On the basis of LM and SEM observations as well as of environmental claw, three species of the predominantly-acidophilous diatom genus Eunotia (E. cisalpina, E. fallacoides, E. insubrica) are described as new to science, and characterized from the ecological point of view. The three new species were not distinguished from other similar ones in the past hut can be identified at the LM by careful observation of diacritical characters such as valve outline (in particular the shape of the endings). dimensions, and stria density. One of the three new species (E. insubrica) presents a very peculiar ultrastructural feature. i.e. well-developed pseudoseptum-like structures at the apices. The three new species were pointed out by detailed analyses of materials sampled in the south-eastern Alps. It is put forward that diatom investigations adopting high-resolution taxonomy are particularly opportune in habitats such as those colonized by the three new species. The three new species were found to be characteristic of low-alkalinity, naturally slightly-acidic, strictly-oligotrophic, high-mountain springs and lakes. Efficient desiccation-resistance strategies, apparently widespread in the genus Eunotia, might be supposed also far the three new species, that were found to thrive also in low-discharge springs and in the shallow littoral waters of lakes showing seasonal or exploitation-enhanced water-level fluctuations. The diatom assemblages of these aquatic habitats possess a high species richness, and include many rare and Red List species, and are thus of prominent importance for diatom biodiversity, conservation. These relatively-pristine aquatic habitats on siliceous bedrocks are however highly sensitive, and endangered because of diffuse pollution. Climate- and environmental-change driven increased release of organic acids, and contamination by airborne inorganic acids and nutrients are all potential threats to these still high-integrity but fragile systems. The detailed characterization of their diatom assemblages, that are excellent monitors of acid-base and nutrient status is thus of the foremost importance. In particular the distinction between naturally-acidic and acidified systems is a relevant topic that might benefit from detailed knowledge of taxonomy and ecology of both communities and indicative taxa of the diatom assemblages.
Diatom monitors of close-to-pristine, very-low alkalinity habitats: three new Eunotia species from springs in Nature Parks of the south-eastern Alps
2011
Abstract
On the basis of LM and SEM observations as well as of environmental claw, three species of the predominantly-acidophilous diatom genus Eunotia (E. cisalpina, E. fallacoides, E. insubrica) are described as new to science, and characterized from the ecological point of view. The three new species were not distinguished from other similar ones in the past hut can be identified at the LM by careful observation of diacritical characters such as valve outline (in particular the shape of the endings). dimensions, and stria density. One of the three new species (E. insubrica) presents a very peculiar ultrastructural feature. i.e. well-developed pseudoseptum-like structures at the apices. The three new species were pointed out by detailed analyses of materials sampled in the south-eastern Alps. It is put forward that diatom investigations adopting high-resolution taxonomy are particularly opportune in habitats such as those colonized by the three new species. The three new species were found to be characteristic of low-alkalinity, naturally slightly-acidic, strictly-oligotrophic, high-mountain springs and lakes. Efficient desiccation-resistance strategies, apparently widespread in the genus Eunotia, might be supposed also far the three new species, that were found to thrive also in low-discharge springs and in the shallow littoral waters of lakes showing seasonal or exploitation-enhanced water-level fluctuations. The diatom assemblages of these aquatic habitats possess a high species richness, and include many rare and Red List species, and are thus of prominent importance for diatom biodiversity, conservation. These relatively-pristine aquatic habitats on siliceous bedrocks are however highly sensitive, and endangered because of diffuse pollution. Climate- and environmental-change driven increased release of organic acids, and contamination by airborne inorganic acids and nutrients are all potential threats to these still high-integrity but fragile systems. The detailed characterization of their diatom assemblages, that are excellent monitors of acid-base and nutrient status is thus of the foremost importance. In particular the distinction between naturally-acidic and acidified systems is a relevant topic that might benefit from detailed knowledge of taxonomy and ecology of both communities and indicative taxa of the diatom assemblages.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.