Your search keyword '"Liu, Chang-Jun"' showing total 18 results

1. Cytochrome b5 diversity in green lineages preceded the evolution of syringyl lignin biosynthesis.

Author

Zhao X, Zhao Y, Zeng QY, and Liu CJ

Subjects

Phylogeny, Cytochrome P-450 Enzyme System genetics, Cytochrome P-450 Enzyme System metabolism, Evolution, Molecular, Magnoliopsida genetics, Magnoliopsida metabolism, Embryophyta genetics, Charophyceae genetics, Charophyceae metabolism, Lignin biosynthesis, Lignin metabolism, Cytochromes b5 genetics, Cytochromes b5 metabolism, Plant Proteins genetics, Plant Proteins metabolism

Abstract

Lignin production marked a milestone in vascular plant evolution, and the emergence of syringyl (S) lignin is lineage specific. S-lignin biosynthesis in angiosperms, mediated by ferulate 5-hydroxylase (F5H, CYP84A1), has been considered a recent evolutionary event. F5H uniquely requires the cytochrome b5 protein CB5D as an obligatory redox partner for catalysis. However, it remains unclear how CB5D functionality originated and whether it coevolved with F5H. We reveal here the ancient evolution of CB5D-type function supporting F5H-catalyzed S-lignin biosynthesis. CB5D emerged in charophyte algae, the closest relatives of land plants, and is conserved and proliferated in embryophytes, especially in angiosperms, suggesting functional diversification of the CB5 family before terrestrialization. A sequence motif containing acidic amino residues in Helix 5 of the CB5 heme-binding domain contributes to the retention of CB5D function in land plants but not in algae. Notably, CB5s in the S-lignin-producing lycophyte Selaginella lack these residues, resulting in no CB5D-type function. An independently evolved S-lignin biosynthetic F5H (CYP788A1) in Selaginella relies on NADPH-dependent cytochrome P450 reductase as sole redox partner, distinct from angiosperms. These results suggest that angiosperm F5Hs coopted the ancient CB5D, forming a modern cytochrome P450 monooxygenase system for aromatic ring meta-hydroxylation, enabling the reemergence of S-lignin biosynthesis in angiosperms., Competing Interests: Conflict of interest statement. None declared., (© The Author(s) 2024. Published by Oxford University Press on behalf of American Society of Plant Biologists. All rights reserved. For commercial re-use, please contact reprints@oup.com for reprints and translation rights for reprints. All other permissions can be obtained through our RightsLink service via the Permissions link on the article page on our site—for further information please contact journals.permissions@oup.com.)

Published

2024

2. Biocatalytic system for comparatively assessing the functional association of monolignol cytochrome P450 monooxygenases with their redox partners.

Author

Zhao X and Liu CJ

Subjects

NADP, Trans-Cinnamate 4-Monooxygenase metabolism, Cytochromes b metabolism, Benzene, NAD metabolism, NADPH-Ferrihemoprotein Reductase chemistry, Cytochrome P-450 Enzyme System metabolism, Oxidation-Reduction, Esters, Cytochrome-B(5) Reductase metabolism, Lignin metabolism

Abstract

Lignin is a complex heterogenous polymer derived from oxidative radical polymerization of three monolignols, i.e., p-coumaryl alcohol, coniferyl alcohol and sinapyl alcohol. These lignin monomeric precursors structurally differ in their methoxy groups of the benzene rings. In phenylpropanoid-monolignol biosynthetic pathway, the endoplasmic reticulum (ER)-resident cytochrome P450 monooxygenases, cinnamate 4-hydroxylase, coumaroyl ester 3'-hydroxylase and ferulate 5-hydroxylase, establish the key structural characteristics of monolignols. The catalysis of cytochrome P450 monooxygenase requires reducing power, which is supplied by the ER electron transfer chains, composed of cytochrome P450 oxidoreductase (CPR), cytochrome b 5 reductase (CBR) and/or cytochrome b 5 protein (CB5), from cofactor NADPH or NADH. While NADPH-dependent CPR serves as the typical electron donor for most P450 enzymes, in some cases, the CBR-CB5 or CPR-CB5 electron transfer system also transfers electrons to the terminal P450 enzymes. There are tremendous studies focusing on the discovery and characterization of cytochrome P450 monooxygenases. However, very limited attention has been paid to the versatility and the roles of electron transfer components in the P450 catalytic system. Due to the membrane-residence property of both P450 enzymes and electron transfer components, it is challenging to establish an effective experimental system to evaluate the functional association of P450s with their redox partners. This chapter describes a yeast cell biocatalytic system and the related experimental procedures for comparatively assessing the functional relationship of monolignol biosynthetic P450 enzymes and different redox partners in their catalysis., Competing Interests: Competing interests The authors declare that they have no competing interests., (Copyright © 2022 Elsevier Inc. All rights reserved.)

Published

2022

3. Monolignol acyltransferase for lignin p-hydroxybenzoylation in Populus.

Author

Zhao Y, Yu X, Lam PY, Zhang K, Tobimatsu Y, and Liu CJ

Subjects

Gene Expression Regulation, Plant, Genes, Plant, Genetic Variation, Genotype, Plants, Genetically Modified metabolism, Acyltransferases genetics, Acyltransferases metabolism, Hydroxybenzoates metabolism, Lignin biosynthesis, Lignin genetics, Populus genetics, Populus metabolism

Abstract

Plant lignification exhibits notable plasticity. Lignin in many species, including Populus spp., has long been known to be decorated with p-hydroxybenzoates. However, the molecular basis for such structural modification remains undetermined. Here, we report the identification and characterization of a Populus BAHD family acyltransferase that catalyses monolignol p-hydroxybenzoylation, thus controlling the formation of p-hydroxybenzoylated lignin structures. We reveal that Populus acyltransferase PHBMT1 kinetically preferentially uses p-hydroxybenzoyl-CoA to acylate syringyl lignin monomer sinapyl alcohol in vitro. Consistently, disrupting PHBMT1 in Populus via CRISPR-Cas9 gene editing nearly completely depletes p-hydroxybenzoates of stem lignin; conversely, overexpression of PHBMT1 enhances stem lignin p-hydroxybenzoylation, suggesting PHBMT1 functions as a prime monolignol p-hydroxybenzoyltransferase in planta. Altering lignin p-hydroxybenzoylation substantially changes the lignin solvent dissolution rate, indicative of its structural significance on lignin physiochemical properties. Identification of monolignol p-hydroxybenzoyltransferase offers a valuable tool for tailoring lignin structure and physiochemical properties and for engineering the industrially important platform chemical in woody biomass., (© 2021. The Author(s), under exclusive licence to Springer Nature Limited.)

Published

2021

4. Cytochrome b 5 Is an Obligate Electron Shuttle Protein for Syringyl Lignin Biosynthesis in Arabidopsis.

Author

Gou M, Yang X, Zhao Y, Ran X, Song Y, and Liu CJ

Subjects

Arabidopsis genetics, Arabidopsis Proteins genetics, Cell Wall genetics, Cell Wall metabolism, Cytochrome P-450 Enzyme System genetics, Cytochrome P-450 Enzyme System metabolism, Cytochromes b genetics, Gene Expression Regulation, Plant, Plant Proteins genetics, Plants, Genetically Modified genetics, Plants, Genetically Modified metabolism, Arabidopsis metabolism, Arabidopsis Proteins metabolism, Cytochromes b metabolism, Lignin biosynthesis, Plant Proteins metabolism

Abstract

Angiosperms have evolved the metabolic capacity to synthesize p -hydroxyphenyl, guaiacyl (G), and syringyl (S) lignin subunits in their cell walls to better adapt to the harsh terrestrial environment. The structural characteristics of lignin subunits are essentially determined by three cytochrome P450-catalzyed reactions. NADPH-dependent cytochrome P450 oxidoreductase (CPR) is commonly regarded as the electron carrier for P450-catalyzed reactions during monolignol biosynthesis. Here, we show that cytochrome b isoform D (CB5D) is an indispensable electron shuttle protein specific for S-lignin biosynthesis. Arabidopsis ( 5 isoform D (CB5D) is an indispensable electron shuttle protein specific for S-lignin biosynthesis. Arabidopsis ( Arabidopsis thaliana in Arabidopsis resulted in a >60% reduction in S-lignin subunit levels but no impairment in G-lignin formation compared with the wild type, which sharply contrasts with the impaired G- and S-lignin synthesis observed after disrupting CB5D , encoding Arabidopsis CPR. The defective S-lignin synthesis in ATR2 , encoding Arabidopsis CPR. The defective S-lignin synthesis in cb5d mutants was rescued by the expression of the gene encoding CB5D but not with mutant CB5D devoid of its electron shuttle properties. Disrupting ATR2 specifically depleted the latter's activity. Therefore, CB5D functions as an obligate electron shuttle intermediate that specifically augments F5H-catalyzed reactions, thereby controlling S-lignin biosynthesis.CB5D specifically depleted the latter's activity. Therefore, CB5D functions as an obligate electron shuttle intermediate that specifically augments F5H-catalyzed reactions, thereby controlling S-lignin biosynthesis., (© 2019 American Society of Plant Biologists. All rights reserved.)

Published

2019

5. The scaffold proteins of lignin biosynthetic cytochrome P450 enzymes.

Author

Gou M, Ran X, Martin DW, and Liu CJ

Subjects

Arabidopsis genetics, Arabidopsis growth & development, Arabidopsis Proteins genetics, Carrier Proteins genetics, Cytochrome P-450 Enzyme System genetics, Endoplasmic Reticulum metabolism, Immunoprecipitation, Intracellular Membranes metabolism, Membrane Proteins genetics, Phenols metabolism, Plants, Genetically Modified, Protein Stability, Nicotiana genetics, Nicotiana metabolism, Two-Hybrid System Techniques, Arabidopsis metabolism, Arabidopsis Proteins metabolism, Carrier Proteins metabolism, Cytochrome P-450 Enzyme System metabolism, Lignin biosynthesis, Membrane Proteins metabolism

Abstract

Lignin is a complex and irregular biopolymer of crosslinked phenylpropanoid units in plant secondary cell walls. Its biosynthesis requires three endoplasmic reticulum (ER)-resident cytochrome P450 monooxygenases, C4H, C3'H and F5H, to establish the structural characteristics of its monomeric precursors. These P450 enzymes were reported to associate with each other or potentially with other soluble monolignol biosynthetic enzymes to form an enzyme complex or a metabolon. However, the molecular basis governing such enzyme or pathway organization remains elusive. Here, we show that Arabidopsis membrane steroid-binding proteins (MSBPs) serve as a scaffold to physically organize monolignol P450 monooxygenases, thereby regulating the lignin biosynthetic process. We find that although C4H, C3'H and F5H are in spatial proximity to each other on the ER membrane in vivo, they do not appear to directly interact with each other. Instead, two MSBP proteins physically interact with all three P450 enzymes and, moreover, MSBPs themselves associate as homomers and heteromers on the ER membrane, thereby organizing P450 clusters. Downregulation of MSBP genes does not affect the transcription levels of monolignol biosynthetic P450 genes but substantially impairs the stability and activity of the MSBP-interacting P450 enzymes and, consequently, lignin deposition, and the accumulation of soluble phenolics in the monolignol branch but not in the flavonoid pathway. Our study suggests that MSBP proteins are essential structural components in the ER membrane that physically organize and stabilize the monolignol biosynthetic P450 enzyme complex, thereby specifically controlling phenylpropanoid-monolignol branch biosynthesis.

Published

2018

6. Enhancing digestibility and ethanol yield of Populus wood via expression of an engineered monolignol 4-O-methyltransferase.

Author

Cai Y, Zhang K, Kim H, Hou G, Zhang X, Yang H, Feng H, Miller L, Ralph J, and Liu CJ

Subjects

Biomass, Cell Wall metabolism, Fermentation, Genetic Engineering, Phenols metabolism, Plants, Genetically Modified, Polysaccharides metabolism, Populus anatomy & histology, Populus genetics, Populus growth & development, Biofuels, Ethanol metabolism, Lignin metabolism, Methyltransferases chemistry, Methyltransferases genetics, Populus enzymology

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.

Published

2016

7. Engineering a monolignol 4-O-methyltransferase with high selectivity for the condensed lignin precursor coniferyl alcohol.

Author

Cai Y, Bhuiya MW, Shanklin J, and Liu CJ

Subjects

Amino Acid Substitution, Cell Wall chemistry, Cell Wall enzymology, Cell Wall genetics, Cloning, Molecular, Coumaric Acids, Crystallography, X-Ray, Escherichia coli genetics, Escherichia coli metabolism, Gene Expression, Gene Library, Lignin metabolism, Methyltransferases genetics, Methyltransferases metabolism, Mutation, Phenols metabolism, Phenylpropionates chemistry, Phenylpropionates metabolism, Plant Proteins genetics, Plant Proteins metabolism, Plasmids chemistry, Plasmids metabolism, Populus chemistry, Populus enzymology, Propionates chemistry, Propionates metabolism, Protein Engineering, Recombinant Proteins chemistry, Recombinant Proteins genetics, Recombinant Proteins metabolism, Structural Homology, Protein, Substrate Specificity, Lignin chemistry, Methyltransferases chemistry, Phenols chemistry, Plant Proteins chemistry, Populus genetics

Abstract

Lignin, a rigid biopolymer in plant cell walls, is derived from the oxidative polymerization of three monolignols. The composition of monolignol monomers dictates the degree of lignin condensation, reactivity, and thus the degradability of plant cell walls. Guaiacyl lignin is regarded as the condensed structural unit. Polymerization of lignin is initiated through the deprotonation of the para-hydroxyl group of monolignols. Therefore, preferentially modifying the para-hydroxyl of a specific monolignol to deprive its dehydrogenation propensity would disturb the formation of particular lignin subunits. Here, we test the hypothesis that specific remodeling the active site of a monolignol 4-O-methyltransferase would create an enzyme that specifically methylates the condensed guaiacyl lignin precursor coniferyl alcohol. Combining crystal structural information with combinatorial active site saturation mutagenesis and starting with the engineered promiscuous enzyme, MOMT5 (T133L/E165I/F175I/F166W/H169F), we incrementally remodeled its substrate binding pocket by the addition of four substitutions, i.e. M26H, S30R, V33S, and T319M, yielding a mutant enzyme capable of discriminately etherifying the para-hydroxyl of coniferyl alcohol even in the presence of excess sinapyl alcohol. The engineered enzyme variant has a substantially reduced substrate binding pocket that imposes a clear steric hindrance thereby excluding bulkier lignin precursors. The resulting enzyme variant represents an excellent candidate for modulating lignin composition and/or structure in planta., (© 2015 by The American Society for Biochemistry and Molecular Biology, Inc.)

Published

2015

8. Tailoring lignin biosynthesis for efficient and sustainable biofuel production.

Author

Liu CJ, Cai Y, Zhang X, Gou M, and Yang H

Subjects

Genetic Engineering, Industry, Biofuels, Biotechnology methods, Lignin biosynthesis

Abstract

Increased global interest in a bio-based economy has reinvigorated the research on the cell wall structure and composition in plants. In particular, the study of plant lignification has become a central focus, with respect to its intractability and negative impact on the utilization of the cell wall biomass for producing biofuels and bio-based chemicals. Striking progress has been achieved in the last few years both on our fundamental understanding of lignin biosynthesis, deposition and assembly, and on the interplay of lignin synthesis with the plant growth and development. With the knowledge gleaned from basic studies, researchers are now able to invent and develop elegant biotechnological strategies to sophisticatedly manipulate the quantity and structure of lignin and thus to create economically viable bioenergy feedstocks. These concerted efforts open an avenue for the commercial production of cost-competitive biofuel to meet our energy needs., (© 2014 Society for Experimental Biology, Association of Applied Biologists and John Wiley & Sons Ltd.)

Published

2014

9. An engineered monolignol 4-o-methyltransferase depresses lignin biosynthesis and confers novel metabolic capability in Arabidopsis.

Author

Zhang K, Bhuiya MW, Pazo JR, Miao Y, Kim H, Ralph J, and Liu CJ

Subjects

Arabidopsis enzymology, Arabidopsis genetics, Arabidopsis growth & development, Biocatalysis, Cell Wall chemistry, Cell Wall metabolism, Crystallization, Gene Expression, Genetic Engineering, Methylation, Methyltransferases metabolism, Models, Molecular, Mutant Proteins genetics, Mutant Proteins metabolism, Phenotype, Plant Proteins genetics, Plant Proteins metabolism, Plants, Genetically Modified, Propanols metabolism, Recombinant Proteins, Structure-Activity Relationship, Substrate Specificity, Arabidopsis metabolism, Lignin biosynthesis, Methyltransferases genetics, Phenols metabolism

Abstract

Although the practice of protein engineering is industrially fruitful in creating biocatalysts and therapeutic proteins, applications of analogous techniques in the field of plant metabolic engineering are still in their infancy. Lignins are aromatic natural polymers derived from the oxidative polymerization of primarily three different hydroxycinnamyl alcohols, the monolignols. Polymerization of lignin starts with the oxidation of monolignols, followed by endwise cross-coupling of (radicals of) a monolignol and the growing oligomer/polymer. The para-hydroxyl of each monolignol is crucial for radical generation and subsequent coupling. Here, we describe the structure-function analysis and catalytic improvement of an artificial monolignol 4-O-methyltransferase created by iterative saturation mutagenesis and its use in modulating lignin and phenylpropanoid biosynthesis. We show that expressing the created enzyme in planta, thus etherifying the para-hydroxyls of lignin monomeric precursors, denies the derived monolignols any participation in the subsequent coupling process, substantially reducing lignification and, ultimately, lignin content. Concomitantly, the transgenic plants accumulated de novo synthesized 4-O-methylated soluble phenolics and wall-bound esters. The lower lignin levels of transgenic plants resulted in higher saccharification yields. Our study, through a structure-based protein engineering approach, offers a novel strategy for modulating phenylpropanoid/lignin biosynthesis to improve cell wall digestibility and diversify the repertories of biologically active compounds.

Published

2012

10. Deciphering the enigma of lignification: precursor transport, oxidation, and the topochemistry of lignin assembly.

Author

Liu CJ

Subjects

Biological Transport, Cell Membrane metabolism, Oxidation-Reduction, Lignin chemistry, Lignin metabolism

Abstract

Plant lignification is a tightly regulated complex cellular process that occurs via three sequential steps: the synthesis of monolignols within the cytosol; the transport of monomeric precursors across plasma membrane; and the oxidative polymerization of monolignols to form lignin macromolecules within the cell wall. Although we have a reasonable understanding of monolignol biosynthesis, many aspects of lignin assembly remain elusive. These include the precursors' transport and oxidation, and the initiation of lignin polymerization. This review describes our current knowledge of the molecular mechanisms underlying monolignol transport and oxidation, discusses the intriguing yet least-understood aspects of lignin assembly, and highlights the technologies potentially aiding in clarifying the enigma of plant lignification.

Published

2012

11. Sequestration and transport of lignin monomeric precursors.

Author

Liu CJ, Miao YC, and Zhang KW

Subjects

ATP-Binding Cassette Transporters metabolism, Biological Transport, Lignin metabolism

Abstract

Lignin is the second most abundant terrestrial biopolymer after cellulose. It is essential for the viability of vascular plants. Lignin precursors, the monolignols, are synthesized within the cytosol of the cell. Thereafter, these monomeric precursors are exported into the cell wall, where they are polymerized and integrated into the wall matrix. Accordingly, transport of monolignols across cell membranes is a critical step affecting deposition of lignin in the secondarily thickened cell wall. While the biosynthesis of monolignols is relatively well understood, our knowledge of sequestration and transport of these monomers is sketchy. In this article, we review different hypotheses on monolignol transport and summarize the recent progresses toward the understanding of the molecular mechanisms underlying monolignol sequestration and transport across membranes. Deciphering molecular mechanisms for lignin precursor transport will support a better biotechnological solution to manipulate plant lignification for more efficient agricultural and industrial applications of cell wall biomass.

Published

2011

12. ATP-binding cassette-like transporters are involved in the transport of lignin precursors across plasma and vacuolar membranes.

Author

Miao YC and Liu CJ

Subjects

ATP-Binding Cassette Transporters physiology, Adenosine Triphosphate pharmacology, Arabidopsis genetics, Arabidopsis metabolism, Arabidopsis Proteins genetics, Arabidopsis Proteins metabolism, Biological Transport drug effects, Biological Transport physiology, Blotting, Western, Glucosides metabolism, Glucosyltransferases genetics, Glucosyltransferases metabolism, Inorganic Pyrophosphatase metabolism, Kinetics, Monosaccharides metabolism, Phenols metabolism, Potassium Cyanide pharmacology, Proton-Translocating ATPases metabolism, Vanadates pharmacology, Arabidopsis Proteins physiology, Cell Membrane metabolism, Lignin biosynthesis, Vacuoles metabolism

Abstract

Lignin is a complex biopolymer derived primarily from the condensation of three monomeric precursors, the monolignols. The synthesis of monolignols occurs in the cytoplasm. To reach the cell wall where they are oxidized and polymerized, they must be transported across the cell membrane. However, the molecular mechanisms underlying the transport process are unclear. There are conflicting views about whether the transport of these precursors occurs by passive diffusion or is an energized active process; further, we know little about what chemical forms are required. Using isolated plasma and vacuolar membrane vesicles prepared from Arabidopsis, together with applying different transporter inhibitors in the assays, we examined the uptake of monolignols and their derivatives by these native membrane vesicles. We demonstrate that the transport of lignin precursors across plasmalemma and their sequestration into vacuoles are ATP-dependent primary-transport processes, involving ATP-binding cassette-like transporters. Moreover, we show that both plasma and vacuolar membrane vesicles selectively transport different forms of lignin precursors. In the presence of ATP, the inverted plasma membrane vesicles preferentially take up monolignol aglycones, whereas the vacuolar vesicles are more specific for glucoconjugates, suggesting that the different ATP-binding cassette-like transporters recognize different chemical forms in conveying them to distinct sites, and that glucosylation of monolignols is necessary for their vacuolar storage but not required for direct transport into the cell wall in Arabidopsis.

Published

2010

13. Engineering monolignol 4-O-methyltransferases to modulate lignin biosynthesis.

Author

Bhuiya MW and Liu CJ

Subjects

Amino Acids metabolism, Biocatalysis, Catalytic Domain, Evolution, Molecular, Hydrogenation, Kinetics, Methylation, Methyltransferases metabolism, Models, Molecular, Mutant Proteins metabolism, Phenols metabolism, Phylogeny, Substrate Specificity, Clarkia enzymology, Genetic Engineering, Lignin biosynthesis, Methyltransferases genetics

Abstract

Lignin is a complex polymer derived from the oxidative coupling of three classical monolignols. Lignin precursors are methylated exclusively at the meta-positions (i.e. 3/5-OH) of their phenyl rings by native O-methyltransferases, and are precluded from substitution of the para-hydroxyl (4-OH) position. Ostensibly, the para-hydroxyls of phenolics are critically important for oxidative coupling of phenoxy radicals to form polymers. Therefore, creating a 4-O-methyltransferase to substitute the para-hydroxyl of monolignols might well interfere with the synthesis of lignin. The phylogeny of plant phenolic O-methyltransferases points to the existence of a batch of evolutionarily "plastic" amino acid residues. Following one amino acid at a time path of directed evolution, and using the strategy of structure-based iterative site-saturation mutagenesis, we created a novel monolignol 4-O-methyltransferase from the enzyme responsible for methylating phenylpropenes. We show that two plastic residues in the active site of the parental enzyme are vital in dominating substrate discrimination. Mutations at either one of these separate the evolutionarily tightly linked properties of substrate specificity and regioselective methylation of native O-methyltransferase, thereby conferring the ability for para-methylation of the lignin monomeric precursors, primarily monolignols. Beneficial mutations at both sites have an additive effect. By further optimizing enzyme activity, we generated a triple mutant variant that may structurally constitute a novel phenolic substrate binding pocket, leading to its high binding affinity and catalytic efficiency on monolignols. The 4-O-methoxylation of monolignol efficiently impairs oxidative radical coupling in vitro, highlighting the potential for applying this novel enzyme in managing lignin polymerization in planta.

Published

2010

14. Simultaneous suppression of lignin, tricin and wall‐bound phenolic biosynthesis via the expression of monolignol 4‐O‐methyltransferases in rice.

Author

Dwivedi, Nidhi, Yamamoto, Senri, Zhao, Yunjun, Hou, Guichuan, Bowling, Forrest, Tobimatsu, Yuki, and Liu, Chang‐Jun

Subjects

LIGNINS, FERULIC acid, BIOSYNTHESIS, LIGNOCELLULOSE, RICE straw, RICE, LIGNIN structure, FLAVONOIDS

Abstract

Summary: Grass lignocelluloses feature complex compositions and structures. In addition to the presence of conventional lignin units from monolignols, acylated monolignols and flavonoid tricin also incorporate into lignin polymer; moreover, hydroxycinnamates, particularly ferulate, cross‐link arabinoxylan chains with each other and/or with lignin polymers. These structural complexities make grass lignocellulosics difficult to optimize for effective agro‐industrial applications. In the present study, we assess the applications of two engineered monolignol 4‐O‐methyltransferases (MOMTs) in modifying rice lignocellulosic properties. Two MOMTs confer regiospecific para‐methylation of monolignols but with different catalytic preferences. The expression of MOMTs in rice resulted in differential but drastic suppression of lignin deposition, showing more than 50% decrease in guaiacyl lignin and up to an 90% reduction in syringyl lignin in transgenic lines. Moreover, the levels of arabinoxylan‐bound ferulate were reduced by up to 50%, and the levels of tricin in lignin fraction were also substantially reduced. Concomitantly, up to 11 μmol/g of the methanol‐extractable 4‐O‐methylated ferulic acid and 5–7 μmol/g 4‐O‐methylated sinapic acid were accumulated in MOMT transgenic lines. Both MOMTs in vitro displayed discernible substrate promiscuity towards a range of phenolics in addition to the dominant substrate monolignols, which partially explains their broad effects on grass phenolic biosynthesis. The cell wall structural and compositional changes resulted in up to 30% increase in saccharification yield of the de‐starched rice straw biomass after diluted acid‐pretreatment. These results demonstrate an effective strategy to tailor complex grass cell walls to generate improved cellulosic feedstocks for the fermentable sugar‐based production of biofuel and bio‐chemicals. [ABSTRACT FROM AUTHOR]

Published

2024

15. Down-Regulation of Kelch Domain-Containing F-Box Protein in Arabidopsis Enhances the Production of (Poly)phenols and Tolerance to Ultraviolet Radiation

Author

Zhang, Xuebin, Gou, Mingyue, Guo, Chunrong, Yang, Huijun, and Liu, Chang-Jun

Published

2015

16. Arabidopsis Kelch Repeat F-Box Proteins Regulate Phenylpropanoid Biosynthesis via Controlling the Turnover of Phenylalanine Ammonia-Lyase

Author

Zhang, Xuebin, Gou, Mingyue, and Liu, Chang-Jun

Published

2013

17. Compositional characterization and imaging of "wall-bound" acylesters of Populus trichocarpa reveal differential accumulation of acyl molecules in normal and reactive woods

Author

Gou, Jin-Ying, Park, Simone, Yu, Xiao-Hong, Miller, Lisa M., and Liu, Chang-Jun

Published

2008

18. The Inducible Accumulation of Cell Wall-Bound p -Hydroxybenzoates Is Involved in the Regulation of Gravitropic Response of Poplar.

Author

Zhao, Yunjun, Yu, Xiao-Hong, and Liu, Chang-Jun

Subjects

CELLULOSE fibers, STRAINS & stresses (Mechanics), POPLARS, WOOD chemistry, XYLEM, LIGNINS, GENETIC overexpression, ASPEN (Trees)

Abstract

Lignin in Populus species is acylated with p -hydroxybenzoate. Monolignol p -hydroxybenzoyltransferase 1 (PHBMT1) mediates p -hydroxybenzoylation of sinapyl alcohol, eventually leading to the modification of syringyl lignin subunits. Angiosperm trees upon gravistimulation undergo the re-orientation of their growth along with the production of specialized secondary xylem, i.e., tension wood (TW), that generates tensile force to pull the inclined stem or leaning branch upward. Sporadic evidence suggests that angiosperm TW contains relatively a high percentage of syringyl lignin and lignin-bound p -hydroxybenzoate. However, whether such lignin modification plays a role in gravitropic response remains unclear. By imposing mechanical bending and/or gravitropic stimuli to the hybrid aspens in the wild type (WT), lignin p -hydroxybenzoate deficient, and p -hydroxybenzoate overproduction plants, we examined the responses of plants to gravitropic/mechanical stress and their cell wall composition changes. We revealed that mechanical bending or gravitropic stimulation not only induced the overproduction of crystalline cellulose fibers and increased the relative abundance of syringyl lignin, but also significantly induced the expression of PHBMT1 and the increased accumulation of p -hydroxybenzoates in TW. Furthermore, we found that although disturbing lignin-bound p -hydroxybenzoate accumulation in the PHBMT1 knockout and overexpression (OE) poplars did not affect the major chemical composition shifts of the cell walls in their TW as occurred in the WT plants, depletion of p -hydroxybenzoates intensified the gravitropic curving of the plantlets in response to gravistimulation, evident with the enhanced stem secant bending angle. By contrast, hyperaccumulation of p -hydroxybenzoates mitigated gravitropic response. These data suggest that PHBMT1-mediated lignin modification is involved in the regulation of poplar gravitropic response and, likely by compromising gravitropism and/or enhancing autotropism, negatively coordinates the action of TW cellulose fibers to control the poplar wood deformation and plant growth. [ABSTRACT FROM AUTHOR]

Published

2021