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Transporting Biodiversity Using Transmission Power Lines as Stepping-Stones

The most common ecological response to climate change is the shifts in species distribution ranges. Nevertheless, landscape fragmentation compromises the ability of limited dispersal species to move following these climate changes. Building connected environments that enable species to track climate changes is an ultimate goal for biodiversity conservation. An experiment was conducted to determine if electric power transmission lines could be transformed in a continental network of biodiversity reserves for small animals. The study analysed if the management of the habitat located inside the base of the transmission electric towers (providing refuge and planting seedlings of native shrub) allowed to increase local richness of target species (i.e., small mammals and some invertebrates' groups). The results confirmed that by modifying the base of the electric transmission towers density and diversity of several species of invertebrates and small mammals increased as well as number of birds and bird species, increasing local biodiversity. The study suggests that modifying the base of the electric towers would potentially facilitate the connection of fragmented populations. This idea would be easily applicable in any transmission line network anywhere around the world, making it possible for the first time to build up continental scale networks of connectivity. informacion[at] Ferrer et al (2020) Transporting Biodiversity Using Transmission Power Lines as Stepping-Stones? Diversity 12(11): 439;

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Determination of anthropogenic contamination in surface waters using helophytes

Determination of anthropogenic contamination in surface waters using helophytes

Nitrogen (N) loading from anthropogenic activities is contributing to the eutrophication and degradation of wetlands worldwide. Doñana (southwestern Spain), includes a dynamic marshland protected as a UNESCO World Heritage Site, which has a catchment area exposed to increasing N inputs from intensive agriculture and poorly treated urban wastewaters. Identifying the sources of N entering this iconic wetland complex is vital for its conservation. To this end, multiyear (2014–2016), spatially-explicit data on N concentration in water samples were combined with measurements on the relative abundance of N stable isotopes (d15N) in Bolboschoenus maritimus and Typha domingensis, two dominant helophytes (i.e. emergent macrophytes) in the Doñana marsh and entry streams. Overall, plant tissues from entry streams showed higher d15N values than those from the marsh, particularly in those streams most affected by urban wastewaters. Isotopic values did not differ between plant species. Water samples affected by isotopically-enriched urban wastewaters and other diffuse organic N inputs (e.g. livestock farming) had relatively high Dissolved Inorganic Nitrogen (DIN) concentrations. In contrast, in streams mainly affected by diffuse N pollution from greenhouse crops, high DIN values were related to isotopically-depleted N sources (e.g., inorganic fertilizers). Thus, helophytes, in combination with other parameters such as N concentration in water or land cover, can be valuable indicators of anthropogenic pressures in Mediterranean wetlands. Helophytes have widespread distributions, and can be readily sampled even when water is no longer present. However, identification of specific N sources through helophyte d15N values is limited when key potential N sources are isotopically undistinguishable (e.g. fertilizers vs. atmospheric sources). informacion[at] Paredes et al (2019) Stable isotopes in helophytes reflect anthropogenic nitrogen pollution in entry streams at the Doñana World Heritage Site. Ecol Indicators 97: 130-140. Doi 10.1016/j.ecolind.2018.10.0009