Bacteria and fungi differentially contribute to carbon and nitrogen cycles during biological soil crust succession in arid ecosystems

Abstract. Changing fire regimes in western North America may impact biological soil crust (BSC) communities that influence many ecosystem functions, such as soil stability and C and N cycling. However, longer-term effects of wildfire on BSC abundance, species richness, functional groups, and ecosystem functions after wildfire (i.e. BSC resilience) is still poorly understood. We sampled BSC lichen and bryophyte communities at four sites in Idaho, USA, within foothill steppe communities that included wildfires from 12 to 16 years old. We established six plots outside each burn perimeter and compared them with six plots of varying severity within each fire perimeter at each site. BSC cover was most strongly negatively impacted by wildfire at sites that had well-developed BSC communities in adjacent unburned plots. BSC species richness was estimated to be 65 % greater in unburned plots compared with burned plots. In contrast, there was no evidence that vascular plant functional groups or fire severity (as measured by satellite metrics dNBR or RdNBR) significantly affected longer-term BSC responses. Three BSC functional groups (squamulose lichens, vagrant lichens, and tall turf mosses) exhibited a significant decrease in abundance in burned areas relative to adjacent unburned areas. The decreases in BSC cover and richness along with decreased abundance of several functional groups suggest that wildfire can negatively impact ecosystem function in these semi-arid ecosystems for at least one to two decades. This is a concern given that increased fire frequency is predicted for the region due to exotic grass invasion and climate change.

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Do biotic interactions modulate ecosystem functioning along stress gradients? Insights from semi-arid plant and biological soil crust communities

Philosophical Transactions of the Royal Society B Biological Sciences ◽

10.1098/rstb.2010.0016 ◽

2010 ◽

Vol 365 (1549) ◽

pp. 2057-2070 ◽

Cited By ~ 93

Author(s):

Fernando T. Maestre ◽

Matthew A. Bowker ◽

Cristina Escolar ◽

María D. Puche ◽

Santiago Soliveres ◽

...

Keyword(s):

Climate Change ◽

Species Richness ◽

Abiotic Stress ◽

Ecosystem Functioning ◽

Biological Soil Crust ◽

Biotic Interactions ◽

Arid Ecosystems ◽

Soil Crust ◽

Stress Gradients ◽

Semi Arid

Climate change will exacerbate the degree of abiotic stress experienced by semi-arid ecosystems. While abiotic stress profoundly affects biotic interactions, their potential role as modulators of ecosystem responses to climate change is largely unknown. Using plants and biological soil crusts, we tested the relative importance of facilitative–competitive interactions and other community attributes (cover, species richness and species evenness) as drivers of ecosystem functioning along stress gradients in semi-arid Mediterranean ecosystems. Biotic interactions shifted from facilitation to competition along stress gradients driven by water availability and temperature. These changes were, however, dependent on the spatial scale and the community considered. We found little evidence to suggest that biotic interactions are a major direct influence upon indicators of ecosystem functioning (soil respiration, organic carbon, water-holding capacity, compaction and the activity of enzymes related to the carbon, nitrogen and phosphorus cycles) along stress gradients. However, attributes such as cover and species richness showed a direct effect on ecosystem functioning. Our results do not agree with predictions emphasizing that the importance of plant–plant interactions will be increased under climate change in dry environments, and indicate that reductions in the cover of plant and biological soil crust communities will negatively impact ecosystems under future climatic conditions.

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Deciphering the potential niche of novel black yeast fungal isolates in a biological soil crust based on genomes, phenotyping, and melanin regulation

10.1101/2021.12.03.471027 ◽

2021 ◽

Author(s):

Erin C. Carr ◽

Quin Barton ◽

Sarah Grambo ◽

Mitchell Sullivan ◽

Cecile M. Renfro ◽

...

Keyword(s):

Novel Species ◽

Biological Soil Crust ◽

Nitrogen Sources ◽

Black Yeast ◽

Soil Crust ◽

Uv Resistance ◽

Carbon And Nitrogen Sources ◽

Carbon And Nitrogen ◽

Yeast Fungi ◽

Insight Into

AbstractBlack yeasts are polyextremotolerant fungi that contain high amounts of melanin in their cell wall and maintain a primarily yeast form. These fungi grow in xeric, nutrient deplete environments which implies that they require highly flexible metabolisms and the ability to form lichen-like mutualisms with nearby algae and bacteria. However, the exact ecological niche and interactions between these fungi and their surrounding community is not well understood. We have isolated two novel black yeast fungi of the genus Exophiala: JF 03-3F “Goopy” E. viscosium and JF 03-4F “Slimy” E. limosus, which are from dryland biological soil crusts. A combination of whole genome sequencing and various phenotyping experiments have been performed on these isolates to determine their fundamental niches within the biological soil crust consortium. Our results reveal that these Exophiala spp. are capable of utilizing a wide variety of carbon and nitrogen sources potentially from symbiotic microbes, they can withstand many abiotic stresses, and can potentially provide UV resistance to the crust community in the form of secreted melanin. Besides the identification of two novel species within the genus Exophiala, our study also provides new insight into the production and regulation of melanin in extremotolerant fungi.

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Biological Soil Crust effects and responses in arid ecosystems: recent advances at the species level

Ecosistemas ◽

10.7818/ecos.2013.22-3.13 ◽

2013 ◽

Vol 22 (3) ◽

pp. 95-100

Author(s):

Laura Concostrina-Zubiri ◽

Isabel Martínez ◽

Elisabeth Huber-Sannwald ◽

Adrián Escudero

Keyword(s):

Biological Soil Crust ◽

Species Level ◽

Arid Ecosystems ◽

Soil Crust ◽

Recent Advances

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Biological soil crust distribution on the Boardman Conservation Area

10.3411/col.04072147 ◽

2010 ◽

Cited By ~ 1

Author(s):

Adrien Elseroad ◽

Joseph St. Peter ◽

Maile Uchida

Keyword(s):

Biological Soil Crust ◽

Soil Crust ◽

Conservation Area

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Functional ecology of the biological soil crust in semiarid SE Spain: sun and shade populations of Diploschistes diacapsis (Ach.) Lumbsch.

The Lichenologist ◽

10.1017/s0024282905015021 ◽

2005 ◽

Vol 37 (5) ◽

pp. 425-432 ◽

Cited By ~ 38

Author(s):

Ana PINTADO ◽

Leopoldo G. SANCHO ◽

T. G. Allan GREEN ◽

José Manuel BLANQUER ◽

Roberto LÁZARO

Keyword(s):

Water Content ◽

Chlorophyll Content ◽

Unit Area ◽

Biological Soil Crust ◽

Dry Weight ◽

Mean Annual Precipitation ◽

Plant Colonization ◽

Soil Crust ◽

Active Time ◽

Exposed Population

The Tabernas badlands in semiarid south-east Spain is one of the driest regions in Europe with a mean annual precipitation of c. 240 mm. The landscape is deeply dissected, with canyons, ramblas and sparsely vegetated eroded badland slopes. The vegetation is predominantly a biological soil crust consisting of different types of lichen-rich communities, one of the more conspicuous being dominated by Diploschistes diacapsis (Ach.) Lumbsch. This lichen is mainly restricted to the north- facing slopes, where it forms extensive whitish carpets and probably plays an important role in preventing erosion of the slopes and allowing plant colonization. South-facing slopes are much more eroded and generally lack vegetation. %The photosynthetic performance of north (shade) and south-facing (sun) populations of D. diacapsis was studied to determine if these different populations showed any adaptations to the microclimatic conditions of their individual habitats. The response of CO2 exchange to light intensity, temperature and water content was measured under controlled conditions in the laboratory. Dry weight-based net photosynthetic rates were higher in the southern-exposed population but quantum efficiency, and light compensation points were similar. Thallus weight per unit area (LMA) was considerably higher for shade specimens but maximum water content and optimal water content were very similar and chlorophyll content on a dry weight basis was also similar. Chlorophyll content on an area basis was higher in the northern-exposed population and always much larger than those reported in other studies on the same species (up to 8 times larger) with the result that NP values on a chlorophyll basis were relatively low. The larger LMA meant that shade thalli stored more water per unit area which should ensure longer active periods than sun thalli. The results support a strategy pair of high NP and short active time versus low NP and long active time, both having been reported for other soil crust species. However, the visibly larger biomass of the shade D. diacapsis suggests that the lichen is at the limit of its adaptability in these habitats.

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