AI Article Synopsis
- Marine sediments contribute significantly to nitrogen loss in coastal areas, primarily through a process called sedimentary denitrification, which affects the global nitrogen budget.
- A study analyzed the diversity of nitrite reductase (nirS) genes from Gulf of Mexico sediments at different depths, showing a decrease in nitrate and oxygen levels, as well as a decline in denitrifying bacteria diversity with greater depth.
- Community structure changes were more pronounced between shallow (oxic) and deep (anoxic) sediments, with deeper layers showing a shift in dominant nirS sequences likely due to nutrient availability, and many recovered sequences being genetically distinct from known denitrifying bacteria.
Article Abstract
Marine sediments account for up to 66% of the loss of nitrogen load to coastal areas. Sedimentary denitrification is the main sink for fixed nitrogen in the global nitrogen budget, and thus it is important to understand the structure and composition of denitrifying communities. To understand the structure and composition of denitrifying communities, the diversity of nitrite reductase (nirS) genes from sediments along the Gulf of Mexico was examined using a PCR-based cloning approach. Sediments were collected at three different depths (0-0.5, 4-5 and 19-21 cm). Geochemical analysis revealed decreasing nitrate and oxygen concentrations with increasing sediment depth. This trend coincided with the decrease in diversity of denitrifying bacteria. LIBSHUFF analysis indicated that the clone library in the shallowest sediment (depth, 0-0.5 cm) was significantly different from that in the deepest sediment (depth, 19-21 cm), and that the deeper sediments (depths of 4-5 and 19-21 cm) were significantly similar. Community structural shifts were evident between the shallowest (oxic zone) and deepest (anoxic zone) sediments. Community changes within the deepest sediments were more subtle, with the presence of different nirS clone sequences gradually becoming dominant or, alternatively, decreasing with depth. The changes in community structure at this depth are possibly driven by nutrient availability, with lower quality sources of carbon and energy leading to the disappearance of nirS sequences common in the top layer. The majority of recovered nirS sequences were phylogenetically divergent relative to known denitrifying bacteria in the database.
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| http://dx.doi.org/10.1111/j.1574-6941.2006.00173.x | DOI Listing |
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