|Size and shape of ocean margin nematodes: morphological diversity and depth-related patterns|
Soetaert, K.; Muthumbi, A.; Heip, C.H.R. (2002). Size and shape of ocean margin nematodes: morphological diversity and depth-related patterns, in: (2002). VLIZ Coll. Rep. 32(2002). VLIZ Collected Reprints: Marine and Coastal Research in Flanders, 32: pp. chapter 39
In: (2002). VLIZ Coll. Rep. 32(2002). VLIZ Collected Reprints: Marine and Coastal Research in Flanders, 32. Flanders Marine Institute (VLIZ): Oostende, more
In: VLIZ Collected Reprints: Marine and Coastal Research in Flanders. Vlaams Instituut voor de Zee: Oostende. ISSN 1376-3822, more
|Also published as |
- Soetaert, K.; Muthumbi, A.; Heip, C.H.R. (2002). Size and shape of ocean margin nematodes: morphological diversity and depth-related patterns. Mar. Ecol. Prog. Ser. 242: 179-193, more
Abundance; Animal morphology; Biogeochemistry; Body size; Dissolved oxygen; Dry weight; Literature reviews; Porosity; Sediment analysis; Vertical distribution; Nematoda [WoRMS]; ANE, Spain, Galicia [Marine Regions]; Marine
We studied the composition and variation of nematode body size as a function of nematode depth in the sediment and water depth at 18 stations, ranging from 137 to 4951 m depth, along the Galician margin (NE Atlantic). The analysis is based on more than 10000 individuals and demonstrates that nematodes have adapted mainly in response to the vertical changing conditions in the sediment. Nematode length and width are similar in the upper 0.5 cm of sediment at all stations, but differ greatly as their depth in the sediment increases. The observed trends are consistent with an adaptation to changing oxygen concentrations in the sediments. In lower slope and abyssal plain stations, oxygen decreases gradually until depletion at about 5 cm depth, and nematode body width decreases concurrently, resulting in higher oxygen absorption efficiency per unit of volume. On the shelf and in the canyons, sediments become anoxic at short distances below the sediment-water interface, and more than 50% of the nematodes are present in the anoxic part of the sediment. Here, mean nematode length increases as their depth in the sediment increases. This may result in increased mobility, which enables the organisms to migrate between anoxic patches of food and parts of the sediment where oxygen is available and/or the ability to bridge the gap between oxic and anoxic patches with their body. Order of magnitude calculation shows that in shelf sediments, the chemosynthetic bacterial production, which accompanies the oxidation of reduced substances, can not fulfill the feeding requirements of nematodes in the anoxic zone. The different size adaptations with sediment depth in shallow as compared to deep stations combined with deeper penetration of nematodes into the sediment at shallow water depth cause the observed pattern of miniaturization with increasing water depth. We conclude that nematode size distribution is determined by food availability. However, organic matter, as a food source, is not directly responsible, as a limiting resource, but indirectly because its respiration generates reduced conditions in the sediment. Within the smaller size range (<500 µm length), there are 2 clearly distinct morphological types, which, to a certain extent, impart a taxonomic division. Similar findings at other localities suggest that this is a common feature of nematodes from ocean margin areas. One group consists of corpulent nematodes, which are less than 15 times as long as wide; most prominent in this group are members of the order of the Desmoscolecida. The other group contains significantly more slender nematodes and comprises a large variety of nematode taxa. We hypothesize that this duality in nematode design reflects an ecological adaptation designed to meet the conflicting requirements of either increased mobility (slender) or reduced vulnerability to predation (corpulent) at these small sizes.