Your search keyword '"Spitale D."' showing total 6 results

1. Climate warming effects on epiphytes in spruce forests of the Alps

Author

Daniel Spitale, Pier Luigi Nimis, Petra Mair, Juri Nascimbene, Nascimbene, J., Nimis, P. L., Mair, P., Spitale, D., Nascimbene J., Nimis P.L., Mair P., and Spitale D.

Subjects

0106 biological sciences, 010504 meteorology & atmospheric sciences, Lichens, Range (biology), elevational gradients, Occurrence data, Lichen, 010603 evolutionary biology, 01 natural sciences, Single species, mountain areas, elevational gradient, Bryophytes, lichens, elevational gradients, species elevational shifts, mountain areas, South Tyrol, Italy, mountain area, 0105 earth and related environmental sciences, Ecology, Global warming, Bryophytes, SOUTH TYROL, Italy, species elevational shifts, Community composition, Local extinction, Bryophyte, Environmental science, Epiphyte

Abstract

Nascimbene J., Nimis P.L., Mair P. & Spitale D. 2018: Climate warming effects on epiphytes in spruce forests of the Alps. – Herzogia 31: 374–384.Climate warming in the Alps is setting major challenges to biodiversity conservation, potentially threatening epiphytic bryophytes and lichens, whose poikilohydric nature makes their eco-physiology strongly dependent on ambient temperature. In this work, we used species occurrence data along steep elevational-temperature gradients within the range of Alpine spruce-dominated forests for modelling the response of epiphytes to temperature shifts. Results provide evidence for species-specific and differently shaped species-temperature relationships, indicating that the sensitiveness of single species to climate warming is likely to influence community composition. Many epiphytes that currently occur in Alpine forests are vulnerable to warming, and may soon experience local extinction. The local assessment of the current altitudinal range of species may provide a tool to monitor the effects of warming by identifying the most critical species and the locations where their conservation is expected to be more effective.

Published

2018

2. Contrasting multitaxon responses to climate change in Mediterranean mountains

Author

Chiara Vallese, Chiara Lelli, Michele Di Musciano, Alessandro Chiarucci, Luciano Di Martino, Valter Di Cecco, Luca Di Nuzzo, Paolo Giordani, Daniel Spitale, Juri Nascimbene, Renato Benesperi, Gabriele Gheza, Di Nuzzo L., Vallese C., Benesperi R., Giordani P., Chiarucci A., Di Cecco V., Di Martino L., Di Musciano M., Gheza G., Lelli C., Spitale D., and Nascimbene J.

Subjects

0106 biological sciences, Mediterranean climate, Southern Europe, 010504 meteorology & atmospheric sciences, lichens, vascular plants, bryophytes, climatic factors, Science, Beta diversity, Climate change, Biology, 010603 evolutionary biology, 01 natural sciences, Article, species richne, Taxonomic rank, Community ecology, Lichen, skin and connective tissue diseases, taxon, 0105 earth and related environmental sciences, nonhuman, Multidisciplinary, Ecology, Climate-change ecology, vascular plant, Climatic variables, lichen (organism), cold stre, mo, climate change, Taxon, Medicine, Species richness, heat

Abstract

We explored the influence of climatic factors on diversity patterns of multiple taxa (lichens, bryophytes, and vascular plants) along a steep elevational gradient to predict communities’ dynamics under future climate change scenarios in Mediterranean regions. We analysed (1) species richness patterns in terms of heat-adapted, intermediate, and cold-adapted species; (2) pairwise beta-diversity patterns, also accounting for its two different components, species replacement and richness difference; (3) the influence of climatic variables on species functional traits. Species richness is influenced by different factors between three taxonomic groups, while beta diversity differs mainly between plants and cryptogams. Functional traits are influenced by different factors in each taxonomic group. On the basis of our observations, poikilohydric cryptogams could be more impacted by climate change than vascular plants. However, contrasting species-climate and traits-climate relationships were also found between lichens and bryophytes suggesting that each group may be sensitive to different components of climate change. Our study supports the usefulness of a multi-taxon approach coupled with a species traits analysis to better unravel the response of terrestrial communities to climate change. This would be especially relevant for lichens and bryophytes, whose response to climate change is still poorly explored.

Published

2021

3. Species richness and beta diversity patterns of multiple taxa along an elevational gradient in pastured grasslands in the European Alps

Author

Elia Guariento, Julia Seeber, Michael Steinwandter, Daniel Spitale, Ulrike Tappeiner, Georg Niedrist, Veronika Fontana, Andreas Hilpold, Juri Nascimbene, Fontana V., Guariento E., Hilpold A., Niedrist G., Steinwandter M., Spitale D., Nascimbene J., Tappeiner U., and Seeber J.

Subjects

multitaxon, biodiversity, elevational gradients, 0106 biological sciences, Multidisciplinary, Ecology, Gamma diversity, Science, 010604 marine biology & hydrobiology, Biodiversity, Beta diversity, Biology, 010603 evolutionary biology, 01 natural sciences, Article, Habitat, Medicine, Nestedness, Alpha diversity, Species richness, Lichen, human activities

Abstract

To understand how diversity is distributed in space is a fundamental aim for optimizing future species and community conservation. We examined in parallel species richness and beta diversity components of nine taxonomic groups along a finite space, represented by pastured grasslands along an elevational gradient. Beta diversity, which is assumed to bridge local alpha diversity to regional gamma diversity was partitioned into the two components turnover and nestedness and analyzed at two levels: from the lowest elevation to all other elevations, and between neighboring elevations. Species richness of vascular plants, butterflies, beetles, spiders and earthworms showed a hump-shaped relationship with increasing elevation, while it decreased linearly for grasshoppers and ants, but increased for lichens and bryophytes. For most of the groups, turnover increased with increasing elevational distance along the gradient while nestedness decreased. With regard to step-wise beta diversity, rates of turnover or nestedness did not change notably between neighboring steps for the majority of groups. Our results support the assumption that species communities occupying the same habitat significantly change along elevation, however transition seems to happen continuously and is not detectable between neighboring steps. Our findings, rather than delineating levels of major diversity losses, indicate that conservation actions targeting at a preventive protection for species and their environment in mountainous regions require the consideration of entire spatial settings.

Published

2020

4. Geological and hydrochemical prerequisites of unexpectedly high biodiversity in spring ecosystems at the landscape level

Author

Stefano Segadelli, Maria Teresa De Nardo, Nicola Angeli, John D. Wehr, Marco Cantonati, Kei Ogata, Reinhard Gerecke, Jacopo Gabrieli, Daniel Spitale, Cantonati, M., Segadelli, S., Spitale, D., Gabrieli, J., Gerecke, R., Angeli, N., De Nardo, M. T., Ogata, K., and Wehr, J. D.

Subjects

Environmental Engineering, 010504 meteorology & atmospheric sciences, Biodiversity, 010501 environmental sciences, 01 natural sciences, Spring (hydrology), Zoobentho, Environmental Chemistry, Animals, Ecosystem, Invertebrate, Waste Management and Disposal, 0105 earth and related environmental sciences, geography, geography.geographical_feature_category, Ecology, Geodiversity, Water mite, Animal, Biota, Diatom, Natural Springs, Vegetation, Pollution, Anthroposphere, Invertebrates, Spring, Italy, Bryophyte, Environmental science, Species richness

Abstract

This study explores the factors affecting the biodiversity of diatoms, vegetation with focus on bryophytes, and invertebrates with focus on water mites, in a series of 16 spring-habitats. The springs are located primarily from the mountainous part of the Emilia-Romagna Region (Northern Apennines, Italy), and two pool-springs from agricultural and industrial lowland locations. Overall, data indicate that biological diversity (Shannon-Wiener, α-diversity) within individual springs was relatively low, e.g.: Sdiatoms = 0–46, Swater-mites = 0–11. However, when examined at the regional scale, they hosted a very high total number of taxa (γ-diversity; Sdiatoms = 285, Swater-mites = 40), including several new or putatively-new species, and many Red-List taxa. This pattern suggested there is high species turnover among springs, as well as high distinctiveness of individual spring systems. A key goal was to assess the hydrogeological and hydrochemical conditions associated with this high regional-pool species richness, and to provide a guide to future conservation strategies. There was a striking variety of geological conditions (geodiversity, captured mainly with lithotype and aquifer structure) across the study region, which led to wide variation in the hydrosphere, especially in conductivity and pH. Agriculture and industrial activities (anthroposphere) in the lowlands resulted in nutrient enrichment and other forms of pollution. Across all 16 spring-systems, several hydrogeological conditions most strongly influenced the presence or absence of particular biota and were determinants of species importance: spring-head morphology, hydroperiod, discharge, current velocity, and elemental concentration. These findings have important practical consequences for conservation strategies. Our data show that it is imperative to protect entire regional groups of springs, including representatives of the different ecomorphological spring types, lithologies, and degrees of human influence. These findings suggest that springs, when studied from an ecohydrogeological perspective, are excellent systems in which to further investigate and understand geo-biodiversity relationships.

Published

2020

5. Patterns of bryophyte life-forms are predictable across land cover types

Author

Daniel Spitale, Juri Nascimbene, Petra Mair, Spitale D., Mair P., and Nascimbene J.

Subjects

0106 biological sciences, Ecology, Land use, Bryophyte database, General Decision Sciences, Global change, Land cover, 010501 environmental sciences, Ecological indicator, 010603 evolutionary biology, 01 natural sciences, Altitude, Herbarium, Geography, Habitat, Landscape, Bryophyte, Species traits, Herbarium collection, Ecology, Evolution, Behavior and Systematics, 0105 earth and related environmental sciences

Abstract

Bryophytes are promising indicators for detecting the impact of rapid global change. However, despite their great potential, they are still largely neglected, and their patterns across wide areas and environmental gradients are still poorly explored. Here we tested the capacity of bryophyte life-forms to respond to the main environmental and anthropogenic factors using an herbarium collection of high quality. The database consists of over 40,000 records referred to an Alpine area (Bolzano province, Northern Italy). The main aim of the work was to assess the relationship between bryophyte life-forms and different Corine Land Cover types which spans a wide elevational gradient and land uses. Results showed a broad match between similar land cover types and life-forms composition. For example, there was a positive relationship between plagiotropic forms and coniferous forests and between cushion- turf forms and natural grasslands. Anthropogenic habitats like vineyards and urban areas showed a high proportion of dendroid and thallose forms whereas plagiotropic species were underrepresented. Our results indicate that patterns of bryophyte life-forms are predictable across land cover types and altitude thus providing a direct link between the organism and the environmental conditions.

Published

2020

6. Spatial structure, rock type, and local environmental conditions drive moss and lichen distribution on calcareous boulders

Author

Juri Nascimbene, Daniel Spitale, Spitale D, and Nascimbene J

Subjects

Calcareous rock, biology, Ecology, Species distribution, Biota, Conservation, biology.organism_classification, Moss, Species composition, Geography, Habitat, Biological dispersal, Species richness, Lichen, Calcareous, Dispersal ability, Ecology, Evolution, Behavior and Systematics

Abstract

Although mosses and lichens are a relevant component of the biota of rock habitats targeted for biodiversity conservation in Europe, the ecological factors driving their distribution are still poorly known. In this work, we examined the epilithic moss and lichen assemblages colonizing boulders of different types of calcareous rocks co-occurring in the same area in the Italian Alps. The goals were: (1) to evaluate if and to what extent different calcareous rocks host different assemblages; (2) to identify species associated to each rock type; (3) to quantify the relative importance of rock type, local environmental factors, and habitat spatial structure in explaining species distribution. Our results demonstrated that different calcareous rocks host different moss and lichen assemblages with some typical species, indicating that each rock type contributes to the total diversity of both mosses and lichens. Local environmental conditions influenced mosses and not lichens whose distribution is mainly associated to rock type. The patterns of both organism groups were also significantly related to habitat spatial structure, species assemblages tending to have a patchy distribution, which may reflect dispersal dynamics. Our results have implications for conservation: (1) each rock type may play a relevant role in maintaining the overall diversity contributing with unique assemblages and typical species; (2) the patchy distribution of both moss and lichen assemblages should warn from considering rock patches as a monotonous repetition of the same habitat across space.

Published

2012