Anoxic Biodegradation of Isosaccharinic Acids at Alkaline pH by Natural Microbial Communities

One design concept for the long-term management of the UK's intermediate level radioactive wastes (ILW) is disposal to a cementitious geological disposal facility (GDF). Under the alkaline (10.013.0) anoxic conditions expected within a GDF, cellulosic wastes will undergo chemical hydrolysis. Th...

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Bibliographic Details
Published in:PloS one 2015-09, Vol.10 (9), p.e0137682-e0137682
Main Authors: Rout, Simon P, Charles, Christopher J, Doulgeris, Charalampos, McCarthy, Alan J, Rooks, Dave J, Loughnane, J Paul, Laws, Andrew P, Humphreys, Paul N
Format: Article
Language:English
Subjects:
Accumulation
Acetic acid
Acids
Alcaligenes
Anoxic conditions
Archaea - genetics
Archaea - metabolism
Bacteriology
Biodegradation
Biodegradation, Environmental
Biology
Biotechnology
Carbon
Carbon sources
Cellulose
Clostridium - genetics
Clostridium - metabolism
Colonization
Communities
Consortia
Degradation products
Environmental degradation
Fermentation
Gene Library
Geology
Hydrogen-Ion Concentration
Methane - metabolism
Methanogenesis
Methanogenic bacteria
Methanosarcina
Microbial activity
Microbiomes
Microcosms
Microorganisms
Organic carbon
pH effects
Phylogeny
Radioactive Waste
Radioactive waste disposal
Radioactive wastes
RNA, Bacterial - chemistry
Sediments
Sequence Analysis, RNA
Sugar Acids - metabolism
Waste disposal
Waste Management - methods
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Summary:One design concept for the long-term management of the UK's intermediate level radioactive wastes (ILW) is disposal to a cementitious geological disposal facility (GDF). Under the alkaline (10.013.0) anoxic conditions expected within a GDF, cellulosic wastes will undergo chemical hydrolysis. The resulting cellulose degradation products (CDP) are dominated by α- and β-isosaccharinic acids (ISA), which present an organic carbon source that may enable subsequent microbial colonisation of a GDF. Microcosms established from neutral, near-surface sediments demonstrated complete ISA degradation under methanogenic conditions up to pH 10.0. Degradation decreased as pH increased, with β-ISA fermentation more heavily influenced than α-ISA. This reduction in degradation rate was accompanied by a shift in microbial population away from organisms related to Clostridium sporosphaeroides to a more diverse Clostridial community. The increase in pH to 10.0 saw an increase in detection of Alcaligenes aquatilis and a dominance of hydrogenotrophic methanogens within the Archaeal population. Methane was generated up to pH 10.0 with acetate accumulation at higher pH values reflecting a reduced detection of acetoclastic methanogens. An increase in pH to 11.0 resulted in the accumulation of ISA, the absence of methanogenesis and the loss of biomass from the system. This study is the first to demonstrate methanogenesis from ISA by near surface microbial communities not previously exposed to these compounds up to and including pH 10.0.
ISSN:1932-6203
1932-6203
DOI:10.1371/journal.pone.0137682