Eric J. Raes scite author profile

Marine microbes along with microeukaryotes are key regulators of oceanic biogeochemical pathways. Here we present a high-resolution (every 0.5° of latitude) dataset describing microbial pro- and eukaryotic richness in the surface and just below the thermocline along a 7,000-km transect from 66°S at the Antarctic ice edge to the equator in the South Pacific Ocean. The transect, conducted in austral winter, covered key oceanographic features including crossing of the polar front (PF), the subtropical front (STF), and the equatorial upwelling region. Our data indicate that temperature does not determine patterns of marine microbial richness, complementing the global model data from Ladau et al. [Ladau J, et al. (2013) ISME J 7:1669-1677]. Rather, NH, nanophytoplankton, and primary productivity were the main drivers for archaeal and bacterial richness. Eukaryote richness was highest in the least-productive ocean region, the tropical oligotrophic province. We also observed a unique diversity pattern in the South Pacific Ocean: a regional increase in archaeal and bacterial diversity between 10°S and the equator. Rapoport's rule describes the tendency for the latitudinal ranges of species to increase with latitude. Our data showed that the mean latitudinal ranges of archaea and bacteria decreased with latitude. We show that permanent oceanographic features, such as the STF and the equatorial upwelling, can have a significant influence on both alpha-diversity and beta-diversity of pro- and eukaryotes.

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Changes in latitude and dominant diazotrophic community alter N2 fixation

Raes

Waite

McInnes

et al. 2014

Mar. Ecol. Prog. Ser.

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The contribution of planktonic diazotrophs to the overall N budget is a key unknown in the eastern Indian Ocean. Here we investigated the relationships between dissolved inorganic nutrients, phytoplankton pigment composition, microbial community structure, nitrogen fixation rates and the δ 15 N of fractionated zooplankton samples along the shelf break of Western Australia (32° to 12°S) in September 2012. Bulk nitrogen fixation rates declined from 4.8 nmol l −1 h −1 in the colder and more saline sub-tropical waters at higher latitudes to 1.5 nmol l −1 h −1 in the warmer and fresher Timor Sea at lower latitudes. A regional bloom of Trichodesmium was identified between 13° and 9°S in the Timor Sea. Trichodesmium-specific N 2 fixation rates were 0.05 ± 0.01 nmol colony −1 h −1. Highest dissolved inorganic nitrogen (DIN) concentrations occurred at the highest NH 4 + :NO 3 − ratios, thereby deviating from the paradigm that greater DIN concentrations come primarily from increased NO 3 − through advection, mixing or upwelling. Both the microplankton and nanoflagellate fraction declined significantly in warmer waters, with higher DIN concentrations but decreasing % NO 3 − . A clear increase in the prokaryotic diagnostic pigment zeaxanthin was seen with increasing temperatures from higher to lower latitudes. The microbial community, measured using automated ribosomal intergenic spacer analysis (ARISA), clustered strongly according to the water mass biogeochemistry including temperature, salinity, DIN and phosphate concentrations (p < 0.001). Isotope analysis suggested that injections of low δ 15 N from N 2 fixation lowered the zooplankton δ 15 N signature of animals up to ~500 µm in size and that nearly 47% of the fixed nitrogen was used by zooplankton (≤500 µm fraction) in the Timor Sea.

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Eric J. Raes

Oceanographic boundaries constrain microbial diversity gradients in the South Pacific Ocean

Changes in latitude and dominant diazotrophic community alter N2 fixation

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