Your search keyword '"Karlen, Steven D."' showing total 9 results

1. Achieving high productivity of 2-pyrone-4,6-dicarboxylic acid from aqueous aromatic streams with Novosphingobium aromaticivorans.

Author

Kim, Bumkyu, Perez, Jose M., Karlen, Steven D., Coplien, Jason, Donohue, Timothy J., and Noguera, Daniel R.

Subjects

SYRINGIC acid, PLANT biomass, DICARBOXYLIC acids, MICROBIAL cells, AROMATIC compounds, LIGNOCELLULOSE

Abstract

Enhancing the production of biochemicals from lignocellulosic biomass is one potential way to decrease society's dependence on fossil fuels. Aromatic compounds obtained from plant biomass can be used as substrates for microbial production of dicarboxylic acids such as 2-pyrone-4,6-dicarboxylic acid (PDC) and cis,cis-muconic acid, which are building blocks for the manufacturing of polymer-based fibers and materials. In this study, we used an engineered strain of the bacterium Novosphingobium aromaticivorans to investigate how to increase PDC productivity in flow-through bioreactors receiving aqueous solutions of aromatics. At the best operational conditions tested, we achieved stable PDC production rates of 0.77 gPDC L−1 h−1 with p-hydroxybenzoic acid, 1.93 gPDC L−1 h−1 with syringic acid, and 1.53 gPDC L−1 h−1 with the products from alkaline pretreated poplar biomass. PDC titers in these reactors ranged from 7.7 to 15 g L−1 (42 to 80 mM) and were limited by aromatic solubility in the case of syringic acid, or by accumulation of protocatechuic acid from p-hydroxybenzoic acid when high aromatic loading rates were used. The use of high aromatic loading rates, hollow-fiber membranes to concentrate the microbial cells, and NH4OH for pH control were factors that contributed to this study achieving the highest PDC productivities reported to date. Overall, our findings demonstrate strategies that can be used to increase bioreactor productivity when aromatic substrates are delivered in aqueous form. These findings may also provide useful insight for production of other biochemicals from aromatic streams using N. aromaticivorans or other microbial chassis. [ABSTRACT FROM AUTHOR]

Published

2024

2. Evolution of p‐coumaroylated lignin in eudicots provides new tools for cell wall engineering.

Author

Mottiar, Yaseen, Smith, Rebecca A., Karlen, Steven D., Ralph, John, and Mansfield, Shawn D.

Subjects

LIGNINS, ACYLTRANSFERASES, KENAF, FEEDSTOCK, LIGNIN structure, EUDICOTS, CONVERGENT evolution, PLANT biomass

Abstract

Summary: Ester‐linked p‐coumarate (pCA) is a hallmark feature of the secondary cell walls in commelinid monocot plants. It has been shown that pCA groups arise during lignin polymerisation from the participation of monolignol conjugates assembled by p‐coumaroyl‐CoA:monolignol transferase (PMT) enzymes, members of the BAHD superfamily of acyltransferases.Herein, we report that a eudicot species, kenaf (Hibiscus cannabinus), naturally contains p‐coumaroylated lignin in the core tissues of the stems but not in the bast fibres. Moreover, we identified a novel acyltransferase, HcPMT, that shares <30% amino acid identity with known monocot PMT sequences.Recombinant HcPMT showed a preference in enzyme assays for p‐coumaroyl‐CoA and benzoyl‐CoA as acyl donor substrates and sinapyl alcohol as an acyl acceptor. Heterologous expression of HcPMT in hybrid poplar trees led to the incorporation of pCA in lignin, but no improvement in the saccharification potential of the wood.This work illustrates the value in mining diverse plant taxa for new monolignol acyltransferases. Furthermore, the occurrence of pCA outside monocot lineages may represent another example of convergent evolution in lignin structure. This discovery expands textbook views on cell wall biochemistry and provides a new molecular tool for engineering the lignin of biomass feedstock plants. [ABSTRACT FROM AUTHOR]

Published

2023

3. A new approach to zip‐lignin: 3,4‐dihydroxybenzoate is compatible with lignification.

Author

Unda, Faride, Mottiar, Yaseen, Mahon, Elizabeth L., Karlen, Steven D., Kim, Kwang Ho, Loqué, Dominique, Eudes, Aymerick, Ralph, John, and Mansfield, Shawn D.

Subjects

LIGNINS, LIGNIN structure, LIGNIFICATION, NUCLEAR magnetic resonance, PLANT biomass, WOOD

Abstract

Summary: Renewed interests in the development of bioenergy, biochemicals, and biomaterials have elicited new strategies for engineering the lignin of biomass feedstock plants. This study shows, for the first time, that 3,4‐dihydroxybenzoate (DHB) is compatible with the radical coupling reactions that assemble polymeric lignin in plants.We introduced a bacterial 3‐dehydroshikimate dehydratase into hybrid poplar (Populus alba × grandidentata) to divert carbon flux away from the shikimate pathway, which lies upstream of lignin biosynthesis.Transgenic poplar wood had up to 33% less lignin with p‐hydroxyphenyl units comprising as much as 10% of the lignin. Mild alkaline hydrolysis of transgenic wood released fewer ester‐linked p‐hydroxybenzoate groups than control trees, and revealed the novel incorporation of cell‐wall‐bound DHB, as well as glycosides of 3,4‐dihydroxybenzoic acid (DHBA). Two‐dimensional nuclear magnetic resonance (2D‐NMR) analysis uncovered DHBA‐derived benzodioxane structures suggesting that DHB moieties were integrated into the lignin polymer backbone. In addition, up to 40% more glucose was released from transgenic wood following ionic liquid pretreatment and enzymatic hydrolysis.This work highlights the potential of diverting carbon flux from the shikimate pathway for lignin engineering and describes a new type of 'zip‐lignin' derived from the incorporation of DHB into poplar lignin. [ABSTRACT FROM AUTHOR]

Published

2022

4. Downregulation of p‐COUMAROYL ESTER 3‐HYDROXYLASE in rice leads to altered cell wall structures and improves biomass saccharification.

Author

Takeda, Yuri, Tobimatsu, Yuki, Karlen, Steven D., Koshiba, Taichi, Suzuki, Shiro, Yamamura, Masaomi, Murakami, Shinya, Mukai, Mai, Hattori, Takefumi, Osakabe, Keishi, Ralph, John, Sakamoto, Masahiro, and Umezawa, Toshiaki

Subjects

PLANT biomass, DOWNREGULATION, PLANT cell walls, HYDROXYLASES, BIOSYNTHESIS, LIGNINS

Abstract

Summary: p‐Coumaroyl ester 3‐hydroxylase (C3′H) is a key enzyme involved in the biosynthesis of lignin, a phenylpropanoid polymer that is the major constituent of secondary cell walls in vascular plants. Although the crucial role of C3′H in lignification and its manipulation to upgrade lignocellulose have been investigated in eudicots, limited information is available in monocotyledonous grass species, despite their potential as biomass feedstocks. Here we address the pronounced impacts of C3′H deficiency on the structure and properties of grass cell walls. C3′H‐knockdown lines generated via RNA interference (RNAi)‐mediated gene silencing, with about 0.5% of the residual expression levels, reached maturity and set seeds. In contrast, C3′H‐knockout rice mutants generated via CRISPR/Cas9‐mediated mutagenesis were severely dwarfed and sterile. Cell wall analysis of the mature C3′H‐knockdown RNAi lines revealed that their lignins were largely enriched in p‐hydroxyphenyl (H) units while being substantially reduced in the normally dominant guaiacyl (G) and syringyl (S) units. Interestingly, however, the enrichment of H units was limited to within the non‐acylated lignin units, with grass‐specific γ‐p‐coumaroylated lignin units remaining apparently unchanged. Suppression of C3′H also resulted in relative augmentation in tricin residues in lignin as well as a substantial reduction in wall cross‐linking ferulates. Collectively, our data demonstrate that C3′H expression is an important determinant not only of lignin content and composition but also of the degree of cell wall cross‐linking. We also demonstrated that C3′H‐suppressed rice displays enhanced biomass saccharification. [ABSTRACT FROM AUTHOR]

Published

2018

5. Variation in energy sorghum hybrid TX08001 biomass composition and lignin chemistry during development under irrigated and non-irrigated field conditions.

Author

McKinley, Brian A., Olson, Sara N., Ritter, Kimberley B., Herb, Dustin W., Karlen, Steven D., Lu, Fachuang, Ralph, John, Rooney, William L., and Mullet, John E.

Subjects

PLANT shoots, PLANT biomass, COMPOSITION of sorghum, ENERGY crops, PLANT growth, GENOTYPES

Abstract

This study was conducted to document the extent and basis of compositional variation of shoot biomass of the energy Sorghum bicolor hybrid TX08001 during development under field conditions. TX08001 is capable of accumulating ~40 Mg/ha of dry biomass under good growing conditions and this genotype allocates ~80% of its shoot biomass to stems. After 150 days of growth TX08001 stems had a fresh/dry weight ratio of ~3:1 and soluble biomass accounted for ~30% of stem biomass. A panel of diverse energy sorghum genotypes varied ~6-fold in the ratio of stem structural to soluble biomass after 150 days of growth. Near-infrared spectroscopic analysis (NIRS) showed that TX08001 leaves accumulated higher levels of protein, water extractives and ash compared to stems, which have higher sugar, cellulose, and lignin contents. TX08001 stem sucrose content varied during development, whereas the composition of TX08001 stem cell walls, which consisted of ~45–49% cellulose, ~27–30% xylan, and ~15–18% lignin, remained constant after 90 days post emergence until the end of the growing season (180 days). TX08001 and Della stem syringyl (S)/guaiacyl (G) (0.53–0.58) and ferulic acid (FA)/para-coumaric acid (pCA) ratios were similar whereas ratios of pCA/(S+G) differed between these genotypes. Additionally, an analysis of irrigated versus non-irrigated TX08001 revealed that non-irrigated hybrids exhibited a 50% reduction in total cell wall biomass, an ~2-fold increase in stem sugars, and an ~25% increase in water extractives relative to irrigated hybrids. This study provides a baseline of information to help guide further optimization of energy sorghum composition for various end-uses. [ABSTRACT FROM AUTHOR]

Published

2018

6. Tricin-lignins: occurrence and quantitation of tricin in relation to phylogeny.

Author

Lan, Wu, Rencoret, Jorge, Lu, Fachuang, Karlen, Steven D., Smith, Bronwen G., Harris, Philip J., Río, José Carlos, and Ralph, John

Subjects

FLAVONES, LIGNIFICATION, PHYLOGENY, PLANT biomass, NUCLEATION

Abstract

Tricin [5,7-dihydroxy-2-(4-hydroxy-3,5-dimethoxyphenyl)-4H-chromen-4-one], a flavone, was recently established as an authentic monomer in grass lignification that likely functions as a nucleation site. It is linked onto lignin as an aryl alkyl ether by radical coupling with monolignols or their acylated analogs. However, the level of tricin that incorporates into lignin remains unclear. Herein, three lignin characterization methods: acidolysis; thioacidolysis; and derivatization followed by reductive cleavage; were applied to quantitatively assess the amount of lignin-integrated tricin. Their efficiencies at cleaving the tricin-(4′- O-β)-ether bonds and the degradation of tricin under the corresponding reaction conditions were evaluated. A hexadeuterated tricin analog was synthesized as an internal standard for accurate quantitation purposes. Thioacidolysis proved to be the most efficient method, liberating more than 91% of the tricin with little degradation. A survey of different seed-plant species for the occurrence and content of tricin showed that it is widely distributed in the lignin from species in the family Poaceae (order Poales). Tricin occurs at low levels in some commelinid monocotyledon families outside the Poaceae, such as the Arecaceae (the palms, order Arecales) and Bromeliaceae (Poales), and the non-commelinid monocotyledon family Orchidaceae (Orchidales). One eudicotyledon was found to have tricin ( Medicago sativa, Fabaceae). The content of lignin-integrated tricin is much higher than the extractable tricin level in all cases. Lignins, including waste lignin streams from biomass processing, could therefore provide a large and alternative source of this valuable flavone, reducing the costs, and encouraging studies into its application beyond its current roles. [ABSTRACT FROM AUTHOR]

Published

2016

7. Effects of PHENYLALANINE AMMONIA LYASE (PAL) knockdown on cell wall composition, biomass digestibility, and biotic and abiotic stress responses in Brachypodium.

Author

Cass, Cynthia L., Peraldi, Antoine, Dowd, Patrick F., Mottiar, Yaseen, Santoro, Nicholas, Karlen, Steven D., Bukhman, Yury V., Foster, Cliff E., Thrower, Nick, Bruno, Laura C., Moskvin, Oleg V., Johnson, Eric T., Willhoit, Megan E., Phutane, Megha, Ralph, John, Mansfield, Shawn D., Nicholson, Paul, and Sedbrook, John C.

Subjects

BRACHYPODIUM, PLANT cell walls, PHENYLALANINE ammonia lyase, PLANT biomass, ABIOTIC stress, GENE knockout, RNA interference, PLANT mutation

Abstract

The phenylpropanoid pathway in plants synthesizes a variety of structural and defence compounds, and is an important target in efforts to reduce cell wall lignin for improved biomass conversion to biofuels. Little is known concerning the trade-offs in grasses when perturbing the function of the first gene family in the pathway, PHENYLALANINE AMMONIA LYASE (PAL). Therefore, PAL isoforms in the model grass Brachypodium distachyon were targeted, by RNA interference (RNAi), and large reductions (up to 85%) in stem tissue transcript abundance for two of the eight putative BdPAL genes were identified. The cell walls of stems of BdPAL-knockdown plants had reductions of 43% in lignin and 57% in cell wall-bound ferulate, and a nearly 2-fold increase in the amounts of polysaccharide-derived carbohydrates released by thermo-chemical and hydrolytic enzymic partial digestion. PAL-knockdown plants exhibited delayed development and reduced root growth, along with increased susceptibilities to the fungal pathogens Fusarium culmorum and Magnaporthe oryzae. Surprisingly, these plants generally had wild-type (WT) resistances to caterpillar herbivory, drought, and ultraviolet light. RNA sequencing analyses revealed that the expression of genes associated with stress responses including ethylene biosynthesis and signalling were significantly altered in PAL knocked-down plants under non-challenging conditions. These data reveal that, although an attenuation of the phenylpropanoid pathway increases carbohydrate availability for biofuel, it can adversely affect plant growth and disease resistance to fungal pathogens. The data identify notable differences between the stress responses of these monocot pal mutants versus Arabidopsis (a dicot) pal mutants and provide insights into the challenges that may arise when deploying phenylpropanoid pathway-altered bioenergy crops. [ABSTRACT FROM AUTHOR]

Published

2015

8. Anaerobic Degradation of Syringic Acid by an Adapted Strain of Rhodopseudomonas palustris.

Author

Oshlag, J. Zachary, Yanjun Ma, Morse, Kaitlin, Burger, Brian T., Lemke, Rachelle A., Karlen, Steven D., Myers, Kevin S., Donohue, Timothy J., and Noguera, Daniel R.

Subjects

*RHODOPSEUDOMONAS palustris, *SYRINGIC acid, *LIGNINS, *HYDROXYBENZOIC acid, *OPERONS, *PLANT biomass, *AROMATIC compounds

Abstract

While lignin represents a major fraction of the carbon in plant biomass, biological strategies to convert the components of this heterogeneous polymer into products of industrial and biotechnological value are lacking. Syringic acid (3,5-dimethoxy-4- hydroxybenzoic acid) is a by-product of lignin degradation, appearing in lignocellulosic hydrolysates, deconstructed lignin streams, and other agricultural products. Rhodopseudomonas palustris CGA009 is a known degrader of phenolic compounds under photoheterotrophic conditions via the benzoyl coenzyme A (CoA) degradation (BAD) pathway. However, R. palustris CGA009 is reported to be unable to metabolize meta-methoxylated phenolics, such as syringic acid. We isolated a strain of R. palustris (strain SA008.1.07), adapted from CGA009, which can grow on syringic acid under photoheterotrophic conditions, utilizing it as a sole source of organic carbon and reducing power. An SA008.1.07 mutant with an inactive benzoyl-CoA reductase structural gene was able to grow on syringic acid, demonstrating that the metabolism of this aromatic compound is not through the BAD pathway. Comparative gene expression analyses of SA008.1.07 implicated the involvement of products of the vanARB operon (rpa3619, rpa3620, rpa3621), which has been described as catalyzing aerobic aromatic ring demethylation in other bacteria, in anaerobic syringic acid degradation. In addition, experiments with a vanARB deletion mutant demonstrated the involvement of the vanARB operon in anaerobic syringic acid degradation. These observations provide new insights into the anaerobic degradation of meta-methoxylated and other aromatics by R. palustris. [ABSTRACT FROM AUTHOR]

Published

2020

9. A heterodimeric glutathione S-transferase that stereospecifically breaks lignin’s β(R)-aryl ether bond reveals the diversity of bacterial β-etherases.

Author

Kontur, Wayne S., Olmsted, Charles N., Yusko, Larissa M., Niles, Alyssa V., Walters, Kevin A., Beebe, Emily T., Meulen, Kirk A. Vander, Karlen, Steven D., Gall, Daniel L., Noguera, Daniel R., and Donohue, Timothy J.

Subjects

*GLUTATHIONE transferase, *HETERODIMERS, *LIGNINS, *PLANT biomass, *PHOSPHATES

Abstract

Lignin is a heterogeneous polymer of aromatic subunits that is a major component of lignocellulosic plant biomass. Understanding how microorganisms deconstruct lignin is important for understanding the global carbon cycle and could aid in developing systems for processing plant biomass into valuable commodities. Sphingomonad bacteria use stereospecific glutathione S-transferases (GSTs) called β-etherases to cleave the β-aryl ether (β-O-4) bond, the most common bond between aromatic subunits in lignin. Previously characterized bacterial β-etherases are homodimers that fall into two distinct GST sub-classes: LigE homologues, which cleave theβ(R) stereoisomer of the bond, and LigF homologues, which cleave the β(S) stereoisomer. Here, we report on a heterodimeric β-etherase (BaeAB) from the sphingomonad Novosphingobium aromaticivorans that stereospecifically cleaves the β(R)-aryl ether bond of the di-aromatic compound β-(2-methoxyphenoxy)-γ-hydroxypropiovanillone (MPHPV). BaeAB’s subunits are phylogenetically distinct from each other and from other β-etherases, although they are evolutionarily related to LigF, despite the fact that BaeAB and LigF cleave different β-aryl ether bond stereoisomers. We identify amino acid residues in BaeAB’s BaeA subunit important for substrate binding and catalysis, including an asparagine that is proposed to activate the GSH cofactor. We also show that BaeAB homologues from other sphingomonads can cleave β(R)-MPHPV and that they may be as common in bacteria as LigE homologues. Our results suggest that the ability to cleave theβ-aryl ether bond arose independently at least twice in GSTs and that BaeAB homologues may be important for cleaving the β(R)-aryl ether bonds of lignin-derived oligomers in nature. [ABSTRACT FROM AUTHOR]

Published

2019