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  • 11
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    Unknown
    Oxygen to Argon ratio measured with Equilibrator Inlet Mass Spectrometer [EIMS] during the Tara Pacific Expedition 2016-2018 (2022)
    PANGAEA
    Details
    Publication Date: 2024-01-06
    Description: The Tara Pacific expedition (2016-2018) sampled coral ecosystems around 32 islands in the Pacific Ocean, and sampled the surface of oceanic waters at 249 locations, resulting in the collection of nearly 58,000 samples. The expedition was designed to systematically study corals, fish, plankton, and seawater, and included the collection of samples for advanced biogeochemical, molecular, and imaging analysis. Here we provide the continuous dataset originating from Equilibrator Inlet Mass Spectrometer [EIMS] (Pfeiffer Vacuum Quadrupole 1–100 amu) instruments acquiring continuously during the full course of the campaign. Surface seawater was pumped continuously through a hull inlet located 1.5 m under the waterline using a membrane pump (10 LPM; Shurflo), circulated through a vortex debubbler, a flow meter, and distributed to a number of flow-through instruments.
    Keywords: argon; DATE/TIME; Equilibrator Inlet Mass Spectrometry (EIMS); Fondation Tara Expeditions; FondTara; LATITUDE; LONGITUDE; Oxygen; Oxygen/Argon ratio; Pacific Ocean; SV Tara; TARA_2016-2018; Tara_Pacific; TARA_PACIFIC_2016-2018; Tara Pacific Expedition; UMS; Underway, multiple sensors
    Type: Dataset
    Format: text/tab-separated-values, 146536 data points
    Location Call Number Expected Availability
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    DATA PANGAEA
  • 12
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    Relative dissolved organic matter DOM fluorescence, using CDOM fluorometer [WSCD] (WETLabs) during the Tara Pacific Expedition 2016-2018 (2022)
    PANGAEA
    Details
    Publication Date: 2024-01-06
    Description: The Tara Pacific expedition (2016-2018) sampled coral ecosystems around 32 islands in the Pacific Ocean, and sampled the surface of oceanic waters at 249 locations, resulting in the collection of nearly 58,000 samples. The expedition was designed to systematically study corals, fish, plankton, and seawater, and included the collection of samples for advanced biogeochemical, molecular, and imaging analysis. Here we provide the continuous dataset originating from CDOM fluorometer [WSCD] (WETLabs) instruments acquiring continuously during the full course of the campaign. Surface seawater was pumped continuously through a hull inlet located 1.5 m under the waterline using a membrane pump (10 LPM; Shurflo), circulated through a vortex debubbler, a flow meter, and distributed to a number of flow-through instruments. The CDOM fluorometer [WSCD] (WETLabs), was added to the underway system to measure the fluorescence of colored dissolved organic matter [fdom].
    Keywords: CTD, Sea-Bird; measured with Thermosalinograph (TSG) sensor; DATE/TIME; DOM; Fluorescence, dissolved organic matter; Fluorescence, dissolved organic matter, standard deviation; Fondation Tara Expeditions; FondTara; LATITUDE; LONGITUDE; Number; Pacific Ocean; Salinity; SV Tara; TARA_2016-2018; Tara_Pacific; TARA_PACIFIC_2016-2018; Tara Pacific Expedition; Temperature, water; UMS; Underway, multiple sensors; WET Labs CDOM
    Type: Dataset
    Format: text/tab-separated-values, 2740189 data points
    Location Call Number Expected Availability
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    DATA PANGAEA
  • 13
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    Photosynthetically Active Radiation using PAR sensor (Biospherical Instruments Inc. QCR-2150) during the Tara Pacific Expedition 2016-2018 (2022)
    PANGAEA
    Details
    Publication Date: 2024-01-06
    Description: The Tara Pacific expedition (2016-2018) sampled coral ecosystems around 32 islands in the Pacific Ocean, and sampled the surface of oceanic waters at 249 locations, resulting in the collection of nearly 58,000 samples. The expedition was designed to systematically study corals, fish, plankton, and seawater, and included the collection of samples for advanced biogeochemical, molecular, and imaging analysis. Here we provide the continuous dataset originating from PAR sensor (Biospherical Instruments Inc. QCR-2150) acquiring continuously during the full course of the campaign and mounted at the stern of the boat (~7 m altitude).
    Keywords: CTD, Sea-Bird; measured with Thermosalinograph (TSG) sensor; DATE/TIME; Fondation Tara Expeditions; FondTara; LATITUDE; LONGITUDE; Number; Pacific Ocean; PAR; PAR sensor, Biospherical, QCR-2150; Radiation, photosynthetically active; Radiation, photosynthetically active, standard deviation; Salinity; SV Tara; TARA_2016-2018; Tara_Pacific; TARA_PACIFIC_2016-2018; Tara Pacific Expedition; Temperature, water; UMS; Underway, multiple sensors
    Type: Dataset
    Format: text/tab-separated-values, 4154275 data points
    Location Call Number Expected Availability
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    DATA PANGAEA
  • 14
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    Oxygen concentration in the seawater measured with with an optode (Aanderaa optode 4835) during the Tara Pacific Expedition 2016-2018 (2022)
    PANGAEA
    Details
    Publication Date: 2024-01-06
    Description: The Tara Pacific expedition (2016-2018) sampled coral ecosystems around 32 islands in the Pacific Ocean, and sampled the surface of oceanic waters at 249 locations, resulting in the collection of nearly 58,000 samples. The expedition was designed to systematically study corals, fish, plankton, and seawater, and included the collection of samples for advanced biogeochemical, molecular, and imaging analysis. Here we provide the continuous dataset originating from optode (Aanderaa optode 4835) instruments acquiring continuously during the full course of the campaign. Surface seawater was pumped continuously through a hull inlet located 1.5 m under the waterline using a membrane pump (10 LPM; Shurflo), circulated through a vortex debubbler, a flow meter, and distributed to a number of flow-through instruments. The optode (Aanderaa optode 4835) measured the Oxygen concentration in the seawater.
    Keywords: DATE/TIME; Fondation Tara Expeditions; FondTara; LATITUDE; LONGITUDE; Oxygen; Oxygen optode, Aanderaa, type 4835; Oxygen saturation; Pacific Ocean; SV Tara; TARA_2016-2018; Tara_Pacific; TARA_PACIFIC_2016-2018; Tara Pacific Expedition; UMS; Underway, multiple sensors
    Type: Dataset
    Format: text/tab-separated-values, 563274 data points
    Location Call Number Expected Availability
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    DATA PANGAEA
  • 15
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    Particles Volume scattering, backscattering, POC, phytoplankton carbon, using backscattering sensor [BB3] (WETLabs ECO-BB3) during the Tara Pacific Expedition 2016-2018 (2022)
    PANGAEA
    Details
    Publication Date: 2024-01-06
    Description: The Tara Pacific expedition (2016-2018) sampled coral ecosystems around 32 islands in the Pacific Ocean, and sampled the surface of oceanic waters at 249 locations, resulting in the collection of nearly 58,000 samples. The expedition was designed to systematically study corals, fish, plankton, and seawater, and included the collection of samples for advanced biogeochemical, molecular, and imaging analysis. Here we provide the continuous dataset originating from backscattering sensor [BB3] (WETLabs ECO-BB3) instruments acquiring continuously during the full course of the campaign. Surface seawater was pumped continuously through a hull inlet located 1.5 m under the waterline using a membrane pump (10 LPM; Shurflo), circulated through a vortex debubbler, a flow meter, and distributed to a number of flow-through instruments. The backscattering sensor [BB3] (WETLabs ECO-BB3) was added to the underway system to measure the volume scattering function [VSF] at 124° and 3 wavelengths (470, 532, 650 nm). The flow was automatically directed through a 0.2 µm filter for 10 minutes every hour before being circulated through the [BB3] allowing the calculation of particulate backscattering [bbp] by removing the signal due to dissolved matter, drift, and biofouling (Slade et al. 2010, doi:10.1175/2010JTECHO755.1). The particulate organic carbon concentration [poc] was estimated by applying an empirical relation between measured [poc] and [bbp] (Cetinić et al. 2012, doi:10.1175/2010JTECHO755.1). Phytoplankton organic carbon [cphyto] was estimated by an empirical relationship with [bbp] (Graff et al. 2015, doi:10.1016/j.dsr.2015.04.006).
    Keywords: According to Cetinić et al. (2012); According to Graff et al. (2015); Backscatter; Backscattering coefficient of particles, 470 nm; Backscattering coefficient of particles, 532 nm; Backscattering coefficient of particles, 650 nm; Carbon, organic, particulate; CTD, Sea-Bird; measured with Thermosalinograph (TSG) sensor; DATE/TIME; Fondation Tara Expeditions; FondTara; LATITUDE; LONGITUDE; Number; Pacific Ocean; Phytoplankton, biomass as carbon; phytoplankton carbon; POC; Salinity; Spectral backscattering sensor (WET Labs, Eco-bb3); SV Tara; TARA_2016-2018; Tara_Pacific; TARA_PACIFIC_2016-2018; Tara Pacific Expedition; Temperature, water; UMS; Underway, multiple sensors; Volume scattering function at 124°, 470 nm; Volume scattering function at 124°, 470 nm, standard deviation; Volume scattering function at 124°, 532 nm; Volume scattering function at 124°, 532 nm, standard deviation; Volume scattering function at 124°, 650 nm; Volume scattering function at 124°, 650 nm, standard deviation
    Type: Dataset
    Format: text/tab-separated-values, 6020692 data points
    Location Call Number Expected Availability
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    DATA PANGAEA
  • 16
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    CTD dataset collected during the Tara Pacific Expedition 2016-2018 using a castaway CTD (2022)
    PANGAEA
    Details
    Publication Date: 2024-01-06
    Description: The Tara Pacific expedition (2016-2018) sampled coral ecosystems around 32 islands in the Pacific Ocean, and sampled the surface of oceanic waters at 249 locations, resulting in the collection of nearly 58,000 samples. The expedition was designed to systematically study corals, fish, plankton, and seawater, and included the collection of samples for advanced biogeochemical, molecular, and imaging analysis. Here we provide the dataset obtained with a small CTD probe (Castaway CTD) deployed from the dinghy down to the reef (generally ~5 to 10m) to record temperature and conductivity profiles.
    Keywords: Conductance; Conductivity; Conductivity, electrical; CTD, SonTek, CastAway-CTD; CTD-CAST; DATE/TIME; Density, sigma-theta (0); DEPTH, water; Event label; File name; Fondation Tara Expeditions; FondTara; HANDHELD-CTD; LATITUDE; LONGITUDE; OA000-I01-S02; OA000-I01-S03; OA000-I02-S01; OA000-I02-S02; OA000-I02-S03; OA000-I04-S01; OA000-I04-S04; OA000-I05-S00; OA000-I05-S02; OA000-I05-S03; OA000-I06-S01; OA000-I06-S02; OA000-I06-S03; OA000-I07-S01; OA000-I07-S02; OA000-I07-S03; OA000-I08-S01; OA000-I08-S02; OA000-I08-S03; OA000-I09-S01; OA000-I09-S02; OA000-I09-S03; OA000-I10-S01; OA000-I10-S02; OA000-I10-S03; OA000-I11-S01; OA000-I12-S02; OA000-I13-S01; OA000-I13-S03; OA000-I14-S02; OA000-I14-S03; OA000-I15-S01; OA000-I15-S02; OA000-I15-S03; OA000-I16-S01; OA000-I16-S02; OA000-I16-S03; OA000-I19-S01; OA000-I19-S02; OA000-I19-S03; OA000-I19-S04; OA000-I20-S01; OA000-I20-S02; OA000-I20-S03; OA000-I21-S01; OA000-I21-S02; OA000-I21-S03; OA000-I22-S01; OA000-I22-S02; OA000-I22-S03; OA000-I23-S01; OA000-I23-S02; OA000-I23-S03; OA000-I23-S11; OA000-I23-S12; OA000-I23-S13; OA000-I23-S14; OA000-I23-S15; OA000-I23-S16; OA000-I23-S21; OA000-I23-S22; OA000-I23-S23; OA000-I23-S24; OA000-I23-S25; OA000-I23-S26; OA000-I23-S31; OA000-I23-S32; OA000-I23-S33; OA000-I23-S34; OA000-I23-S35; OA000-I23-S36; OA000-I24-S01; OA000-I24-S02; OA000-I24-S03; OA000-I24-S04; OA000-I25-S01; OA000-I25-S02; OA000-I25-S03; OA000-I25-S04; OA000-I26-S01; OA000-I26-S02; OA000-I26-S03; OA000-I27-S01; OA000-I27-S02; OA000-I28-S01; OA000-I28-S02; OA000-I28-S03; OA000-I29-S01; OA000-I29-S03; OA000-I30-S01; OA000-I31-S01; OA000-I31-S02; OA000-I31-S03; OA000-I32-S01; OA000-I32-S02; OA000-I32-S03; OA000-I32-S04; OA000-TS2-FA1; OA000-TS2-FA3; OA000-TS2-HI1; OA000-TS2-HI2; OA000-TS2-KA1; OA000-TS2-KA2; OA000-TS2-KA3; OA000-TS2-MA1; OA000-TS2-MA2; OA000-TS2-MA3; OA000-TS2-MT1; OA000-TS2-MT2; OA000-TS2-MT3; OA000-TS2-MT4; OA000-TS2-TA1; OA000-TS2-TA2; OA000-TS2-TA3; OA050-I05-S00; OA054-I06-S00; Pacific; Pressure; Salinity; Sample code/label; Sample comment; Sample ID; Sound velocity in water; SV Tara; TARA_20160718T1511Z_D_S-WATER_HANDHELD-CTD; TARA_20160720T2159Z_D_S-WATER_HANDHELD-CTD; TARA_20160721T1532Z_D_S-WATER_HANDHELD-CTD; TARA_20160723T1301Z_D_S-WATER_HANDHELD-CTD; TARA_20160725T1455Z_D_S-WATER_HANDHELD-CTD; TARA_20160903T1525Z_D_S-WATER_HANDHELD-CTD; TARA_20160907T1436Z_D_S-WATER_HANDHELD-CTD; TARA_20160914T2212Z_D_S-WATER_HANDHELD-CTD; TARA_20160915T0136Z_D_I-WATER_HANDHELD-CTD; TARA_20160915T1538Z_D_S-WATER_HANDHELD-CTD; TARA_20160918T0058Z_D_I-WATER_HANDHELD-CTD; TARA_20160921T0808Z_N_I-WATER_HANDHELD-CTD; TARA_20160922T0045Z_D_S-WATER_HANDHELD-CTD; TARA_20160923T1734Z_D_S-WATER_HANDHELD-CTD; TARA_20160925T0031Z_D_S-WATER_HANDHELD-CTD; TARA_20161010T0110Z_D_S-WATER_HANDHELD-CTD; TARA_20161011T0049Z_D_S-WATER_HANDHELD-CTD; TARA_20161011T1733Z_D_S-WATER_HANDHELD-CTD; TARA_20161011T1742Z_D_S-WATER_HANDHELD-CTD; TARA_20161011T2340Z_D_S-WATER_HANDHELD-CTD; TARA_20161012T1906Z_D_S-WATER_HANDHELD-CTD; TARA_20161013T1736Z_D_S-WATER_HANDHELD-CTD; TARA_20161013T2325Z_D_S-WATER_HANDHELD-CTD; TARA_20161014T1820Z_D_S-WATER_HANDHELD-CTD; TARA_20161015T0028Z_D_S-WATER_HANDHELD-CTD; TARA_20161015T1742Z_D_S-WATER_HANDHELD-CTD; TARA_20161016T0038Z_D_S-WATER_HANDHELD-CTD; TARA_20161016T1737Z_D_S-WATER_HANDHELD-CTD; TARA_20161017T0032Z_D_S-WATER_HANDHELD-CTD; TARA_20161017T1725Z_D_S-WATER_HANDHELD-CTD; TARA_20161018T0021Z_D_S-WATER_HANDHELD-CTD; TARA_20161018T1717Z_D_S-WATER_HANDHELD-CTD; TARA_20161018T2354Z_D_S-WATER_HANDHELD-CTD; TARA_20161108T1758Z_D_S-WATER_HANDHELD-CTD; TARA_20161109T0112Z_D_S-WATER_HANDHELD-CTD; TARA_20161109T0321Z_D_S-WATER_HANDHELD-CTD; TARA_20161113T1725Z_D_S-WATER_HANDHELD-CTD; TARA_20161115T1842Z_D_S-WATER_HANDHELD-CTD; TARA_20161116T1728Z_D_S-WATER_HANDHELD-CTD; TARA_20161122T1949Z_D_S-WATER_HANDHELD-CTD; TARA_20161123T1910Z_D_S-WATER_HANDHELD-CTD; TARA_20161124T1939Z_D_S-WATER_HANDHELD-CTD; TARA_20161130T2307Z_D_S-WATER_HANDHELD-CTD; TARA_20161201T1827Z_D_S-WATER_HANDHELD-CTD; TARA_20161202T1816Z_D_S-WATER_HANDHELD-CTD; TARA_20161220T2118Z_D_S-WATER_HANDHELD-CTD; TARA_20170101T0322Z_D_S-WATER_HANDHELD-CTD; TARA_20170108T0342Z_D_S-WATER_HANDHELD-CTD; TARA_20170109T2144Z_D_S-WATER_HANDHELD-CTD; TARA_20170109T2346Z_D_S-WATER_HANDHELD-CTD; TARA_20170121T2050Z_D_S-WATER_HANDHELD-CTD; TARA_20170121T2054Z_D_S-WATER_HANDHELD-CTD; TARA_20170122T0003Z_D_S-WATER_HANDHELD-CTD; TARA_20170122T2205Z_D_S-WATER_HANDHELD-CTD; TARA_20170129T0045Z_D_S-WATER_HANDHELD-CTD; TARA_20170129T2129Z_D_S-WATER_HANDHELD-CTD; TARA_20170130T2141Z_D_S-WATER_HANDHELD-CTD; TARA_20170130T2308Z_D_S-WATER_HANDHELD-CTD; TARA_20170130T2310Z_D_S-WATER_HANDHELD-CTD; TARA_20170209T2253Z_D_S-WATER_HANDHELD-CTD; TARA_20170210T0129Z_D_S-WATER_HANDHELD-CTD; TARA_20170210T2240Z_D_S-WATER_HANDHELD-CTD; TARA_20170211T2310Z_D_S-WATER_HANDHELD-CTD; TARA_20170211T2312Z_D_S-WATER_HANDHELD-CTD; TARA_20170830T0440Z_D_S-WATER_HANDHELD-CTD; TARA_20170830T0442Z_D_S-WATER_HANDHELD-CTD; TARA_20170830T2145Z_D_S-WATER_HANDHELD-CTD; TARA_20170901T2258Z_D_S-WATER_HANDHELD-CTD; TARA_20170901T2300Z_D_S-WATER_HANDHELD-CTD; TARA_20170903T0018Z_D_S-WATER_HANDHELD-CTD; TARA_20170903T2159Z_D_S-WATER_HANDHELD-CTD; TARA_20170903T2203Z_D_S-WATER_HANDHELD-CTD; TARA_20170910T2220Z_D_S-WATER_HANDHELD-CTD; TARA_20170910T2221Z_D_S-WATER_HANDHELD-CTD; TARA_20170911T2104Z_D_S-WATER_HANDHELD-CTD; TARA_20170911T2105Z_D_S-WATER_HANDHELD-CTD; TARA_20170913T0427Z_D_S-WATER_HANDHELD-CTD; TARA_20170913T0429Z_D_S-WATER_HANDHELD-CTD; TARA_20170925T0301Z_D_S-WATER_HANDHELD-CTD; TARA_20170925T2327Z_D_S-WATER_HANDHELD-CTD; TARA_20170927T0140Z_D_S-WATER_HANDHELD-CTD; TARA_20171021T0515Z_D_S-WATER_HANDHELD-CTD; TARA_20171022T2223Z_D_S-WATER_HANDHELD-CTD; TARA_20171023T0647Z_D_S-WATER_HANDHELD-CTD; TARA_20171025T2048Z_D_S-WATER_HANDHELD-CTD; TARA_20171102T0413Z_D_S-WATER_HANDHELD-CTD; TARA_20171102T0415Z_D_S-WATER_HANDHELD-CTD; TARA_20171102T0416Z_D_S-WATER_HANDHELD-CTD; TARA_20171102T0418Z_D_S-WATER_HANDHELD-CTD; TARA_20171102T0420Z_D_S-WATER_HANDHELD-CTD; TARA_20171102T0421Z_D_S-WATER_HANDHELD-CTD; TARA_20171102T0424Z_D_S-WATER_HANDHELD-CTD; TARA_20171102T0426Z_D_S-WATER_HANDHELD-CTD; TARA_20171102T0428Z_D_S-WATER_HANDHELD-CTD; TARA_20171102T0429Z_D_S-WATER_HANDHELD-CTD; TARA_20171102T0430Z_D_S-WATER_HANDHELD-CTD; TARA_20171102T0431Z_D_S-WATER_HANDHELD-CTD; TARA_20171102T0433Z_D_S-WATER_HANDHELD-CTD; TARA_20171102T0434Z_D_S-WATER_HANDHELD-CTD; TARA_20171102T0435Z_D_S-WATER_HANDHELD-CTD; TARA_20171102T0437Z_D_S-WATER_HANDHELD-CTD; TARA_20171102T0438Z_D_S-WATER_HANDHELD-CTD; TARA_20171102T0440Z_D_S-WATER_HANDHELD-CTD; TARA_20171102T0443Z_D_S-WATER_HANDHELD-CTD; TARA_20171102T0448Z_D_S-WATER_HANDHELD-CTD; TARA_20171102T0452Z_D_S-WATER_HANDHELD-CTD; TARA_20171103T2226Z_D_S-WATER_HANDHELD-CTD; TARA_20171105T2330Z_D_S-WATER_HANDHELD-CTD; TARA_20171106T0449Z_D_S-WATER_HANDHELD-CTD; TARA_20171109T2124Z_D_S-WATER_HANDHELD-CTD; TARA_20171112T2231Z_D_S-WATER_HANDHELD-CTD; TARA_20171117T2250Z_D_S-WATER_HANDHELD-CTD; TARA_20171118T0144Z_D_S-WATER_HANDHELD-CTD; TARA_20171119T2231Z_D_S-WATER_HANDHELD-CTD; TARA_20171120T0051Z_D_S-WATER_HANDHELD-CTD; TARA_20171202T0121Z_D_S-WATER_HANDHELD-CTD; TARA_20171222T0506Z_D_S-WATER_HANDHELD-CTD; TARA_20171222T0507Z_D_S-WATER_HANDHELD-CTD; TARA_20171223T2350Z_D_S-WATER_HANDHELD-CTD; TARA_20171225T2307Z_D_S-WATER_HANDHELD-CTD; TARA_20171226T2259Z_D_S-WATER_HANDHELD-CTD; TARA_20171228T0532Z_D_S-WATER_HANDHELD-CTD; TARA_20180105T2345Z_D_S-WATER_HANDHELD-CTD; TARA_20180106T0636Z_D_S-WATER_HANDHELD-CTD; TARA_20180106T2343Z_D_S-WATER_HANDHELD-CTD; TARA_20180107T2357Z_D_S-WATER_HANDHELD-CTD; TARA_20180316T0219Z_D_S-WATER_HANDHELD-CTD; TARA_20180316T2306Z_D_S-WATER_HANDHELD-CTD; TARA_20180321T0803Z_D_S-WATER_HANDHELD-CTD; TARA_20180322T0056Z_D_S-WATER_HANDHELD-CTD; TARA_20180323T0654Z_D_S-WATER_HANDHELD-CTD; TARA_20180324T0304Z_D_S-WATER_HANDHELD-CTD; TARA_20180324T0313Z_D_S-WATER_HANDHELD-CTD; TARA_20180614T1849Z_D_S-WATER_HANDHELD-CTD;
    Type: Dataset
    Format: text/tab-separated-values, 63887 data points
    Location Call Number Expected Availability
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    DATA PANGAEA
  • 17
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    Navigation and meteorological data collected during the Tara Pacific Expedition 2016-2018 (2022)
    PANGAEA
    Details
    Publication Date: 2024-01-06
    Description: The Tara Pacific expedition (2016-2018) sampled coral ecosystems around 32 islands in the Pacific Ocean, and sampled the surface of oceanic waters at 249 locations, resulting in the collection of nearly 58,000 samples. The expedition was designed to systematically study corals, fish, plankton, and seawater, and included the collection of samples for advanced biogeochemical, molecular, and imaging analysis. Here we provide the continuous dataset originating from navigation and meteorological instruments acquiring continuously during the full course of the campaign.
    Keywords: Course; DATE/TIME; Humidity, relative; LATITUDE; LONGITUDE; meteorological data; Navigation; Navigation and meteorological acquiring during the full course of the campaign; Pacific Ocean; position; Pressure, atmospheric; Solar azimuth angle; Solar zenith angle; Speed; SV Tara; TARA_2016-2018; Tara_Pacific; TARA_PACIFIC_2016-2018; Tara Pacific Expedition; Temperature, air; Temperature, water; UMS; Underway, multiple sensors; Validation flag/comment; Wind apparent direction, reference angle, bow; Wind apparent direction, reference angle, north; Wind apparent speed; Wind direction, true; Wind speed, true
    Type: Dataset
    Format: text/tab-separated-values, 10873547 data points
    Location Call Number Expected Availability
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    DATA PANGAEA
  • 18
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    Aerosol concentration and size distribution (25-685nm) measured with a scanning mobility particle sizer [SMPS] during the Tara Pacific Expedition 2016-2018 (2022)
    PANGAEA
    Details
    Publication Date: 2024-01-06
    Description: The Tara Pacific expedition (2016-2018) sampled coral ecosystems around 32 islands in the Pacific Ocean, and sampled the surface of oceanic waters at 249 locations, resulting in the collection of nearly 58,000 samples. The expedition was designed to systematically study corals, fish, plankton, and seawater, and included the collection of samples for advanced biogeochemical, molecular, and imaging analysis. Here we provide the continuous dataset originating from scanning mobility particle sizer ([SMPS], SMPS-C GRIMM Aerosol Technik Ainring GmbH & Co. KG, Ainring, Germany) instruments acquiring continuously during the full course of the campaign. Aerosols pumped through one of the ([MAST-PUMP]) inlets were channeled through a conductive tubing of 1.9 cm inner diameter to four parallel 47mm filter holders installed in the rear hold using a vacuum pump (Diaphragm pumpME16 NT, VACUUBRAND BmbH & Co KG, Wertheim, Germany) at a minimum flow rate of 30 lpm (20lpm prior to may 2016). Air was conducted to a scanning mobility particle sizer ([SMPS], SMPS-C GRIMM Aerosol Technik Ainring GmbH & Co. KG, Ainring, Germany) measuring particles in the size range 0.025 – 0.70 µm. The SMPS was set to perform a full scan of particle distribution every 5 min. Data from [SMPS] are averaged at the 30 minute scale and provided both at the scale of particle concentration (nb cm-3) together with its normalized size distribution (dN/dlogDp (nb cm-3) i.e., the concentration divided by the log of the width of the bin).
    Keywords: aerosols; DATE/TIME; Fondation Tara Expeditions; FondTara; LATITUDE; Log-normal particle size distribution, normalized concentration at particle diameter 101.82 nm; Log-normal particle size distribution, normalized concentration at particle diameter 101.82 nm, standard deviation; Log-normal particle size distribution, normalized concentration at particle diameter 105.54 nm; Log-normal particle size distribution, normalized concentration at particle diameter 105.54 nm, standard deviation; Log-normal particle size distribution, normalized concentration at particle diameter 109.41 nm; Log-normal particle size distribution, normalized concentration at particle diameter 109.41 nm, standard deviation; Log-normal particle size distribution, normalized concentration at particle diameter 113.42 nm; Log-normal particle size distribution, normalized concentration at particle diameter 113.42 nm, standard deviation; Log-normal particle size distribution, normalized concentration at particle diameter 117.57 nm; Log-normal particle size distribution, normalized concentration at particle diameter 117.57 nm, standard deviation; Log-normal particle size distribution, normalized concentration at particle diameter 121.88 nm; Log-normal particle size distribution, normalized concentration at particle diameter 121.88 nm, standard deviation; Log-normal particle size distribution, normalized concentration at particle diameter 126.35 nm; Log-normal particle size distribution, normalized concentration at particle diameter 126.35 nm, standard deviation; Log-normal particle size distribution, normalized concentration at particle diameter 130.97 nm; Log-normal particle size distribution, normalized concentration at particle diameter 130.97 nm, standard deviation; Log-normal particle size distribution, normalized concentration at particle diameter 135.77 nm; Log-normal particle size distribution, normalized concentration at particle diameter 135.77 nm, standard deviation; Log-normal particle size distribution, normalized concentration at particle diameter 140.75 nm; Log-normal particle size distribution, normalized concentration at particle diameter 140.75 nm, standard deviation; Log-normal particle size distribution, normalized concentration at particle diameter 145.9 nm; Log-normal particle size distribution, normalized concentration at particle diameter 145.9 nm, standard deviation; Log-normal particle size distribution, normalized concentration at particle diameter 151.25 nm; Log-normal particle size distribution, normalized concentration at particle diameter 151.25 nm, standard deviation; Log-normal particle size distribution, normalized concentration at particle diameter 156.79 nm; Log-normal particle size distribution, normalized concentration at particle diameter 156.79 nm, standard deviation; Log-normal particle size distribution, normalized concentration at particle diameter 162.53 nm; Log-normal particle size distribution, normalized concentration at particle diameter 162.53 nm, standard deviation; Log-normal particle size distribution, normalized concentration at particle diameter 168.49 nm; Log-normal particle size distribution, normalized concentration at particle diameter 168.49 nm, standard deviation; Log-normal particle size distribution, normalized concentration at particle diameter 174.66 nm; Log-normal particle size distribution, normalized concentration at particle diameter 174.66 nm, standard deviation; Log-normal particle size distribution, normalized concentration at particle diameter 181.06 nm; Log-normal particle size distribution, normalized concentration at particle diameter 181.06 nm, standard deviation; Log-normal particle size distribution, normalized concentration at particle diameter 187.69 nm; Log-normal particle size distribution, normalized concentration at particle diameter 187.69 nm, standard deviation; Log-normal particle size distribution, normalized concentration at particle diameter 194.56 nm; Log-normal particle size distribution, normalized concentration at particle diameter 194.56 nm, standard deviation; Log-normal particle size distribution, normalized concentration at particle diameter 201.69 nm; Log-normal particle size distribution, normalized concentration at particle diameter 201.69 nm, standard deviation; Log-normal particle size distribution, normalized concentration at particle diameter 209.08 nm; Log-normal particle size distribution, normalized concentration at particle diameter 209.08 nm, standard deviation; Log-normal particle size distribution, normalized concentration at particle diameter 216.74 nm; Log-normal particle size distribution, normalized concentration at particle diameter 216.74 nm, standard deviation; Log-normal particle size distribution, normalized concentration at particle diameter 224.68 nm; Log-normal particle size distribution, normalized concentration at particle diameter 224.68 nm, standard deviation; Log-normal particle size distribution, normalized concentration at particle diameter 232.91 nm; Log-normal particle size distribution, normalized concentration at particle diameter 232.91 nm, standard deviation; Log-normal particle size distribution, normalized concentration at particle diameter 241.44 nm; Log-normal particle size distribution, normalized concentration at particle diameter 241.44 nm, standard deviation; Log-normal particle size distribution, normalized concentration at particle diameter 25.03 nm; Log-normal particle size distribution, normalized concentration at particle diameter 25.03 nm, standard deviation; Log-normal particle size distribution, normalized concentration at particle diameter 25.95 nm; Log-normal particle size distribution, normalized concentration at particle diameter 25.95 nm, standard deviation; Log-normal particle size distribution, normalized concentration at particle diameter 250.29 nm; Log-normal particle size distribution, normalized concentration at particle diameter 250.29 nm, standard deviation; Log-normal particle size distribution, normalized concentration at particle diameter 259.46 nm; Log-normal particle size distribution, normalized concentration at particle diameter 259.46 nm, standard deviation; Log-normal particle size distribution, normalized concentration at particle diameter 26.9 nm; Log-normal particle size distribution, normalized concentration at particle diameter 26.9 nm, standard deviation; Log-normal particle size distribution, normalized concentration at particle diameter 268.96 nm; Log-normal particle size distribution, normalized concentration at particle diameter 268.96 nm, standard deviation; Log-normal particle size distribution, normalized concentration at particle diameter 27.88 nm; Log-normal particle size distribution, normalized concentration at particle diameter 27.88 nm, standard deviation; Log-normal particle size distribution, normalized concentration at particle diameter 278.81 nm; Log-normal particle size distribution, normalized concentration at particle diameter 278.81 nm, standard deviation; Log-normal particle size distribution, normalized concentration at particle diameter 28.9 nm; Log-normal particle size distribution, normalized concentration at particle diameter 28.9 nm, standard deviation; Log-normal particle size distribution, normalized concentration at particle diameter 289.03 nm; Log-normal particle size distribution, normalized concentration at particle diameter 289.03 nm, standard deviation; Log-normal particle size distribution, normalized concentration at particle diameter 29.96 nm; Log-normal particle size distribution, normalized concentration at particle diameter 29.96 nm, standard deviation; Log-normal particle size distribution, normalized concentration at particle diameter 299.61 nm; Log-normal particle size distribution, normalized concentration at particle diameter 299.61 nm, standard deviation; Log-normal particle size distribution, normalized concentration at particle diameter 31.06 nm; Log-
    Type: Dataset
    Format: text/tab-separated-values, 2410457 data points
    Location Call Number Expected Availability
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    DATA PANGAEA
  • 19
    facet.materialart.
    Unknown
    Sampling events from the Tara Pacific Expedition 2016-2018 (2022)
    PANGAEA
    Details
    Publication Date: 2024-04-20
    Description: The Tara Pacific expedition (2016-2018) sampled coral ecosystems around 32 islands in the Pacific Ocean, and sampled the surface of oceanic waters at 249 locations, resulting in the collection of nearly 58,000 samples. The expedition was designed to systematically study corals, fish, plankton, and seawater, and included the collection of samples for advanced biogeochemical, molecular, and imaging analysis. Here we provide the dataset obtained with a small CTD probe (Castaway CTD) deployed from the dinghy down to the reef (generally ~5 to 10m) to record temperature and conductivity profiles.
    Keywords: Binary Object; BOAT-PIPE; Conductivity; DATE/TIME; Device type; Distance; DOLPHIN-CARBOY; DOLPHIN-CARTRIDGE-300; DOLPHIN-DECKNET-20; DOLPHIN-UBAT; Event label; EXP; Experiment; Fondation Tara Expeditions; FondTara; HANDHELD-BOW-POLE; HANDHELD-BUCKET; HANDHELD-CTD; HANDHELD-MICROTOPS; HANDHELD-NISKIN; HANDHELD-SIMBADA; HSN-NET-20; HSN-NET-300; INLINE-PUMP; INSITU-UBAT; LATITUDE; LONGITUDE; MANTA-NET-300; MAST-PUMP; OA000-I00-S00; OA000-I01-S01; OA000-I01-S02; OA000-I01-S03; OA000-I02-S01; OA000-I02-S02; OA000-I02-S03; OA000-I03-S00; OA000-I03-S01; OA000-I03-S02; OA000-I04-S00; OA000-I04-S01; OA000-I04-S02; OA000-I04-S03; OA000-I04-S04; OA000-I05-S00; OA000-I05-S01; OA000-I05-S02; OA000-I05-S03; OA000-I05-S04; OA000-I06-S01; OA000-I06-S02; OA000-I06-S03; OA000-I06-S04; OA000-I07-S00; OA000-I07-S01; OA000-I07-S02; OA000-I07-S03; OA000-I07-S04; OA000-I08-S00; OA000-I08-S01; OA000-I08-S02; OA000-I08-S03; OA000-I09-S00; OA000-I09-S01; OA000-I09-S02; OA000-I09-S03; OA000-I10-S00; OA000-I10-S01; OA000-I10-S02; OA000-I10-S03; OA000-I10-S04; OA000-I10-S05; OA000-I11-S00; OA000-I11-S01; OA000-I11-S02; OA000-I11-S03; OA000-I12-S00; OA000-I12-S01; OA000-I12-S02; OA000-I12-S03; OA000-I12-S04; OA000-I13-S00; OA000-I13-S01; OA000-I13-S02; OA000-I13-S03; OA000-I13-S04; OA000-I14-S00; OA000-I14-S01; OA000-I14-S02; OA000-I14-S03; OA000-I15-S00; OA000-I15-S01; OA000-I15-S02; OA000-I15-S03; OA000-I16-S00; OA000-I16-S01; OA000-I16-S02; OA000-I16-S03; OA000-I17-S01; OA000-I17-S02; OA000-I17-S03; OA000-I18-S00; OA000-I18-S01; OA000-I18-S02; OA000-I18-S03; OA000-I19-S00; OA000-I19-S01; OA000-I19-S02; OA000-I19-S03; OA000-I19-S04; OA000-I20-S00; OA000-I20-S01; OA000-I20-S02; OA000-I20-S03; OA000-I21-S00; OA000-I21-S01; OA000-I21-S02; OA000-I21-S03; OA000-I22-S00; OA000-I22-S01; OA000-I22-S02; OA000-I22-S03; OA000-I23-S00; OA000-I23-S01; OA000-I23-S02; OA000-I23-S03; OA000-I23-S11; OA000-I23-S12; OA000-I23-S13; OA000-I23-S14; OA000-I23-S15; OA000-I23-S16; OA000-I23-S21; OA000-I23-S22; OA000-I23-S23; OA000-I23-S24; OA000-I23-S25; OA000-I23-S26; OA000-I23-S31; OA000-I23-S32; OA000-I23-S33; OA000-I23-S34; OA000-I23-S35; OA000-I23-S36; OA000-I24-S00; OA000-I24-S01; OA000-I24-S02; OA000-I24-S03; OA000-I24-S04; OA000-I25-S00; OA000-I25-S01; OA000-I25-S02; OA000-I25-S03; OA000-I25-S04; OA000-I25-S05; OA000-I26-S00; OA000-I26-S01; OA000-I26-S02; OA000-I26-S03; OA000-I26-S04; OA000-I27-S00; OA000-I27-S01; OA000-I27-S02; OA000-I28-S00; OA000-I28-S01; OA000-I28-S02; OA000-I28-S03; OA000-I29-S00; OA000-I29-S01; OA000-I29-S02; OA000-I29-S03; OA000-I30-S00; OA000-I30-S01; OA000-I30-S02; OA000-I30-S03; OA000-I30-S04; OA000-I31-S00; OA000-I31-S01; OA000-I31-S02; OA000-I31-S03; OA000-I31-S04; OA000-I32-S00; OA000-I32-S01; OA000-I32-S02; OA000-I32-S03; OA000-I32-S04; OA000-I32-S05; OA000-TS2-FA1; OA000-TS2-FA2; OA000-TS2-FA3; OA000-TS2-HI1; OA000-TS2-HI2; OA000-TS2-KA1; OA000-TS2-KA2; OA000-TS2-KA3; OA000-TS2-MA1; OA000-TS2-MA2; OA000-TS2-MA3; OA000-TS2-MT1; OA000-TS2-MT2; OA000-TS2-MT3; OA000-TS2-MT4; OA000-TS2-S11; OA000-TS2-S12; OA000-TS2-S21; OA000-TS2-S22; OA000-TS2-S23; OA000-TS2-S24; OA000-TS2-S31; OA000-TS2-S33; OA000-TS2-S41; OA000-TS2-S42; OA000-TS2-S43; OA000-TS2-S51; OA000-TS2-S52; OA000-TS2-S53; OA000-TS2-S54; OA000-TS2-S61; OA000-TS2-S62; OA000-TS2-TA1; OA000-TS2-TA2; OA000-TS2-TA3; OA000-TS3-S99; OA000-TS4-S00; OA000-TS4-S03; OA000-TS4-S12; OA000-TS4-S15; OA000-TS4-S17; OA000-TS4-S18; OA000-TS4-S20; OA000-TS5-S00; OA000-TS5-S11; OA000-TS5-S12; OA000-TS5-S21; OA000-TS5-S22; OA000-TS5-S31; OA000-TS5-S41; OA000-TS5-S51; OA000-TS6-S00; OA000-TS6-S11; OA000-TS6-S12; OA000-TS6-S21; OA000-TS6-S22; OA000-TS7-P01; OA000-TS7-P02; OA000-TS7-P03; OA000-TS7-P04; OA000-TS7-P05; OA000-TS7-P06; OA000-TS7-P07; OA000-TS7-P08; OA000-TS7-P09; OA000-TS7-S00; OA000-TS9-S00; OA000-TS9-S1A; OA000-TS9-S1C; OA000-TS9-S2A; OA000-TS9-S2C; OA000-TS9-S3C; OA000-TS9-S99; OA001-I00-S00; OA002-I00-S00; OA003-I00-S00; OA004-I00-S00; OA005-I00-S00; OA006-I00-S00; OA007-I00-S00; OA008-I00-S00; OA009-I00-S00; OA010-I00-S00; OA011-I00-S00; OA012-I00-S00; OA013-I00-S00; OA014-I00-S00; OA015-I00-S00; OA016-I00-S00; OA017-I00-S00; OA018-I00-S00; OA019-I00-S00; OA020-I00-S00; OA021-I00-S00; OA022-I00-S00; OA023-I00-S00; OA024-I00-S00; OA025-I00-S00; OA026-I00-S00; OA027-I00-S00; OA028-I00-S00; OA029-I03-S00; OA030-I03-S00; OA031-I00-S00; OA032-I00-S00; OA033-I00-S00; OA034-I00-S00; OA035-I00-S00; OA036-I00-S00; OA037-I00-S00; OA038-I00-S00; OA039-I00-S00; OA040-I00-S00; OA041-I04-S00; OA042-I04-S00; OA043-I04-S00; OA044-I04-S00; OA045-I00-S00; OA046-I00-S00; OA047-I00-S00; OA048-I05-S00; OA048-I05-S01; OA049-I05-S00; OA050-I05-S00; OA051-I00-S00; OA052-I00-S00; OA053-I06-S00; OA054-I06-S00; OA055-I06-S00; OA056-I00-S00; OA057-I00-S00; OA058-I00-S00; OA059-I07-S00; OA060-I07-S00; OA061-I07-S00; OA062-I00-S00; OA063-I08-S00; OA063-I08-S01; OA064-I08-S00; OA065-I00-S00; OA066-I09-S00; OA067-I09-S00; OA068-I10-S00; OA069-I10-S00; OA070-I10-S00; OA071-I10-S00; OA072-I11-S00; OA073-I11-S00; OA074-I11-S00; OA075-I12-S00; OA076-I12-S00; OA076-I12-S01; OA077-I12-S00; OA078-I00-S00; OA079-I00-S00; OA080-I13-S00; OA081-I13-S00; OA082-I13-S00; OA083-I13-S00; OA084-I00-S00; OA085-I00-S00; OA086-I00-S00; OA087-I00-S00; OA088-I00-S00; OA089-I14-S00; OA090-I14-S00; OA091-I14-S00; OA092-I15-S00; OA093-I15-S00; OA094-I00-S00; OA095-I00-S00; OA095-I16-S00; OA096-I00-S00; OA097-I00-S00; OA098-I00-S00; OA099-I00-S00; OA100-I00-S00; OA101-I00-S00; OA102-I00-S00; OA103-I00-S00; OA104-I00-S00; OA105-I00-S00; OA106-I00-S00; OA107-I00-S00; OA108-I00-S00; OA109-I00-S00; OA110-I00-S00; OA111-I00-S00; OA112-I00-S00; OA113-I00-S00; OA114-I00-S00; OA115-I00-S00; OA116-I00-S00; OA117-I00-S00; OA118-I00-S00; OA119-I00-S00; OA120-I00-S00; OA121-I00-S00; OA122-I00-S00; OA123-I00-S00; OA124-I00-S00; OA125-I00-S00; OA126-I00-S00; OA127-I18-S00; OA128-I18-S00; OA129-I18-S00; OA130-I18-S00; OA131-I00-S00; OA132-I00-S00; OA133-I00-S00; OA134-I00-S00; OA135-I00-S00; OA136-I00-S00; OA137-I00-S00; OA138-I00-S00; OA139-I00-S00; OA140-I19-S00; OA141-I19-S00; OA142-I19-S00; OA143-I19-S00; OA144-I00-S00; OA145-I00-S00; OA145-I20-S00; OA146-I20-S00; OA147-I00-S00; OA148-I21-S00; OA149-I21-S00; OA150-I00-S00; OA151-I00-S00; OA152-I00-S00; OA153-I00-S00; OA154-I00-S00; OA155-I22-S00; OA156-I23-S00; OA157-I23-S00; OA158-I23-S00; OA159-I23-S00; OA160-I24-S00; OA161-I24-S00; OA162-I24-S00; OA163-I00-S00; OA164-I00-S00; OA165-I00-S00; OA166-I25-S00; OA167-I26-S00; OA168-I26-S00; OA169-I00-S00; OA170-I27-S00; OA171-I27-S00; OA172-I28-S00; OA173-I00-S00; OA174-I00-S00; OA175-I00-S00; OA176-I00-S00; OA177-I00-S00; OA178-I00-S00; OA179-I00-S00; OA180-I00-S00; OA181-I00-S00; OA182-I00-S00; OA183-I00-S00; OA184-I00-S00; OA185-I00-S00; OA186-I00-S00; OA187-I00-S00; OA188-I00-S00; OA189-I00-S00; OA190-I29-S00; OA191-I29-S00; OA192-I00-S00; OA193-I00-S00; OA194-I00-S00; OA195-I00-S00; OA196-I00-S00; OA197-I00-S00; OA198-I00-S00; OA199-I00-S00; OA200-I00-S00; OA201-I00-S00; OA202-I00-S00; OA203-I00-S00; OA204-I00-S00; OA205-I00-S00; OA206-I00-S00; OA207-I00-S00; OA208-I00-S00; OA209-I00-S00; OA210-I00-S00; OA211-I00-S00; OA212-I00-S00; OA213-I00-S00; OA214-I00-S00; OA216-I30-S00; OA217-I00-S00; OA218-I00-S00; OA220-I31-S00; OA221-I31-S00; OA222-I00-S00; OA223-I00-S00; OA224-I00-S00; OA225-I00-S00; OA226-I00-S00; OA227-I00-S00; OA228-I00-S00; OA229-I00-S00; OA230-I32-S00; OA232-I32-S00; OA233-I00-S00; OA234-I00-S00; OA235-I00-S00; OA236-I00-S00; OA237-I00-S00; OA238-I00-S00; OA239-I00-S00; OA240-I00-S00; OA241-I00-S00; OA242-I00-S00; OA243-I00-S00; OA244-I00-S00; OA245-I00-S00; OA246-I00-S00; OA247-I00-S00; OA249-I00-S00; Pacific; Reference/source; Salinity; Sample code/label; Sample comment; Sampling date; SCUBA-3X10; SCUBA-CORER; SCUBA-NET-20; SCUBA-PUMP; SCUBA-SURVEY; SNORKLE-SPEAR; Speed; stanopump-UBAT; SV Tara; TARA_20160528T1915Z_ND_O-ATM_MAST-PUMP; TARA_20160529T0725Z_D_O-SRF_HSN-NET-300; TARA_20160529T1513Z_D_O-SRF_DOLPHIN-CARBOY; TARA_20160529T1543Z_D_O-SRF_DOLPHIN-
    Type: Dataset
    Format: text/tab-separated-values, 75470 data points
    Location Call Number Expected Availability
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    DATA PANGAEA
  • 20
    facet.materialart.
    Unknown
    Three Prochlorococcus cyanophage genomes : signature features and ecological interpretations (2005)
    Public Library of Science (PLoS)
    Details
    Publication Date: 2022-05-25
    Description: © 2005 Sullivan et al. This is an open-access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited. The definitive version was published in PLoS Biology 3 (2005): e144, doi:10.1371/journal.pbio.0030144.
    Description: The oceanic cyanobacteria Prochlorococcus are globally important, ecologically diverse primary producers. It is thought that their viruses (phages) mediate population sizes and affect the evolutionary trajectories of their hosts. Here we present an analysis of genomes from three Prochlorococcus phages: a podovirus and two myoviruses. The morphology, overall genome features, and gene content of these phages suggest that they are quite similar to T7-like (P-SSP7) and T4-like (P-SSM2 and P-SSM4) phages. Using the existing phage taxonomic framework as a guideline, we examined genome sequences to establish ‘‘core’’ genes for each phage group. We found the podovirus contained 15 of 26 core T7-like genes and the two myoviruses contained 43 and 42 of 75 core T4-like genes. In addition to these core genes, each genome contains a significant number of ‘‘cyanobacterial’’ genes, i.e., genes with significant best BLAST hits to genes found in cyanobacteria. Some of these, we speculate, represent ‘‘signature’’ cyanophage genes. For example, all three phage genomes contain photosynthetic genes (psbA, hliP) that are thought to help maintain host photosynthetic activity during infection, as well as an aldolase family gene (talC) that could facilitate alternative routes of carbon metabolism during infection. The podovirus genome also contains an integrase gene (int) and other features that suggest it is capable of integrating into its host. If indeed it is, this would be unprecedented among cultured T7-like phages or marine cyanophages and would have significant evolutionary and ecological implications for phage and host. Further, both myoviruses contain phosphate-inducible genes (phoH and pstS) that are likely to be important for phage and host responses to phosphate stress, a commonly limiting nutrient in marine systems. Thus, these marine cyanophages appear to be variations of two well-known phages—T7 and T4—but contain genes that, if functional, reflect adaptations for infection of photosynthetic hosts in low-nutrient oceanic environments.
    Description: This research was supported by the US DOE under grant numbers DEFG02– 99ER62814 and DE-FG02–02ER63445, and the National Science Foundation under grant number OCE-9820035 (to SWC).
    Keywords: Oceanic cyanobacteria ; Prochlorococcus phages
    Repository Name: Woods Hole Open Access Server
    Type: Article
    Format: 696275 bytes
    Format: application/pdf
    Location Call Number Expected Availability
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    PAPER (OA)
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