Microbial diversity of browning Peninsula, Eastern Antarctica revealed using molecular and cultivation methods

Browning Peninsula is an ice-free polar desert situated in the Windmill Islands, Eastern Antarctica. The entire site is described as a barren landscape, comprised of frost boils with soils dominated by microbial life. In this study, we explored the microbial diversity and edaphic drivers of communit...

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Bibliographic Details
Published in:Frontiers in Microbiology
Main Authors: Pudasaini, S, Wilson, J, Ji, M, van Dorst, J, Snape, I, Palmer, AS, Burns, BP, Ferrari, BC
Format: Article in Journal/Newspaper
Language:unknown
Published: Frontiers 2017
Subjects:
antarctic soil
bacterial diversity
cultivation
frost boils
fungal diversity
anzsrc-for: 0502 Environmental Science and Management
anzsrc-for: 0503 Soil Sciences
anzsrc-for: 0605 Microbiology
Antarctic
Windmill Islands
Browning
Browning Peninsula
Antarc*
Antarctica
polar desert
Online Access:http://hdl.handle.net/1959.4/unsworks_53894
https://doi.org/10.3389/fmicb.2017.00591
Description
Summary:Browning Peninsula is an ice-free polar desert situated in the Windmill Islands, Eastern Antarctica. The entire site is described as a barren landscape, comprised of frost boils with soils dominated by microbial life. In this study, we explored the microbial diversity and edaphic drivers of community structure across this site using traditional cultivation methods, a novel approach the soil substrate membrane system (SSMS), and culture-independent 454-tag pyrosequencing. The measured soil environmental and microphysical factors of chlorine, phosphate, aspect and elevation were found to be significant drivers of the bacterial community, while none of the soil parameters analyzed were significantly correlated to the fungal community. Overall, Browning Peninsula soil harbored a distinctive microbial community in comparison to other Antarctic soils comprised of a unique bacterial diversity and extremely limited fungal diversity. Tag pyrosequencing data revealed the bacterial community to be dominated by Actinobacteria (36%), followed by Chloroflexi (18%), Cyanobacteria (14%), and Proteobacteria (10%). For fungi, Ascomycota (97%) dominated the soil microbiome, followed by Basidiomycota. As expected the diversity recovered from culture-based techniques was lower than that detected using tag sequencing. However, in the SSMS enrichments, that mimic the natural conditions for cultivating oligophilic "k-selected" bacteria, a larger proportion of rare bacterial taxa (15%), such as Blastococcus, Devosia, Herbaspirillum, Propionibacterium and Methylocella and fungal (11%) taxa, such as Nigrospora, Exophiala, Hortaea, and Penidiella were recovered at the genus level. At phylum level, a comparison of OTU's showed that the SSMS shared 21% of Acidobacteria, 11% of Actinobacteria and 10% of Proteobacteria OTU's with soil. For fungi, the shared OTUs was 4% (Basidiomycota) and < 0.5% (Ascomycota). This was the first known attempt to culture microfungi using the SSMS which resulted in an increase in diversity from 14 to 57 ...

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