@article {1030, title = {Metagenomes of tropical soil-derived anaerobic switchgrass-adapted consortia with and without iron.}, journal = {Stand Genomic Sci}, volume = {7}, year = {2013}, month = {2013}, pages = {382-98}, abstract = {

Tropical forest soils decompose litter rapidly with frequent episodes of anoxia, making it likely that bacteria using alternate terminal electron acceptors (TEAs) such as iron play a large role in supporting decomposition under these conditions. The prevalence of many types of metabolism in litter deconstruction makes these soils useful templates for improving biofuel production. To investigate how iron availability affects decomposition, we cultivated feedstock-adapted consortia (FACs) derived from iron-rich tropical forest soils accustomed to experiencing frequent episodes of anaerobic conditions and frequently fluctuating redox. One consortium was propagated under fermenting conditions, with switchgrass as the sole carbon source in minimal media (SG only FACs), and the other consortium was treated the same way but received poorly crystalline iron as an additional terminal electron acceptor (SG + Fe FACs). We sequenced the metagenomes of both consortia to a depth of about 150 Mb each, resulting in a coverage of 26\× for the more diverse SG + Fe FACs, and 81\× for the relatively less diverse SG only FACs. Both consortia were able to quickly grow on switchgrass, and the iron-amended consortium exhibited significantly higher microbial diversity than the unamended consortium. We found evidence of higher stress in the unamended FACs and increased sugar transport and utilization in the iron-amended FACs. This work provides metagenomic evidence that supplementation of alternative TEAs may improve feedstock deconstruction in biofuel production.

}, issn = {1944-3277}, doi = {10.4056/sigs.3377516}, author = {Deangelis, Kristen M and D{\textquoteright}haeseleer, Patrik and Chivian, Dylan and Simmons, Blake and Arkin, Adam P and Mavromatis, Konstantinos and Malfatti, Stephanie and Tringe, Susannah and Hazen, Terry C} } @article {371, title = {Complete genome sequence of "Enterobacter lignolyticus" SCF1.}, journal = {Stand Genomic Sci}, volume = {5}, year = {2011}, month = {2011 Oct 15}, pages = {69-85}, abstract = {In an effort to discover anaerobic bacteria capable of lignin degradation, we isolated "Enterobacter lignolyticus" SCF1 on minimal media with alkali lignin as the sole source of carbon. This organism was isolated anaerobically from tropical forest soils collected from the Short Cloud Forest site in the El Yunque National Forest in Puerto Rico, USA, part of the Luquillo Long-Term Ecological Research Station. At this site, the soils experience strong fluctuations in redox potential and are net methane producers. Because of its ability to grow on lignin anaerobically, we sequenced the genome. The genome of "E. lignolyticus" SCF1 is 4.81 Mbp with no detected plasmids, and includes a relatively small arsenal of lignocellulolytic carbohydrate active enzymes. Lignin degradation was observed in culture, and the genome revealed two putative laccases, a putative peroxidase, and a complete 4-hydroxyphenylacetate degradation pathway encoded in a single gene cluster.}, issn = {1944-3277}, doi = {10.4056/sigs.2104875}, author = {Deangelis, Kristen M and D{\textquoteright}haeseleer, Patrik and Chivian, Dylan and Fortney, Julian L and Khudyakov, Jane and Simmons, Blake and Woo, Hannah and Arkin, Adam P and Davenport, Karen Walston and Goodwin, Lynne and Chen, Amy and Ivanova, Natalia and Kyrpides, Nikos C and Mavromatis, Konstantinos and Woyke, Tanja and Hazen, Terry C} }