Abstract
Copepod carcasses are prevalent in marine ecosystems and might represent an important component of the sinking flux of particulate organic carbon in the ocean. The extent to which copepod carcasses contribute to the biological carbon pump is controlled by different environmental factors, including temperature. However, the effect of temperature on the longer-term kinetics of carbon mineralization of copepod carcasses is not well-studied. We conducted laboratory experiments to quantify the carbon mineralization associated with sinking carcasses of the cosmopolitan copepod Acartia tonsa through aerobic microbial respiration at 5 temperatures (20, 16, 12, 8, and 4°C). Microbial respiration rates associated with the carcasses were positively correlated with temperature and characterized by an initial short lag-phase, a rapid increase to a maximum rate, and a subsequent gradual decline in the rate of degradation. On average, 50% of the total carbon of the carcasses was mineralized within 6-12 d at 20°C, versus >60 d at 4°C. During the incubations, most carbon mineralization occurred in the ambient seawater, likely fueled by dissolved organic carbon leaking from the carcasses into the surrounding seawater. Extrapolating measured carbon turnover and sinking rates suggests that at 20°C, the mineralization of sinking copepod carcasses is constrained to the surface ocean. In contrast, at 4°C, sinking copepod carcasses can reach the deep ocean before they have been completely degraded. Hence, in low-temperature regions, copepod carcasses may represent an important agent for carbon export through the biological carbon pump.
Highlights
The biological carbon pump mediates the vertical transport of organic material from the surface to the deep ocean, contributing to marine carbon sequestration (Turner 2015, Guidi et al 2016)
The objectives of this study were to (1) define a killing method for producing copepod carcasses with minimal effects on the performance of carcassattached bacteria, (2) quantify the effect of temperature on the mineralization of sinking copepod carcasses via aerobic microbial respiration, and (3) estimate the amount of particulate organic carbon (POC) which can be exported from the euphotic zone to deeper waters, using the cosmopolitan copepod Acartia tonsa as a model organism; based on our results, the potential quantitative contribution of copepod carcasses to the biological carbon pump is discussed
The anoxia treatment resulted in the highest respiration rates; more than 5-fold higher than the lowest rates measured for the acetic acid treatment
Summary
The biological carbon pump mediates the vertical transport of organic material from the surface to the deep ocean, contributing to marine carbon sequestration (Turner 2015, Guidi et al 2016). The efficiency of the pump to large extent depends on the abundance and composition of the plankton community in the surface water, and the mineralization of sinking particulate organic carbon (POC) during sinking towards deeper waters (Turner 2015). 25−33% of copepod mortality is due to non-predatory factors (Hirst & Kiørboe 2002), producing carcasses which sink through the water column while being degraded by microorganisms. The fate of copepod carcasses will depend on different biological and physical factors affecting their degradation and sinking rates
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