with the latter compound being particularly abundant in cultured members of the Methanosarcinales. The concentrations of these compounds were among the highest observed so far in studies of methane seep environments. The δ-13C values of these lipids (δ-13C = -89 to -58%) indicate an origin from anaerobic methanotrophic archaea. This molecular-isotopic signature was found not only in samples that yielded predominantly ANME-2 clones but also in samples that yielded exclusively ANME-1 clones. ANME-1 archaea therefore remain strong candidates for mediation of the anaerobic oxidation of methane. Based on 16S rRNA data, the Guaymas sediments harbor phylogenetically diverse bacterial populations, which show considerable overlap with bacterial populations of geothermal habitats and natural or anthropogenic hydrocarbon-rich sites. Consistent with earlier observations, our combined evidence from bacterial phylogeny and molecular-isotopic data indicates an important role of some novel deeply branching bacteria in anaerobic methanotrophy. Anaerobic methane oxidation likely represents a significant and widely occurring process in the trophic ecology of methane-rich hydrothermal vents, This study stresses a high diversity among communities capable of anaerobic oxidation of methane.

Published

2002

27. Molecular indicators of microbial diversity in oolitic sands of Highborne Cay, Bahamas

Author

Edgcomb, V. P., primary, Bernhard, J. M., additional, Beaudoin, D., additional, Pruss, S., additional, Welander, P. V., additional, Schubotz, F., additional, Mehay, S., additional, Gillespie, A. L., additional, and Summons, R. E., additional

Published

2013

28. Accessing marine protists from the anoxic Cariaco Basin

Author

Edgcomb, V, primary, Orsi, W, additional, Taylor, G T, additional, Vdacny, P, additional, Taylor, C, additional, Suarez, P, additional, and Epstein, S, additional

Published

2011

29. Identity of epibiotic bacteria on symbiontid euglenozoans in O2-depleted marine sediments: evidence for symbiont and host co-evolution

Author

Edgcomb, V P, primary, Breglia, S A, additional, Yubuki, N, additional, Beaudoin, D, additional, Patterson, D J, additional, Leander, B S, additional, and Bernhard, J M, additional

Published

2010

30. Phylogenetic position of the trichomonad parasite of turkeys, Histomonas meleagridis (Smith) Tyzzer, inferred from small subunit rRNA sequence

Author

Gerbod, Delphine, Edgcomb, V P, Noel, Claire, Zenner, L, Wintjens, René, Delgado-Viscogliosi, P, Holder, M E, Sogin, M L, Viscogliosi, Eric, Gerbod, Delphine, Edgcomb, V P, Noel, Claire, Zenner, L, Wintjens, René, Delgado-Viscogliosi, P, Holder, M E, Sogin, M L, and Viscogliosi, Eric

Abstract

The phylogenetic position of the trichomonad, Histomonas meleagridis was determined by analysis of small subunit rRNAs. Molecular trees including all identified parabasalid sequences available in data bases were inferred by distance, parsimony, and likelihood methods. All reveal a close relationship between H. meleagridis, and Dientamoeba fragilis. Moreover, small subunit rRNAs of both amoeboid species have a reduced G + C content and increased chain length relative to other parabasalids. Finally, the rRNA genes from H. meleagridis and D. fragilis share a recent common ancestor with Tritrichomonasfoetus, which exhibits a more developed cytoskeleton. This indicates that Histomonas and Dientamoeba secondarily lost most of the typical trichomonad cytoskeletal structures and hence, do not represent primitive morphologies. A global phylogeny of parabasalids revealed significant discrepancies with morphology-based classifications, such as the polyphyly of most of the parabasalid families and classes included in our study., Journal Article, Research Support, Non-U.S. Gov't, Research Support, U.S. Gov't, Non-P.H.S., FLWIN, info:eu-repo/semantics/published

Published

2001

31. Phylogenetic relationships of class II fumarase genes from trichomonad species.

Author

Gerbod, Delphine, Edgcomb, V P, Noel, Claire, Vanácová, S, Wintjens, René, Tachezy, J, Sogin, M L, Viscogliosi, Eric, Gerbod, Delphine, Edgcomb, V P, Noel, Claire, Vanácová, S, Wintjens, René, Tachezy, J, Sogin, M L, and Viscogliosi, Eric

Abstract

Class II fumarase sequences were obtained by polymerase chain reaction from five trichomonad species. All residues known to be highly conserved in this enzyme were present. Nuclear run-on assays showed that one of the two genes identified in Tritrichomonas foetus was expressed, whereas no fumarase transcripts were detected in the related species Trichomonas vaginalis. These findings corroborate previous biochemical data. Fumarase genes were also expressed in Monocercomonas sp. and Tetratrichomonas gallinarum but not in Pentatrichomonas hominis, Trichomonas gallinae, Trichomonas tenax, and Trichomitus batrachorum under the culture conditions used. Molecular trees inferred by likelihood methods reveal that trichomonad sequences have no affinity to described class II fumarase genes from other eukaryotes. The absence of functional mitochondria in protists such as trichomonads suggests that they diverged from other eukaryotes prior to the alpha-proteobacterial symbiosis that led to mitochondria. Furthermore, they are basal to other eukaryotes in rRNA analyses. However, support for the early-branching status of trichomonads and other amitochondriate protists based on phylogenetic analyses of multiple data sets has been equivocal. Although the presence of hydrogenosomes suggests that trichomonads once had mitochondria, their class II iron-independent fumarase sequences differ markedly from those of other mitochondriate eukaryotes. All of the class II fumarase genes described from other eukaryotes are of apparent alpha-proteobacterial origin and hence a marker of mitochondrial evolution. In contrast, the class II fumarase from trichomonads emerges among other eubacterial homologs. This is intriguing evidence for an independent acquisition of these genes in trichomonads apart from the mitochondrial endosymbiosis event that gave rise to the form present in other eukaryotes. The ancestral trichomonad class II fumarase may represent a prokaryotic form that was replaced in other, Journal Article, Research Support, Non-U.S. Gov't, Research Support, U.S. Gov't, Non-P.H.S., info:eu-repo/semantics/published

Published

2001

32. Identity of epibiotic bacteria on symbiontid euglenozoans in O2-depleted marine sediments: evidence for symbiont and host co-evolution.

Author

Edgcomb, V P, Breglia, S A, Yubuki, N, Beaudoin, D, Patterson, D J, Leander, B S, and Bernhard, J M

Subjects

*BACTERIAL typing, *MARINE sediments, *ZOOFLAGELLATES, *COEVOLUTION, *MOLECULAR phylogeny, *NUCLEOTIDE sequence, *HOST-parasite relationships

Abstract

A distinct subgroup of euglenozoans, referred to as the 'Symbiontida,' has been described from oxygen-depleted and sulfidic marine environments. By definition, all members of this group carry epibionts that are intimately associated with underlying mitochondrion-derived organelles beneath the surface of the hosts. We have used molecular phylogenetic and ultrastructural evidence to identify the rod-shaped epibionts of the two members of this group, Calkinsia aureus and B.bacati, hand-picked from the sediments of two separate oxygen-depleted, sulfidic environments. We identify their epibionts as closely related sulfur or sulfide-oxidizing members of the epsilon proteobacteria. The epsilon proteobacteria generally have a significant role in deep-sea habitats as primary colonizers, primary producers and/or in symbiotic associations. The epibionts likely fulfill a role in detoxifying the immediate surrounding environment for these two different hosts. The nearly identical rod-shaped epibionts on these two symbiontid hosts provides evidence for a co-evolutionary history between these two sets of partners. This hypothesis is supported by congruent tree topologies inferred from 18S and 16S rDNA from the hosts and bacterial epibionts, respectively. The eukaryotic hosts likely serve as a motile substrate that delivers the epibionts to the ideal locations with respect to the oxic/anoxic interface, whereby their growth rates can be maximized, perhaps also allowing the host to cultivate a food source. Because symbiontid isolates and additional small subunit rDNA gene sequences from this clade have now been recovered from many locations worldwide, the Symbiontida are likely more widespread and diverse than presently known. [ABSTRACT FROM AUTHOR]

Published

2011

33. IODP Expedition 360: First stage of drilling into Earth's Mantle,Ekspedycja IODP 360: Pierwszy etap odwiertu do plaszcza Ziemi

Author

Ciązela, J., Dick, H. J. B., Macleod, C. J., Blum, P., Abe, N., Blackman, D. K., Bowles, J. A., Cheadle, M. J., Cho, K., Deans, J. R., Edgcomb, V. P., Ferrando, C., France, L., Ghosh, B., Ildefonse, B. M., Mark, M., Kendrick, A., Koepke, J., Leong, J. A. M., Liu, C., Ma, Q., Morishita, T., Morris, A., Natland, J. H., Nozaka, T., Pluemper, O., Sanfilippo, A., Sylvan, J. B., Tivey, M. A., Tribuzio, R., and Gustavo Viegas

34. IODP Expedition 360: First stage of drilling into Earth's Mantle | Ekspedycja IODP 360: Pierwszy etap odwiertu do plaszcza Ziemi

Author

Ciązela, J., Dick, H. J. B., Macleod, C. J., Blum, P., Abe, N., Blackman, D. K., Bowles, J. A., Cheadle, M. J., Cho, K., Deans, J. R., Edgcomb, V. P., Ferrando, C., Lyderic France, Ghosh, B., Ildefonse, B. M., Mark, M., Kendrick, A., Koepke, J., Leong, J. A. M., Liu, C., Ma, Q., Morishita, T., Morris, A., Natland, J. H., Nozaka, T., Pluemper, O., Sanfilippo, A., Sylvan, J. B., Tivey, M. A., Tribuzio, R., and Viegas, L. G. F.

35. Pelobionts are degenerate protists: Insights from molecules and morphology [5]

Author

Edgcomb, V. P., Simpson, A. G. B., Zettler, L. A., Nerad, T. A., David J. Patterson, Holder, M. E., and Sogin, M. L.

36. Multicellular magnetotactic bacteria are genetically heterogeneous consortia with metabolically differentiated cells.

Author

Schaible GA, Jay ZJ, Cliff J, Schulz F, Gauvin C, Goudeau D, Malmstrom RR, Ruff SE, Edgcomb V, and Hatzenpichler R

Subjects

Metagenome, Microbial Consortia genetics, Genome, Bacterial, Bacteria genetics, Bacteria metabolism, Genetic Variation, Phylogeny, In Situ Hybridization, Fluorescence

Abstract

Consortia of multicellular magnetotactic bacteria (MMB) are currently the only known example of bacteria without a unicellular stage in their life cycle. Because of their recalcitrance to cultivation, most previous studies of MMB have been limited to microscopic observations. To study the biology of these unique organisms in more detail, we use multiple culture-independent approaches to analyze the genomics and physiology of MMB consortia at single-cell resolution. We separately sequenced the metagenomes of 22 individual MMB consortia, representing 8 new species, and quantified the genetic diversity within each MMB consortium. This revealed that, counter to conventional views, cells within MMB consortia are not clonal. Single consortia metagenomes were then used to reconstruct the species-specific metabolic potential and infer the physiological capabilities of MMB. To validate genomic predictions, we performed stable isotope probing (SIP) experiments and interrogated MMB consortia using fluorescence in situ hybridization (FISH) combined with nanoscale secondary ion mass spectrometry (NanoSIMS). By coupling FISH with bioorthogonal noncanonical amino acid tagging (BONCAT), we explored their in situ activity as well as variation of protein synthesis within cells. We demonstrate that MMB consortia are mixotrophic sulfate reducers and that they exhibit metabolic differentiation between individual cells, suggesting that MMB consortia are more complex than previously thought. These findings expand our understanding of MMB diversity, ecology, genomics, and physiology, as well as offer insights into the mechanisms underpinning the multicellular nature of their unique lifestyle., Competing Interests: The authors have declared that no competing interests exist., (Copyright: This is an open access article, free of all copyright, and may be freely reproduced, distributed, transmitted, modified, built upon, or otherwise used by anyone for any lawful purpose. The work is made available under the Creative Commons CC0 public domain dedication.)

Published

2024

37. Gazing into the abyss: A glimpse into the diversity, distribution, and behaviour of heterotrophic protists from the deep-sea floor.

Author

Cadena LR, Edgcomb V, and Lukeš J

Subjects

Animals, Biomass, Earth, Planet, Ecosystem, Predatory Behavior, Biodiversity

Abstract

The benthic biome of the deep-sea floor, one of the largest biomes on Earth, is dominated by diverse and highly productive heterotrophic protists, second only to prokaryotes in terms of biomass. Recent evidence suggests that these protists play a significant role in ocean biogeochemistry, representing an untapped source of knowledge. DNA metabarcoding and environmental sample sequencing have revealed that deep-sea abyssal protists exhibit high levels of specificity and diversity across local regions. This review aims to provide a comprehensive summary of the known heterotrophic protists from the deep-sea floor, their geographic distribution, and their interactions in terms of parasitism and predation. We offer an overview of the most abundant groups and discuss their potential ecological roles. We argue that the exploration of the biodiversity and species-specific features of these protists should be integrated into broader deep-sea research and assessments of how benthic biomes may respond to future environmental changes., (© 2024 The Authors. Environmental Microbiology published by Applied Microbiology International and John Wiley & Sons Ltd.)

Published

2024

38. Metagenomic profiles of archaea and bacteria within thermal and geochemical gradients of the Guaymas Basin deep subsurface.

Author

Mara P, Geller-McGrath D, Edgcomb V, Beaudoin D, Morono Y, and Teske A

Subjects

Metagenome genetics, Geologic Sediments chemistry, Phylogeny, Bacteria genetics, RNA, Ribosomal, 16S, Archaea genetics, Crenarchaeota

Abstract

Previous studies of microbial communities in subseafloor sediments reported that microbial abundance and diversity decrease with sediment depth and age, and microbes dominating at depth tend to be a subset of the local seafloor community. However, the existence of geographically widespread, subsurface-adapted specialists is also possible. Here, we use metagenomic and metatranscriptomic analyses of the hydrothermally heated, sediment layers of Guaymas Basin (Gulf of California, Mexico) to examine the distribution and activity patterns of bacteria and archaea along thermal, geochemical and cell count gradients. We find that the composition and distribution of metagenome-assembled genomes (MAGs), dominated by numerous lineages of Chloroflexota and Thermoproteota, correlate with biogeochemical parameters as long as temperatures remain moderate, but downcore increasing temperatures beyond ca. 45 ºC override other factors. Consistently, MAG size and diversity decrease with increasing temperature, indicating a downcore winnowing of the subsurface biosphere. By contrast, specific archaeal MAGs within the Thermoproteota and Hadarchaeota increase in relative abundance and in recruitment of transcriptome reads towards deeper, hotter sediments, marking the transition towards a specialized deep, hot biosphere., (© 2023. The Author(s).)

Published

2023

39. Multicellular magnetotactic bacterial consortia are metabolically differentiated and not clonal.

Author

Schaible GA, Jay ZJ, Cliff J, Schulz F, Gauvin C, Goudeau D, Malmstrom RR, Emil Ruff S, Edgcomb V, and Hatzenpichler R

Abstract

Consortia of multicellular magnetotactic bacteria (MMB) are currently the only known example of bacteria without a unicellular stage in their life cycle. Because of their recalcitrance to cultivation, most previous studies of MMB have been limited to microscopic observations. To study the biology of these unique organisms in more detail, we use multiple culture-independent approaches to analyze the genomics and physiology of MMB consortia at single cell resolution. We separately sequenced the metagenomes of 22 individual MMB consortia, representing eight new species, and quantified the genetic diversity within each MMB consortium. This revealed that, counter to conventional views, cells within MMB consortia are not clonal. Single consortia metagenomes were then used to reconstruct the species-specific metabolic potential and infer the physiological capabilities of MMB. To validate genomic predictions, we performed stable isotope probing (SIP) experiments and interrogated MMB consortia using fluorescence in situ hybridization (FISH) combined with nano-scale secondary ion mass spectrometry (NanoSIMS). By coupling FISH with bioorthogonal non-canonical amino acid tagging (BONCAT) we explored their in situ activity as well as variation of protein synthesis within cells. We demonstrate that MMB consortia are mixotrophic sulfate reducers and that they exhibit metabolic differentiation between individual cells, suggesting that MMB consortia are more complex than previously thought. These findings expand our understanding of MMB diversity, ecology, genomics, and physiology, as well as offer insights into the mechanisms underpinning the multicellular nature of their unique lifestyle., Competing Interests: Competing interest statement: none declared

Published

2023

40. Microbial gene expression in Guaymas Basin subsurface sediments responds to hydrothermal stress and energy limitation.

Author

Mara P, Zhou YL, Teske A, Morono Y, Beaudoin D, and Edgcomb V

Subjects

Phylogeny, Bacteria, Gene Expression, RNA, Ribosomal, 16S genetics, RNA, Ribosomal, 16S metabolism, Geologic Sediments microbiology, Archaea

Abstract

Analyses of gene expression of subsurface bacteria and archaea provide insights into their physiological adaptations to in situ subsurface conditions. We examined patterns of expressed genes in hydrothermally heated subseafloor sediments with distinct geochemical and thermal regimes in Guaymas Basin, Gulf of California, Mexico. RNA recovery and cell counts declined with sediment depth, however, we obtained metatranscriptomes from eight sites at depths spanning between 0.8 and 101.9 m below seafloor. We describe the metabolic potential of sediment microorganisms, and discuss expressed genes involved in tRNA, mRNA, and rRNA modifications that enable physiological flexibility of bacteria and archaea in the hydrothermal subsurface. Microbial taxa in hydrothermally influenced settings like Guaymas Basin may particularly depend on these catalytic RNA functions since they modulate the activity of cells under elevated temperatures and steep geochemical gradients. Expressed genes for DNA repair, protein maintenance and circadian rhythm were also identified. The concerted interaction of many of these genes may be crucial for microorganisms to survive and to thrive in the Guaymas Basin subsurface biosphere., (© 2023. The Author(s), under exclusive licence to International Society for Microbial Ecology.)

Published

2023

41. Metatranscriptomics and metabarcoding reveal spatiotemporal shifts in fungal communities and their activities in Chinese coastal waters.

Author

Wang M, Mara P, Burgaud G, Edgcomb V, Long X, Yang H, Cai L, and Li W

Subjects

Fungi genetics, China, Water Microbiology, Seawater microbiology, Ecosystem, Mycobiome genetics

Abstract

Fungal communities are diverse and abundant in coastal waters, yet, their ecological roles and adaptations remain largely unknown. To address these gaps, ITS2 metabarcoding and metatranscriptomic analyses were used to capture the whole suite of fungal diversity and their metabolic potential in water column and sediments in the Yellow Sea during August and October 2019. ITS2 metabarcoding described successfully the abundance of Dikarya during August and October at the different examined habitats, but strongly underrepresented or failed to identify other fungal taxa, including zoosporic and early-diverging lineages, that were abundant in the mycobiome as uncovered by metatranscriptomes. Metatranscriptomics also revealed enriched expression of genes annotated to zoosporic fungi (e.g., chytrids) mainly in the surface water column in October. This enriched expression was correlated with the two-fold increase in chlorophyll-a intensity attributed to phytoplanktonic species which are known to be parasitized by chytrids. The concurrent high expression of genes related to calcium signalling and GTPase activity suggested that these metabolic traits facilitate the parasitic lifestyle of chytrids. Similarly, elevated expression of phagosome genes annotated to Rozellomycota, an early-diverging fungal phylum not fully detected with ITS2 metabarcoding, suggested that this taxon utilizes a suite of feeding modes, including phagotrophy in this coastal setting. Our data highlight the necessity of using combined approaches to accurately describe the community structure of coastal mycobiome. We also provide in-depth insights into the fungal ecological roles in coastal waters, and report potential metabolic mechanisms utilized by fungi to cope with environmental stresses that occur during distinct seasonal months in coastal ecosystems., (© 2023 John Wiley & Sons Ltd.)

Published

2023

42. Diverse secondary metabolites are expressed in particle-associated and free-living microorganisms of the permanently anoxic Cariaco Basin.

Author

Geller-McGrath D, Mara P, Taylor GT, Suter E, Edgcomb V, and Pachiadaki M

Subjects

Bacteria metabolism, Metagenome, Water metabolism, Seawater microbiology, Microbiota genetics

Abstract

Secondary metabolites play essential roles in ecological interactions and nutrient acquisition, and are of interest for their potential uses in medicine and biotechnology. Genome mining for biosynthetic gene clusters (BGCs) can be used for the discovery of new compounds. Here, we use metagenomics and metatranscriptomics to analyze BGCs in free-living and particle-associated microbial communities through the stratified water column of the Cariaco Basin, Venezuela. We recovered 565 bacterial and archaeal metagenome-assembled genomes (MAGs) and identified 1154 diverse BGCs. We show that differences in water redox potential and microbial lifestyle (particle-associated vs. free-living) are associated with variations in the predicted composition and production of secondary metabolites. Our results indicate that microbes, including understudied clades such as Planctomycetota, potentially produce a wide range of secondary metabolites in these anoxic/euxinic waters., (© 2023. The Author(s).)

Published

2023

43. Deep-sea hydrothermal vent sediments reveal diverse fungi with antibacterial activities.

Author

Keeler E, Burgaud G, Teske A, Beaudoin D, Mehiri M, Dayras M, Cassand J, and Edgcomb V

Subjects

Anti-Bacterial Agents pharmacology, Biodiversity, Fungi genetics, Geologic Sediments, Humans, Mexico, Phylogeny, RNA, Ribosomal, 18S, Seawater, Ascomycota genetics, Hydrothermal Vents

Abstract

Relatively little is known about the diversity of fungi in deep-sea, hydrothermal sediments. Less thoroughly explored environments are likely untapped reservoirs of unique biodiversity with the potential to augment our current arsenal of microbial compounds with biomedical and/or industrial applications. In this study, we applied traditional culture-based methods to examine a subset of the morphological and phylogenetic diversity of filamentous fungi and yeasts present in 11 hydrothermally influenced sediment samples collected from eight sites on the seafloor of Guaymas Basin, Mexico. A total of 12 unique isolates affiliating with Ascomycota and Basidiomycota were obtained and taxonomically identified on the basis of morphological features and analyses of marker genes including actin, β-tubulin, small subunit ribosomal DNA (18S rRNA), internal transcribed spacer (ITS) and large subunit ribosomal DNA (26S rRNA) D1/D2 domain sequences (depending on taxon). A total of 11 isolates possess congeners previously detected in, or recovered from, deep-sea environments. A total of seven isolates exhibited antibacterial activity against human bacterial pathogens Staphylococcus aureus ATCC-35556 and/or Escherichia coli ATCC-25922. This first investigation suggests that hydrothermal environments may serve as promising reservoirs of much greater fungal diversity, some of which may produce biomedically useful metabolites., (© The Author(s) 2021. Published by Oxford University Press on behalf of FEMS. All rights reserved. For permissions, please e-mail: journals.permissions@oup.com.)

Published

2021

44. Highlighting the Biotechnological Potential of Deep Oceanic Crust Fungi through the Prism of Their Antimicrobial Activity.

Author

Quemener M, Dayras M, Frotté N, Debaets S, Le Meur C, Barbier G, Edgcomb V, Mehiri M, and Burgaud G

Subjects

Animals, Drug Resistance, Microbial, Microbial Sensitivity Tests, Pseudomonas aeruginosa drug effects, Staphylococcus aureus drug effects, Anti-Bacterial Agents pharmacology, Aquatic Organisms chemistry, Fungi metabolism

Abstract

Among the different tools to address the antibiotic resistance crisis, bioprospecting in complex uncharted habitats to detect novel microorganisms putatively producing original antimicrobial compounds can definitely increase the current therapeutic arsenal of antibiotics. Fungi from numerous habitats have been widely screened for their ability to express specific biosynthetic gene clusters (BGCs) involved in the synthesis of antimicrobial compounds. Here, a collection of unique 75 deep oceanic crust fungi was screened to evaluate their biotechnological potential through the prism of their antimicrobial activity using a polyphasic approach. After a first genetic screening to detect specific BGCs, a second step consisted of an antimicrobial screening that tested the most promising isolates against 11 microbial targets. Here, 12 fungal isolates showed at least one antibacterial and/or antifungal activity (static or lytic) against human pathogens. This analysis also revealed that Staphylococcus   aureus ATCC 25923 and Enterococcus   faecalis CIP A 186 were the most impacted, followed by Pseudomonas   aeruginosa ATCC 27853. A specific focus on three fungal isolates allowed us to detect interesting activity of crude extracts against multidrug-resistant Staphylococcus aureus . Finally, complementary mass spectrometry (MS)-based molecular networking analyses were performed to putatively assign the fungal metabolites and raise hypotheses to link them to the observed antimicrobial activities.

Published

2021

45. Meta-omics highlights the diversity, activity and adaptations of fungi in deep oceanic crust.

Author

Quemener M, Mara P, Schubotz F, Beaudoin D, Li W, Pachiadaki M, Sehein TR, Sylvan JB, Li J, Barbier G, Edgcomb V, and Burgaud G

Subjects

Biodiversity, Carbon Cycle, Fungi classification, Fungi genetics, Fungi metabolism, Geologic Sediments chemistry, Indian Ocean, Seawater chemistry, Adaptation, Physiological, Fungi physiology, Geologic Sediments microbiology, Mycobiome genetics, Seawater microbiology

Abstract

The lithified oceanic crust, lower crust gabbros in particular, has remained largely unexplored by microbiologists. Recently, evidence for heterogeneously distributed viable and transcriptionally active autotrophic and heterotrophic microbial populations within low-biomass communities was found down to 750 m below the seafloor at the Atlantis Bank Gabbro Massif, Indian Ocean. Here, we report on the diversity, activity and adaptations of fungal communities in the deep oceanic crust from ~10 to 780 mbsf by combining metabarcoding analyses with mid/high-throughput culturing approaches. Metabarcoding along with culturing indicate a low diversity of viable fungi, mostly affiliated to ubiquitous (terrestrial and aquatic environments) taxa. Ecophysiological analyses coupled with metatranscriptomics point to viable and transcriptionally active fungal populations engaged in cell division, translation, protein modifications and other vital cellular processes. Transcript data suggest possible adaptations for surviving in the nutrient-poor, lithified deep biosphere that include the recycling of organic matter. These active communities appear strongly influenced by the presence of cracks and veins in the rocks where fluids and resulting rock alteration create micro-niches., (© 2020 Society for Applied Microbiology and John Wiley & Sons Ltd.)

Published

2020

46. Genetic tool development in marine protists: emerging model organisms for experimental cell biology.

Author

Faktorová D, Nisbet RER, Fernández Robledo JA, Casacuberta E, Sudek L, Allen AE, Ares M Jr, Aresté C, Balestreri C, Barbrook AC, Beardslee P, Bender S, Booth DS, Bouget FY, Bowler C, Breglia SA, Brownlee C, Burger G, Cerutti H, Cesaroni R, Chiurillo MA, Clemente T, Coles DB, Collier JL, Cooney EC, Coyne K, Docampo R, Dupont CL, Edgcomb V, Einarsson E, Elustondo PA, Federici F, Freire-Beneitez V, Freyria NJ, Fukuda K, García PA, Girguis PR, Gomaa F, Gornik SG, Guo J, Hampl V, Hanawa Y, Haro-Contreras ER, Hehenberger E, Highfield A, Hirakawa Y, Hopes A, Howe CJ, Hu I, Ibañez J, Irwin NAT, Ishii Y, Janowicz NE, Jones AC, Kachale A, Fujimura-Kamada K, Kaur B, Kaye JZ, Kazana E, Keeling PJ, King N, Klobutcher LA, Lander N, Lassadi I, Li Z, Lin S, Lozano JC, Luan F, Maruyama S, Matute T, Miceli C, Minagawa J, Moosburner M, Najle SR, Nanjappa D, Nimmo IC, Noble L, Novák Vanclová AMG, Nowacki M, Nuñez I, Pain A, Piersanti A, Pucciarelli S, Pyrih J, Rest JS, Rius M, Robertson D, Ruaud A, Ruiz-Trillo I, Sigg MA, Silver PA, Slamovits CH, Jason Smith G, Sprecher BN, Stern R, Swart EC, Tsaousis AD, Tsypin L, Turkewitz A, Turnšek J, Valach M, Vergé V, von Dassow P, von der Haar T, Waller RF, Wang L, Wen X, Wheeler G, Woods A, Zhang H, Mock T, Worden AZ, and Lukeš J

Subjects

Biodiversity, Ecosystem, Environment, Eukaryota classification, Species Specificity, DNA administration & dosage, Eukaryota physiology, Green Fluorescent Proteins metabolism, Marine Biology, Models, Biological, Transformation, Genetic

Abstract

Diverse microbial ecosystems underpin life in the sea. Among these microbes are many unicellular eukaryotes that span the diversity of the eukaryotic tree of life. However, genetic tractability has been limited to a few species, which do not represent eukaryotic diversity or environmentally relevant taxa. Here, we report on the development of genetic tools in a range of protists primarily from marine environments. We present evidence for foreign DNA delivery and expression in 13 species never before transformed and for advancement of tools for eight other species, as well as potential reasons for why transformation of yet another 17 species tested was not achieved. Our resource in genetic manipulation will provide insights into the ancestral eukaryotic lifeforms, general eukaryote cell biology, protein diversification and the evolution of cellular pathways.

Published

2020

47. Publisher Correction: Genetic tool development in marine protists: emerging model organisms for experimental cell biology.

Author

Faktorová D, Nisbet RER, Fernández Robledo JA, Casacuberta E, Sudek L, Allen AE, Ares M Jr, Aresté C, Balestreri C, Barbrook AC, Beardslee P, Bender S, Booth DS, Bouget FY, Bowler C, Breglia SA, Brownlee C, Burger G, Cerutti H, Cesaroni R, Chiurillo MA, Clemente T, Coles DB, Collier JL, Cooney EC, Coyne K, Docampo R, Dupont CL, Edgcomb V, Einarsson E, Elustondo PA, Federici F, Freire-Beneitez V, Freyria NJ, Fukuda K, García PA, Girguis PR, Gomaa F, Gornik SG, Guo J, Hampl V, Hanawa Y, Haro-Contreras ER, Hehenberger E, Highfield A, Hirakawa Y, Hopes A, Howe CJ, Hu I, Ibañez J, Irwin NAT, Ishii Y, Janowicz NE, Jones AC, Kachale A, Fujimura-Kamada K, Kaur B, Kaye JZ, Kazana E, Keeling PJ, King N, Klobutcher LA, Lander N, Lassadi I, Li Z, Lin S, Lozano JC, Luan F, Maruyama S, Matute T, Miceli C, Minagawa J, Moosburner M, Najle SR, Nanjappa D, Nimmo IC, Noble L, Novák Vanclová AMG, Nowacki M, Nuñez I, Pain A, Piersanti A, Pucciarelli S, Pyrih J, Rest JS, Rius M, Robertson D, Ruaud A, Ruiz-Trillo I, Sigg MA, Silver PA, Slamovits CH, Jason Smith G, Sprecher BN, Stern R, Swart EC, Tsaousis AD, Tsypin L, Turkewitz A, Turnšek J, Valach M, Vergé V, von Dassow P, von der Haar T, Waller RF, Wang L, Wen X, Wheeler G, Woods A, Zhang H, Mock T, Worden AZ, and Lukeš J

Abstract

An amendment to this paper has been published and can be accessed via a link at the top of the paper.

Published

2020

48. Symbiotic magnetic motility.

Author

Edgcomb V

Subjects

Bacteria, Eukaryota, Symbiosis

Published

2019

49. Strength in numbers: Collaborative science for new experimental model systems.

Author

Waller RF, Cleves PA, Rubio-Brotons M, Woods A, Bender SJ, Edgcomb V, Gann ER, Jones AC, Teytelman L, von Dassow P, Wilhelm SW, and Collier JL

Subjects

Aquatic Organisms physiology, Eukaryota classification, Phylogeny, Transformation, Genetic, Cooperative Behavior, Models, Theoretical

Abstract

Our current understanding of biology is heavily based on a small number of genetically tractable model organisms. Most eukaryotic phyla lack such experimental models, and this limits our ability to explore the molecular mechanisms that ultimately define their biology, ecology, and diversity. In particular, marine protists suffer from a paucity of model organisms despite playing critical roles in global nutrient cycles, food webs, and climate. To address this deficit, an initiative was launched in 2015 to foster the development of ecologically and taxonomically diverse marine protist genetic models. The development of new models faces many barriers, some technical and others institutional, and this often discourages the risky, long-term effort that may be required. To lower these barriers and tackle the complexity of this effort, a highly collaborative community-based approach was taken. Herein, we describe this approach, the advances achieved, and the lessons learned by participants in this novel community-based model for research., Competing Interests: I have read the journal's policy and the authors of this manuscript have the following competing interests. Leonid Teytelman is an employee of protocols.io and owns equity in the company. Adam C. Jones and Sara J. Bender are employees of the Gordon and Betty Moore Foundation.

Published

2018

50. UniEuk: Time to Speak a Common Language in Protistology!

Author

Berney C, Ciuprina A, Bender S, Brodie J, Edgcomb V, Kim E, Rajan J, Parfrey LW, Adl S, Audic S, Bass D, Caron DA, Cochrane G, Czech L, Dunthorn M, Geisen S, Glöckner FO, Mahé F, Quast C, Kaye JZ, Simpson AGB, Stamatakis A, Del Campo J, Yilmaz P, and de Vargas C

Subjects

Animals, Bacteria classification, Biodiversity, Databases, Nucleic Acid, Ecosystem, Environment, Eukaryota cytology, Eukaryota genetics, Eukaryota physiology, Eukaryotic Cells, Fungi classification, Phylogeny, Classification, Eukaryota classification

Abstract

Universal taxonomic frameworks have been critical tools to structure the fields of botany, zoology, mycology, and bacteriology as well as their large research communities. Animals, plants, and fungi have relatively solid, stable morpho-taxonomies built over the last three centuries, while bacteria have been classified for the last three decades under a coherent molecular taxonomic framework. By contrast, no such common language exists for microbial eukaryotes, even though environmental '-omics' surveys suggest that protists make up most of the organismal and genetic complexity of our planet's ecosystems! With the current deluge of eukaryotic meta-omics data, we urgently need to build up a universal eukaryotic taxonomy bridging the protist -omics age to the fragile, centuries-old body of classical knowledge that has effectively linked protist taxa to morphological, physiological, and ecological information. UniEuk is an open, inclusive, community-based and expert-driven international initiative to build a flexible, adaptive universal taxonomic framework for eukaryotes. It unites three complementary modules, EukRef, EukBank, and EukMap, which use phylogenetic markers, environmental metabarcoding surveys, and expert knowledge to inform the taxonomic framework. The UniEuk taxonomy is directly implemented in the European Nucleotide Archive at EMBL-EBI, ensuring its broad use and long-term preservation as a reference taxonomy for eukaryotes., (© 2017 The Author(s) Journal of Eukaryotic Microbiology published by Wiley Periodicals, Inc. on behalf of International Society of Protistologists.)

Published

2017