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Quantitative food web modeling unravels the importance of the microphytobenthos-meiofauna pathway for a high trophic transfer by meiofauna in soft-bottom intertidal food webs

Artikel i vetenskaplig tidskrift
Författare L. H. van Der Heijden
N. Niquil
Matilda Haraldsson
R. M. Asmus
S. R. Pacella
M. Graeve
J. Rzeznik-Orignac
H. Asmus
B. Saint-Beat
B. Lebreton
Publicerad i Ecological Modelling
Volym 430
ISSN 0304-3800
Publiceringsår 2020
Publicerad vid Institutionen för marina vetenskaper
Språk en
Länkar dx.doi.org/10.1016/j.ecolmodel.2020...
Ämnesord food web model, linear inverse model, meiofauna, microphytobenthos, stable isotope mixing models, intertidal habitats, marennes-oleron bay, sylt-romo bight, brouage mudflat, energy-flow, spatiotemporal structure, ecosystem attributes, nematode community, feeding ecology, aiguillon cove, seagrass beds, Environmental Sciences & Ecology
Ämneskategorier Geovetenskap och miljövetenskap

Sammanfattning

Meiofauna are known to have an important role on many ecological processes, although, their role in food web dynamics is often poorly understood, partially as they have been an overlooked and under sampled organism group. Here, we used quantitative food web modeling to evaluate the trophic relationship between meiofauna and their food sources and how meiofauna can mediate the carbon flow to higher trophic levels in five contrasting soft-bottom intertidal habitats (including seagrass beds, mudflats and sandflats). Carbon flow networks were constructed using the linear inverse model-Markov chain Monte Carlo technique, with increased resolution of the meiofauna compartments (i.e. biomass and feeding ecology of the different trophic groups of meiofauna) compared to most previous modeling studies. These models highlighted that the flows between the highly productive microphytobenthos and the meiofauna compartments play an important role in transferring carbon to the higher trophic levels, typically more efficiently so than macrofauna. The pathway from microphytobenthos to meiofauna represented the largest flow in all habitats and resulted in high production of meiofauna independent of habitat. All trophic groups of meiofauna, except for selective deposit feeders, had a very high dependency on microphytobenthos. Selective deposit feeders relied instead on a wider range of food sources, with varying contributions of bacteria, microphytobenthos and sediment organic matter. Ecological network analyses (e.g. cycling, throughput and ascendency) of the modeled systems highlighted the close positive relationship between the food web efficiency and the assimilation of high-quality food sources by primary consumers, e.g. meiofauna and macrofauna. Large proportions of these flows can be attributed to trophic groups of meiofauna. The sensitivity of the network properties to the representation of meiofauna in the models leads to recommending a greater attention in ecological data monitoring and integrating meiofauna into food web models.

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