Monitoring and analysis of the impacts of climate change on plant biodiversity and terrestrial ecosystems in alpine and polar environment.

High altitude and latitude environments are among those areas of the Planet that are experiencing the most significant changes of the climatic conditions due to the recent global change. Terrestrial ecosystems in these regions are extremely sensitive to climate, and for this reason, well suited for the comprehension, evaluation and monitoring of their responses, and their modelling under different climate change scenarios. This thesis focuses on the impacts of climate change on terrestrial ecosystems of alpine (Foscagno valley, central Italian Alps) and Polar (both Continental Antarctica and Maritime Antarctica) tundra habitats. European Alps and Maritime Antarctica are two of the three areas of the world where have been recorded the greatest air temperature warming in the last 50 years, whereas simultaneously in Continental Antarctica, air temperature was almost stable. Due to different trends of climate and anthropogenic pressures around the world, contemporary global change is characterized by a large spatial variability that makes the planning of adaptation and mitigation strategies particularly complicate. Peculiar habitats have been protected by international, European and national programs (the Foscagno valley belongs to the Nature 2000 network, while the Antarctica ecosystems are protected under the Antarctic treaty and specially protected areas). However, analyzing the dynamics of terrestrial ecosystems in regions that are facing different climate change scenarios, as well as biological and anthropogenic constrains, could improve the knowledge of the dynamics of terrestrial ecosystems, that could be used for modelling future scenarios and to implement the adaptation plans for such protected areas. The identification of conservation actions and monitoring plans is thus the priority for such threatened environments, to ensure a correct management of the biodiversity and of the ecosystem services that they can provide. The alpine site is the Foscagno Valley, a high altitude site (>2500 m a.s.l.) located in the central Italian Alps, where since 2007 a field-based project of snow, ground surface temperature and plant phenology monitoring started. This PhD is part of this project, that since summer 2015 was implemented with manipulation experiments on two typical alpine vegetation communities (snowbed and grassland) to simulate potential future climate change related impacts on plant phenology and growth, including increase of nutrient availability (simulated by additions of urea, ammonium sulfate, NPK respectively), water availability (once or twice per week additions of water), lack of reproductive stages (flowers removal). The primary aim of this PhD was to investigate alpine plant phenology and its relationships with climate change. We monitored phenology of 21 plants typical of alpine environments and representative of different growth forms types. In particular, we hypothesized that: a) the vegetative development (shoot appearance and leaf emergence) is regulated by snow melt timing, while the other phenological stages (i.e. flowering, seed development and ripening, and leaf senescence) are regulated mostly by photoperiod, which should indicate a conservative and adaptive strategy of alpine plants; b) plant phenology shows different plasticity depending on the growth form types and also on the phenological stage; c) extreme events can overwhelm the effect of photoperiod, and can lead to carry over effects in the phenological cycle and plant growth. Our data indicated that the main predictor of the vegetative development stages was the snow melt, while the photoperiod was the best predictor of phenological stages from flowering peak up to leaf senescence. Therefore, the photoperiodic control on alpine plant phenology should be considered for the evaluation and modelling of the impacts of climate change in alpine region, not only concerning the reproductive stages, but also for the leaf senescence. This constitute a novelty concerning literature data about phenology of alpine plants (which have been always related to snow and/or temperature as triggering factors) because provides new insights on the capability of alpine plants to profit of potential future autumn warming. Alpine plant phenology showed thus a strong conservative strategy, which differed among growth forms, according to our hypothesis. Over all the investigated phenological stages graminoids were the most plastic and responsive growth form and their higher adaptation capability could help to explain why this growth form is expanding more than forbs in alpine and Polar tundra habitats. Extreme events showed impact on plant phenology, with differences among growth forms and phenological stage. In particular, we found the leaf senescence of herbaceous species to be highly sensitive to the combination of drought and heat, which led to an advance of almost one month in the season, while deciduous shrubs were not or less sensitive. Moreover, an extreme leaf senescence showed carry over effects on the next season growth rate. Our results indicate also a statistically significant increase of the height of evergreen shrubs on the period 2010-2016, which was in agreement with the observed range expansion of shrubs in the Alps. Relating to the long-term ground surface temperature (GST) monitoring, 13 temperature data loggers were installed in the Foscagno valley, under different surface types conditions, covering the most widespread growth forms of the area. In particular, we hypothesized that: a) GST was strongly influenced by the soil coverage types and snow cover, b) although the actual climatic conditions are less favorable, some vegetated soils could lead a ground cooling until to permafrost condition; c) the shrubland expansion could drive to an energetic disequilibrium of soils with thus positive feedbacks on the carbon cycle. Our data confirmed that the snow cover duration was the main driver of the mean annual ground surface temperature, while the beginning of snow cover deeper than 80 cm influenced the freezing state of the soils during winter, and the timing of snow melt was related to the thawing degree days of the snow free period. Vegetated soils (shrublands and grasslands surface types) were warmer compared to bare ground, except for pioneer species (i.e. Cerastium uniflorum), that involved a cooling on soils leading to permafrost condition. Therefore, future changes in vegetation cover can lead to different soil thermal regimes and different spatial distribution of temperatures in alpine terrains. Potentially, the expansion of pioneer species could be related to longer persistence of permafrost conditions; on the contrary, if the shrublands expansion that we are facing in the Alps will continue in the future, soil temperatures will be warmer, which imply positive feedbacks to the carbon cycle. The main purpose of the manipulation experiments started at the Foscagno Valley in 2015 was to investigate the responses of phenology and plant growth under different simulations of climate change. As many phenophases exhibited a strong photoperiodic control, we aimed to assess and quantify the eventual effects of the different manipulation treatments and identify the most responsive phenophases and communities types. Concerning the quantitative development, we hypothesized that: a) the vegetative development (shoot length, leaf length, maximum plant height) would be influenced by manipulations, with nutrients exerting the higher impacts, compared to flower removal and water addition (since terrestrial ecosystems are N and P limited); b) the above ground biomass (ABG) would be strongly influenced by the addition of nutrients, more than flowers removal or water addition. Our data showed that manipulation experiments (in particular nutrient additions) involved strong impacts on plant phenology and growth, lengthening (with xNPK) or shortening (with ammonium sulfate) the duration of flowering and leaf senescence, and enhancing the vegetative quantitative phenology of alpine plants (with xNPK). One of the most important findings is that the photoperiodic limitation observed at the long-term phenology monitoring, could be overcome under future climate changes, with potentially consequences on niche competition within communities. Above all the manipulation we found a strong N and P limitation, in particular concerning the vegetative development, which thus will imply strong consequences also on the carbon budget. Also the flower removal exerted visible effects especially on the quantitative growth, highlighting differences among the vegetation communities, with higher capability for snowbeds species to remobilize nutrients than grasslands species. Another feedback of the manipulations experiments concerned the occurrence of carry over effects on the quantitative growth of the first shooting stage at the beginning of the season, provided by the enhanced nutrient availability from the previous year. While in the alpine tundra vascular plants are dominant, in high latitude ecosystems, cryptogams (mosses and lichens) are the major components of terrestrial ecosystems. In particular, in Antarctica only few long-term data are available on the responses of mosses and lichens to climate change. Comparable to Alps, the Maritime Antarctica is one of the regions of the planet recording the most rapid air warming, and Signy Island (South Orkney Islands) has been identified as a suitable context for the monitoring of biological changes. Here we analyzed the contemporary abundance and distribution of moss banks on the entire island, assessing their ecological requirements, and providing thus a baseline for future monitoring. Thanks to the availability of previous field-based studies on the spatial distribution of moss banks carried out in the 1960s and 1970s, we assessed long-term and large-scale moss responses to climate change underlying the related ecological processes. Differently to Alps and Maritime Antarctica, Continental Antarctica in the last 50 years showed a stable air temperature trend. This region is the last pristine environment on Earth, which provides a unique opportunity to assess the natural dynamics and responses to climate. In Victoria Land, in 2002 started a long-term monitoring project of the climate, permafrost and vegetation, of which we present here the results after 10 years of monitoring. Concerning this activity, we aim to: a) identify the patterns of spatial and temporal active layer variability; b) analyze the changes of the associated vegetation; c) identify the climatic forcing of active layer and vegetation changes. In the Antarctic summer 2014/2015, we installed over a latitudinal gradient (73-77\ub0S) in Victoria Land, some manipulation experiments (additions of snow, water, urea, ammonium sulfate, NPK, guano respectively) coupled with the manipulation of snow accumulation, soil temperature and precipitation (installing respectively snow fences, open top chambers and snow shield) for the simulation of potential future climate change impacts. We thus briefly evaluated the effects on soil temperatures after the first year of the experiments, providing thus the start point for future further monitoring. Among all the experiments, we found that the snow cover exerted the largest effect on the GST, thus highlighting its main role in regulating soil temperatures, which effects overcome the influence of air temperature, leading also to changes of soil moisture and water regim

[Wetlands in the Continental biogeographical region of Northern Italy: from scenarios of change to conservation perspectives]

[Wetlands are extremely important ecosystems for supporting biodiversity and providing services. Nonetheless, although they are mostly protected through several regulations, wetlands are affected by many negative factors that are leading to progressive deterioration of their conservation status. This circumstance is especially obvious in the Continental biogeographical region of Northern Italy, which is included in Piedmont and Lombardy on the left hydrographic side of the River Po. The goal of this study was to assess the main ecological drivers, i.e. the most important ecological factors, including pressures and threats, that shape negatively ecosystem dynamics, hence affecting conservation targets, and finally to suggest actions for counteracting them. Analyses were done at different scales, through bibliographic researches and site-specific data processing. As a result, we identified groups of ecological drivers, among which three were recognized as prevalent: a) the anthropic alteration of water levels; and b) the natural ecological succession in combination to c) the abandonment of traditional land use practices. The last two main ecological drivers were regarded as those to be counteracted by removing biomass (through digging, mowing, fire), because they may produce cascading effects and work against all the other ecological drivers. However, it is necessary to define a new reference framework based on pointing out conservation priorities at large scale (regional or supra-regional) and conservation actions at local scale, both focused on adaptive management.] [Article in Italian

Ecology of moss banks on Signy Island (maritime Antarctic)

Mosses are dominant components of high-latitude environments, and Signy Island (maritime Antarctic) provides a representative example of polar cryptogam-dominated terrestrial ecosystems. In 2011, we mapped all moss banks, their characteristics (thickness, area, floristic composition) and investigated their relationship with selected environmental factors including topography (elevation, slope, aspect), biotic disturbance (fur seals), deglaciation age of the surfaces, location on the eastern vs. western side of the island and snow cover as a proxy of water supply during the summer (December). We here identify the most important environmental factors influencing moss bank characteristics and distribution and provide a baseline for future monitoring. Moss bank abundance and distribution are the result of the interaction of multiple abiotic and biotic factors acting at different spatial scales. The most important factors are the location of moss banks on the eastern vs. western side of the island at the macroscale (with thicker and larger moss banks and a prevalence of Chorisodontium aciphyllum on the western side) and their favourable aspect (mainly N, NW) at the microscale, providing better microclimatic conditions suitable for their development. The elevation threshold detected at 120 m could indicate the occurrence of a ‘moss bank line’, analogous to the tree line, and corresponds with a threshold of mean annual temperature of −4.8 °C. The other factors examined play a subsidiary role in affecting bank distribution and characteristics. These findings allow a better understanding of this key feature of maritime Antarctic vegetation and provide quantitative information about their ecology

Habitats Directive in northern Italy: a series of proposals for habitat definition improvement

Habitats Directive (92/43/EEC) is the cornerstone of nature conservation in Europe and is at the core of the EU Biodiversity Strategy for 2030. There is room, however, for its improvement, at least for northern Italy, where ambiguities in the definition of habitat types of Annex I of the Habitats Directive are not novel and interpretation difficulties have been highlighted. Sharpening the characterization of habitat types represents an opportunity for lowering classification uncertainties and improving conservation success. With the aim to refine the definitions of habitat types and associated typical species of the Habitats Directive, a group of vegetation scientists of the Italian Society of Vegetation Science based in northern Italy made the exercise of finding viable proposals for those habitat types having a problematic interpretation in the Alpine biogeographical region of Italy. Such proposals arise from group discussions among scientists, and professionals, thus offering a shared view. We prepared 9 habitat proposals important for this geographic area. They include new habitat types at the European level, new subtypes within pre-existing habitat types, including some adjustments of the recently proposed subtypes with respect to northern Italy, and recognition of priority criteria for a pre-existing habitat type. With a vision of tailored conservation, our proposals represent a starting point in view of a future update of Annex I. Furthermore, the list of typical species could be useful for preparing expert systems for automatic classification. Irrespective of legally binding solutions in place, we caution these proposals represent relevant baseline conservation indications that local and regional administrations of the Alpine Arch should consider

Woody and herbaceous invasive alien plant species‐derived biochars are potentially optimal for soil amendment, soil remediation, and carbon storage

Invasive alien plant species (IAPS) are a global problem, representing a threat to ecosystem functioning, biodiversity, and human health. Legislation requires the management and eradication of IAPS populations; yet, management practices are costly, require several interventions, and produce large amounts of waste biomass. However, the biomass of eradicated IAPS can become a resource by being used as feedstock for biochar production and, at the same time, implementing the management of IAPS. Here we carried out an in-depth characterization of biochar produced at 550°C derived from 10 (five woody and five herbaceous) widespread IAPS in the central-southern lps region to determine their potential applications for soil amendment, soil remediation, and carbon storage. Biochar was produced at a laboratory scale, where its physicochemical characteristics, micromorphological features, and lead adsorption from aqueous solutions were measured. To investigate any possible trade-offs among the potential biochar applications, a principal component analysis was performed. IAPS-derived biochars exhibited relevant properties in different fields of application, suggesting that IAPS biomass can be exploited in a circular economy framework. We found coordinated variation and trade-offs from biochars with high stability to biochars with high soil amendment potential (PC1), while the biochar soil remediation potential represents an independent axis of variation (PC2). Specifically, IAPS-derived biochar had species-specific characteristics, with differences between the woody and herbaceous IAPS, the latter being more suitable for soil amendment due to their greater pH, macronutrient content, and macropore area. Biochar derived from woody IAPS showed a greater surface area, smaller pores, and had higher lead adsorption potentials from aqueous solutions, hinting at their higher potential for heavy metal pollution remediation. Moreover, biochar derived from woody IAPS had a higher fixed carbon content, indicating higher carbon stability, and suggesting that their biochar is preferable for carbon sequestration in the view of climate change mitigation

Mulching in lowland hay meadows drives an adaptive convergence of above- and below-ground traits reducing plasticity and improving biomass: A possible tool for enhancing phytoremediation

We aimed to understand the effect of mulching (i.e., cutting and leaving the crushed biomass to decompose in situ) on above- and below-ground plant functional traits and whether this practice may be a potential tool for enhancing the phytoremediation of lowland hay meadows. To this aim, we evaluated at the community level seven years of mulching application in a PCBs and HMs soil-polluted Site of National Interest (SIN Brescia-Caffaro) through the analysis of the floristic composition and the above- and below-ground plant traits. We found that the abandonment of agricultural activities led to a marked increase in the soil organic carbon and pH, and the over-imposed mulching additionally induced a slight increase in soil nutrients. Mulching favored the establishment of a productive plant community characterized by a more conservative-resource strategy, a higher biomass development, and lower plasticity through an adaptative convergence between above- and below-ground organs. In particular, the analysis of the root depth distribution highlighted the key role of roots living in the upper soil layer (10 cm). Mulching did not show a significant effect on plant species known to be effective in terms of PCB phytoremediation. However, the mulching application appears to be a promising tool for enhancing the root web that functions as the backbone for the proliferation of microbes devoted to organic contaminants' degradation and selects a two-fold number of plant species known to be metal-tolerant. However, besides these potential positive effects of the mulching application, favoring species with a higher biomass development, in the long term, may lead to a biodiversity reduction and thus to potential consequences also on the diversity of native species important for the phytoremediation

Intraspecific variability of leaf form and function across habitat types

: Trait-based ecology has already revealed main independent axes of trait variation defining trait spaces that summarize plant adaptive strategies, but often ignoring intraspecific trait variability (ITV). By using empirical ITV-level data for two independent dimensions of leaf form and function and 167 species across five habitat types (coastal dunes, forests, grasslands, heathlands, wetlands) in the Italian peninsula, we found that ITV: (i) rotated the axes of trait variation that define the trait space; (ii) increased the variance explained by these axes and (iii) affected the functional structure of the target trait space. However, the magnitude of these effects was rather small and depended on the trait and habitat type. Our results reinforce the idea that ITV is context-dependent, calling for careful extrapolations of ITV patterns across traits and spatial scales. Importantly, our study provides a framework that can be used to start integrating ITV into trait space analyses

Shedding light on typical species : implications for habitat monitoring

Habitat monitoring in Europe is regulated by Article 17 of the Habitats Directive, which suggests the use of typical species to assess habitat conservation status. Yet, the Directive uses the term “typical” species but does not provide a definition, either for its use in reporting or for its use in impact assessments. To address the issue, an online workshop was organized by the Italian Society for Vegetation Science (SISV) to shed light on the diversity of perspectives regarding the different concepts of typical species, and to discuss the possible implications for habitat monitoring. To this aim, we inquired 73 people with a very different degree of expertise in the field of vegetation science by means of a tailored survey composed of six questions. We analysed the data using Pearson's Chi-squared test to verify that the answers diverged from a random distribution and checked the effect of the degree of experience of the surveyees on the results. We found that most of the surveyees agreed on the use of the phytosociological method for habitat monitoring and of the diagnostic and characteristic species to evaluate the structural and functional conservation status of habitats. With this contribution, we shed light on the meaning of “typical” species in the context of habitat monitoring

Plant–environment interactions through a functional traits perspective: a review of Italian studies

Italy is among the European countries with the greatest plant diversity due to both a great environmental heterogeneity and a long history of man–environment interactions. Trait-based approaches to ecological studies have developed greatly over recent decades worldwide, although several issues concerning the relationships between plant functional traits and the environment still lack sufficient empirical evaluation. To draw insights on the association between plant functional traits and direct and indirect human and natural pressures on the environmental drivers, this article summarizes the existing knowledge on this topic by reviewing the results of studies performed in Italy adopting a functional trait approach on vascular plants, bryophytes and lichens. Although we recorded trait measurements for 1418 taxa, our review highlighted some major gaps in plant traits knowledge: Mediterranean ecosystems are poorly represented; traits related to belowground organs are still overlooked; traits measurements for bryophytes and lichens are lacking. Finally, intraspecific variation has been little studied at community level so far. We conclude by highlighting the need for approaches evaluating trait–environment relationship at large spatial and temporal scales and the need of a more effective contribution to online databases to tie more firmly Italian researchers to international scientific networks on plant traits

TRY plant trait database – enhanced coverage and open access

Plant traits - the morphological, anatomical, physiological, biochemical and phenological characteristics of plants - determine how plants respond to environmental factors, affect other trophic levels, and influence ecosystem properties and their benefits and detriments to people. Plant trait data thus represent the basis for a vast area of research spanning from evolutionary biology, community and functional ecology, to biodiversity conservation, ecosystem and landscape management, restoration, biogeography and earth system modelling. Since its foundation in 2007, the TRY database of plant traits has grown continuously. It now provides unprecedented data coverage under an open access data policy and is the main plant trait database used by the research community worldwide. Increasingly, the TRY database also supports new frontiers of trait‐based plant research, including the identification of data gaps and the subsequent mobilization or measurement of new data. To support this development, in this article we evaluate the extent of the trait data compiled in TRY and analyse emerging patterns of data coverage and representativeness. Best species coverage is achieved for categorical traits - almost complete coverage for ‘plant growth form’. However, most traits relevant for ecology and vegetation modelling are characterized by continuous intraspecific variation and trait–environmental relationships. These traits have to be measured on individual plants in their respective environment. Despite unprecedented data coverage, we observe a humbling lack of completeness and representativeness of these continuous traits in many aspects. We, therefore, conclude that reducing data gaps and biases in the TRY database remains a key challenge and requires a coordinated approach to data mobilization and trait measurements. This can only be achieved in collaboration with other initiatives