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  • 1.
    Blume-Werry, Gesche
    et al.
    Umeå universitet, Institutionen för ekologi, miljö och geovetenskap.
    Lindén, Elin
    Umeå universitet, Institutionen för ekologi, miljö och geovetenskap.
    Andresen, Lisa
    Umeå universitet, Institutionen för ekologi, miljö och geovetenskap.
    Classen, Aimée T.
    Sanders, Nathan J.
    von Oppen, Jonathan
    Umeå universitet, Institutionen för ekologi, miljö och geovetenskap.
    Sundqvist, Maja K.
    Umeå universitet, Institutionen för ekologi, miljö och geovetenskap.
    Proportion of fine roots, but not plant biomass allocation below ground, increases with elevation in arctic tundra2018In: Journal of Vegetation Science, ISSN 1100-9233, E-ISSN 1654-1103, Vol. 29, no 2, p. 226-235Article in journal (Refereed)
    Abstract [en]

    Questions: Roots represent a considerable proportion of biomass, primary production and litter input in arctic tundra, and plant allocation of biomass to above- or below-ground tissue in response to climate change is a key factor in the future C balance of these ecosystems. According to optimality theory plants allocate C to the above- or below-ground structure that captures the most limiting resource. We used an elevational gradient to test this theory and as a space-for-time substitution to inform on tundra carbon allocation patterns under a shifting climate, by exploring if increasing elevation was positively related to the root:shoot ratio, as well as a larger plant allocation to adsorptive over storage roots.

    Location: Arctic tundra heath dominated by Empetrum hermaphroditum close to Abisko, Sweden.

    Methods: We measured root:shoot and fine:coarse root ratios of the plant communities along an elevational gradient by sampling above- and below-ground biomass, further separating root biomass into fine (<1 mm) and coarse roots.

    Results: Plant biomass was higher at the lower elevations, but the root:shoot ratio did not vary with elevation. Resource allocation to fine relative to coarse roots increased with elevation, resulting in a fine:coarse root ratio that more than doubled with increasing elevation.

    Conclusions: Contrary to previous works, the root:shoot ratio along this elevational gradient remained stable. However, communities along our study system were dominated by the same species at each elevation, which suggests that when changes in the root:shoot ratio occur with elevation these changes may be driven by differences in allocation patterns among species and thus turnover in plant community structure. Our results further reveal that the allocation of biomass to fine relative to coarse roots can differ between locations along an elevational gradient, even when overall above- vs below-ground biomass allocation does not. Given the functionally different roles of fine vs coarse roots this could have large implications for below-ground C cycling. Our results highlight the importance of direct effects vs indirect effects (such as changes in plant community composition and nutrient availability) of climate change for future C allocation above and below ground.

  • 2. Bognounou, Fidele
    et al.
    Hulme, Philip E.
    Oksanen, Lauri
    Suominen, Otso
    Olofsson, Johan
    Role of climate and herbivory on native and alien conifer seedling recruitment at and above the Fennoscandian tree line2018In: Journal of Vegetation Science, ISSN 1100-9233, E-ISSN 1654-1103, Vol. 29, no 4, p. 573-584Article in journal (Refereed)
    Abstract [en]

    We investigated the importance of climate and herbivory on native and alien conifer colonization of the birch-dominated Fennoscandian tree line by addressing the following questions: (a) are tree line and tundra habitats similarly suitable for conifer seedling recruitment; (b) do ungulate and rodent herbivores differentially impact seedling recruitment; and (c) how does the role of habitat and herbivory on seedling recruitment vary across a marked climate gradient? Location Northern Fennoscandia, Sweden (Vassijaure and Paddus), and Norway (Joatka and Seiland). Methods We conducted an experiment to assess the emergence rate, survival probability and height development of Norway spruce (Picea abies), Scots pine (Pinus sylvestris) and Siberian larch (Larix sibirica) seedlings. Three experimental plots (i.e., open control, reindeer exclosure and complete vertebrate exclosure) were established in both tree line and tundra habitats at each of the four locations. Seeds of the three conifer species were sown in each plot in June 1999 during three consecutive years. The surviving seedlings were counted in August to September 1999, 2000, 2001, 2002 and 2007. The height of all seedlings was measured in 2007. Results Our study reveals that Norway spruce, Scots pine and Siberian larch can regenerate from seed at and above the current tree line in northern Fennoscandia. Their performance was generally higher above tree line in tundra than at tree line, but depended on species identity, climate aridity and mammal herbivory, particularly by rodents. These results suggest that the species composition and latitudinal limit of the tree line in the future might depend not only on direct effects of the future climate on the current tree line species, but also on the intensity of alien and native conifer introductions, as well as changes in herbivore populations. Conclusion If sufficient seeds of Norway spruce, Scots pine and Siberian larch should reach the current tree line, their performances will increase with a warmer and wetter climate, and this effect will be markedly modulated by herbivores (particularly rodents). Further work is required to extend these results to determine the ability of these conifers to become tree line-forming species in the future.

  • 3. Elumeeva, Tatiana G.
    et al.
    Soudzilovskaia, Nadejda A.
    During, Heinjo J.
    Cornelissen, Johannes H.C.
    The importance of colony structure versus shoot morphology for the water balance of 22 subarctic bryophyte species2011In: Journal of Vegetation Science, ISSN 1100-9233, E-ISSN 1654-1103, Vol. 22, no 1, p. 152-164Article in journal (Refereed)
    Abstract [en]

    Questions: What are the water economy strategies of the dominant subarctic bryophytes in terms of colony and shoot traits? Can colony water retention capacity be predicted from morphological traits of both colonies and separate shoots? Are suites of water retention traits consistently related to bryophyte habitat and phylogenetic position?

    Location: Abisko Research Station, North Sweden.

    Methods: We screened 22 abundant subarctic bryophyte species from diverse habitats for water economy traits of shoots and colonies, including desiccation rates, water content at field capacity, volume and density (mg cm−3) of water‐saturated and oven‐dried patches, evaporation rate (g·m−2·s−1) and cell wall thickness. The relationships between these traits and shoot and colony desiccation rates were analysed with Spearman rank correlations. Subsequent multivariate (cluster followed by PCA) analyses were based on turf density, turf and shoot desiccation rate, cell wall thickness and amount of external and internal water.

    Results: Individual shoot properties, i.e. leaf cell wall properties, water retention capacity and desiccation rate, did not correspond with colony water retention capacity. Colony desiccation rate depended on density of water‐saturated colonies, and was marginally significantly negatively correlated with species individual shoot desiccation rate but not related to any other shoot or colony trait. Multivariate analyses based on traits assumed to determine colony desiccation rate revealed six distinct species groups reflecting habitat choice and phylogenetic relationships.

    Conclusions: General relationships between shoot and colony traits as determinants of water economy will help to predict and upscale changes in hydrological function of bryophyte‐dominated peatlands undergoing climate‐induced shifts in species abundance, and feedbacks of such species shifts on permafrost insulation and carbon sequestration functions.

  • 4. Hostens, Lore
    et al.
    Van Meerbeek, Koenraad
    Wiegmans, Dymphna
    Larson, Keith
    Lenoir, Jonathan
    Clavel, Jan
    Wedegärtner, Ronja
    Pirée, Amber
    Nijs, Ivan
    Lembrechts, Jonas J.
    The drivers of dark diversity in the Scandinavian mountains are metric-dependent2023In: Journal of Vegetation Science, ISSN 1100-9233, E-ISSN 1654-1103, Vol. 34, no 6Article in journal (Refereed)
    Abstract [en]

    Question

    Dark diversity refers to the set of species that are not observed in an area but could potentially occur based on suitable local environmental conditions. In this paper, we applied both niche-based and co-occurrence-based methods to estimate the dark diversity of vascular plant species in the subarctic mountains. We then aimed to unravel the drivers explaining (a) why some locations were missing relatively more suitable species than others, and (b) why certain plant species were more often absent from suitable locations than others.

    Location

    The Scandinavian mountains around Abisko, northern Sweden.

    Methods

    We calculated the dark diversity in 107 plots spread out across four mountain trails using four different methods: two co-occurrence-based (Beals? index and the hypergeometric method) and two niche-based (the climatic niche model and climatic niche model followed by species-specific threshold). We then applied multiple Generalized Linear Mixed-Effects Models and General Linear Models to determine which habitat characteristics and species traits contributed the most to dark diversity.

    Results

    The study showed a notable divergence in the predicted drivers of dark diversity depending on the method used. Nevertheless, we can conclude that plot-level dark diversity was generally 17% higher in areas at low elevations and 31% higher in areas with a low species richness.

    Conclusion

    Our findings call for caution when interpreting statistical findings of dark-diversity estimates. Even so, all analyses point toward an important role for natural processes such as competitive dominance as the main driver of the spatial patterns found in dark diversity in the northern Scandes.

  • 5. Moles, Angela T.
    et al.
    Perkins, Sarah E.
    Laffan, Shawn W.
    Flores-Moreno, Habacuc
    Awasthy, Monica
    Tindall, Marianne L.
    Sack, Lawren
    Pitman, Andy
    Kattge, Jens
    Aarssen, Lonnie W.
    Anand, Madhur
    Bahn, Michael
    Blonder, Benjamin
    Cavender-Bares, Jeannine
    Cornelissen, J. Hans C.
    Cornwell, Will K.
    Díaz, Sandra
    Dickie, John B.
    Freschet, Grégoire T.
    Griffiths, Joshua G.
    Gutierrez, Alvaro G.
    Hemmings, Frank A.
    Hickler, Thomas
    Hitchcock, Timothy D.
    Keighery, Matthew
    Kleyer, Michael
    Kurokawa, Hiroko
    Leishman, Michelle R.
    Liu, Kenwin
    Niinemets, Ülo
    Onipchenko, Vladimir
    Onoda, Yusuke
    Penuelas, Josep
    Pillar, Valério D.
    Reich, Peter B.
    Shiodera, Satomi
    Siefert, Andrew
    Sosinski, Enio E.
    Soudzilovskaia, Nadejda A.
    Swaine, Emily K.
    Swenson, Nathan G.
    van Bodegom, Peter M.
    Warman, Laura
    Weiher, Evan
    Wright, Ian J.
    Zhang, Hongxiang
    Zobel, Martin
    Bonser, Stephen P.
    Which is a better predictor of plant traits: temperature or precipitation?2014In: Journal of Vegetation Science, ISSN 1100-9233, E-ISSN 1654-1103, Vol. 25, no 5, p. 1167-1180Article in journal (Refereed)
    Abstract [en]

    Question Are plant traits more closely correlated with mean annual temperature, or with mean annual precipitation? Location Global. Methods We quantified the strength of the relationships between temperature and precipitation and 21 plant traits from 447,961 species-site combinations worldwide. We used meta-analysis to provide an overall answer to our question. Results Mean annual temperature was significantly more strongly correlated with plant traits than was mean annual precipitation. Conclusions Our study provides support for some of the assumptions of classical vegetation theory, and points to many interesting directions for future research. The relatively low R2 values for precipitation might reflect the weak link between mean annual precipitation and the availability of water to plants.

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