@article{straub_khatibi_otten_adams_kelly_2019, title={Lignocellulose solubilization and conversion by extremely thermophilic Caldicellulosiruptor bescii improves by maintaining metabolic activity}, volume={116}, ISSN={["1097-0290"]}, DOI={10.1002/bit.26993}, abstractNote={AbstractThe extreme thermophile Caldicellulosiruptor bescii solubilizes and metabolizes the carbohydrate content of lignocellulose, a process that ultimately ceases because of biomass recalcitrance, accumulation of fermentation products, inhibition by lignin moieties, and reduction of metabolic activity. Deconstruction of low loadings of lignocellulose (5 g/L), either natural or transgenic, whether unpretreated or subjected to hydrothermal processing, by C. bescii typically results in less than 40% carbohydrate solubilization. Mild alkali pretreatment (up to 0.09 g NaOH/g biomass) improved switchgrass carbohydrate solubilization by C. bescii to over 70% compared to less than 30% for no pretreatment, with two‐thirds of the carbohydrate content in the treated switchgrass converted to acetate and lactate. C. bescii grown on high loadings of unpretreated switchgrass (50 g/L) retained in a pH‐controlled bioreactor slowly purged (τ = 80 hr) with growth media without a carbon source improved carbohydrate solubilization to over 40% compared to batch culture at 29%. But more significant was the doubling of solubilized carbohydrate conversion to fermentation products, which increased from 40% in batch to over 80% in the purged system, an improvement attributed to maintaining the bioreactor culture in a metabolically active state. This strategy should be considered for optimizing solubilization and conversion of lignocellulose by C. bescii and other lignocellulolytic microorganisms.}, number={8}, journal={BIOTECHNOLOGY AND BIOENGINEERING}, author={Straub, Christopher T. and Khatibi, Piyum A. and Otten, Jonathan K. and Adams, Michael W. W. and Kelly, Robert M.}, year={2019}, month={Aug}, pages={1901–1908} }
 @article{straub_khatibi_wang_conway_williams-rhaesa_peszlen_chiang_adams_kelly_2019, title={Quantitative fermentation of unpretreated transgenic poplar by Caldicellulosiruptor bescii}, volume={10}, ISSN={["2041-1723"]}, url={http://www.scopus.com/inward/record.url?eid=2-s2.0-85070390326&partnerID=MN8TOARS}, DOI={10.1038/s41467-019-11376-6}, abstractNote={AbstractMicrobial fermentation of lignocellulosic biomass to produce industrial chemicals is exacerbated by the recalcitrant network of lignin, cellulose and hemicelluloses comprising the plant secondary cell wall. In this study, we show that transgenic poplar (Populus trichocarpa) lines can be solubilized without any pretreatment by the extreme thermophile Caldicellulosiruptor bescii that has been metabolically engineered to shift its fermentation products away from inhibitory organic acids to ethanol. Carbohydrate solubilization and conversion of unpretreated milled biomass is nearly 90% for two transgenic lines, compared to only 25% for wild-type poplar. Unexpectedly, unpretreated intact poplar stems achieved nearly 70% of the fermentation production observed with milled poplar as the substrate. The nearly quantitative microbial conversion of the carbohydrate content of unpretreated transgenic lignocellulosic biomass bodes well for full utilization of renewable biomass feedstocks.}, number={1}, journal={NATURE COMMUNICATIONS}, publisher={Springer Science and Business Media LLC}, author={Straub, Christopher T. and Khatibi, Piyum A. and Wang, Jack P. and Conway, Jonathan M. and Williams-Rhaesa, Amanda M. and Peszlen, Ilona M. and Chiang, Vincent L. and Adams, Michael W. W. and Kelly, Robert M.}, year={2019}, month={Aug} }
 @article{zurawski_khatibi_akinosho_straub_compton_conway_lee_ragauskas_davison_adams_et al._2017, title={Bioavailability of Carbohydrate Content in Natural and Transgenic Switchgrasses for the Extreme Thermophile Caldicellulosiruptor bescii}, volume={83}, ISSN={["1098-5336"]}, DOI={10.1128/aem.00969-17}, abstractNote={ABSTRACT
          
            Improving access to the carbohydrate content of lignocellulose is key to reducing recalcitrance for microbial deconstruction and conversion to fuels and chemicals.
            Caldicellulosiruptor bescii
            completely solubilizes naked microcrystalline cellulose, yet this transformation is impeded within the context of the plant cell wall by a network of lignin and hemicellulose. Here, the bioavailability of carbohydrates to
            C. bescii
            at 70°C was examined for reduced lignin transgenic switchgrass lines COMT3(+) and MYB Trans, their corresponding parental lines (cultivar Alamo) COMT3(−) and MYB wild type (WT), and the natural variant cultivar Cave-in-Rock (CR). Transgenic modification improved carbohydrate solubilization by
            C. bescii
            to 15% (2.3-fold) for MYB and to 36% (1.5-fold) for COMT, comparable to the levels achieved for the natural variant, CR (36%). Carbohydrate solubilization was nearly doubled after two consecutive microbial fermentations compared to one microbial step, but it never exceeded 50% overall. Hydrothermal treatment (180°C) prior to microbial steps improved solubilization 3.7-fold for the most recalcitrant line (MYB WT) and increased carbohydrate recovery to nearly 50% for the least recalcitrant lines [COMT3(+) and CR]. Alternating microbial and hydrothermal steps (T→M→T→M) further increased bioavailability, achieving carbohydrate solubilization ranging from 50% for MYB WT to above 70% for COMT3(+) and CR. Incomplete carbohydrate solubilization suggests that cellulose in the highly lignified residue was inaccessible; indeed, residue from the T→M→T→M treatment was primarily glucan and inert materials (lignin and ash). While
            C. bescii
            could significantly solubilize the transgenic switchgrass lines and natural variant tested here, additional or alternative strategies (physical, chemical, enzymatic, and/or genetic) are needed to eliminate recalcitrance.
          
          
            IMPORTANCE
            Key to a microbial process for solubilization of plant biomass is the organism's access to the carbohydrate content of lignocellulose. Economically viable routes will characteristically minimize physical, chemical, and biological pretreatment such that microbial steps contribute to the greatest extent possible. Recently, transgenic versions of plants and trees have been developed with the intention of lowering the barrier to lignocellulose conversion, with particular focus on lignin content and composition. Here, the extremely thermophilic bacterium
            Caldicellulosiruptor bescii
            was used to solubilize natural and genetically modified switchgrass lines, with and without the aid of hydrothermal treatment. For lignocellulose conversion, it is clear that the microorganism, plant biomass substrate, and processing steps must all be considered simultaneously to achieve optimal results. Whether switchgrass lines engineered for low lignin or natural variants with desirable properties are used, conversion will depend on microbial access to crystalline cellulose in the plant cell wall.
          }, number={17}, journal={APPLIED AND ENVIRONMENTAL MICROBIOLOGY}, author={Zurawski, Jeffrey V. and Khatibi, Piyum A. and Akinosho, Hannah O. and Straub, Christopher T. and Compton, Scott H. and Conway, Jonathan M. and Lee, Laura L. and Ragauskas, Arthur J. and Davison, Brian H. and Adams, Michael W. W. and et al.}, year={2017}, month={Sep} }
 @article{williams-rhaesa_poole_dinsmore_lipscomb_rubinstein_scott_conway_lee_khatibi_kelly_et al._2017, title={Genome Stability in Engineered Strains of the Extremely Thermophilic Lignocellulose-Degrading Bacterium Caldicellulosiruptor bescii}, volume={83}, ISSN={["1098-5336"]}, DOI={10.1128/aem.00444-17}, abstractNote={ABSTRACT
          
            Caldicellulosiruptor bescii
            is the most thermophilic cellulose degrader known and is of great interest because of its ability to degrade nonpretreated plant biomass. For biotechnological applications, an efficient genetic system is required to engineer it to convert plant biomass into desired products. To date, two different genetically tractable lineages of
            C. bescii
            strains have been generated. The first (JWCB005) is based on a random deletion within the pyrimidine biosynthesis genes
            pyrFA
            , and the second (MACB1018) is based on the targeted deletion of
            pyrE
            , making use of a kanamycin resistance marker. Importantly, an active insertion element, IS
            Cbe4
            , was discovered in
            C. bescii
            when it disrupted the gene for lactate dehydrogenase (
            ldh
            ) in strain JWCB018, constructed in the JWCB005 background. Additional instances of IS
            Cbe4
            movement in other strains of this lineage are presented herein. These observations raise concerns about the genetic stability of such strains and their use as metabolic engineering platforms. In order to investigate genome stability in engineered strains of
            C. bescii
            from the two lineages, genome sequencing and Southern blot analyses were performed. The evidence presented shows a dramatic increase in the number of single nucleotide polymorphisms, insertions/deletions, and IS
            Cbe4
            elements within the genome of JWCB005, leading to massive genome rearrangements in its daughter strain, JWCB018. Such dramatic effects were not evident in the newer MACB1018 lineage, indicating that JWCB005 and its daughter strains are not suitable for metabolic engineering purposes in
            C. bescii
            . Furthermore, a facile approach for assessing genomic stability in
            C. bescii
            has been established.
          
          
            IMPORTANCE
            Caldicellulosiruptor bescii
            is a cellulolytic extremely thermophilic bacterium of great interest for metabolic engineering efforts geared toward lignocellulosic biofuel and bio-based chemical production. Genetic technology in
            C. bescii
            has led to the development of two uracil auxotrophic genetic background strains for metabolic engineering. We show that strains derived from the genetic background containing a random deletion in uracil biosynthesis genes (
            pyrFA
            ) have a dramatic increase in the number of single nucleotide polymorphisms, insertions/deletions, and IS
            Cbe4
            insertion elements in their genomes compared to the wild type. At least one daughter strain of this lineage also contains large-scale genome rearrangements that are flanked by these IS
            Cbe4
            elements. In contrast, strains developed from the second background strain developed using a targeted deletion strategy of the uracil biosynthetic gene
            pyrE
            have a stable genome structure, making them preferable for future metabolic engineering studies.
          }, number={14}, journal={APPLIED AND ENVIRONMENTAL MICROBIOLOGY}, author={Williams-Rhaesa, Amanda M. and Poole, Farris L., II and Dinsmore, Jessica T. and Lipscomb, Gina L. and Rubinstein, Gabriel M. and Scott, Israel M. and Conway, Jonathan M. and Lee, Laura L. and Khatibi, Piyum A. and Kelly, Robert M. and et al.}, year={2017}, month={Jul} }
 @article{khatibi_chou_loder_zurawski_adams_kelly_2017, title={Impact of growth mode, phase, and rate on the metabolic state of the extremely thermophilic archaeon Pyrococcus furiosus}, volume={114}, ISSN={["1097-0290"]}, DOI={10.1002/bit.26408}, abstractNote={AbstractThe archaeon Pyrococcus furiosus is emerging as a metabolic engineering platform for production of fuels and chemicals, such that more must be known about this organism's characteristics in bioprocessing contexts. Its ability to grow at temperatures from 70 to greater than 100°C and thereby avoid contamination, offers the opportunity for long duration, continuous bioprocesses as an alternative to batch systems. Toward that end, we analyzed the transcriptome of P. furiosus to reveal its metabolic state during different growth modes that are relevant to bioprocessing. As cells progressed from exponential to stationary phase in batch cultures, genes involved in biosynthetic pathways important to replacing diminishing supplies of key nutrients and genes responsible for the onset of stress responses were up‐regulated. In contrast, during continuous culture, the progression to higher dilution rates down‐regulated many biosynthetic processes as nutrient supplies were increased. Most interesting was the contrast between batch exponential phase and continuous culture at comparable growth rates (∼0.4 hr−1), where over 200 genes were differentially transcribed, indicating among other things, N‐limitation in the chemostat and the onset of oxidative stress. The results here suggest that cellular processes involved in carbon and electron flux in P. furiosus were significantly impacted by growth mode, phase and rate, factors that need to be taken into account when developing successful metabolic engineering strategies.}, number={12}, journal={BIOTECHNOLOGY AND BIOENGINEERING}, author={Khatibi, Piyum A. and Chou, Chung-jung and Loder, Andrew J. and Zurawski, Jeffrey V. and Adams, Michael W. W. and Kelly, Robert M.}, year={2017}, month={Dec}, pages={2947–2954} }
 @article{adducci_gruszewski_khatibi_schmale_2016, title={Differential detection of a surrogate biological threat agent (Bacillus globigii) with a portable surface plasmon resonance biosensor}, volume={78}, journal={Biosensors & Bioelectronics}, author={Adducci, B. A. and Gruszewski, H. A. and Khatibi, P. A. and Schmale, D. G.}, year={2016}, pages={160–166} }