%0 Journal Article %1 thummes_temporal_2007 %A Thummes, Kathrin %A Kämpfer, Peter %A Jäckel, Udo %D 2007 %J Systematic and applied microbiology %K Archaea Archaeal DNA IFZ Methane Molecular_Sequence_Data Polymorphism Restriction_Fragment_Length Sequence_Analysis Soil Soil_Microbiology Temperature %P 418-29 %T Temporal change of composition and potential activity of the thermophilic archaeal community during the composting of organic material %V 30 %X To date, composting has been regarded as an aerobic process but it has been shown that composting piles are often sources of atmospheric methane. In order to gain a more comprehensive view on the diversity of methanogenic Archaea in compost, gas chromatographical methods and molecular cloning were used to study relationships of thermophilic archaeal communities and changes in methane production potential during compost maturation. According to the thermophilic methane production potential, wide differences could be detected between differently aged compost materials. In material derived from 3- and 4-week-old piles, low and no thermophilic methane production potential, respectively, was observed at 50 degrees C. Material from a 6-week-old pile showed the maximum methane production. With compost maturation, the production slowly decreased again with 6 weeks, 8 weeks, and mature compost showing an optimum methane production potential at 60 degrees C. At 70 degrees C, only 6-week-old material showed a comparable high production of methane. The 16S rRNA-based phylogenetic surveys revealed an increase of archaeal diversity with compost maturation. In the 6-week-old material, 86\% of the sequences in the archaeal 16S rRNA library had the highest sequence similarities to Methanothermobacter spp. and the remaining 14\% of the clones were related to Methanosarcina thermophila. Quantification of methanogens in 6-week-old material, on the basis of the methane production rate, resulted in values of about 2x10(7) cells per gram fresh weight. In 8-week-old and mature compost material, the proportion of sequences similar to Methanothermobacter spp. decreased to 34\% and 0\%, respectively. The mature compost material showed the highest variation in identified sequences, although 33\% could be assigned to as yet uncultured Archaea (e.g. Rice cluster I, III, and IV). Our results indicate that compost harbours a diverse community of thermophilic methanogens, with changing composition during the maturation process, presumably due to altered pile conditions. Likewise, compost may act as a potential carrier for thermophilic methanogens in temperate soils because it is widely used as a soil amendment.

@article{thummes_temporal_2007, abstract = {To date, composting has been regarded as an aerobic process but it has been shown that composting piles are often sources of atmospheric methane. In order to gain a more comprehensive view on the diversity of methanogenic Archaea in compost, gas chromatographical methods and molecular cloning were used to study relationships of thermophilic archaeal communities and changes in methane production potential during compost maturation. According to the thermophilic methane production potential, wide differences could be detected between differently aged compost materials. In material derived from 3- and 4-week-old piles, low and no thermophilic methane production potential, respectively, was observed at 50 degrees C. Material from a 6-week-old pile showed the maximum methane production. With compost maturation, the production slowly decreased again with 6 weeks, 8 weeks, and mature compost showing an optimum methane production potential at 60 degrees C. At 70 degrees C, only 6-week-old material showed a comparable high production of methane. The 16S rRNA-based phylogenetic surveys revealed an increase of archaeal diversity with compost maturation. In the 6-week-old material, 86\% of the sequences in the archaeal 16S rRNA library had the highest sequence similarities to Methanothermobacter spp. and the remaining 14\% of the clones were related to Methanosarcina thermophila. Quantification of methanogens in 6-week-old material, on the basis of the methane production rate, resulted in values of about 2x10(7) cells per gram fresh weight. In 8-week-old and mature compost material, the proportion of sequences similar to Methanothermobacter spp. decreased to 34\% and 0\%, respectively. The mature compost material showed the highest variation in identified sequences, although 33\% could be assigned to as yet uncultured Archaea (e.g. Rice cluster I, III, and IV). Our results indicate that compost harbours a diverse community of thermophilic methanogens, with changing composition during the maturation process, presumably due to altered pile conditions. Likewise, compost may act as a potential carrier for thermophilic methanogens in temperate soils because it is widely used as a soil amendment.}, added-at = {2008-05-07T16:02:06.000+0200}, author = {Thummes, Kathrin and Kämpfer, Peter and Jäckel, Udo}, biburl = {https://www.bibsonomy.org/bibtex/235a81c889de06d3472e95181b61b6251/recymikrobio}, interhash = {ca1c746781da576e7675ea866d0b2651}, intrahash = {35a81c889de06d3472e95181b61b6251}, issn = {07232020}, journal = {Systematic and applied microbiology}, keywords = {Archaea Archaeal DNA IFZ Methane Molecular_Sequence_Data Polymorphism Restriction_Fragment_Length Sequence_Analysis Soil Soil_Microbiology Temperature}, month = {July}, note = {PMID: 17336478}, pages = {418-29}, timestamp = {2008-07-18T13:58:09.000+0200}, title = {Temporal change of composition and potential activity of the thermophilic archaeal community during the composting of organic material}, volume = 30, year = 2007 }