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Genomes and secretomes of Ascomycota fungi reveal diverse functions in plant biomass decomposition and pathogenesis
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Genomes and secretomes of Ascomycota fungi reveal diverse functions in plant biomass decomposition and pathogenesis
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Journal Article
Genomes and secretomes of Ascomycota fungi reveal diverse functions in plant biomass decomposition and pathogenesis
2019
Overview
Background
The dominant fungi in arid grasslands and shrublands are members of the Ascomycota phylum. Ascomycota fungi are important drivers in carbon and nitrogen cycling in arid ecosystems. These fungi play roles in soil stability, plant biomass decomposition, and endophytic interactions with plants. They may also form symbiotic associations with biocrust components or be latent saprotrophs or pathogens that live on plant tissues. However, their functional potential in arid soils, where organic matter, nutrients and water are very low or only periodically available, is poorly characterized.
Results
Five Ascomycota fungi were isolated from different soil crust microhabitats and rhizosphere soils around the native bunchgrass
Pleuraphis jamesii
in an arid grassland near Moab, UT, USA. Putative genera were
Coniochaeta
, isolated from lichen biocrust,
Embellisia
from cyanobacteria biocrust
, Chaetomium
from below lichen biocrust,
Phoma
from a moss microhabitat, and
Aspergillus
from the soil. The fungi were grown in replicate cultures on different carbon sources (chitin, native bunchgrass or pine wood) relevant to plant biomass and soil carbon sources. Secretomes produced by the fungi on each substrate were characterized. Results demonstrate that these fungi likely interact with primary producers (biocrust or plants) by secreting a wide range of proteins that facilitate symbiotic associations. Each of the fungal isolates secreted enzymes that degrade plant biomass, small secreted effector proteins, and proteins involved in either beneficial plant interactions or virulence.
Aspergillus
and
Phoma
expressed more plant biomass degrading enzymes when grown in grass- and pine-containing cultures than in chitin.
Coniochaeta
and
Embellisia
expressed similar numbers of these enzymes under all conditions, while
Chaetomium
secreted more of these enzymes in grass-containing cultures.
Conclusions
This study of Ascomycota genomes and secretomes provides important insights about the lifestyles and the roles that Ascomycota fungi likely play in arid grassland, ecosystems. However, the exact nature of those interactions, whether any or all of the isolates are true endophytes, latent saprotrophs or opportunistic phytopathogens, will be the topic of future studies.
Publisher
BioMed Central,BioMed Central Ltd,Springer Nature B.V,Springer,BMC
Subject
/ Arid
/ Aridity
/ Ascomycota - isolation & purification
/ Biocrust
/ Biomass
/ Biomedical and Life Sciences
/ Carbon
/ Chitin
/ Comparative and evolutionary genomics
/ Enzymes
/ Fungal Proteins - metabolism
/ Fungi
/ Genome
/ Genomes
/ Genomics
/ Grasses
/ Lichens
/ Microbial Genetics and Genomics
/ Phoma
/ Plant Physiological Phenomena
/ Plants
/ Proteins
/ Soil
/ Soils
