Your search keyword '"plant traits"' showing total 3,145 results

101. Shoot Flammability Patterns in Native and Exotic Street Tree Species at the Wildland–Urban Interface of Eastern Australia.

Author

Huber-Smith, Nicola K., Morley, Elisabeth S., Krix, Daniel W., Murray, Megan L., Webb, Jonathan K., Martin, Leigh J., Young, Kieran, McLean, Christopher M., Hingee, Matthew C., and Murray, Brad R.

Subjects

*WILDLAND-urban interface, *INTRODUCED species, *NATIVE species, *URBAN trees, *FLAMMABILITY, *FLAME temperature, *BIODIVERSITY conservation, *ECOSYSTEM services

Abstract

Street trees provide ecosystem services such as heat mitigation, improved community well-being, and biodiversity conservation. At the wildland–urban interface (WUI), high-flammability street trees also provide a conflicting ecosystem disservice, heightening risks of wildfire spread into urban areas. We addressed this service–disservice conflict by assessing shoot flammability patterns in 10 street tree species, to identify low-flammability species that can potentially mitigate wildfire risks at the WUI. We found significant differences among species in flammability attributes including time-to-flame (TTF), flame duration (FD), number of flaming events (nF), and flame temperature (FT), and identified low-flammability species for each attribute. Overall, species' rankings from least to most flammable differed considerably across the four attributes. For example, native water gum (Tristaniopsis laurina) had the slowest TTF, but had the longest FD. Among nine shoot traits, we found that high leafing intensity was the most frequent trait correlated with flammability. In particular, high leafing intensity was significantly related to fast TTF and high FT. Lack of coordination among flammability attributes suggests that, in general, selection of low-flammability street tree species should consider how each flammability attribute differentially contributes to wildfire spread risk. Nonetheless, native Tuckeroo (Cupaniopsis anacardioides) emerged as a potential candidate for further exploration as a low-flammability street tree as it had comparatively long TTF, short FD, and low nF. We found no consistent evidence that exotic species were less flammable than native species, and suggest that native trees be the focus of further research to identify low-flammability street trees. [ABSTRACT FROM AUTHOR]

Published

2023

102. Impact of Phytophthora cinnamomi on the taxonomic and functional diversity of forest plants in a mediterranean‐type biodiversity hotspot.

Author

Harshani, Himbutugoda S., Tsakalos, James L., Mansfield, Thomas M., McComb, Jen, Burgess, Treena I., and St. J. Hardy, Giles E.

Subjects

*PHYTOPHTHORA, *PHYTOPHTHORA cinnamomi, *PLANT diversity, *FOREST biodiversity, *FOREST plants, *FOREST reserves, *SPECIES diversity

Abstract

Aim: Diversity‐rich mediterranean‐type sclerophyllous forests are home to 20% of described species on Earth. In the Eucalyptus marginata (jarrah) forest of southwest of Western Australia diversity is being reduced by extensive human use and the introduction of the plant pathogen Phytophthora cinnamomi. This study investigated the influence of P. cinnamomi infestation on the structure, taxonomic and functional diversity, and species composition of the forest. Location: Jarrah forest of southwestern Australia. Methods: Species abundance, understorey cover and canopy cover were assessed along 22, 30 m long transects which crossed infested and non‐infested zones in five reserves in the jarrah forest. A trait database was assembled for 137 plants using 13 traits related to nutrient and carbon acquisition, disturbance tolerance and reproduction. The responses of canopy cover, understorey cover, species richness, Shannon diversity, evenness, abundance, and functional diversity for trait groups, and all groups combined were modelled against reserve and zone as fixed effects and transect and transect section as random effects. To assess the species composition, non‐metric multidimensional scaling (NMDS) ordination based on Jaccard resemblance and indicator species analyses were used. Results: Significantly higher understorey cover, species richness, Shannon diversity and evenness were recorded in non‐infested compared to infested zones, but there were no changes in the canopy cover and overall abundance. In non‐infested zones, the functional diversity of nutrient acquisition and reproductive traits was higher, but the functional diversity of carbon acquisition traits was lower. No difference in functional diversity was recorded in disturbance tolerance and overall traits between the two zones. NMDS ordination and analysis of similarities (ANOSIM) revealed a significant difference in the species composition between the two zones, and 11 indicator species significantly associated with infested and non‐infested zones were identified. Conclusion: Phytophthora cinnamomi has significantly affected the forest structure, taxonomic and functional diversity, and species composition. Contrasting responses of functional trait groups obscured overall trait responses to P. cinnamomi. [ABSTRACT FROM AUTHOR]

Published

2023

103. The drivers of dark diversity in the Scandinavian mountains are metric‐dependent.

Author

Hostens, Lore, Van Meerbeek, Koenraad, Wiegmans, Dymphna, Larson, Keith, Lenoir, Jonathan, Clavel, Jan, Wedegärtner, Ronja, Pirée, Amber, Nijs, Ivan, and Lembrechts, Jonas J.

Subjects

*PLANT species diversity, *SPECIES diversity, *PLANT species

Abstract

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. [ABSTRACT FROM AUTHOR]

Published

2023

104. Seasonal and Elevational Variability in Dwarf Birch VOC Emissions in Greenlandic Tundra.

Author

Rieksta, Jolanta, Li, Tao, Davie‐Martin, Cleo L., Simin, Tihomir, Brogaard Aeppli, Laurids Christian, Høye, Toke Thomas, Rasmussen, Morten Arendt, and Rinnan, Riikka

Subjects

SEASONS, BIRCH, CLIMATE feedbacks, TUNDRAS, SUMMER

Abstract

Rising temperatures amplify biogenic volatile organic compound (VOC) emissions from Arctic vegetation, causing feedbacks to the climate system. Changes in climate also alter plant physiology and vegetation composition, all of which can influence VOC emissions. Moreover, leaf development and biotic stresses cause highly variable emissions during the growing season. Therefore, linking VOC emissions with plant traits and tracking responses to climate change might provide better understanding of VOC emission regulation under future conditions. We measured VOC emissions and other plant traits in dwarf birch (Betula glandulosa) at two elevations in Narsarsuaq, South Greenland. The measurements were performed in warming experiments that have run since 2016. We collected VOCs using the branch enclosure method from early June until late July 2019 (n = 200). Emissions of green leaf volatiles (GLVs), oxygenated monoterpenes (oMTs), and homoterpenes followed a seasonal trend. VOC emission rates and the diversity of the VOC blend decreased at the end of the measurement period. Differences in VOC emission rates between elevations were pronounced early in the season. Majority of the traits did not explain the variation in VOC emissions. We show strong seasonal variability in VOC emissions within the growing season, which is likely driven by leaf phenology. While the diversity of VOCs was greater at the milder low‐elevation site, VOC emission rates were higher or similar at the harsher high‐elevation site, showing stronger VOC emission potentials than previously assumed. Seasonal variations in the emissions of VOCs are crucial for accurate predictions of current and future VOC emissions from arctic ecosystems. Plain Language Summary: Plants release mixtures of trace gases to the atmosphere, called plant volatiles. Plants are the largest source of volatile emissions to the atmosphere, which may cause feedbacks on our climate. With ongoing climate change, we expect higher plant volatile emissions from the Arctic. We used a field experiment in South Greenlandic tundra to study how contrasting environments (warmer and colder), rising temperatures, and changes in plant structure would affect the release of plant volatiles from dwarf birch during the summer growing season. Lower amounts and less diverse mixtures of volatiles were released by plants as the summer progressed. Plant structure generally had a minor effect on the volatiles released from dwarf birch. Plants at the colder site released less diverse volatile mixtures, but the amounts were higher or similar when compared to the warmer site. Key Points: Strong seasonal variability of VOC emissions in dwarf birch within the growing season are likely driven by leaf phenologyHigher VOC emission potentials from dwarf birch observed at the harsher high‐elevation site than previously assumed, due to abiotic limitationsMore environmentally challenging abiotic conditions limit the VOC diversity, but not the emission rates [ABSTRACT FROM AUTHOR]

Published

2023

105. Plant susceptibility to a shared herbivore is reduced by belowground competition with neighbors.

Author

Holmes, Katherine D., Getman-Pickering, Zoe L., Mudrak, Erika L., and Power, Alison G.

Subjects

*HERBIVORES, *HOST plants, *LEAF area, *PLANT variation, *CHEMICAL composition of plants, *GREENHOUSES

Abstract

Spatial variation in plant community composition is an important driver of variation in susceptibility to herbivores. In close proximity, certain neighbors can attract or repel herbivores to a focal plant ("associational effects"). Neighboring plants may also compete for resources, modifying their phenotype in ways that affect susceptibility to herbivores. To test whether and how competition contributes to associational effects, we manipulated the sharing of belowground resources among plant neighbors (spotted Joe Pye weed and common boneset) that serve as alternate hosts for an herbivorous beetle. In the field, the beetle Ophraella notata laid more eggs and inflicted more damage on plants of both species that were released from belowground competition with neighbors. Competition also weakened the effects of neighbor identity during field trials, reducing associational susceptibility. When beetles were forced to choose between the two host species in cage trials, competition again reduced beetle use of Joe Pye weed as a secondary host. To test the role of plant traits related to herbivore defense and nutrition, we quantified leaf protein, specific leaf area, and trichomes, and conducted behavioral assays on leaf disks. Beetles did not distinguish between Joe Pye weed treatments at the leaf disk level, and competition did not impact specific leaf area and protein. Trichome density was higher in both species in the preferred treatment. Overall, our results suggest that belowground interactions between plants may mediate the strength of associational effects, as secondary hosts become more attractive when released from competition with primary host plants. [ABSTRACT FROM AUTHOR]

Published

2023

106. Apparent effect of range size and fruit colour on palm diversification may be spurious.

Author

Hill, Adrian, Jiménez, Maria Fernanda Torres, Chazot, Nicolas, Cássia‐Silva, Cibele, Faurby, Søren, Herrera‐Alsina, Leonel, and Bacon, Christine D.

Subjects

*PALMS, *BIOLOGICAL extinction, *COLOR of birds, *FRUIT, *DATA distribution, *DYNAMIC models

Abstract

Aim: Fruit selection by animal dispersers with different mobility directly impacts plant geographical range size, which, in turn, may impact plant diversification. Here, we examine the interaction between fruit colour, range size and diversification rate in palms by testing two hypotheses: (1) species with fruit colours attractive to birds have larger range sizes due to high dispersal ability and (2) disperser mobility affects whether small or large range size has higher diversification, and intermediate range size is expected to lead to the highest diversification rate regardless of disperser. Location: Global. Taxon: Arecaceae (palms). Methods: Palm species were grouped based on likely animal disperser group for given fruit colours. Range sizes were estimated by constructing alpha convex hull polygons from distribution data. We examined disperser group, range size or an interaction of both as possible drivers of change in diversification rate over time in a likelihood dynamic model (Several Examined State‐dependent Speciation and Extinction [SecSSE]). Models were fitted, rate estimates were retrieved and likelihoods were compared to those of appropriate null models. Results: Species with fruit colours associated with mammal dispersal had larger ranges than those with colours associated with bird dispersal. The best fitting SecSSE models indicated that the examined traits were not the primary driver of the heterogeneity in diversification rates in the model. Extinction rate complexity had a marked impact on model performance and on diversification rates. Main Conclusions: Two traits related to dispersal mobility, range size and fruit colour, were not identified as the main drivers of diversification in palms. Increased model extinction rate complexity led to better performing models, which indicates that net diversification should be estimated rather than speciation alone. However, increased complexity may lead to incorrect SecSSE model conclusions without careful consideration. Finally, we find palms with more mobile dispersers do not have larger range sizes, meaning other factors are more important determinants of range size. [ABSTRACT FROM AUTHOR]

Published

2023

107. Key hydraulic traits control the dynamics of plant dehydration in four contrasting tree species during drought.

Author

Blackman, Chris J, Billon, Lise-Marie, Cartailler, Julien, Torres-Ruiz, José M, and Cochard, Hervé

Subjects

*DEHYDRATION in plants, *DROUGHTS, *HYDRAULIC control systems, *DROUGHT management, *PLANT size, *LEAF area, *ALEPPO pine

Abstract

Trees are at risk of mortality during extreme drought, yet our understanding of the traits that govern the timing of drought-induced hydraulic failure remains limited. To address this, we tested SurEau, a trait-based soil–plant–atmosphere model designed to predict the dynamics of plant dehydration as represented by the changes in water potential against those observed in potted trees of four contrasting species (Pinus halepensis Mill. , Populus nigra L. , Quercus ilex L. and Cedrus atlantica (Endl.) Manetti ex Carriére) exposed to drought. SurEau was parameterized with a range of plant hydraulic and allometric traits, soil and climatic variables. We found a close correspondence between the predicted and observed plant water potential (in MPa) dynamics during the early phase drought, leading to stomatal closure, as well as during the latter phase of drought, leading to hydraulic failure in all four species. A global model's sensitivity analysis revealed that, for a common plant size (leaf area) and soil volume, dehydration time from full hydration to stomatal closure (T close) was most strongly controlled by the leaf osmotic potential (P i0) and its influence on stomatal closure, in all four species, while the maximum stomatal conductance (g smax) also contributed to T close in Q. ilex and C. atlantica. Dehydration times from stomatal closure to hydraulic failure (T cav) was most strongly controlled by P i0, the branch residual conductance (g res) and Q 10 a sensitivity of g res in the three evergreen species, while xylem embolism resistance (P 50) was most influential in the deciduous species P. nigra. Our findings point to SurEau as a highly useful model for predicting changes in plant water status during drought and suggest that adjustments made in key hydraulic traits are potentially beneficial to delaying the onset of drought-induced hydraulic failure in trees. [ABSTRACT FROM AUTHOR]

Published

2023

108. Legacy effects of nitrogen deposition and increased precipitation on plant productivity in a semi-arid grassland.

Author

Meng, Ya-ni, Li, Tianpeng, Liu, Heyong, Li, Shao-peng, Xu, Zhuwen, and Jiang, Yong

Subjects

*PLANT productivity, *GRASSLANDS, *PLANT communities, *FIELD research, *FUNCTIONAL groups, *NITROGEN, *WILDLIFE management areas

Abstract

Purpose: Nitrogen (N) deposition and increased precipitation were widely reported to promote plant productivity in terrestrial ecosystems. However, few studies have explored the effects of historical resource supplements on plant communities (legacy effects). Methods: Based on a field experiment, we examined the legacy effects of N deposition and increased precipitation on plant productivity in a semi-arid steppe after the cessation of 13-year N and water addition. Results: We found historical N and water addition generally had positive effects on plant productivity even after the treatments were ceased. However, such legacy effects showed strong inter-annual variation, and the positive effects of historical N and water addition on productivity were stronger in a wet year (i.e., 2019) than in an extreme drought year (i.e., 2018). Although N availability decreased rapidly, the positive effect of historical N input persisted after 2 years of cessation largely due to the maintenance of the enhanced community plant stature (CWMstature) through the increased stature of all functional groups. Moreover, the dominance of tall grasses persisted in water added plots largely contributed to the increased productivity after the historical N and water addition. Conclusions: Our study highlights the importance of plant traits and community compositions in regulating the short-term legacy effects of historical N and water input on community productivity. The positive N and water legacy effects on productivity would both last for long given the substantially changed species compositions. Long-term observation is needed for further validation of these legacy effects because of their great year-to-year variability. [ABSTRACT FROM AUTHOR]

Published

2023

109. British species that are present in Australia have different traits from British species that are not present in Australia.

Author

Earle, Rosa A. D., Atkinson, Joe, and Moles, Angela T.

Subjects

*SEED viability, *PLANT species, *FLOWER seeds, *SPECIES, *CHI-squared test, *FLOWERING of plants, *SEED yield

Abstract

Aim: Introduced species spreading to natural ecosystems is a leading cause of environmental change and a key feature of the Anthropocene. While there have been many studies of the traits of introduced and invasive species, less is known about the traits that affect a species' chances of reaching and establishing in new areas. We asked whether British species that are present in Australia have different traits to British species that are not present in Australia. Location: Great Britain and Australia. Methods: We compiled a list of all vascular plant species from Great Britain and divided them into those that are present in Australia (395 species) and those that are not present in Australia (1171 species). We compiled data for each species' seed mass, seedbank longevity, maximum plant height, flower size, flower colour and geographical extent in the British Isles. We conducted independent sample t‐tests for continuous variables and Chi‐squared tests for categorical variables to determine differences between groups. Results: We found British species present in Australia have, on average, larger geographic extents in the British Isles, longer periods of seed bank longevity (mean ~3 months as opposed to ~3 weeks), and maximum heights that are on average 36% taller than British species that are not present in Australia. However, British species present in Australia did not have significantly different flower size, flower colour or seed mass from British species that are not present in Australia. Main Conclusions: British species that are present in Australia and British species that are not present in Australia differ in several traits. These differences likely result from a combination of factors including introduction biases, environmental filters during establishment and stochasticity. Our results suggest that humans may be consciously and unconsciously selecting species for introduction. Some of the traits that are associated with an increased chance of a species being transported to/establishing in a new range also contribute to invasiveness. Thus, anthropogenic introduction biases could contribute to an increased risk of ecosystem invasion. [ABSTRACT FROM AUTHOR]

Published

2023

110. Plant traits modulate grassland stability during drought and post‐drought periods.

Author

Luo, Wentao, Shi, Yuan, Wilkins, Kate, Song, Lin, Te, Niwu, Chen, Jiaqi, Zhang, Hongxiang, Yu, Qiang, Wang, Zhengwen, Han, Xingguo, and Collins, Scott L.

Subjects

*DROUGHTS, *GRASSLANDS, *CLIMATE extremes, *STRUCTURAL equation modeling, *CLIMATE change, *LEAF area

Abstract

Grasslands are subject to climate change, such as severe drought, and an important aspect of their functioning is temporal stability in response to extreme climate events. Previous research has explored the impacts of extreme drought and post‐drought periods on grassland stability, yet the mechanistic pathways behind these changes have rarely been studied.Here, we implemented an experiment with 4 years of drought and 3 years of recovery to assess the effects of drought and post‐drought on the temporal stability of above‐ground net primary productivity (ANPP) and its underlying mechanisms. To do so, we measured community‐weighted mean (CWM) of six plant growth and nine seed traits, functional diversity, population stability and species asynchrony across two cold, semiarid grasslands in northern China. We also performed piecewise structural equation models (SEMs) to assess the relationships between ANPP stability and its underlying mechanisms and how drought and post‐drought periods alter the relative contribution of these mechanisms to ANPP stability.We found that temporal stability of ANPP was not reduced during drought due to grasses maintaining productivity, which compensated for increased variation of forb productivity. Moreover, ANPP recovered rapidly after drought, and both grasses and forbs contributed to community stability during the post‐drought period. Overall, ANPP stability decreased during the combined drought and post‐drought periods because of rapid changes in ANPP from drought to post‐drought. SEMs revealed that the temporal stability of ANPP during drought and post‐drought periods was modulated by functional diversity and community‐weighted mean traits directly and indirectly by altering species asynchrony and population stability. Specifically, the temporal stability of ANPP was positively correlated with functional divergence of plant communities. CWMs of seed traits (e.g. seed width and thickness), rather than plant growth traits (e.g. specific leaf area and leaf nutrient content), stabilized grassland ANPP. Productivity of plant communities with large and thick seeds was less sensitive to precipitation changes over time.These results emphasize the importance of considering both the functional trait distribution among species and seed traits of dominant species since their combined effects can stabilize ecosystem functions under global climate change scenarios. Read the free Plain Language Summary for this article on the Journal blog. [ABSTRACT FROM AUTHOR]

Published

2023

111. Spectroscopy Imaging Techniques as In Vivo Analytical Tools to Detect Plant Traits.

Author

Hernanda, Reza Adhitama Putra, Lee, Junghyun, and Lee, Hoonsoo

Subjects

SPECTRAL imaging, PLANT growth, CHEMOMETRICS, SPECTROMETRY, MULTISPECTRAL imaging

Abstract

The efficiency of hyper- and multispectral imaging (HSI and MSI) has gained considerable attention in research on plant phenotyping. This is due to their ease of use while being considered a nondestructive technology. Unlike current point-scanned spectroscopy, both HSI and MSI extract spatial and spectral information while covering a wide range of a plant body. Moreover, it is necessary to equip the extracted information with multivariate calibration techniques, followed by model evaluation. To date, the application of HSI and MSI for monitoring plant growth under a controlled environment is emerging and showing a good trend. Our systematic literature review discusses spectroscopy imaging techniques and their chemometric approaches as a sustainable sensor technology to detect plant traits. In conclusion, we also explore the possibility of carrying out HSI and MSI during plant trait analysis. [ABSTRACT FROM AUTHOR]

Published

2023

112. Fire Responses Shape Plant Communities in a Minimal Model for Fire Ecosystems across the World.

Author

Magnani, Marta, Díaz-Sierra, Rubén, Sweeney, Luke, Provenzale, Antonello, and Baudena, Mara

Subjects

*PLANT communities, *PLANT competition, *SAVANNAS, *TAIGAS, *ECOSYSTEMS, *RIFLE-ranges

Abstract

Across plant communities worldwide, fire regimes reflect a combination of climatic factors and plant characteristics. To shed new light on the complex relationships between plant characteristics and fire regimes, we developed a new conceptual mechanistic model that includes plant competition, stochastic fires, and fire-vegetation feedback. Considering a single standing plant functional type, we observed that highly flammable and slowly colonizing plants can persist only when they have a strong fire response, while fast colonizing and less flammable plants can display a larger range of fire responses. At the community level, the fire response of the strongest competitor determines the existence of alternative ecological states (i.e., different plant communities) under the same environmental conditions. Specifically, when the strongest competitor had a very strong fire response, such as in Mediterranean forests, only one ecological state could be achieved. Conversely, when the strongest competitor was poorly fire adapted, alternative ecological states emerged—for example, between tropical humid savannas and forests or between different types of boreal forests. These findings underline the importance of including the plant fire response when modeling fire ecosystems, for example, to predict the vegetation response to invasive species or to climate change. [ABSTRACT FROM AUTHOR]

Published

2023

113. Transpiration response to soil drying versus increasing vapor pressure deficit in crops: physical and physiological mechanisms and key plant traits.

Author

Koehler, Tina, Wankmüller, Fabian J P, Sadok, Walid, and Carminati, Andrea

Subjects

*VAPOR pressure, *SOIL drying, *PHYSIOLOGY, *DROUGHT tolerance, *CROPS

Abstract

The water deficit experienced by crops is a function of atmospheric water demand (vapor pressure deficit) and soil water supply over the whole crop cycle. We summarize typical transpiration response patterns to soil and atmospheric drying and the sensitivity to plant hydraulic traits. We explain the transpiration response patterns using a soil–plant hydraulic framework. In both cases of drying, stomatal closure is triggered by limitations in soil–plant hydraulic conductance. However, traits impacting the transpiration response differ between the two drying processes and act at different time scales. A low plant hydraulic conductance triggers an earlier restriction in transpiration during increasing vapor pressure deficit. During soil drying, the impact of the plant hydraulic conductance is less obvious. It is rather a decrease in the belowground hydraulic conductance (related to soil hydraulic properties and root length density) that is involved in transpiration down-regulation. The transpiration response to increasing vapor pressure deficit has a daily time scale. In the case of soil drying, it acts on a seasonal scale. Varieties that are conservative in water use on a daily scale may not be conservative over longer time scales (e.g. during soil drying). This potential independence of strategies needs to be considered in environment-specific breeding for yield-based drought tolerance. [ABSTRACT FROM AUTHOR]

Published

2023

114. Relationships between Environmental Factors and Functional Traits of Macrophyte Assemblages in Running Waters of Greece.

Author

Stefanidis, Konstantinos, Oikonomou, Anthi, Dimitrellos, Georgios, Tsoukalas, Dionysios, and Papastergiadou, Eva

Subjects

*MACROPHYTES, *DISCRETE groups, *ENVIRONMENTAL indicators, *ECOSYSTEM health, *HIERARCHICAL clustering (Cluster analysis), *CHEMICAL composition of plants

Abstract

The analysis of plant trait composition has raised significant interest among freshwater ecologists as a complementary approach for assessing the effects of environmental change on ecosystem functions. In this study, we investigated patterns of functional traits of the aquatic macrophyte assemblages of 74 lotic ecosystems of Greece, and we identified associations between species traits and environmental variables (hydromorphological and physicochemical parameters) through testing the hypothesis that the environmental features determine the spatial structure of traits. We allocated 12 traits to a total of 39 hydrophyte species, and we conducted RLQ and fourth corner analysis to explore relationships between species, trait composition, and environmental gradients. Based on the results of the RLQ, a hierarchical cluster analysis was conducted to identify groups of plants that share common trait characteristics. Plants were discriminated into five discrete groups based mostly on their life form (e.g., free-floating, rooted submerged etc.) and their ecological preference for nitrogen levels. Hydromorphological parameters had a higher contribution than physicochemical variables in explaining the total variance of the trait data, with water abstraction, channel substrate, and hydrologic alteration being the most important. Our analysis did not reveal significant bivariate relationships between single traits and environmental parameters, although the five groups of macrophyte assemblages appeared to associate with certain environmental gradients. Free-floating and emergent plants were related to higher concentrations of nutrients, whereas rooted submerged plants were related to higher oxygen concentration and increased pH. In addition, free-floating plants were highly associated with metrics of hydromorphological change. Our findings showed clear discrimination of macrophytes based on their functional composition and association of traits with environmental gradients. Thus, further research could explore whether macrophyte functional groups can serve as indicators of environmental change and the overall ecosystem health. [ABSTRACT FROM AUTHOR]

Published

2023

115. The plant–mycorrhizal fungi collaboration gradient depends on plant functional group.

Author

Romero, Ferran, Argüello, Alicia, de Bruin, Susanne, and van der Heijden, Marcel G. A.

Subjects

*FUNCTIONAL groups, *VESICULAR-arbuscular mycorrhizas, *PLANT colonization, *MYCORRHIZAL plants, *LEAF area, *LEGUMES, *GRASSLAND soils, *CLOVER

Abstract

Plant colonization by arbuscular mycorrhizal fungi (AMF) is widespread and can offer considerable benefits in terms of growth, nutrient uptake and plant yield. However, it is still unresolved how different plant species and plant functional groups respond to AMF and to different AMF taxa.Here we established 336 grassland microcosms to determine the response of 14 plant species displaying contrasting functional groups (grasses, legumes and non‐leguminous forbs) for the presence of three different AMF taxa. For each plant species, we calculated the degree to which plant growth depended on AMF colonization (i.e. mycorrhizal dependency [MD]). We also determined the degree to which each plant species relied on specific AMF taxa for optimal growth (i.e. mycorrhizal species sensitivity [MSS]). Additionally, we determined whether MD and MSS correlated to specific plant traits (i.e. specific root length [SRL], specific leaf area [SLA]).The plant growth response to AMF ranged from −84.9% for a non‐mycorrhizal plant (Luzula campestris) to +94.0% for a legume (Trifolium arvensis). The MD was systematically higher in legumes (91.9% ± 2.4%), followed by non‐leguminous forbs (77.1% ± 11.06) and grasses (42.1% ± 15.73%). MSS was less variable (8.9%–37.7%); it was independent of plant functional group and did not correlate with MD. MD was linked to various mycorrhizal plant parameters, including AMF colonization (R2 = +0.80) and total dry biomass (R2 = +0.32). Moreover, among mycorrhizal plants (n = 12), MD negatively correlated with SRL (R2 = −0.24) and positively with SLA (R2 = +0.24).Synthesis. This study shows that plants relying on AMF for biomass production also show higher root colonization, lower SRL, higher SLA and that different plant traits are interlinked with the way how plants respond to AMF. Overall, this study further demonstrates that different plant functional groups vary in their response to AMF. Read the free Plain Language Summary for this article on the Journal blog. [ABSTRACT FROM AUTHOR]

Published

2023

116. Proglacial slopes are protected against erosion by trait diverse and dense plant communities associated with specific microbial communities.

Author

Ohler, Lisa-Maria, Haselberger, Stefan, Janssen, Stefan, Otto, Jan-Christoph, Kraushaar, Sabine, and Junker, Robert R.

Subjects

PLANT communities, MICROBIAL communities, EROSION, SOIL erosion, SEDIMENT transport, PLANT diversity

Abstract

Soil erosion is a severe threat for ecosystems and anthropogenic infrastructure. Glaciers are retreating rapidly due to global warming and the receding ice leaves unvegetated depositions of sediment, which are prone to mobilisation during precipitation events. Vegetation is known to serve as erosion protection, but how above- and belowground plant traits, vegetation cover and plant diversity on community level are jointly affecting erosion is unclear. Additionally, soil microbial communities may have effects on slope stability by promoting plant growth and function. We measured sediment transport on 30 plots of 2 × 3 m size on proglacial slopes of the Gepatschferner glacier (Kaunertal, Austria) over three years in a natural pristine high alpine environment. Vegetation cover, species abundances and relevant above- and belowground traits were measured for each occurring plant species on community level. Path model analysis revealed that dense and species-rich plant cover characterized by specific plant growth strategies and trait diversity was best suited to decrease erosion. Vegetation properties were also closely linked to the composition of soil microbial communities characterised by next generation amplicon sequencing, which may facilitate soil formation and further enhance the plants' soil stabilising potential. Our study illustrates that erosion control may benefit from a high vegetation cover, which is facilitated by diverse plant communities with complementary morphological traits. These vegetation properties also affect soil microbiota, but their impact on slope protection in combination with the vegetation remains to be elucidated. Our findings may inform nature-based solutions against erosion such as revegetation of alpine slopes using specific seed mixtures. [ABSTRACT FROM AUTHOR]

Published

2023

117. Deciduous Tundra Shrubs Shift Toward More Acquisitive Light Absorption Strategy Under Climate Change Treatments.

Author

Heim, R. J., Iturrate‐Garcia, M., Reji Chacko, M., Karsanaev, S., Maximov, T. C., Heijmans, M. M. P. D., and Schaepman‐Strub, G.

Subjects

TUNDRAS, LIGHT absorption, CLIMATE change, SOIL heating, NUTRIENT cycles, SHRUBS, PLANT size

Abstract

The effects of climate change on plants are particularly pronounced in the Arctic region. Warming relaxes the temperature and nutrients boundaries that limit tundra plant growth. Increased resource availability under future climate conditions may induce a shift from a conservative economic strategy to an acquisitive one. Following the leaf economics spectrum that hypothesizes a strategy gradient between survival, plant size and costs for the photosynthetic leaf area, light absorption of tundra plants may increase. We investigated climate change effects on light absorptance and the relationship between light absorptance (fraction of absorbed photosynthetically active radiation, FAPAR) and structural and nutritional leaf traits, performing a soil warming and surface soil fertilization experiment on two deciduous tundra shrub species. Our results show that fertilization and warming combined increase light absorptance in Arctic shrubs and that FAPAR is correlated with leaf nutrients but not with structural leaf traits. This indicates an economic strategy shift of shrubs from conservative to acquisitive induced by warming and fertilization combined. We found species‐specific differences: FAPAR was influenced by warming alone in Betula nana but not in Salix pulchra, and FAPAR was correlated with leaf phosphorus in B. nana but not in S. pulchra. We attribute this to water limitation of B. nana that generally grows in drier areas within the study site compared to S. pulchra. We conclude that FAPAR is a measure that opens up more possibilities to estimate nutritional leaf traits and nutrient cycles, plant economic strategies, and ecological feedbacks of the tundra ecosystem on broader scales. Plain Language Summary: The effects of climate change on plants are very strong in the Arctic. Tundra plants are usually limited by temperature and nutrients. Tundra plants usually have an energy saving strategy, with long lifespan and small leaves. A warmer environment with more nutrients may shift their strategy to faster growth, larger leaves, and more light absorption. We examined climate change effects on the light absorptance of two tundra shrubs. In order to do this, we made an experiment in which we warmed and fertilized the soil. We furthermore studied the relationship between light absorptance and plant traits. Our results show that fertilization and warming combined increase light absorptance in Arctic shrubs. Furthermore, we could show that light absorptance is strongly related to the concentration of nutrients in the leaves. We also found differences in light absorptance between the two shrub species. We believe that these differences are due to Betula nana growing in drier areas with less water compared to Salix pulchra. We think that light absorptance is a good measure for predicting changes in nutrient cycles and plant strategies in the tundra ecosystem. Key Points: Fertilization and warming combined increase light absorptance in two deciduous Arctic shrub species. This indicates an economic strategy shiftLight absorptance is correlated with leaf nutrients but not with structural leaf traits in Arctic shrubsThere are species‐specific differences between the shrub species in regard to light absorptance [ABSTRACT FROM AUTHOR]

Published

2023

118. Species-Specific Responses to Human Trampling Indicate Alpine Plant Size Is More Sensitive than Reproduction to Disturbance.

Author

Chardon, Nathalie Isabelle, Stone, Philippa, Hilbert, Carly, Maclachlan, Teagan, Ragsdale, Brianna, Zhao, Allen, Goodwin, Katie, Collins, Courtney G., Hewitt, Nina, and Elphinstone, Cassandra

Subjects

MOUNTAIN plants, PLANT size, MOUNTAIN ecology, GROUND cover plants, TRAILS

Abstract

Human disturbance, such as trampling, is an integral component of global change, yet we lack a comprehensive understanding of its effects on alpine ecosystems. Many alpine systems are seeing a rapid increase in recreation and in understudied regions, such as the Coast Mountains of British Columbia, yet disturbance impacts on alpine plants remain unclear. We surveyed disturbed (trail-side) and undisturbed (off-trail) transects along elevational gradients of popular hiking trails in the T'ak't'ak'múy'in tl'a In'inyáxa7n region (Garibaldi Provincial Park), Canada, focusing on dominant shrubs (Phyllodoce empetriformis, Cassiope mertensiana, Vaccinium ovalifolium) and graminoids (Carex spp). We used a hierarchical Bayesian framework to test for disturbance by elevation effects on total plant percent cover, maximum plant height and diameter (growth proxies), and buds, flowers, and fruits (reproduction proxies). We found that trampling reduces plant cover and impacts all species, but that effects vary by species and trait, and disturbance effects only vary with elevation for one species' trait. Growth traits are more sensitive to trampling than reproductive traits, which may lead to differential impacts on population persistence and species-level fitness outcomes. Our study highlights that disturbance responses are species-specific, and this knowledge can help land managers minimize disturbance impacts on sensitive vegetation types. [ABSTRACT FROM AUTHOR]

Published

2023

119. 三江源地区人工克隆植物群落生物多样性 对初级生产力的影响及机制.

Author

刘增辉, 卢素锦, 王雨欣, 张春辉, and 尹鑫

Abstract

Copyright of Acta Prataculturae Sinica is the property of Acta Prataculturae Sinica Editorial Office and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2023

120. Some like it hot: small genomes may be more prevalent under climate extremes

Author

Meyerson, Laura A., Cronin, James T., Lučanová, Magdalena, Lambertini, Carla, Brix, Hans, Packer, Jasmin G., Čuda, Jan, Wild, Jan, Pergl, Jan, and Pyšek, Petr

Published

2024

121. When the growing gets tough: Ecological restoration in southern California shrublands

Author

Dewees, Shane Landau

Subjects

Ecology, Physiology, Botany, drought, fire, nucleation restoration, plant traits, restoration, shrublands

Abstract

Habitat degradation and conversion have become a ubiquitous problem globally and are expected to increase with climate change. In areas where degradation and conversion have already occurred, ecological restoration – defined by the Society for Ecological Restoration as the process of assisting the recovery of an ecosystem that has been degraded, damaged, or destroyed – provides a promising avenue to conserve biodiversity and ecosystem function. However, while projects have achieved restoration success, that is not a consistent outcome, even in the most well-studied ecosystems. The burgeoning field of plant functional trait ecology posits, however, that there are fundamental relationships between plant functional traits and how species respond to their environment. Therefore, classifying species by their plant traits, instead of taxonomic identity, offers a promising way to expand the findings of restoration ecology research to new settings and species.Here, we investigate how to conduct successful ecological restoration in the mediterranean shrublands of southern California, an ecosystem with very little ecological restoration research. Specifically, the research presented herein took place in the Los Padres National Forest, just outside Piru, California. This area has experienced extensive shrubland conversion to non-native grasses over the last few decades and has been identified as a specific area of restoration interest by the United States Forest Service. We first conduct a regional spatial analysis to identify where and why shrublands are being lost to inform how we might conduct restoration. Second, we conducted a large-scale landscape restoration project with a physiologically diverse set of ten species, measured a variety of plant traits (i.e. wood density, integrated water use efficiency, and parts of the leaf economics spectrum) and measured daily microsite temperature (n = 115), humidity (n = 39) and soil moisture (n = 30). This then allowed us to map microsite environmental conditions across the whole landscape, assess how the microsite differences influenced survival, and test how plant traits related to these interspecific responses. Lastly, we conducted another restoration experiment with 13 shrubland species. This experiment evaluated how a spectrum of planting densities in a ‘restoration island’ approach influenced survival in the harshest parts of the landscape and how plant traits relate to those influences.Our findings showed 1.) shrubland conversion is primarily happening in low elevation, southwest facing slopes (i.e. more arid slopes) and during periods of postfire drought. 2.) Low soil moisture and high vapor pressure deficit (VPD) are primary drivers of year one mortality. Additionally, species with higher water use efficiencies can survive high VPD if soil moisture remains moderate. Conversely, species on the more acquisitive side of the leaf economics spectrum can survive low soil moisture if VPD remains moderate. And 3.) in general plot level survival increases significantly with higher planting densities. Inclusion of plant traits revealed that more acquisitive species benefiting the most from this facilitation. Conversely, species with higher water use efficiencies were negatively impacted by higher planting densities. Overall, my dissertation details foundational knowledge for the restoration of southern California shrublands and more broadly shows the potential for plant functional traits to inform restoration planning and increase the consistency of restoration success.

Published

2024

122. Optical remote sensing of vegetation canopy properties from local to global scales

Author

Thomson, Eleanor, Malhi, Yadvinder, and Doughty, Chris

Subjects

Remote sensing, Machine learning, Environmental mapping, Plant traits, Satellite image maps, Drone aircraft in remote sensing

Abstract

We are in the midst of a new era of Earth Observation for vegetation monitoring. Recent enhancements in the spectral, spatial and temporal resolution, as well as availability, of optical sensors provides opportunities to significantly advance the retrieval of vegetation properties at multiple scales. However, directed research linking optical imagery to field-collected vegetation measurements is required to optimally harness current and future advances in remote sensor technologies. This thesis aims to investigate the optical remote sensing of plant functional traits at four scales: the leaf, unmanned aerial vehicle (UAV), aircraft and satellite level. This thesis has four objectives, each of which are addressed through a research article. The main objective of the first article, entitled 'Multiscale mapping of plant functional groups and plant traits in the High Arctic using field spectroscopy, UAV imagery and Sentinel-2 data', is to evaluate the use of multispectral UAV imagery for mapping biochemical leaf traits in high Arctic tundra. The High Arctic is an ideal environment for establishing a baseline potential for mapping leaf traits using UAV imagery, as species richness is low and vegetation cover lacks the structure and confounding effects of a forest canopy. The article starts by using field spectroscopy to classify plant species and quantify biochemical plant traits (water content, nitrogen (N), phosphorus (P) and C:N ratios). At the UAV level, it classifies three plant functional types (mosses, graminoids and dwarf shrubs) at 72% accuracy and generates maps of plant chemistry. (r2 = 0.44-0.54, RMSEmean = 26%-48%). Lastly, the UAV results were used to explore two methods of upscaling plant water content to the wider landscape using Sentinel-2 imagery. The objective of the second article, entitled 'Mapping the Leaf Economic Spectrum across West African Tropical Forests Using UAV-Acquired Hyperspectral Imagery' is to evaluate the use of hyperspectral UAV imagery for mapping biochemical leaf traits across a species-rich, structurally complex forest canopy in Ghana, West Africa. Similarly, the article starts by using field spectroscopy to estimate six biochemical plant traits (leaf mass per area (LMA), N, P, calcium (Ca) and magnesium (Mg)). At the airborne level, four of the six leaf traits demonstrated weak (p < 0.10) correlations with the UAV-collected hyperspectral imagery: r2 = 0.25 (LMA), r2 = 0.22 (N), r2 = 0.22 (P), and r2 = 0.25 (Ca). Mapping the leaf economic spectrum (LMA, N and P) across a precipitation gradient reflected carbon cycling data, and revealed precipitation and substrate as co-dominant drivers of trait distributions and relationships. The objective of the third article, entitled 'Mapping photosynthetic capacity in a Bornean tropical forest from airborne and satellite imagery: challenges and recommendations', expands focus from mapping biochemical leaf traits to mapping photosynthetic capacity (Vcmax25 and Jmax25) across a forest disturbance gradient in Malaysian Borneo using aircraft-collected hyperspectral imagery and Sentinel-2 imagery. In addition, it explores increased image quality issues associated with expanded spatial coverage. Aircraft-collected hyperspectral imagery was found to exhibit poor radiometric calibration and Sentinel-2 imagery was found to suffer from processing errors related to cloud masking and inconsistent surface reflectance values, especially over humid tropical forests. The strongest model performance (r2=0.36 and 0.43 for Vcmax25 and Jmax25 respectively) was produced by tuning the high spectral and spatial resolution of the aircraft-collected hyperspectral imagery with the improved signal-to-noise ratio of a Sentinel time-series composite, demonstrating the importance of diagnosing and minimising data quality issues. The last article entitled 'Global mapping of the photosynthetic capacity of tropical forests', combines Sentinel-2A imagery, environmental datasets and photosynthesis data from 35 tropical forest GEM plots to create a pan-tropical map of Vcmax25 and Jmax25. To the best of my knowledge, this is the first research that uses Sentinel-2 imagery to map tropical forest Vcmax25 and Jmax25 globally. Models captured 38% and 57% of variation in Vcmax25 and Jmax25 across lowland forest, and 62% and 61% of variation across lowland-and-montane forest. In lowland-only forest, mean climatic water deficit (MCWD) and solar radiation were most important predictors of Vcmax25 and Jmax25 respectively. In lowland-and-montane forest, the strongest predictor of both Vcmax25 and Jmax25 was mean annual temperature (MAT). At intercontinental scales, Vcmax25 and Jmax25 values were mainly controlled by climate. At the regional level, trait distributions were shaped by soil type. At local levels, trait patterns reflected spectral variation arising from topography and canopy structure. Overall, this thesis offers new methodologies to measure and monitor tropical forest functional diversity and productivity. It builds from a simple ecosystem to a floristically and structurally complex tropical forest, and explores the trade-offs of expanding spatial coverage and decreasing spectral resolution for the retrieval of vegetation canopy traits. Alongside, it highlights current limitations of optical remote sensing, and presents best-practice recommendations for future imaging studies. The results are pertinent for high resolution, low cost mapping of tundra and tropical forest ecosystems (and potentially for other terrestrial ecosystems), and for improving the representation of vegetation properties, especially photosynthetic capacity, in the next generation of Earth System Models.

Published

2021

123. Ecological legacies of past fire and human activity in a Panamanian forest

Author

Crystal N. H. McMichael, Veerle Vink, Britte M. Heijink, Nina H. Witteveen, Dolores R. Piperno, William D. Gosling, and Mark B. Bush

Subjects

charcoal, fire, Oenocarpus, palms, phytoliths, plant traits, Environmental sciences, GE1-350, Botany, QK1-989

Abstract

Societal Impact Statement Tropical forests provide global ecosystem services and harbor much of Earth's terrestrial biodiversity, but the mechanisms driving the patterns of biodiversity remain uncertain. Palms are one of the most abundant and most widely used plant groups, particularly in the Neotropics. Our data highlight how both direct and indirect human influence that occurred decades to hundreds of years ago can affect the abundances of palm species in modern tropical forests. Our results highlight that biodiversity is dynamic, and changes through time, and that human activities can affect species composition for centuries in tropical forests. Summary Human activities over the past decades and centuries, including fire, cultivation, and forest opening, may have left ecological legacies that persist in modern tropical forests, particularly among palms. We investigated whether past human activities affected modern palm abundances in a well‐studied plot located in a tropical semievergreen forest of Panama. We analyzed soil cores for charcoal to reconstruct past fire events and phytoliths to reconstruct past vegetation changes. We dated as many charcoal fragments as possible to place a temporal framework on past fire events. Our analysis documented widespread fires that occurred 600–900 years ago across the plot. Oenocarpus mapora increased in abundance as a result of these fires, though other palms did not. A subsequent increase in O. mapora occurred later in the relative absence of fire and was likely due to game hunting during the construction of the Panama Canal. Our results showed that the enrichment of O. mapora was determined by disturbance characteristics (e.g., timing, type, and intensity), but the persistence of increased abundances was likely determined by traits (life history characteristics). These data highlight the complexity of human–environment interactions and how they can persist for centuries in settings with long‐lived trees such as tropical forests. These data highlight the importance of adding a historical context to further understand modern ecological patterns and processes.

Published

2023

124. Age-Related Conservation in Plant–Soil Feedback Accompanied by Ectomycorrhizal Domination in Temperate Forests in Northeast China

Author

Zhen Bai, Ji Ye, Shu-Fang Liu, Hai-Hong Sun, Zuo-Qiang Yuan, Zi-Kun Mao, Shuai Fang, Shao-Fen Long, and Xu-Gao Wang

Subjects

ectomycorrhizal (EcM) fungi, forest aging, soil nutrient dynamics, plant traits, temperate forest ecology, mycorrhizal exploration type, Biology (General), QH301-705.5

Abstract

This study investigates the effects of forest aging on ectomycorrhizal (EcM) fungal community and foraging behavior and their interactions with plant–soil attributes. We explored EcM fungal communities and hyphal exploration types via rDNA sequencing and investigated their associations with plant–soil traits by comparing younger (~120 years) and older (~250 years) temperate forest stands in Northeast China. The results revealed increases in the EcM fungal richness and abundance with forest aging, paralleled by plant–soil feedback shifting from explorative to conservative nutrient use strategies. In the younger stands, Tomentella species were prevalent and showed positive correlations with nutrient availability in both the soil and leaves, alongside rapid increases in woody productivity. However, the older stands were marked by the dominance of the genera Inocybe, Hymenogaster, and Otidea which were significantly and positively correlated with soil nutrient contents and plant structural attributes such as the community-weighted mean height and standing biomass. Notably, the ratios of longer-to-shorter distance EcM fungal exploration types tended to decrease along with forest aging. Our findings underscore the integral role of EcM fungi in the aging processes of temperate forests, highlighting the EcM symbiont-mediated mechanisms adapting to nutrient scarcity and promoting sustainability in plant–soil consortia.

Published

2024

125. Both management practices and landscape influence plant communities in urban grasslands

Author

Clément Gros, Adeline Bulot, Stéphanie Aviron, Véronique Beaujouan, and Hervé Daniel

Subjects

herbaceous green spaces, low intensity mowing, urbanization, plant traits, biodiversity conservation, meadows, Evolution, QH359-425, Ecology, QH540-549.5

Abstract

The development of urban areas now requires the integration of biodiversity issues, and this leads to better consideration of their seminatural habitats. Among these habitats, urban grasslands subjected to mowing management practices are commonly promoted over lawns to enhance biodiversity in cities. Despite their ecological value, relatively little attention has been paid to the effects of urban grassland management regimes or the landscape contexts of these habitats in terms of biodiversity. This study aims to investigate the effects of mowing practices and the landscape context of urban grasslands on species diversity and composition and the ecological strategies of plant communities. In this study, 66 sites (mown grasslands) were selected in the Angers and Rennes conurbations of western France according to their management practices (regarding mowing) and landscape gradient (more or less urbanized). The results show that mowing practices and landscape composition did not affect the richness or diversity of plant species but significantly influenced the composition of communities. Partitioning analysis showed that landscape composition explained twice as much of the variance in plant species composition as mowing practices did. Landscape composition favors plant species according to their strategies, preferential habitats, and life spans. Furthermore, diversification of management practices limits the establishment of nonnative species and induces a wider range of functional strategies, as late mowing favors competitors and disfavors stress-tolerant species. Nevertheless, management practices need to be put into perspective in the context of urban grasslands. Thus, this research brings new perspectives to recommendations for the management of urban green spaces.

Published

2023

126. Isolating the effects of land use and functional variation on Yucatán's forest biomass under global change

Author

Stephanie P. George-Chacon, T. Luke Smallman, Juan Manuel Dupuy, José Luis Hernández-Stefanoni, David T. Milodowski, and Mathew Williams

Subjects

forest biomass, plant traits, carbon cycle, land surface model, chronosequence, leaf area index, Forestry, SD1-669.5, Environmental sciences, GE1-350

Abstract

Tropical forests hold large stocks of carbon in biomass and face pressures from changing climate and anthropogenic disturbance. Forests' capacity to store biomass under future conditions and accumulate biomass during regrowth after clearance are major knowledge gaps. Here we use chronosequence data, satellite observations and a C-cycle model to diagnose woody C dynamics in two dry forest ecotypes (semi-deciduous and semi-evergreen) in Yucatán, Mexico. Woody biomass differences between mature semi-deciduous (90 MgC ha−1) and semi-evergreen (175 MgC ha−1) forest landscapes are mostly explained by differences in climate (c. 60%), particularly temperature, humidity and soil moisture effects on production. Functional variation in foliar phenology, woody allocation, and wood turnover rate explained c. 40% of biomass differences between ecotypes. Modeling experiments explored varied forest clearance and regrowth cycles, under a range of climate and CO2 change scenarios to 2100. Production and steady state biomass in both ecotypes were reduced by forecast warming and drying (mean biomass 2021–2100 reduced 16–19% compared to 2001–2020), but compensated by fertilisation from rising CO2. Functional analysis indicates that trait adjustments amplify biomass losses by 70%. Experiments with disturbance and recovery across historically reported levels indicate reductions to mean forest biomass stocks over 2021–2100 similar in magnitude to climate impacts (10–19% reductions for disturbance with recovery). Forest disturbance without regrowth amplifies biomass loss by three- or four-fold. We conclude that vegetation functional differences across the Yucatán climate gradient have developed to limit climate risks. Climate change will therefore lead to functional adjustments for all forest types. These adjustments are likely to magnify biomass reductions caused directly by climate change over the coming century. However, the range of impacts of land use and land use change are as, or more, substantive than the totality of direct and indirect climate impacts. Thus the carbon storage of Yucatan's forests is highly vulnerable both to climate and land use and land use change. Our results here should be used to test and enhance land surface models use for dry forest carbon cycle assessment regionally and globally. A single plant functional type approach for modeling Yucatán's forests is not justified.

Published

2023

127. Plant Traits and Phylogeny Predict Soil Carbon and Nutrient Cycling in Mediterranean Mixed Forests.

Author

Prieto-Rubio, J., Perea, A., Garrido, J. L., Alcántara, J. M., Azcón-Aguilar, C., López-García, A., and Rincón, A.

Subjects

*MIXED forests, *NUTRIENT cycles, *CARBON cycle, *BIOTIC communities, *FOREST soils

Abstract

Soil functioning is closely linked to the interactions between biological communities with the physical environment. Yet, the impact of plant community attributes on metabolic processes promoting soil nutrient cycling remains largely unknown. We hypothesized that the plant community acts as a regulating agent of nutrient mobilization in soils according to the phylogenetic and morpho-functional traits of plant species of which it is composed. Rhizosphere soils were collected in autumn and spring under 32 tree and shrub species in two Mediterranean mixed forests (four plots in each) located in southern Spain, and nine soil enzymatic activities related to C, N and P mobilization were assessed. Phylogeny and morpho-functional traits of plant species were recorded and their imprint in soil enzymatic activities across forests was determined. The results showed a plant phylogenetic signal for N mobilization in both forests, while it varied across forests for non-labile C and P mobilization. The plant phylogenetic signals were primarily driven by lineages that diversified through the Miocene, about 25 Myr ago. In addition, leaf traits and plant's mycorrhizal type explained soil enzymatic activities independently from phylogeny. C and P mobilization increased under ectomycorrhizal plants, whilst enhanced N mobilization did occur under arbuscular mycorrhizal ones. The plant community composition led to a different carbon and nutrient mobilization degree, which in turn was mediated by distinct microbial communities mirroring differentiated resource-acquisition strategies of plants. Our results highlight the role of plant traits and mycorrhizal interactions in modulating carbon and nutrient cycling in Mediterranean mixed forest soils. [ABSTRACT FROM AUTHOR]

Published

2023

128. Water‐limited environments affect the association between functional diversity and forest productivity.

Author

Lammerant, Roel, Rita, Angelo, Borghetti, Marco, and Muscarella, Robert

Subjects

*FOREST biodiversity, *FOREST productivity, *FOREST management, *FOREST surveys, *TEMPERATE forests, *PLANT gene banks, *ECOSYSTEM management, WOOD density

Abstract

The link between biodiversity and ecosystem function can depend on environmental conditions. This contingency can impede our ability to predict how biodiversity‐ecosystem function (BEF) relationships will respond to future environmental change, causing a clear need to explore the processes underlying shifts in BEF relationships across large spatial scales and broad environmental gradients. We compiled a dataset on five functional traits (maximum height, wood density, specific leaf area [SLA], seed size, and xylem vulnerability to embolism [P50]), covering 78%–90% of the tree species in the National Forest Inventory from Italy, to test (i) how a water limitation gradient shapes the functional composition and diversity of forests, (ii) how functional composition and diversity of trees relate to forest annual increment via mass ratio and complementarity effects, and (iii) how the relationship between functional diversity and annual increment varies between Mediterranean and temperate climate regions. Functional composition varied with water limitation; tree communities tended to have more conservative traits in sites with higher levels of water limitation. The response of functional diversity differed among traits and climatic regions but among temperate forest plots, we found a consistent increase of functional diversity with water limitation. Tree diversity was positively associated with annual increment of Italian forests through a combination of mass ratio and niche complementarity effects, but the relative importance of these effects depended on the trait and range of climate considered. Specifically, niche complementarity effects were more strongly associated with annual increment in the Mediterranean compared to temperate forests. Synthesis: Overall, our results suggest that biodiversity mediates forest annual increment under water‐limited conditions by promoting beneficial interactions between species and complementarity in resource use. Our work highlights the importance of conserving functional diversity for future forest management to maintain forest annual increment under the expected increase in intensity and frequency of drought. [ABSTRACT FROM AUTHOR]

Published

2023

129. Physiological Traits and Biomass Production of Two Euterpe Species under Drought Stress.

Author

Martins, M. O., Souza, T., de Melo, I. R., and da Silva, L. J. R.

Abstract

Our aim here was to evaluate the effects of drought stress on plant growth rate, biomass production, and physiological traits of endemic Euterpe species (Euterpe precatoria Mart.and Euterpe oleraceae Mart.) from Brazil’s Legal Amazon at greenhouse conditions. We characterized photosynthesis, gas exchange parameters, total chlorophyll concentration, plant water concentration, plant growth rate, and dry biomass production using four drought stress treatments (e.g., 25, 50, 75, and 100% of soil field capacity) considering two Euterpe species (E. precatoria and E. oleraceae). We found the highest values of net photosynthesis, Fv/Fm, chlorophyll b concentration, root dry biomass, and shoot dry biomass production on pots where E. oleraceae was cultivated. On the other hand, E. precatoria showed the highest values of non-photochemical quenching, carotenoids, stomatal conductance, photochemical quenching, energy excess, and water use efficiency at 25% of the soil field capacity. Our findings suggest that (1) the drought stress can change both physiological responses and dry biomass production of Euterpe species; (2) E. oleraceae showed the highest biomass production in our experiment, but E. precatoria showed the highest water use efficiency; and (3) we could consider E. precatoria more resistant to drought stress than E. oleraceae. The drought stress altered Euterpe physiological traits, and dry biomass production. Euterpe species may create different pathways into their life history to produce biomass and improve their own performance even submitted in drought conditions. [ABSTRACT FROM AUTHOR]

Published

2023

130. Plant–soil feedback under drought: does history shape the future?

Author

de Vries, Franciska, Lau, Jennifer, Hawkes, Christine, and Semchenko, Marina

Subjects

*DROUGHTS, *DROUGHT management, *VEGETATION dynamics, *LOCAL history, *SOIL microbiology, *PLANT adaptation, *PLANT communities

Abstract

Drought, which is increasing in intensity and frequency with climate change, can severely affect plant growth and alter vegetation dynamics. Plants modify microbial communities in their rhizosphere, which in turn affect plant productivity and local persistence, creating so-called plant–soil feedback (PSF). As droughts impact both plant and soil microbial attributes, PSF is likely to change under and following drought events, but limited experimental tests produce widely diverging results regarding the direction and magnitude of changes. Combined evidence from a range of related research fields suggests that PSF response to drought may be predicted by plant traits, the intensity of drought, and the drought histories of both plants and microbes. Explicit inclusion of coexistence history and the local adaptation of plants and soil microbes at local and regional scales will enable more realistic predictions about the contribution of plant–microbial associations to plant community response to climate change. Plant–soil feedback (PSF) is widely recognised as a driver of plant community composition, but understanding of its response to drought remains in its infancy. Here, we provide a conceptual framework for the role of drought in PSF, considering plant traits, drought severity, and historical precipitation over ecological and evolutionary timescales. Comparing experimental studies where plants and microbes do or do not share a drought history (through co-sourcing or conditioning), we hypothesise that plants and microbes with a shared drought history experience more positive PSF under subsequent drought. To reflect real-world responses to drought, future studies need to explicitly include plant–microbial co-occurrence and potential co-adaptation and consider the precipitation history experienced by both plants and microbes. [ABSTRACT FROM AUTHOR]

Published

2023

131. Evolutionary history shapes grassland productivity through opposing effects on complementarity and selection.

Author

Larkin, Daniel J., Glasenhardt, Mary‐Claire, Williams, Evelyn W., Karimi, Nisa, Barak, Rebecca S., Leavens, Emma, and Hipp, Andrew L.

Subjects

*GRASSLANDS, *SPECIES diversity, *CONTRAST effect, *CONSERVATION & restoration, *ECOSYSTEMS, *PRAIRIES

Abstract

Phylogenetic diversity (PD), the evolutionary history of the organisms comprising a community, is increasingly recognized as an important driver of ecosystem function. However, biodiversity–ecosystem function experiments have rarely included PD as an a priori treatment. Thus, PD's effects in existing experiments are often confounded by covarying differences in species richness and functional trait diversity (FD). Here we report an experimental demonstration of strong PD effects on grassland primary productivity that are independent of FD, which was separately manipulated, and species richness, which was planted uniformly high to mimic diverse natural grasslands. Partitioning diversity effects demonstrated that higher PD increased complementarity (niche partitioning and/or facilitation) but lowered selection effects (probability of sampling highly productive species). Specifically, for every 5% increase in PD, complementarity increased by 26% on average (±8% SE), while selection effects decreased more modestly (8 ± 16%). PD also shaped productivity through clade‐level effects on functional traits, that is, trait values associated with particular plant families. This clade effect was most pronounced in the Asteraceae (sunflower family), which, in tallgrass prairies, generally comprises tall, high‐biomass species with low phylogenetic distinctiveness. FD also reduced selection effects but did not alter complementarity. Our results show that PD, independent of richness and FD, mediates ecosystem function through contrasting effects on complementarity and selection. This adds to growing evidence that consideration of phylogenetic dimensions of biodiversity can advance ecological understanding and inform conservation and restoration. [ABSTRACT FROM AUTHOR]

Published

2023

132. On trait variability in harsh habitats.

Author

Seifan, Merav

Subjects

*HABITATS, *BIOTIC communities, *PHYSIOLOGY, *BOTANY, *EXTREME weather, *PHYSIOLOGICAL adaptation

Abstract

Keywords: arid ecosystems; deserts; drylands; functional traits; limiting resources; local adaptation; plant traits EN arid ecosystems deserts drylands functional traits limiting resources local adaptation plant traits 1 4 4 08/31/23 20230801 NES 230801 Population success is an elusive term that integrates assumptions regarding traits that enable individuals to respond to local conditions with assumptions regarding the effects of these traits on characteristics of the population in which the individuals grow. Arid ecosystems, deserts, drylands, functional traits, limiting resources, local adaptation, plant traits Dryland mechanisms could widely control ecosystem functioning in a drier and warmer world. In such a case, while part of the trait variation may result from non-adaptive responses, it is highly unlikely that the major driver of plant responses, as reflected by their trait composition and variability, is an inadequate ability of individuals to respond to local habitat conditions. [Extracted from the article]

Published

2023

133. 矮壮素滴施时期对冬小麦茎秆抗倒伏能力的调控分析.

Author

张永强, 陈传信, 聂石辉, 徐其江, 赛力汗·赛, and 雷钧杰

Abstract

Copyright of Xinjiang Agricultural Sciences is the property of Xinjiang Agricultural Sciences Editorial Department and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2023

134. Trees harbouring ants are better defended than con-generic and sympatric ant-free trees.

Author

de Melo Teles e Gomes, Inácio José, Neves, Matheus Oliveira, and Paolucci, Lucas Navarro

Abstract

Plant strategies against herbivores are classically divided into chemical, physical, biotic defences. However, little is known about the relative importance of each type of plant defence, especially in the same species. Using the myrmecophyte Triplaris americana (both with and without ants), and the congeneric non-myrmecophyte T. gardneriana, we tested whether ant defence is more effective than other defences of naturally ant-free myrmecophytes and the non-myrmecophyte congeneric species, all spatially co-occurring. In addition, we investigated how plant traits vary among plant groups, and how these traits modulate herbivory. We sampled data on leaf area loss and plant traits from these tree groups in the Brazilian Pantanal floodplain, and found that herbivory is sixfold lower in plants with ants than in ant-free plants, supporting a major role of biotic defences against herbivory. Whereas ant-free plants had more physical defences (sclerophylly and trichomes), they had little effect on herbivory—only sclerophylly modulated herbivory, but with opposite effects depending on ants' presence and species identity. Despite little variation in the chemicals among plant groups, tannin concentrations and δ13C signatures negatively affected herbivory in T. americana plants with ants and in T. gardneriana, respectively. We showed that ant defence in myrmecophytic systems is the most effective against herbivory, as the studied plants could not fully compensate the lack of this biotic defence. We highlight the importance of positive insect-plant interactions in limiting herbivory, and therefore potentially plant fitness. [ABSTRACT FROM AUTHOR]

Published

2023

135. Plant–Soil Feedback of Companion Species during Grassland Community Succession.

Author

Zhang, Li, Zhang, Linhui, Huang, Lulu, Zhou, Huiling, Xue, Sha, Wang, Minggang, and Xu, Hongwei

Subjects

GRASSLANDS, GRASSLAND soils, SPECIES, LEAD in soils, PLANT growth, PLATEAUS, PLANT-soil relationships

Abstract

The responses of dominant species to plant–soil feedback (PSF) are well established; however, the changes in the PSF of companion species remain unclear. This study aims to assess the direction and intensity of PSF, determine the main factors influencing it, and interpret the ecological significance of PSF in companion species within the context of grassland community succession. Three typical companion species, namely Artemisia sacrorum, Artemisia capillaris, and Artemisia giraldii, were planted in soils at three grassland community succession stages (early, middle, and late) on the Loess Plateau. Our results indicate that during both plant growth periods, the shoot biomass of A. sacrorum, A. capillaris, and A. giraldii in early- and late-stage soils was higher than that in the middle-stage soil, suggesting consistent growth of the three companion species during the two growth periods. However, plant growth simultaneously led to a reduction in soil nutrient content and microbial biomass, resulting in an overall decrease in the biomass of the three species, indicating a negative PSF effect in companion species. In conclusion, the negative PSF observed in all three associated species explains the temporary dominance of companion species during succession. This study enhances our understanding of the mechanisms driving PSF in community succession. [ABSTRACT FROM AUTHOR]

Published

2023

136. Tree seedling growth allocation of Castanopsis kawakamii is determined by seed-relative positions.

Author

Jing Zhu, Lan Jiang, Lyuyi Chen, Xing Jin, Cong Xing, Jinfu Liu, Yongchuan Yang, and Zhongsheng He

Subjects

TREE seedlings, TREE growth, FOREST litter, FOREST regeneration, LEAF growth, SEEDLINGS

Abstract

Plants allocate growth to different organs as a strategy to obtain limiting resources in different environments. Tree seeds that fall from a mother tree settle on, within, or below the forest floor and litter layer, and their relative positions can determine seedling biomass and nutrient allocation and ultimately affect survival to the sapling stage. However, how emerged seedling biomass and nutrients of each organ are affected by seeds in different positions is not yet completely understood in subtropical forests. Therefore, an experiment was conducted with seeds positioned above the litter layers of different thicknesses, on the forest floor, and beneath the litter layer, and the influences of seed position on biomass allocation and nutrient use efficiency of emerged seedlings of Castanopsis kawakamii was examined. The aim of the study was to determine the optimal seed position to promote regeneration. Allocation strategies were well coordinated in the emerged seedlings from different seed positions. Seedlings from seeds positioned above litter layers of different thicknesses (~40 and 80 g of litter) allocated growth to leaf tissue at the expense of root tissue (lower root mass fraction) and increased nitrogen (N) and phosphorus (P) accumulation and nutrient use efficiency. Seedlings from seeds positioned beneath a deep litter layer allocated most growth to roots (high root: shoot ratio, root mass fraction) to capture available resources at the expense of leaf growth. Seedlings from seeds positioned on the forest floor allocated most growth to roots to obtain limiting resources. Further, we also found that these traits were clustered into three groups based on trait similarity, and the cumulative interpretation rate was 74.2%. Thus, seed relative positions significantly affected seedling growth by altering the allocation of resources to different organs. The different strategies indicated that root N:P ratios (entropy weight vector was 0.078) and P nutrient use efficiency were essential factors affecting seedling growth in the subtropical forest. Of the seed positions analyzed, beneath a moderate litter layer (~40 g of litter) was the most suitable position for the growth and survival of Castanopsis seedlings. In future studies, field and lab experiments will be combined to reveal the mechanisms underlying forest regeneration. [ABSTRACT FROM AUTHOR]

Published

2023

137. Nitrogen Addition Increases Freeze Resistance in Black Mangrove (Avicennia germinans) Shrubs in a Temperate-Tropical Ecotone.

Author

Feller, Ilka C., Berger, Uta, Chapman, Samantha K., Dangremond, Emily M., Dix, Nicole G., Langley, J. Adam, Lovelock, Catherine E., Osborne, Todd Z., Shor, Audrey C., and Simpson, Loraé T.

Subjects

*MANGROVE plants, *FREEZES (Meteorology), *AVICENNIA, *ECOTONES, *GLOBAL warming, *COASTAL wetlands, *SALT marshes

Abstract

Low temperature stress is the primary factor determining the latitudinal limits of tropical plants. As the climate warms, tropical species are migrating poleward, displacing native species and modifying ecosystem structure and function. Changes are particularly evident along latitudinal gradients with the highest velocity of change occurring in wetlands. In coastal wetlands, saltmarshes dominate at latitudes above 30°, whereas mangroves occur mostly in the tropics because most species are intolerant of freezing temperatures, but others, like Avicennia germinans (black mangrove), do tolerate freezing temperatures. In response to a warmer climate and fewer killing freezes, mangroves are currently expanding into saltmarshes. However, the speed of the transition from saltmarsh to mangrove can also be modified by extreme events and nutrient subsidies. In a fertilization experiment along the Atlantic coast of North America, we found that nitrogen addition altered plant traits in Avicennia, which increased their resistance to freezing temperatures. This trait shift resulted in negligible freeze effects during a January 2018 extreme freeze event compared to unfertilized plants, which lost more than 80% of the leaves and more than 40% of the wood in their canopies. The freeze-killed litter from unfertilized plants provided a nutrient pulse that influenced recovery, growth and mangrove cover for three years following the freeze. Nutrient enrichment and recovery from the freeze effects led to increased growth and structural complexity of the mangrove canopy, which further enhanced freeze tolerance, shrub growth form and the ability of Avicennia to displace the saltmarsh in the temperate–tropical ecotone. [ABSTRACT FROM AUTHOR]

Published

2023

138. Simulated Photovoltaic Solar Panels Alter the Seed Bank Survival of Two Desert Annual Plant Species.

Author

Hernandez, Rebecca R, Tanner, Karen E, Haji, Sophia, Parker, Ingrid M, Pavlik, Bruce M, and Moore-O'Leary, Kara A

Subjects

disturbance, drylands, photovoltaic, plant community, plant traits, rare species, renewable energy, seed banks, seed traits, solar energy

Abstract

Seed bank survival underpins plant population persistence but studies on seed bank trait-environment interactions are few. Changes in environmental conditions relevant to seed banks occur in desert ecosystems owing to solar energy development. We developed a conceptual model of seed bank survival to complement methodologies using in-situ seed bank packets. Using this framework, we quantified the seed bank survival of two closely related annual desert plant species, one rare (Eriophyllum mohavense) and one common (Eriophyllum wallacei), and the seed bank-environment interactions of these two species in the Mojave Desert within a system that emulates microhabitat variation associated with solar energy development. We tracked 4860 seeds buried across 540 seed packets and found, averaged across both species, that seed bank survival was 21% and 6% for the first and second growing seasons, respectively. After two growing seasons, the rare annual had a significantly greater seed bank survival (10%) than the common annual (2%). Seed bank survival across both species was significantly greater in shade (10%) microhabitats compared to runoff (5%) and control microhabitats (3%). Our study proffers insight into this early life-stage across rare and common congeners and their environmental interactions using a novel conceptual framework for seed bank survival.

Published

2020

139. Accurate forest projections require long‐term wood decay experiments because plant trait effects change through time

Author

Oberle, Brad, Lee, Marissa R, Myers, Jonathan A, Osazuwa‐Peters, Oyomoare L, Spasojevic, Marko J, Walton, Maranda L, Young, Darcy F, and Zanne, Amy E

Subjects

Biological Sciences, Ecology, Carbon Cycle, Ecosystem, Forests, Trees, Wood, carbon cycle, plant traits, temperate forest, temporal scale, wood decay, woody debris, Environmental Sciences, Biological sciences, Earth sciences, Environmental sciences

Abstract

Whether global change will drive changing forests from net carbon (C) sinks to sources relates to how quickly deadwood decomposes. Because complete wood mineralization takes years, most experiments focus on how traits, environments and decomposer communities interact as wood decay begins. Few experiments last long enough to test whether drivers change with decay rates through time, with unknown consequences for scaling short-term results up to long-term forest ecosystem projections. Using a 7 year experiment that captured complete mineralization among 21 temperate tree species, we demonstrate that trait effects fade with advancing decay. However, wood density and vessel diameter, which may influence permeability, control how decay rates change through time. Denser wood loses mass more slowly at first but more quickly with advancing decay, which resolves ambiguity about the after-life consequences of this key plant functional trait by demonstrating that its effect on decay depends on experiment duration and sampling frequency. Only long-term data and a time-varying model yielded accurate predictions of both mass loss in a concurrent experiment and naturally recruited deadwood structure in a 32-year-old forest plot. Given the importance of forests in the carbon cycle, and the pivotal role for wood decay, accurate ecosystem projections are critical and they require experiments that go beyond enumerating potential mechanisms by identifying the temporal scale for their effects.

Published

2020

140. TRY plant trait database – enhanced coverage and open access

Author

Kattge, Jens, Bönisch, Gerhard, Díaz, Sandra, Lavorel, Sandra, Prentice, Iain Colin, Leadley, Paul, Tautenhahn, Susanne, Werner, Gijsbert DA, Aakala, Tuomas, Abedi, Mehdi, Acosta, Alicia TR, Adamidis, George C, Adamson, Kairi, Aiba, Masahiro, Albert, Cécile H, Alcántara, Julio M, C, Carolina Alcázar, Aleixo, Izabela, Ali, Hamada, Amiaud, Bernard, Ammer, Christian, Amoroso, Mariano M, Anand, Madhur, Anderson, Carolyn, Anten, Niels, Antos, Joseph, Apgaua, Deborah Mattos Guimarães, Ashman, Tia‐Lynn, Asmara, Degi Harja, Asner, Gregory P, Aspinwall, Michael, Atkin, Owen, Aubin, Isabelle, Baastrup‐Spohr, Lars, Bahalkeh, Khadijeh, Bahn, Michael, Baker, Timothy, Baker, William J, Bakker, Jan P, Baldocchi, Dennis, Baltzer, Jennifer, Banerjee, Arindam, Baranger, Anne, Barlow, Jos, Barneche, Diego R, Baruch, Zdravko, Bastianelli, Denis, Battles, John, Bauerle, William, Bauters, Marijn, Bazzato, Erika, Beckmann, Michael, Beeckman, Hans, Beierkuhnlein, Carl, Bekker, Renee, Belfry, Gavin, Belluau, Michael, Beloiu, Mirela, Benavides, Raquel, Benomar, Lahcen, Berdugo‐Lattke, Mary Lee, Berenguer, Erika, Bergamin, Rodrigo, Bergmann, Joana, Carlucci, Marcos Bergmann, Berner, Logan, Bernhardt‐Römermann, Markus, Bigler, Christof, Bjorkman, Anne D, Blackman, Chris, Blanco, Carolina, Blonder, Benjamin, Blumenthal, Dana, Bocanegra‐González, Kelly T, Boeckx, Pascal, Bohlman, Stephanie, Böhning‐Gaese, Katrin, Boisvert‐Marsh, Laura, Bond, William, Bond‐Lamberty, Ben, Boom, Arnoud, Boonman, Coline CF, Bordin, Kauane, Boughton, Elizabeth H, Boukili, Vanessa, Bowman, David MJS, Bravo, Sandra, Brendel, Marco Richard, Broadley, Martin R, Brown, Kerry A, Bruelheide, Helge, Brumnich, Federico, Bruun, Hans Henrik, Bruy, David, Buchanan, Serra W, Bucher, Solveig Franziska, Buchmann, Nina, Buitenwerf, Robert, Bunker, Daniel E, and Bürger, Jana

Subjects

Climate Change Impacts and Adaptation, Biological Sciences, Ecology, Environmental Sciences, Access to Information, Biodiversity, Ecosystem, Plants, data coverage, data integration, data representativeness, functional diversity, plant traits, TRY plant trait database, Nutrient Network, Biological sciences, Earth sciences, Environmental sciences

Abstract

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.

Published

2020

141. Population origin determines the adaptive potential for the advancement of flowering onset in Lupinus angustifolius L. (Fabaceae)

Author

Sandra Sacristán‐Bajo, Alfredo García‐Fernández, Carlos Lara‐Romero, Samuel Prieto‐Benítez, Pablo Tabarés, Javier Morente‐López, María Luisa Rubio Teso, Aitor Alameda‐Martín, Elena Torres, and José María Iriondo

Subjects

artificial selection, climate change, evolutionary ecology, manual crosses, plant traits, population origin, Evolution, QH359-425

Abstract

Abstract In the present framework of global warming, it is unclear whether evolutionary adaptation can happen quick enough to preserve the persistence of many species. Specifically, we lack knowledge about the adaptive potential of the different populations in relation to the various constraints that may hamper particular adaptations. There is evidence indicating that early flowering often provides an adaptive advantage to plants in temperate zones in response to global warming. Thus, the objective of this study was to assess the adaptive potential for advancing flowering onset in Lupinus angustifolius L. (Fabaceae). Seeds from four populations from two contrasting latitudes in Spain were collected and sown in a common garden environment. Selecting the 25% of the individuals that flowered earlier in the first generation, over three generations, three different early flowering selection lines were established, involving both self‐crosses and outcrosses. All artificial selection lines advanced their flowering significantly with respect to the control line in the northernmost populations, but not in the southern ones. Selection lines obtained from outcrossing had a greater advancement in flowering than those from self‐crossing. No differences were found in the number or weight of the seeds produced between control and artificial selection lines, probably because plants in the common garden were drip irrigated. These results suggest that northern populations may have a greater adaptive potential and that southern populations may be more vulnerable in the context of climate warming. However, earlier flowering was also associated with changes in other traits (height, biomass, shoot growth, specific leaflet area, and leaflet dry matter content), and the effects of these changes varied greatly depending on the latitude of the population and selection line. Assessments of the ability of populations to cope with climate change through this and other approaches are essential to manage species and populations in a more efficient way.

Published

2023

142. Solanum elaeagnifolium Invasiveness under Semi-Arid Environmental Conditions in Tunisia

Author

Najla Sayari, Giuseppe Brundu, Zayneb Soilhi, and Mounir Mekki

Subjects

plant traits, silverleaf nightshade, Tunisia, vegetative propagation, weed control, Environmental technology. Sanitary engineering, TD1-1066

Abstract

Solanum elaeagnifolium, one of the world’s most widespread invasive weeds, thrives in the regions of Tunisia with a semi-arid climate. An enhanced understanding of its biological traits could be useful for its management. For this purpose, S. elaeagnifolium vegetative propagation, flowering, fruiting, and spread patterns were assessed under semi-arid environmental conditions at Chott Mariem (Tunisia) over three years (2013–2015). Our results revealed that S. elaeagnifolium showed an active vegetative growth phase during the spring (March–May). Thereafter, the plant stopped its vegetative growth in June–August in favor of flowering and fruiting. The vegetative growth resumed during September–October and declined in November, announcing its dormant period. Thanks to its vigorous rhizomatous system, S. elaeagnifolium was able to emit offshoots within a radius of 1.5 m from parent shoots by 30 months after its establishment. These findings could inform and improve dedicated management control options for S. elaeagnifolium. Silverleaf nightshade should be controlled before the full-flowering stage in spring and following the first autumnal rainfall to prevent vegetative propagation and fruiting.

Published

2022

143. Intraspecific phylogeny of a Patagonian fescue: differentiation at molecular markers and morphological traits suggests hybridization at peripheral populations.

Author

Guidalevich, V, Nagahama, N, López, A S, Angeli, J P, Marchelli, P, and Azpilicueta, M M

Subjects

*PLANT hybridization, *PHYLOGENY, *FESCUE, *GENETIC variation, *MAXIMUM likelihood statistics

Abstract

Background and Aims Grasses of the Festuca genus have complex phylogenetic relations due to morphological similarities among species and interspecific hybridization processes. Within Patagonian fescues, information concerning phylogenetic relationships is very scarce. In Festuca pallescens , a widely distributed species, the high phenotypic variability and the occurrence of interspecific hybridization preclude a clear identification of the populations. Given the relevance of natural rangelands for livestock production and their high degradation due to climate change, conservation actions are needed and knowledge about genetic variation is required. Methods To unravel the intraspecific phylogenetic relations and to detect genetic differences, we studied 21 populations of the species along its natural geographical distribution by coupling both molecular [internal transcribed spacer (ITS) and trn L-F markers] and morpho-anatomical analyses. Bayesian inference, maximum likelihood and maximum parsimony methods were applied to assemble a phylogenetic tree, including other native species. The morphological data set was analysed by discriminant and cluster analyses. Key Results The combined information of the Bayesian tree (ITS marker), the geographical distribution of haplotype variants (trn L-F marker) and the morpho-anatomical traits, distinguished populations located at the margins of the distribution. Some of the variants detected were shared with other sympatric species of fescues. Conclusions These results suggest the occurrence of hybridization processes between species of the genus at peripheral sites characterized by suboptimal conditions, which might be key to the survival of these populations. [ABSTRACT FROM AUTHOR]

Published

2023

144. Drought is threatening plant growth and soil nutrients of grassland ecosystems: A meta‐analysis.

Author

Liu, Cheng, Siri, Muji, Li, Hui, Ren, Cheng, Huang, Jing, Feng, Changliang, and Liu, Kesi

Subjects

*GRASSLANDS, *DROUGHTS, *GRASSLAND soils, *DISSOLVED organic matter, *PLANT growth, *PLANT-soil relationships, *SOIL respiration, *ECOSYSTEMS

Abstract

As a widespread direct effect of global warming, drought is currently wreaking havoc on terrestrial ecosystems' structure and function, however, the synthesized analysis is lacked to explore the general rules between drought changes and main functional factors of grassland ecosystems. In this work, meta‐analysis was used to examine the impacts of drought on grassland ecosystems in recent decades. According to the results, drought greatly reduced aboveground biomass (AGB), aboveground net primary production (ANPP), height, belowground biomass (BGB), belowground net primary production (BNPP), microbial biomass nitrogen (MBN), microbial biomass carbon (MBC) and soil respiration (SR), and increased dissolved organic carbon (DOC), total nitrogen (TN), total phosphorus (TP), nitrate nitrogen (NO3−‐N), and the ratio of microbial biomass carbon and nitrogen (MBC/MBN). The drought‐related environmental factor mean annual temperature (MAT) was negatively correlated with AGB, height, ANPP, BNPP, MBC, and MBN, however, mean annual precipitation (MAP) had positive effect on these variables. These findings indicate that drought is threatening the biotic environment of grassland ecosystem, and the positive steps should be taken to address the negative effects of drought on grassland ecosystems due to climate change. [ABSTRACT FROM AUTHOR]

Published

2023

145. Mechanisms by which growth and succession limit the impact of fire in a south‐western Australian forested ecosystem.

Author

Zylstra, Philip, Wardell‐Johnson, Grant, Falster, Daniel, Howe, Melissa, McQuoid, Nathan, and Neville, Simon

Subjects

*FLAME spread, *FIRE management, *ECOSYSTEMS, *FIREFIGHTING, *COMMUNITY forests, *FOREST fire ecology, *PLANT growth, *FLAMMABILITY, *BIOMASS

Abstract

Forest wildfire impact is widely believed to increase with time since disturbance, presenting a dilemma for the persistence of fire‐sensitive species. However, in south‐western Australia, disturbance has been shown to increase wildfire likelihood for some decades before it again declines. It has been proposed that this trend occurs through 'ecological controls' on wildfire such as the self‐thinning of fire‐stimulated understorey growth.Here, we analyse six proposed ecological controls using a surveyed chronosequence of a Eucalyptus jacksonii forest community. We quantify plant growth (growth and self‐pruning) and succession (changing plant traits, self‐thinning), along with consequent changes in surface and suspended litter. We then use a biophysical, mechanistic model to predict the dynamics of flame height and canopy scorch/consumption, along with suppression difficulty during wildfire conditions. To identify the importance of each potential ecological control, we separately manipulate them to grow hypothetical forests from 1 to 100 years; each with one of the controls removed. We then model flame height in each to compare with the original forest that had all controls present.Fire initially promoted dense understorey regeneration, but ecological controls transferred this biomass from fuel (likely to ignite) to overstorey shelter (unlikely to ignite, creating a less flammable microclimate). The effect of these changes was to alter modelled fire behaviour, such that flame dimensions in mature forest were half those in regrowth, canopy damage greatly reduced, and fire suppression opportunities maximised. The primary controls were self‐thinning and self‐pruning.Forest growth and succession explains observed trends in flammability dynamics in south‐western Australian forests, and the persistence of fire‐sensitive species over time. Approaches that cooperate with, rather than disrupt, these processes therefore provide a pathway to mitigate current climatic effects on fire. Read the free Plain Language Summary for this article on the Journal blog. [ABSTRACT FROM AUTHOR]

Published

2023

146. 不同生物有机肥配施化肥对大豆植株生长、抗病及产量的影响.

Author

朱宝国, 匡恩俊, 滕占林, 孟庆英, 王囡囡, 冯浩原, 邱磊, 高雪冬, and 张春峰

Abstract

Copyright of Xinjiang Agricultural Sciences is the property of Xinjiang Agricultural Sciences Editorial Department and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2023

147. An Approach Based on Web Scraping and Denoising Encoders to Curate Food Security Datasets.

Author

Santos, Fabián and Acosta, Nicole

Subjects

FOOD security, WEB databases, FOOD crops, MULTIDIMENSIONAL databases, K-means clustering, DATABASES, COOKIES

Abstract

Ensuring food security requires the publication of data in a timely manner, but often this information is not properly documented and evaluated. Therefore, the combination of databases from multiple sources is a common practice to curate the data and corroborate the results; however, this also results in incomplete cases. These tasks are often labor-intensive since they require a case-wise review to obtain the requested and completed information. To address these problems, an approach based on Selenium web-scraping software and the multiple imputation denoising autoencoders (MIDAS) algorithm is presented for a case study in Ecuador. The objective was to produce a multidimensional database, free of data gaps, with 72 species of food crops based on the data from 3 different open data web databases. This methodology resulted in an analysis-ready dataset with 43 parameters describing plant traits, nutritional composition, and planted areas of food crops, whose imputed data obtained an R-square of 0.84 for a control numerical parameter selected for validation. This enriched dataset was later clustered with K-means to report unprecedented insights into food crops cultivated in Ecuador. The methodology is useful for users who need to collect and curate data from different sources in a semi-automatic fashion. [ABSTRACT FROM AUTHOR]

Published

2023

148. Intensity‐dependent effects of cattle and sheep grazing in sand grasslands — Does livestock type really matter?

Author

Kovacsics‐Vári, Gergely, Sonkoly, Judit, Tóth, Katalin, McIntosh‐Buday, Andrea, Díaz Cando, Patricia, Törő‐Szijgyártó, Viktória, Balogh, Nóra, Guallichico Suntaxi, Luis Roberto, Espinoza Ami, Francis David, Demeter, László, Tóthmérész, Béla, and Török, Péter

Subjects

*GRAZING, *CATTLE, *GRASSLANDS, *LIVESTOCK, *SAND, *SHEEP

Abstract

Aims: By analysing cattle‐ and sheep‐grazed sand grasslands, we tested the following hypotheses: (i) livestock type has a stronger effect on the vegetation characteristics than grazing intensity; (ii) sheep grazing results in lower biomass and species and functional diversity than cattle grazing, regardless of intensity; and (iii) increased grazing intensity causes a shift of the trait composition in grasslands. Location: Sand grasslands in the Nyírség region, East Hungary. Methods: We selected 26 sand grassland sites grazed by cattle or sheep and classified them into four intensity levels. Vegetation composition was surveyed in 2 m × 2 m plots. We harvested the above‐ground biomass from 20 cm × 20 cm plots; then dried and sorted it to live biomass, litter, moss, and lichen. We compared Rao dissimilarity index, species richness, Shannon diversity, evenness, and the community‐weighted means of nine vegetative and generative traits along a grazing intensity gradient. We calculated functional richness, evenness, and divergence for comparison. Results: We found that some diversity metrics and community‐weighted means of most studied traits were significantly affected by grazing intensity. Several characteristics were also affected by the interaction of grazing intensity and livestock type, but none of the studied characteristics was affected by livestock type in itself. Increasing Rao dissimilarity index peaking at the fourth grazing intensity level was detected, but for other multitrait indices, no such changes were proven, except for functional divergence, which was the lowest at the first intensity level. Graminoid, forb, and litter biomass were significantly affected by intensity, but none of the biomass fractions was affected by livestock type. Conclusions: We suggest that for the management of sand grasslands, grazing intensity should be carefully adjusted, considering not only livestock units per hectare. For practical recommendations, well‐defined, long‐term experiments studying different livestock and habitat types along an intensity gradient would be essential. [ABSTRACT FROM AUTHOR]

Published

2023

149. Coordination of hydraulic and morphological traits across dominant grasses in eastern Australia.

Author

Griffin‐Nolan, Robert J., Chieppa, Jeff, Knapp, Alan K., Nielsen, Uffe N., and Tissue, David T.

Subjects

*DROUGHTS, *DROUGHT tolerance, *WOODY plants, *MODULUS of elasticity, *GRASSES, *TURGOR

Abstract

Leaf hydraulic traits characterize plant drought tolerance and responses to climate change. Yet, plant hydraulics are biased towards northern hemisphere woody species. We collected rhizomes of several perennial grass species along a precipitation gradient in eastern Australia and grew them in an experimental pot study to investigate potential trade‐offs between drought tolerance and plant morphology.We measured the following leaf hydraulic traits: the leaf water potential (Ψleaf) at 50% and 88% loss of leaf hydraulic conductance (P50Kleaf and P88Kleaf), the Ψleaf at 50% loss of stomatal conductance (P50gs), leaf turgor loss point (TLP), leaf dry matter content (LDMC), leaf modulus of elasticity (ε), and the slope of the relationship between predawn and midday Ψleaf. We also measured basal area, tiller density, seed head density, root collar diameter, plant height, and aboveground biomass of each individual.As expected, grass species varied widely in leaf‐level drought tolerance, with loss of 88% hydraulic conductance occurring at a Ψleaf ranging from −1.52 to −4.01 MPa. However, all but one species lost leaf turgor, and most reached P50gs before this critical threshold. Taller more productive grass species tended to have drought vulnerable leaves characterized by low LDMC and less negative P88Kleaf. Species with greater tiller production experienced stomatal closure and lost turgor at more negative Ψleaf. Although our sample size was limited, we found no relationships between these species' traits and their climate of origin.Overall, we identified important hydraulic and morphological trade‐offs in Australian grasses that were surprisingly similar to those observed for woody plants: (1) xylem of taller species was less drought tolerant and (2) turgor loss occurs and stomatal closure begins before significant loss of Kleaf. These data build upon a small yet growing field of grass hydraulics and may be informative of species responses to further drought intensification in Australia. Read the free Plain Language Summary for this article on the Journal blog. [ABSTRACT FROM AUTHOR]

Published

2023

150. Drought effects on root and shoot traits and their decomposability.

Author

Reinelt, Laura, Whitaker, Jeanette, Kazakou, Elena, Bonnal, Laurent, Bastianelli, Denis, Bullock, James M., and Ostle, Nicholas J.

Subjects

*DROUGHTS, *CLIMATE feedbacks, *WHITE clover, *LOLIUM perenne, *PHENOTYPIC plasticity, *RYEGRASSES, *PLANT shoots

Abstract

Drought can induce phenotypic plasticity in a range of plant root and shoot traits. These traits have been shown to explain differences in root and shoot litter decomposability between species. However, it is unknown how drought‐induced plasticity of root and shoot traits alters their decomposability.To investigate this issue across a range of species, we grew a grass Lolium perenne, a forb Plantago lanceolata and a legume Trifolium repens common to European temperate grasslands and subjected them to a 5‐week moderate drought treatment. We compared morphological and chemical root and shoot traits of the droughted plants to well‐watered controls. We then conducted a decomposition assay of the senesced root and shoot material over 16 weeks, with mass loss measurements at five timepoints.Drought had significant and sometimes strong effects on morphological and chemical root and shoot traits of all three species, sometimes similar to differences between species and generally in line with a shift to a more resource‐conservative strategy. Drought also increased the labile litter fraction in roots of Lolium perenne, which was associated with a substantial increase in non‐structural carbohydrates. Drought decreased the labile litter fraction in shoots of Plantago lanceolata, but this could not be explained by the traits we measured. Drought effects on litter decomposability were weaker than on plant traits.Our results suggest that plant trait‐mediated effects of drought on litter decomposability can either increase or decrease vegetation feedbacks to climate change. They also show that drought‐induced plasticity in root and shoot traits does not automatically translate into equivalent changes in litter decomposability. Read the free Plain Language Summary for this article on the Journal blog. [ABSTRACT FROM AUTHOR]

Published

2023