Mycorrhizas in changing ecosystems<sup>,</sup>

Dickie, Ian A.; Koele, Nina; Blum, Joel D.; Gleason, James D.; McGlone, Matthew S.

doi:10.1139/cjb-2013-0091

Cited by 84 publications

(80 citation statements)

References 81 publications

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“…Temperate and boreal forests, which cover B14% of the land surface (FAO, 2012), harbor hundreds of taxonomically and functionally diverse EM fungi (Read and PerezMoreno, 2003;Tedersoo et al, 2010;Koide et al, 2014). Recent environmental change may have altered fungal communities, which would subsequently affect the associated plant communities and ecosystem functioning (Parrent et al, 2006;Johnson et al, 2013;Dickie et al, 2014). Clarifying the drivers of the community structure of EM fungi is critical for predicting the effects of environmental change on forest ecosystems from local to global contexts (Lilleskov and Parrent, 2007).…”

Section: Introductionmentioning

confidence: 99%

Strong effect of climate on ectomycorrhizal fungal composition: evidence from range overlap between two mountains

et al. 2015

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Separating the effects of environmental factors and spatial distance on microbial composition is difficult when these factors covary. We examined the composition of ectomycorrhizal (EM) fungi along elevation gradients on geographically distant mountains to clarify the effect of climate at the regional scale. Soil cores were collected from various forest types along an elevation gradient in southwestern Japan. Fungal species were identified by the internal transcribed spacer regions of the rDNA using direct sequencing. The occurrence of fungal species in this study was compared with a previous study conducted on a mountain separated by B550 km. In total, we recorded 454 EM fungi from 330 of 350 soil cores. Forty-seven fungal species (B20% of the total excluding singletons) were shared between two mountains, mostly between similar forest types on both mountains. Variation partitioning in redundancy analysis revealed that climate explained the largest variance in EM fungal composition. The similarity of forest tree composition, which is usually determined by climatic conditions, was positively correlated with the similarity of the EM fungal composition. However, the lack of large host effects implied that communities of forest trees and EM fungi may be determined independently by climate. Our data provide important insights that host plants and mutualistic fungi may respond to climate change idiosyncratically, potentially altering carbon and nutrient cycles in relation to the plant-fungus associations.

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Section: Introductionmentioning

confidence: 99%

Strong effect of climate on ectomycorrhizal fungal composition: evidence from range overlap between two mountains

et al. 2015

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“…Ectomycorrhizal (EM) symbioses emerged among several of the more advanced lineages of plants (18). In many temperate forests, both AM and EM trees commonly cooccur despite fundamental differences in nutrient acquisition strategies (19,20). EM fungi are, on the whole, better adapted to acquire nutrients from organic substrates than AM fungi (21,22).…”

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confidence: 99%

Root morphology and mycorrhizal symbioses together shape nutrient foraging strategies of temperate trees

Chen

Koide

Adams

et al. 2016

Proc. Natl. Acad. Sci. U.S.A.

265

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Photosynthesis by leaves and acquisition of water and minerals by roots are required for plant growth, which is a key component of many ecosystem functions. Although the role of leaf functional traits in photosynthesis is generally well understood, the relationship of root functional traits to nutrient uptake is not. In particular, predictions of nutrient acquisition strategies from specific root traits are often vague. Roots of nearly all plants cooperate with mycorrhizal fungi in nutrient acquisition. Most tree species form symbioses with either arbuscular mycorrhizal (AM) or ectomycorrhizal (EM) fungi. Nutrients are distributed heterogeneously in the soil, and nutrient-rich "hotspots" can be a key source for plants. Thus, predicting the foraging strategies that enable mycorrhizal root systems to exploit these hotspots can be critical to the understanding of plant nutrition and ecosystem carbon and nutrient cycling. Here, we show that in 13 sympatric temperate tree species, when nutrient availability is patchy, thinner root species alter their foraging to exploit patches, whereas thicker root species do not. Moreover, there appear to be two distinct pathways by which thinner root tree species enhance foraging in nutrient-rich patches: AM trees produce more roots, whereas EM trees produce more mycorrhizal fungal hyphae. Our results indicate that strategies of nutrient foraging are complementary among tree species with contrasting mycorrhiza types and root morphologies, and that predictable relationships between below-ground traits and nutrient acquisition emerge only when both roots and mycorrhizal fungi are considered together. mycorrhizal fungi | plant traits | root proliferation | soil heterogeneity | symbioses

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“…In broad terms, the Nothofagaceae have higher photosynthetic rates and therefore are well equipped to take advantage of high insolation days and short summers (Richardson et al, 2005a;Whitehead et al, 2011). The Nothofagaceae are also ectomycorrhizal and this brings with it the ability to directly use nutrients locked into organic complexes and also to lower the nutrient content of organic soils to such an extent that they are largely unsuitable for trees with arbuscular mycorrhizal infection (Dickie et al, 2014). However, these advantages over conifers are lessened under cloudy, low insolation summers (growth rate premium reduced) and long, mild winters (breakdown of soil organic matter and release of nutrients enhanced).…”

Section: Conifers and The Nothofagaceaementioning

confidence: 99%

Palynology and the Ecology of the New Zealand Conifers

et al. 2017

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The New Zealand conifers (20 species of trees and shrubs in the Araucariaceae, Podocarpaceae, and Cupressaceae) are often regarded as ancient Gondwanan elements, but mostly originated much later. Often thought of as tall trees of humid, warm forests, they are present throughout in alpine shrublands, tree lines, bogs, swamps, and in dry, frost-prone regions. The tall conifers rarely form purely coniferous forest and mostly occur as an emergent stratum above evergreen angiosperm trees. During Maori settlement in the thirteenth century, fire-sensitive trees succumbed rapidly, most of the drier forests being lost. As these were also the more conifer-rich forests, ecological research has been skewed toward conifer dynamics of forests wetter and cooler than the pre-human norm. Conifers are well represented in the pollen record and we here we review their late Quaternary history in the light of what is known about their current ecology with the intention of countering this bias. During glacial episodes, all trees were scarce south of c. 40 • S, and extensive conifer-dominant forest was confined to the northern third of the North Island. Drought-and cold-resistant Halocarpus bidwillii and Phyllocladus alpinus formed widespread scrub in the south. During the deglacial, beginning 18,000 years ago, tall conifers underwent explosive spread to dominate the forest biomass throughout. Conifer dominance lessened in favor of angiosperms in the wetter western lowland forests over the Holocene but the dryland eastern forests persisted largely unchanged until settlement. Mid to late Holocene climate change favored the more rapidly growing Nothofagaceae which replaced the previous conifer-angiosperm low forest or shrubland in tree line ecotones and montane areas. The key to this dynamic conifer history appears to be their bimodal ability to withstand stress, and dominate on poor soils and in cool, dry regions but, in wetter, warmer locations, to slowly grow thorough competing broadleaves to occupy an exposed, emergent stratum where their inherent stress resistance ensures little effective angiosperm competition.

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Mycorrhizas in changing ecosystems^,

Cited by 84 publications

References 81 publications

Strong effect of climate on ectomycorrhizal fungal composition: evidence from range overlap between two mountains

Strong effect of climate on ectomycorrhizal fungal composition: evidence from range overlap between two mountains

Root morphology and mycorrhizal symbioses together shape nutrient foraging strategies of temperate trees

Palynology and the Ecology of the New Zealand Conifers

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Mycorrhizas in changing ecosystems,

Cited by 84 publications

References 81 publications

Strong effect of climate on ectomycorrhizal fungal composition: evidence from range overlap between two mountains

Strong effect of climate on ectomycorrhizal fungal composition: evidence from range overlap between two mountains

Root morphology and mycorrhizal symbioses together shape nutrient foraging strategies of temperate trees

Palynology and the Ecology of the New Zealand Conifers

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Mycorrhizas in changing ecosystems^,