Lignification waterproofs and strengthens the secondary plant cell wall, while increasing the energy cost associated with releasing sugars for biofuel production. The physical association between lignin and the carbohydrate scaffold that accommodates lignin polymerization, as well as the temporally distinct roles of different lignin units and carbohydrate partners during lignification, remain largely unclear. Here we map the lignin-carbohydrate interactions by solid-state NMR in 13C-labeled Arabidopsis inflorescence stems as secondary cell walls are formed. Analysis includes wild-type and two mutants that either selectively or globally disrupt lignin biosynthesis. Mature cell walls in the basal regions of older stems are enriched in S-lignin and carbohydrate-lignin interactions. Acetylated xylan is the dominant mediator of interactions with S-lignin, while methylated pectin unexpectedly interacts with G-lignin during early-stage lignification. The critical role of S-lignin in stabilizing carbohydrate-lignin interface is emphasized by the weak lignin-carbohydrate interactions and compromised mechanical properties of a low-S fah1 mutant, whereas the ref3 mutant, with low overall lignin content but a higher S/G ratio, remained unaffected. These findings demonstrate that the molecular mixing pattern, rather than lignin content, is a key determinant of the structure and properties of lignocellulosic materials.
Avian reoviruses (ARVs) cause viral arthritis or tenosynovitis, resulting in poor weight gain and increased feed conversion ratios in chickens. In this study, we generated three Marek's disease virus (MDV) recombinants, namely, rMDV-ARV-σB, rMDV-ARV-σC, and rMDV-ARV-σB + C, expressing ARV σB, σC, and both σB and σC, respectively. In rMDV-ARV-σB and rMDV-ARV-σC, the σB or σC gene was inserted into the US2 gene of MDV vaccine strain 814 using a fosmid-based rescue system. In rMDV-ARV-σB + C, the σB and σC genes were cloned into different expression cassettes, which were co-inserted into the US2 gene of the MDV 814 strain. In infected chicken embryo fibroblasts (CEFs), the recombinant virus rMDV-ARV-σB expressed σB, rMDV-ARV-σC expressed σC, and the rMDV-ARV-σB + C virus simultaneously expressed σB and σC. These recombinant viruses exhibited growth kinetics in CEFs similar to those of the parent MDV, and the inserted genes were stably maintained and expressed in the recombinant MDVs after 20 passages in cell cultures. These recombinant MDVs expressing σB and σC will provide potential vaccines against ARV infection in chickens.
Summary Resveratrol and related stilbenes are thought to play important roles in defence responses in several plant species and have also generated considerable interest as nutraceuticals owing to their diverse health‐promoting properties. Pterostilbene, a 3,5‐dimethylether derivative of resveratrol, possesses properties similar to its parent compound and, additionally, exhibits significantly higher fungicidal activity in vitro and superior pharmacokinetic properties in vivo . Recombinant enzyme studies carried out using a previously characterized O ‐methyltransferase sequence from Sorghum bicolor ( SbOMT3 ) demonstrated its ability to catalyse the A ring‐specific 3,5‐bis‐ O ‐methylation of resveratrol, yielding pterostilbene. A binary vector was constructed for the constitutive co‐expression of SbOMT3 with a stilbene synthase sequence from peanut ( AhSTS3 ) and used for the generation of stably transformed tobacco and Arabidopsis plants, resulting in the accumulation of pterostilbene in both species. A reduced floral pigmentation phenotype observed in multiple tobacco transformants was further investigated by reversed‐phase HPLC analysis, revealing substantial decreases in both dihydroquercetin‐derived flavonoids and phenylpropanoid‐conjugated polyamines in pterostilbene‐producing SbOMT3 / AhSTS3 events. These results demonstrate the potential utility of this strategy for the generation of pterostilbene‐producing crops and also underscore the need for the development of additional approaches for minimizing concomitant reductions in key phenylpropanoid‐derived metabolites.
Cytochrome P450 system consists of P450 monooxygenase and redox pattern(s). While the importance of monooxygenases in plant metabolism is well documented, the metabolic roles of the related redox components have been largely overlooked. Here, we show that distinct electron transfer chains are recruited in phenylpropanoid-monolignol P450 systems to support the synthesis and distribution of different classes of phenolics in different plant tissues. While Arabidopsis cinnamate 4-hydroxylase adopts conventional NADPH-cytochrome P450 oxidoreductase (CPR) electron transfer chain for its para-hydroxylation reaction, ferulate 5-hydroxylase uses both NADPH-CPR-cytochrome b5 (CB5) and NADH-cytochrome b5 reductase-CB5 chains to support benzene ring 5-hydroxylation, in which the former route is primarily recruited in the stem for syringyl lignin synthesis, while the latter dominates in the syntheses of 5-hydroxylated phenolics in seeds and seed coat suberin. Our study unveils an additional layer of complexity and versatility of P450 system that the plants evolved for diversifying phenolic repertoires.
Abstract Producing cellulosic biofuels and bio-based chemicals from woody biomass is impeded by the presence of lignin polymer in the plant cell wall. Manipulating the monolignol biosynthetic pathway offers a promising approach to improved processability, but often impairs plant growth and development. Here, we show that expressing an engineered 4- O -methyltransferase that chemically modifies the phenolic moiety of lignin monomeric precursors, thus preventing their incorporation into the lignin polymer, substantially alters hybrid aspens’ lignin content and structure. Woody biomass derived from the transgenic aspens shows a 62% increase in the release of simple sugars and up to a 49% increase in the yield of ethanol when the woody biomass is subjected to enzymatic digestion and yeast-mediated fermentation. Moreover, the cell wall structural changes do not affect growth and biomass production of the trees. Our study provides a useful strategy for tailoring woody biomass for bio-based applications.
Polyunsaturated fatty acids (PUFAs) have important industrial, physiological, and nutritional properties. Plants use the sequential activities of FAD2 and FAD3 desaturases to convert 18:1Δ9 to the important PUFA 18:3Δ9,12,15, whereas the fungus Fusarium verticillioides 7600 uses the bifunctional desaturase Fm1 for both reactions. Here, we used a combination of sequence comparisons, structural modeling, and mutagenesis experiments to investigate Fm1's regioselectivity and identified two functionally relevant clusters of residues that contribute to Fm1 activity. We found that cluster I (Leu153, Phe157, and His194), located near the catalytic iron ions, predominantly affects activity, whereas cluster II (Tyr280, His284, and Leu287), located in a helix forming the entrance to the substrate-binding pocket, mainly specifies 15-desaturation. Individual or combined substitutions of cluster II residues substantially reduced 15-desaturation. The combination of F157W from cluster I with Y280L, H284V, and L287T from cluster II created an increased-activity variant that almost completely lost the ability to desaturate at C15 and acted almost exclusively as a 12-desaturase. No variants were identified in which 15-desaturation occurred in the absence of 12-desaturation. Fm1 displayed only traces of activity with C16 substrate, but several cluster I variants exhibited increased activity with both 18:1 and 16:1 substrates, converting 16:1Δ9 to 16:3Δ9,12,15, consistent with Fm1 performing sequential v + 3 desaturation reactions at C12 and then C15. We propose that cluster II residues interact with the substrate headgroup when the acyl chain contains both Δ9 and Δ12 double bonds, in which case C15 becomes positioned adjacent to the di-iron site enabling a second v + 3 desaturation.
Abstract Phenylalanine ammonia-lyase (PAL) catalyzes the first rate-limiting step in the phenylpropanoid pathway, which controls carbon flux to a variety of bioactive small-molecule aromatic compounds, and to lignin, the structural component of the cell wall. PAL is regulated at both the transcriptional and translational levels. Our knowledge about the transcriptional regulation of PAL is relatively comprehensive, but our knowledge of the molecular basis of the posttranslational regulation of PAL remains limited. Here, we demonstrate that the Arabidopsis thaliana Kelch repeat F-box (KFB) proteins KFB01, KFB20, and KFB50 physically interact with four PAL isozymes and mediate their proteolytic turnover via the ubiquitination-26S proteasome pathway. The KFB genes are differentially expressed in Arabidopsis tissues and respond to developmental and environmental cues. Up- or downregulation of their expression reciprocally affects the stability of the PAL enzymes, consequently altering the levels of phenylpropanoids. These data suggest that the KFB-mediated protein ubiquitination and degradation regulates the proteolysis of PALs, thus posttranslationally regulating phenylpropanoid metabolism. Characterizing the KFB-mediated proteolysis of PAL enzymes may inform future strategies for manipulating the synthesis of bioactive phenolics.
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