Nutrient dynamics and primary production in a pristine coastal mangrove ecosystem: Andaman Islands, India

Mangrove ecosystems play a key role in supporting coastal food webs and nutrient cycles in the coastal zone. Their strategic position between the land and the sea make them important sites for land-ocean interaction. As part of an Indo-US summer field course we investigated changes in the water chemistry in a pristine mangrove creek located at Wright Myo in the Andaman Islands, India. This study was conducted during the wet season (June 2012) to evaluate the influence of the coastal mangrove wetlands on the water quality and productivity in adjoining pelagic waters. Over a full tidal cycle spanning approximately 24 hrs, we measured nutrient concentrations and other ancillary parameters (e.g. dissolved oxygen, turbidity, salinity, etc.) hourly to evaluate water quality changes in incoming and ebbing tides. Nutrient analyses had the following concentration ranges (μM): nitrite 0.2-0.9, nitrate 2.0-11.5, ammonium 1.3-7.5, dissolved inorganic phosphate 0.7-2.8. The dissolved inorganic nitrogen to dissolved inorganic phosphate (DIN/DIP) ratio was very low relative to an optimal ratio, suggesting growth is nitrogen limited. In addition, we conducted primary production assays to investigate the factors that controlled primary production in this pristine creek. The experiment was carried out in situ using the Winkler method at low and high tide. Four-hour incubation of light and dark bottles representing a fixed control, non-fertilized, fertilized with nitrate, and fertilized with phosphate enabled the measurement of both net oxygen production and dark respiration. The low tide experiment suggests the ecosystem is heterotrophic because the oxygen measured in the light bottles was consistently less than that of the dark bottles. This result may be an experimental artifact of placing the glass bottles in the sun for too long prior to incubation, potentially leading to photolysis of large organic molecules in the light bottles. The high tide experiment also displayed counterintuitive results because less oxygen was produced with nutrient addition relative to the unfertilized samples. Furthermore, community respiration increased slightly in the presence of nitrogen (N) but increased more so in the presence of phosphorus (P), indicating P limits respiration. N and P did not stimulate production but did stimulate consumption. Despite the low DIN/DIP ratio suggesting a N limitation in the system, N addition failed to stimulate primary production. Production at Wright Myo creek is therefore not limited by nutrients but is controlled by other conditions, possibly by a rain flushing event that occurred prior to the high tide primary production experiment or by light availability. Because light must be able to penetrate through the water column to drive photosynthesis, low light availability and high turbidity may have limited production.