Ectomycorrhizal fungal response to warming is linked to poor host performance at the boreal‐temperate ecotone

Fernandez, Christopher W.; Nguyen, Nhu; Stefański, Artur; Han, Yingjie; Hobbie, Sarah E.; Montgomery, Rebecca; Reich, Peter B.; Kennedy, Peter G.

doi:10.1111/gcb.13510

Cited by 123 publications

(139 citation statements)

References 81 publications

(138 reference statements)

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“…In contrast, the opposite response (i.e. decreased plant photosynthesis along with decreased EMF relative abundance and richness under warming) has been recently reported in a boreal/temperate ecotone ecosystem located near the lower latitudinal limit of the host plant range where productivity is limited by water availability (Fernandez et al., ). We found that warming, rainfall reduction and their combination altered ectomycorrhizal community structure and led to drastic decreases in the relative abundance of EMF sequences in the rhizosphere of H. squamatum , which is the only EMF host plant species at our study site.…”

Section: Discussionmentioning

confidence: 95%

“…saprotrophs) did not change significantly in the climate manipulation treatments. This strongly suggests that altered EMF community structure and decreased relative abundance of EMF sequences with climate manipulation was linked to plant responses and largely driven by decreased carbon supply to mycorrhizae from their stressed host plants under hotter and/or drier conditions (Castaño et al., ; Fernandez et al., ).…”

Section: Discussionmentioning

confidence: 99%

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Poor plant performance under simulated climate change is linked to mycorrhizal responses in a semi‐arid shrubland

et al. 2017

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Warmer and drier conditions associated with ongoing climate change will increase abiotic stress for plants and mycorrhizal fungi in drylands worldwide, thereby potentially reducing vegetation cover and productivity and increasing the risk of land degradation and desertification. Rhizosphere microbial interactions and feedbacks are critical processes that could either mitigate or aggravate the vulnerability of dryland vegetation to forecasted climate change.We conducted a four-year manipulative study in a semiarid shrubland in the Iberian Peninsula to assess the effects of warming (~2.5ºC; W), rainfall reduction (~30%; RR) and their combination (W+RR) on the performance of native shrubs () and their associated mycorrhizal fungi.Warming (W and W+RR) decreased the net photosynthetic rates of shrubs by ~31% despite concurrent increases in stomatal conductance (~33%), leading to sharp decreases (~50%) in water use efficiency. Warming also advanced growth phenology, decreased leaf nitrogen and phosphorus contents per unit area, reduced shoot biomass production by ~36% and decreased survival during a dry year in both W and W+RR plants. Plants under RR showed more moderate decreases (~10-20%) in photosynthesis, stomatal conductance and shoot growth.Warming, RR and W+RR altered ectomycorrhizal fungal (EMF) community structure and drastically reduced the relative abundance of EMF sequences obtained by high-throughput sequencing, a response associated with decreases in the leaf nitrogen, phosphorus and dry matter contents of their host plants. In contrast to EMF, the community structure and relative sequence abundances of other non-mycorrhizal fungal guilds were not significantly affected by the climate manipulation treatments. Our findings highlight the vulnerability of both native plants and their symbiotic mycorrhizal fungi to climate warming and drying in semiarid shrublands, and point to the importance of a deeper understanding of plant-soil feedbacks to predict dryland vegetation responses to forecasted aridification. The interdependent responses of plants and ectomycorrhizal fungi to warming and rainfall reduction may lead to a detrimental feedback loop on vegetation productivity and nutrient pool size, which could amplify the adverse impacts of forecasted climate change on ecosystem functioning in EMF-dominated drylands.

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Section: Discussionmentioning

confidence: 95%

Section: Discussionmentioning

confidence: 99%

Poor plant performance under simulated climate change is linked to mycorrhizal responses in a semi‐arid shrubland

et al. 2017

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“…Negative values were considered zeros before data were finally converted to relative abundances (as percentage of normalized read numbers) as per Fernandez et al . (). The negative binomial model performed within D e S eq 2 can simultaneously account for variation in library sizes and biological variability better than simply subsampling to a uniform sequencing depth alone.…”

Section: Methodsmentioning

confidence: 97%

Extreme rainfall affects assembly of the root‐associated fungal community

et al. 2018

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Summary Global warming is resulting in increased frequency of weather extremes. Root‐associated fungi play important roles in terrestrial biogeochemical cycling processes, but the way in which they are affected by extreme weather is unclear. Here, we performed long‐term field monitoring of the root‐associated fungus community of a short rotation coppice willow plantation, and compared community dynamics before and after a once in 100 yr rainfall event that occurred in the UK in 2012.Monitoring of the root‐associated fungi was performed over a 3‐yr period by metabarcoding the fungal internal transcribed spacer (ITS) region. Repeated soil testing and continuous climatic monitoring supplemented community data, and the relative effects of environmental and temporal variation were determined on the root‐associated fungal community.Soil saturation and surface water were recorded throughout the early growing season of 2012, following extreme rainfall. This was associated with a crash in the richness and relative abundance of ectomycorrhizal fungi, with each declining by over 50%. Richness and relative abundance of saprophytes and pathogens increased.We conclude that extreme rainfall events may be important yet overlooked determinants of root‐associated fungal community assembly. Given the integral role of ectomycorrhizal fungi in biogeochemical cycles, these events may have considerable impacts upon the functioning of terrestrial ecosystems.

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“…The relative abundance of ECMF exploration strategies (% of ECMF OTUs) per site were assigned by matching ECMF genera against published lists (Agerer, ; Tedersoo & Smith, ), which are available online (http://www.deemy.de). Strategies were assigned to the following categories according to Fernandez et al (): contact short (CS), contact medium (CM) and medium long (ML). Because of potential differences in the relationship between DNA copy number and fungal biomass, particularly among functional groups known to differ in their morphology, we restricted our analyses to intraguild comparisons (e.g.…”

Section: Methodsmentioning

confidence: 99%

“…Climate change can alter the community composition of ECMF by pushing fungi (Kipfer, Egli, Ghazoul, Moser, & Wohlgemuth, ) or their host plants (Fernandez et al, ) outside their ranges of physiological tolerance (Pickles, Egger, Massicotte, & Green, ). However, most studies to date that have examined ECMF or whole fungal community responses to simulated climate change have found fairly small effects (Fernandez et al, ; Mucha et al, ; Parrent, Morris, & Vilgalys, ; Tu et al, ) relative to natural changes in fungal communities observed along large natural gradients of temperature and precipitation (Jarvis, Woodward, Alexander, & Taylor, ; Nottingham et al, ; Peay et al, ; Talbot et al, ; Tedersoo et al, ). Yet, few datasets currently exist with spatial resolution necessary to make accurate predictions of ECMF response to climate change across relevant geographic regions (Mohan et al, ).…”

Section: Introductionmentioning

confidence: 99%

Ectomycorrhizal fungal diversity predicted to substantially decline due to climate changes in North American Pinaceae forests

Steidinger

Bhatnagar

Vilgalys

et al. 2020

Journal of Biogeography

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Aim Ectomycorrhizal fungi (ECMF) are partners in a globally distributed tree symbiosis implicated in most major ecosystem functions. However, resilience of ECMF to future climates is uncertain. We forecast these changes over the extent of North American Pinaceae forests. Location About 68 sites from North American Pinaceae forests ranging from Florida to Ontario in the east and southern California to Alaska in the west. Taxon Ectomycorrhizal fungi (Asco‐ and Basidiomycetes). Methods We characterized ECMF communities at each site using molecular methods and modelled climatic drivers of diversity and community composition with general additive, generalized dissimilarity models and Threshold Indicator Taxa ANalysis (TITAN). Next, we projected our models across the extent of North American Pinaceae forests and forecast ECMF responses to climate changes in these forests over the next 50 years. Results We predict median declines in ECMF species richness as high as 26% in Pinaceae forests throughout a climate zone comprising more than 3.5 million square kilometres of North America (an area twice that of Alaska state). Mitigation of greenhouse gas emissions can reduce these declines, but not prevent them. The existence of multiple diversity optima along climate gradients suggest regionally divergent trajectories for North American ECMF, which is corroborated by corresponding ECMF community thresholds identified in TITAN models. Warming of forests along the boreal–temperate ecotone results in projected ECMF species loss and declines in the relative abundance of long‐distance foraging ECMF species, whereas warming of eastern temperate forests has the opposite effect. Main Conclusions Our results reveal potentially unavoidable ECMF species‐losses over the next 50 years, which is likely to have profound (if yet unclear) effects on ECMF‐associated biogeochemical cycles.

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Ectomycorrhizal fungal response to warming is linked to poor host performance at the boreal‐temperate ecotone

Cited by 123 publications

References 81 publications

Poor plant performance under simulated climate change is linked to mycorrhizal responses in a semi‐arid shrubland

Poor plant performance under simulated climate change is linked to mycorrhizal responses in a semi‐arid shrubland

Extreme rainfall affects assembly of the root‐associated fungal community

Ectomycorrhizal fungal diversity predicted to substantially decline due to climate changes in North American Pinaceae forests

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