Woody-plant ecosystems under climate change and air pollution : response consistencies across zonobiomes?
Data
2017
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Resumo
Forests store the largest terrestrial pools of carbon (C), helping to stabilize the global climate system, yet are threatened by climate
change (CC) and associated air pollution (AP, highlighting ozone (O3) and nitrogen oxides (NOx)). We adopt the perspective that CC–AP
drivers and physiological impacts are universal, resulting in consistent stress responses of forest ecosystems across zonobiomes.
Evidence supporting this viewpoint is presented from the literature on ecosystem gross/net primary productivity and water cycling.
Responses to CC–AP are compared across evergreen/deciduous foliage types, discussing implications of nutrition and resource turnover
at tree and ecosystem scales. The availability of data is extremely uneven across zonobiomes, yet unifying patterns of ecosystem
response are discernable. Ecosystem warming results in trade-offs between respiration and biomass production, affecting high elevation
forestsmore than in the lowland tropics and low-elevation temperate zone. Resilience to drought is modulated by tree size and species
richness. Elevated O3 tends to counteract stimulation by elevated carbon dioxide (CO2). Biotic stress and genomic structure ultimately
determine ecosystem responsiveness. Aggrading early- rather than mature late-successional communities respond to CO2 enhancement,
whereas O3 affects North American and Eurasian tree species consistently under free-air fumigation. Insect herbivory is exacerbated by
CC–AP in biome-specific ways. Rhizosphere responses reflect similar stand-level nutritional dynamics across zonobiomes, but are modulated
by differences in tree–soil nutrient cycling between deciduous and evergreen systems, and natural versus anthropogenic nitrogen
(N) oversupply. The hypothesis of consistency of forest responses to interacting CC–AP is supported by currently available data, establishing
the precedent for a global network of long-term coordinated research sites across zonobiomes to simultaneously advance both
bottom-up (e.g., mechanistic) and top-down (systems-level) understanding. This global, synthetic approach is needed because high biological
plasticity and physiographic variation across individual ecosystems currently limit development of predictive models of forest
responses to CC–AP. Integrated research on C and nutrient cycling, O3–vegetation interactions and water relations must target mechanisms’
ecosystem responsiveness. Worldwide case studies must be subject to biostatistical exploration to elucidate overarching response
patterns and synthesize the resulting empirical data through advanced modelling, in order to provide regionally coherent, yet globally
integrated information in support of internationally coordinated decision-making and policy development.
Descrição
Palavras-chave
Biotic interactions, Foliage types, Forest ecosystem
Citação
MATYSSEK, R. et al. Woody-plant ecosystems under climate change and air pollution: response consistencies across zonobiomes? Tree Physiology, v. 37, p. 706-732, 2017. Disponível em: <https://academic.oup.com/treephys/article-abstract/37/6/706/3069150/Woody-plant-ecosystems-under-climate-change-and?redirectedFrom=fulltext>. Acesso em: 25 ago. 2017.