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W2893866342 startingPage "103122" @default.
W2893866342 abstract "The upwelling system of coastal Peru supports very high primary production, contributing to an oxygen deficient zone (ODZ) in subsurface waters and high organic matter deposition rates to underlying sediments. Although anammox and denitrification have been relatively well studied in ODZ waters, few studies have investigated these processes in the underlying sediments. We sampled seven stations over a large geographic area along the Peru margin, spanning a water depth of 100–3240 m. At two of the central shelf stations (100 m and 325 m), we observed Thioploca, with a well-developed mat at the shallowest station (100 m). We measured sediment properties and conducted shipboard 15N-incubations of homogenized sediments to determine potential rates of anammox and denitrification and potential controlling factors at each station. Diversity of anammox bacteria based on 16S rRNA and hydrazine oxidoreductase (hzo) sequences and hzo gene abundances were measured at each station. Overall, organic C content was high across the stations (3–12%), except for two of the deepest stations (~1.5%). Porewater ammonium fluxes and ammonium production rates in shipboard incubations, reflecting sediment organic carbon decomposition rates, were higher at the two central shelf stations compared to the other stations. The range in average potential rates was 2.1–80.4 nmol N cm−3 h−1 for denitrification and 1.8–44.2 nmol N cm−3 h−1 for anammox. The range in relative anammox (ra) across stations was 2.6–47.4%, with an average of 34.2%. The lowest ra was found at the shallowest shelf station with Thioploca mats and highest ammonium production rates. The ra jumped up to 45.9% at the station with the next highest ammonium production rates, corresponding to the deeper shelf station (325 m). At the other stations, ra was relatively high (39.6–47.4%), except at one station (16.3%), reflecting similar ammonium production rates due to decomposition across these stations. Anammox bacteria in the Candidatus Scalindua genus were the only anammox bacteria detected in Peru margin sediments based on 16S rRNA or hzo sequences. Copy number of hzo indicated abundant populations of anammox bacteria across the stations. However, hzo copy number did not correlate with anammox rates or ra. Overall, our results suggest that anammox contributes significantly to N2 production in Peru margin sediments, except in shelf sediments with high decomposition rates and dense Thioploca mats." @default.
W2893866342 created "2018-10-05" @default.
W2893866342 creator A5006282712 @default.
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W2893866342 date "2020-07-01" @default.
W2893866342 modified "2023-10-14" @default.
W2893866342 title "Anaerobic ammonium oxidation (anammox) and denitrification in Peru margin sediments" @default.
W2893866342 cites W1973544948 @default.
W2893866342 cites W1974287206 @default.
W2893866342 cites W1974361251 @default.
W2893866342 cites W1976584214 @default.
W2893866342 cites W1987121947 @default.
W2893866342 cites W1988222250 @default.
W2893866342 cites W1988925586 @default.
W2893866342 cites W1990166027 @default.
W2893866342 cites W1992942714 @default.
W2893866342 cites W1998850108 @default.
W2893866342 cites W2003402084 @default.
W2893866342 cites W2006786201 @default.
W2893866342 cites W2015154377 @default.
W2893866342 cites W2019276355 @default.
W2893866342 cites W2020332695 @default.
W2893866342 cites W2024177900 @default.
W2893866342 cites W2024417244 @default.
W2893866342 cites W2027318176 @default.
W2893866342 cites W2030376069 @default.
W2893866342 cites W2031571844 @default.
W2893866342 cites W2038281478 @default.
W2893866342 cites W2038660069 @default.
W2893866342 cites W2043612119 @default.
W2893866342 cites W2043840544 @default.
W2893866342 cites W2053609212 @default.
W2893866342 cites W2063656463 @default.
W2893866342 cites W2064573290 @default.
W2893866342 cites W2067790594 @default.
W2893866342 cites W2078956978 @default.
W2893866342 cites W2079257271 @default.
W2893866342 cites W2080460132 @default.
W2893866342 cites W2085166727 @default.
W2893866342 cites W2091292030 @default.
W2893866342 cites W2095632391 @default.
W2893866342 cites W2098915896 @default.
W2893866342 cites W2103067093 @default.
W2893866342 cites W2106143747 @default.
W2893866342 cites W2107087564 @default.
W2893866342 cites W2107650081 @default.
W2893866342 cites W2108718991 @default.
W2893866342 cites W2109815174 @default.
W2893866342 cites W2111211467 @default.
W2893866342 cites W2113105984 @default.
W2893866342 cites W2113787585 @default.
W2893866342 cites W2122571325 @default.
W2893866342 cites W2122920295 @default.
W2893866342 cites W2130020323 @default.
W2893866342 cites W2131692818 @default.
W2893866342 cites W2134047111 @default.
W2893866342 cites W2134878076 @default.
W2893866342 cites W2142462683 @default.
W2893866342 cites W2144794843 @default.
W2893866342 cites W2146759684 @default.
W2893866342 cites W2149352713 @default.
W2893866342 cites W2153247902 @default.
W2893866342 cites W2156356956 @default.
W2893866342 cites W2156933485 @default.
W2893866342 cites W2162485441 @default.
W2893866342 cites W2165093440 @default.
W2893866342 cites W2165245600 @default.
W2893866342 cites W2166617844 @default.
W2893866342 cites W2171070596 @default.
W2893866342 cites W2171437724 @default.
W2893866342 cites W2171761799 @default.
W2893866342 cites W2294573506 @default.
W2893866342 cites W2315619525 @default.
W2893866342 cites W2485417437 @default.
W2893866342 cites W2515651900 @default.
W2893866342 cites W2522844119 @default.
W2893866342 cites W4238820525 @default.
W2893866342 cites W4240376155 @default.
W2893866342 doi "https://doi.org/10.1016/j.jmarsys.2018.09.007" @default.
W2893866342 hasPublicationYear "2020" @default.
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