Stable isotopes reveal the importance of terrestrially derived resources for the diet of the freshwater pearl mussel (Margaritifera margaritifera)

1. The freshwater pearl mussel (FPM) is among the most endangered freshwater species worldwide. The few remaining populations suffer from low recruitment rates and are subject to habitat fragmentation, pollution, siltation, decline or loss of host fish populations, and climate change.
2. Successful conservation strategies for FPM require a holistic understanding of its ecological requirements, life history, population dynamics, and habitat prerequisites. Although habitat requirements are well described, food requirements at different life stages have received less attention.
3. Stable isotope analyses of FPM and potential food resources in three German streams were combined with mixing model analysis to quantify organic matter resources assimilated by juvenile (first year after encystment from host fish) and semi-adult (10 years old, immature) individuals.
4. There were only slight differences in dietary contributions between the two life stages, and terrestrial particulate organic matter and benthic organic matter contributed substantially to the diet. Tissue type was more important in explaining variation in dietary contributions than individual variation for semi-adult FPM. The strong reliance on terrestrial resources sheds new light on the functional role of unionid mussels and the connection of streams to their riparian area.
5. The dependence of FPM on terrestrial resources also emphasizes the need for a stronger focus on the restoration and protection of intact riparian areas, including wetlands with their specific vegetation, when planning conservation and management strategies for threatened FPM populations.

     

Derivation of site-related measures to minimise soil erosion on the watershed scale in the Saxonian loess belt using the model EROSION 3D

The Saxonian loess belt is one of the areas in Germany most endangered by water erosion. As consequence of extreme rainstorms, farmland and adjacent areas, e.g. villages, roads, biotopes and watercourses, are repeatedly damaged. Estimating soil loss is a crucial factor for sustainable land use planning in this region. Since soil erosion measurements are usually conducted at the scale of plots, thereby being both costly as well as time-consuming, erosion models are substantial tools for soil protection policies. This paper summarises and integrates the results of a research project aimed at assessing the present situation as well as that of future landscape planning alternatives, using the physically based EROSION 3D simulation model on a catchment scale. EROSION 3D can estimate the yields of sediment for small watersheds and enables environmental researchers and planners to locate the main areas of soil loss and deposition. Five different scenarios based on past and present land use information as well as future landscape 2 planning alternatives were simulated.The modelling results showed that scenarios based on only one option for minimising soil loss were not sufficiently effective in reducing sediment production. However, the combination of active soil protection measures such as conservation tillage with passive measures like grassed waterways or buffer strips resulted in an adequate soil protection. In contrast to passive protection measures, best management practices like non-tillage systems are commonly used in the Saxonian loess belt already. Thus, the implementation of passive measures is an important future task in land use planning. Simulation models like EROSION 3D can provide the information needed for the adequate localisation and the dimensioning of site-specific measures.