TY - JOUR
T1 - The influence of light on nitrogen cycling and the primary nitrite maximum in a seasonally stratified sea
AU - Mackey, Katherine R.M.
AU - Bristow, Laura
AU - Parks, David R.
AU - Altabet, Mark A.
AU - Post, Anton F.
AU - Paytan, Adina
PY - 2011/12/1
Y1 - 2011/12/1
N2 - In the seasonally stratified Gulf of Aqaba Red Sea, both NO2- release by phytoplankton and NH4+ oxidation by nitrifying microbes contributed to the formation of a primary nitrite maximum (PNM) over different seasons and depths in the water column. In the winter and during the days immediately following spring stratification, NO2- formation was strongly correlated (R2=0.99) with decreasing irradiance and chlorophyll, suggesting that incomplete NO3- reduction by light limited phytoplankton was a major source of NO2-. However, as stratification progressed, NO2- continued to be generated below the euphotic depth by microbial NH4+ oxidation, likely due to differential photoinhibition of NH4+ and NO2- oxidizing populations. Natural abundance stable nitrogen isotope analyses revealed a decoupling of the δ15N and δ18O in the combined NO3- and NO2- pool, suggesting that assimilation and nitrification were co-occurring in surface waters. As stratification progressed, the δ15N of particulate N below the euphotic depth increased from -5‰ to up to +20‰.N uptake rates were also influenced by light; based on 15N tracer experiments, assimilation of NO3-, NO2-, and urea was more rapid in the light (434±24, 94±17, and 1194±48nmolNL-1day-1 respectively) than in the dark (58±14, 29±14, and 476±31nmolNL-1day-1 respectively). Dark NH4+ assimilation was 314±31nmolNL-1day-1, while light NH4+ assimilation was much faster, resulting in complete consumption of the 15N spike in less than 7h from spike addition. The overall rate of coupled urea mineralization and NH4+ oxidation (14.1±7.6nmolNL-1day-1) was similar to that of NH4+ oxidation alone (16.4±8.1nmolNL-1day-1), suggesting that mineralization of labile dissolved organic N compounds like urea was not a rate limiting step for nitrification. Our results suggest that assimilation and nitrification compete for NH4+ and that N transformation rates throughout the water column are influenced by light over diel and seasonal cycles, allowing phytoplankton and nitrifying microbes to contribute jointly to PNM formation. We identify important factors that influence the N cycle throughout the year, including light intensity, substrate availability, and microbial community structure. These processes could be relevant to other regions worldwide where seasonal variability in mixing depth and stratification influence the contributions of phytoplankton and non-photosynthetic microbes to the N cycle.
AB - In the seasonally stratified Gulf of Aqaba Red Sea, both NO2- release by phytoplankton and NH4+ oxidation by nitrifying microbes contributed to the formation of a primary nitrite maximum (PNM) over different seasons and depths in the water column. In the winter and during the days immediately following spring stratification, NO2- formation was strongly correlated (R2=0.99) with decreasing irradiance and chlorophyll, suggesting that incomplete NO3- reduction by light limited phytoplankton was a major source of NO2-. However, as stratification progressed, NO2- continued to be generated below the euphotic depth by microbial NH4+ oxidation, likely due to differential photoinhibition of NH4+ and NO2- oxidizing populations. Natural abundance stable nitrogen isotope analyses revealed a decoupling of the δ15N and δ18O in the combined NO3- and NO2- pool, suggesting that assimilation and nitrification were co-occurring in surface waters. As stratification progressed, the δ15N of particulate N below the euphotic depth increased from -5‰ to up to +20‰.N uptake rates were also influenced by light; based on 15N tracer experiments, assimilation of NO3-, NO2-, and urea was more rapid in the light (434±24, 94±17, and 1194±48nmolNL-1day-1 respectively) than in the dark (58±14, 29±14, and 476±31nmolNL-1day-1 respectively). Dark NH4+ assimilation was 314±31nmolNL-1day-1, while light NH4+ assimilation was much faster, resulting in complete consumption of the 15N spike in less than 7h from spike addition. The overall rate of coupled urea mineralization and NH4+ oxidation (14.1±7.6nmolNL-1day-1) was similar to that of NH4+ oxidation alone (16.4±8.1nmolNL-1day-1), suggesting that mineralization of labile dissolved organic N compounds like urea was not a rate limiting step for nitrification. Our results suggest that assimilation and nitrification compete for NH4+ and that N transformation rates throughout the water column are influenced by light over diel and seasonal cycles, allowing phytoplankton and nitrifying microbes to contribute jointly to PNM formation. We identify important factors that influence the N cycle throughout the year, including light intensity, substrate availability, and microbial community structure. These processes could be relevant to other regions worldwide where seasonal variability in mixing depth and stratification influence the contributions of phytoplankton and non-photosynthetic microbes to the N cycle.
UR - http://www.scopus.com/inward/record.url?scp=81455131479&partnerID=8YFLogxK
U2 - 10.1016/j.pocean.2011.09.001
DO - 10.1016/j.pocean.2011.09.001
M3 - Article
AN - SCOPUS:81455131479
SN - 0079-6611
VL - 91
SP - 545
EP - 560
JO - Progress in Oceanography
JF - Progress in Oceanography
IS - 4
ER -