Effects of coumarate 3-hydroxylase down-regulation on lignin structure

Down-regulation of the gene encoding 4-coumarate 3-hydroxylase (C3H) in alfalfa massively but predictably increased the proportion of p-hydroxyphenyl (P) units relative to the normally dominant guaiacyl (G) and syringyl (S) units. Stem levels of up to approximately 65% P (from wild-type levels of approximately 1%) resulting from down-regulation of C3H were measured by traditional degradative analyses as well as two-dimensional 13C-1H correlative NMR methods. Such levels put these transgenics well beyond the P:G:S compositional bounds of normal plants; p-hydroxyphenyl levels are reported to reach a maximum of 30% in gymnosperm severe compression wood zones but are limited to a few percent in dicots. NMR also revealed structural differences in the interunit linkage distribution that characterizes a lignin polymer. Lower levels of key beta-aryl ether units were relatively augmented by higher levels of phenylcoumarans and resinols. The C3H-deficient alfalfa lignins were devoid of beta-1 coupling products, highlighting the significant differences in the reaction course for p-coumaryl alcohol versus the two normally dominant monolignols, coniferyl and sinapyl alcohols. A larger range of dibenzodioxocin structures was evident in conjunction with an approximate doubling of their proportion. The nature of each of the structural units was revealed by long range 13C-1H correlation experiments. For example, although beta-ethers resulted from the coupling of all three monolignols with the growing polymer, phenylcoumarans were formed almost solely from coupling reactions involving p-coumaryl alcohol; they resulted from both coniferyl and sinapyl alcohol in the wild-type plants. Such structural differences form a basis for explaining differences in digestibility and pulping performance of C3H-deficient plants.     

Downregulation of caffeic acid 3-O-methyltransferase and caffeoyl CoA 3-O-methyltransferase in transgenic alfalfa. impacts on lignin structure and implications for the biosynthesis of G and S lignin

Transgenic alfalfa plants were generated harboring caffeic acid 3-O-methyltransferase (COMT) and caffeoyl CoA 3-O-methyltransferase (CCOMT) cDNA sequences under control of the bean phenylalanine ammonia-lyase PAL2 promoter. Strong downregulation of COMT resulted in decreased lignin content, a reduction in total guaiacyl (G) lignin units, a near total loss of syringyl (S) units in monomeric and dimeric lignin degradation products, and appearance of low levels of 5-hydroxy guaiacyl units and a novel dimer. No soluble monolignol precursors accumulated. In contrast, strong downregulation of CCOMT led to reduced lignin levels, a reduction in G units without reduction in S units, and increases in beta-5 linked dimers of G units. Accumulation of soluble caffeic acid beta-d-glucoside occurred only in CCOMT downregulated plants. The results suggest that CCOMT does not significantly contribute to the 3-O-methylation step in S lignin biosynthesis in alfalfa and that there is redundancy with respect to the 3-O-methylation reaction of G lignin biosynthesis. COMT is unlikely to catalyze the in vivo methylation of caffeic acid during lignin biosynthesis.     

Basic peroxidases: The gateway for lignin evolution?

Lignins are cell wall phenolic heteropolymers which result from the oxidative coupling of three monolignols, p-coumaryl, coniferyl and sinapyl alcohol, in a reaction mediated by peroxidases. The most distinctive variation in the monomer composition of lignins in vascular plants is that found between the two main groups of seed plants. Thus, while gymnosperms lignins are typically composed of G units, with a minor proportion of H units, angiosperms lignins are largely composed of similar levels of G and S units. The presence of S units in angiosperm lignins raises certain concerns in relation with the step of lignin assembly due to the inability of most peroxidases to oxidize syringyl moieties. Zinnia elegans is currently used as a model for lignification studies: – first because of the simplicity and duality of the lignification pattern shown by hypocotyls and stems, in which hypocotyl lignins are typical of angiosperms, while young stem lignins partially resemble those occurring in gymnosperms. Secondly, because of the nature of the peroxidase isoenzyme complement, which is almost completely restricted to the presence of a basic peroxidase isoenzyme, which is capable of oxidizing both coniferyl and sinapyl alcohol, as well as both coniferyl and sinapyl aldehyde. In fact, the versatility of this enzyme is such that the substrate preference covers the three p-hydroxybenzaldehydes and the three p-hydroxycinnamic acids. The basic pI nature of this peroxidase is not an exceptional frame point in this system since basic peroxidases are differentially expressed during lignification in other model systems, show unusual and unique biochemical properties as regards the oxidation of syringyl moieties, and their down-regulation in transgenic plants leads to a reduction in lignin (G+S) levels. Basic peroxidase isoenzymes capable of oxidizing syringyl moieties are already present in basal gymnosperms, an observation that supports the idea that these enzymes were probably present in an ancestral plant species, pre-dating the early radiation of seed plants. It also suggests that the evolutionary gain of the monolignol branch which leads to the biosynthesis of sinapyl alcohol, and of course to syringyl lignins, was not only possible but also favored because the enzymes responsible for its polymerization had evolved previously. In this scenario, it is not surprising that these enzymes responsible for lignin construction appeared early in the evolution of land plants, and have been largely conserved during plant evolution. Abreviations: 4CL –p-hydroxycinnamate CoA ligase; C3H –p-coumarate-3-hydroxylase; C4H – cinnamate-4-hydroxylase; p-CA –p-coumaric acid; CAD – coniferyl alcohol dehydrogenase; CAld5H – coniferylaldehyde-5-hydroxylase; CCR –p-hydroxycinnamoyl-CoA reductase; CoI – compound I; CoII – compound II; G – guaiacyl unit; H –p-hydroxyphenyl unit; PAL – phenylalanine ammonia-lyase; S – syringyl unit.     

Rapid analysis of poplar lignin monomer composition by a streamlined thioacidolysis procedure and near-infrared reflectance-based prediction modeling

Determination of the physico-chemical attributes of plant cell walls, such as lignin content and composition, is of paramount importance in germplasm screening and for evaluating the results of plant breeding and genetic engineering. There are escalating needs for analyses to be robust, reproducible, accurate, and efficient. We have recently modified an established protocol for discrimination of lignin monomers, thioacidolysis, with the goal of increasing sample throughput while maintaining accuracy and reducing equipment load and consumption of reagents. Numerous methodological changes related to volume scaling, selection of the processing vessel, and sample handling were addressed. The revised protocol permitted rapid processing of some 50 or more samples per person per day. A direct comparison between methods using hybrid poplar ( Populus alba  ×  tremula ) wood samples, resulted in quantities of p -hydroxyphenyl (H), guaiacyl (G), and syringyl (S) lignin monomers that were equivalent to those derived from the original protocol. The revised methodology was then applied to quickly generate phenotypic trait data from 267 hybrid poplar trees (including wild type and eight C4H::F5H transgenic lines), for the development of a near-infrared-based model for predicting the proportion of lignin monomers across a broad phenotypic range of S:G. The resulting partial least squares regression model performed well under full cross-validation, giving strong, linear relationships between actual and predicted monomer proportions, and very high predictive accuracy for the predominant G and S monomers. This research brings considerable refinement to the thioacidolysis procedure, and establishes a method for rapidly and accurately quantifying cell-wall lignin composition that could effectively be employed in routine phenotypic screening platforms.     

A theoretical investigation into the cooperativity effect between the H∙∙∙O and H∙∙∙F– interactions and electrostatic potential upon 1:2 (F–:N-(Hydroxymethyl)acetamide) ternary-system formation

The cooperativity effects between the O/N–H???F^– anionic hydrogen-bonding and O/N–H???O hydrogen-bonding interactions and electrostatic potentials in the 1:2 (F^–:N-(Hydroxymethyl)acetamide (signed as “ha”)) ternary systems are investigated at the B3LYP/6-311++G** and MP2/6-311++G** levels. A comparison of the cooperativity effect in the “F^–???ha???ha” and “FH???ha^–???ha” systems is also carried out. The result shows that the increase of the H???O interaction energy in the O–H???O–H, N–H???O–H or N–H???O?=?C link is more notable than that in the O–H???O?=?C contact upon ternary-system formation. The cooperativity effect is found in the complex formed by the O/N–H???F^– and O/N–H???O interactions, while the anti-cooperativity effect is present in the system with only the O/N–H???F^– H-bond or the “FH???ha^–???ha” complex by the N^–???H–F contact. Atoms in molecules (AIM) analysis and shift of electron density confirm the existence of cooperativity. The most negative surface electrostatic potential (V _S,min ) correlates well with the interaction energy E′ _{int.(ha???F–)} and synergetic energy E _syn., respectively. The relationship between the change of V _S,min (i.e., ΔV _S,min ) and E _syn. is also found.

Lignin characterization of rice CONIFERALDEHYDE 5‐HYDROXYLASE loss‐of‐function mutants generated with the CRISPR/Cas9 system

The aromatic composition of lignin is an important trait that greatly affects the usability of lignocellulosic biomass. We previously identified a rice (Oryza sativa) gene encoding coniferaldehyde 5‐hydroxylase (OsCAld5H1), which was effective in modulating syringyl (S)/guaiacyl (G) lignin composition ratio in rice, a model grass species. Previously characterized OsCAld5H1‐knockdown rice lines, which were produced via an RNA‐interference approach, showed augmented G lignin units yet contained considerable amounts of residual S lignin units. In this study, to further investigate the effect of suppression of OsCAld5H1 on rice lignin structure, we generated loss‐of‐function mutants of OsCAld5H1 using the CRISPR/Cas9‐mediated genome editing system. Homozygous OsCAld5H1‐knockout lines harboring anticipated frame‐shift mutations in OsCAld5H1 were successfully obtained. A series of wet‐chemical and two‐dimensional NMR analyses on cell walls demonstrated that although lignins in the mutant were predictably enriched in G units all the tested mutant lines produced considerable numbers of S units. Intriguingly, lignin γ‐p‐coumaroylation analysis by the derivatization followed by reductive cleavage method revealed that enrichment of G units in lignins of the mutants was limited to the non‐γ‐p‐coumaroylated units, whereas grass‐specific γ‐p‐coumaroylated lignin units were almost unaffected. Gene expression analysis indicated that no homologous genes of OsCAld5H1 were overexpressed in the mutants. These data suggested that CAld5H is mainly involved in the production of non‐γ‐p‐coumaroylated S lignin units, common in both eudicots and grasses, but not in the production of grass‐specific γ‐p‐coumaroylated S units in rice.     

NMR Characterization of C3H and HCT Down-Regulated Alfalfa Lignin

Independent down-regulation of genes encoding p-coumarate 3-hydroxylase (C3H) and hydroxycinnamoyl CoA:shikimate/quinate hydroxycinnamoyl transferase (HCT) has been previously shown to reduce the recalcitrance of alfalfa and thereby improve the release of fermentable sugars during enzymatic hydrolysis. In this study, ball-milled lignins were isolated from wild-type control, C3H, and HCT gene down-regulated alfalfa plants. One- and two-dimensional nuclear magnetic resonance (NMR) techniques were utilized to determine structural changes in the ball-milled alfalfa lignins resulting from this genetic engineering. After C3H and HCT gene down-regulation, significant structural changes had occurred to the alfalfa ball-milled lignins compared to the wild-type control. A substantial increase in p-hydroxyphenyl units was observed in the transgenic alfalfa ball-milled lignins as well as a concomitant decrease in guaiacyl and syringyl units. Two-dimensional ¹³C–¹H heteronuclear single quantum coherence correlation NMR, one-dimensional distortionless enhancement by polarization transfer-135, and ¹³C NMR measurement showed a noteworthy decrease in methoxyl group and β-O-4 linkage contents in these transgenic alfalfa lignins. ¹³C NMR analysis estimated that C3H gene down-regulation reduced the methoxyl content by ~55–58% in the ball-milled lignin, while HCT down-regulation decreased methoxyl content by ~73%. The gene down-regulated C3H and HCT transgenic alfalfa lignin was largely a p-hydroxyphenyl (H) rich type lignin. Compared to the wild-type plant, the C3H and HCT transgenic lines had an increase in relative abundance of phenylcoumaran and resinol in the ball-milled lignins.     

Characterization of lignin-rich residues remaining after continuous super-critical water hydrolysis of poplar wood (Populus albaglandulosa) for conversion to fermentable sugars

Poplar wood flour (Populous albaglandulosa) was treated with sub- and super-critical water (subcritical: 325, 350 °C; super-critical: 380, 400, 425 °C) for 60 s at 220 ± 10 atm. Hydrochloric acid (0.05% v/v) was added to samples as acidic catalyst. The final products were separated into water soluble fraction and undegraded solids. The yields of undegraded solids were thoroughly dependent on temperature severity and mainly composed of lignin fragments. Average molecular weights of the lignins were between 1500 and 4400 Da, which was only 1/3-1/8-fold of poplar milled wood lignin (13,250 Da). DFRC (Derivatization Followed by Reductive Cleavage) analysis revealed that C6C3 phenols (coniferyl and sinapyl alcohol) were rarely detected in the lignins, indicating occurrence of two probable lignin reactions during SCW hydrolysis: lignin fragmentation via splitting of β-O-4 linkage and loss of propane side chains. These results were also confirmed by ¹H and ¹³C NMR spectroscopic analysis.     

Cinnamic Acid Increases Lignin Production and Inhibits Soybean Root Growth

Cinnamic acid is a known allelochemical that affects seed germination and plant root growth and therefore influences several metabolic processes. In the present work, we evaluated its effects on growth, indole-3-acetic acid (IAA) oxidase and cinnamate 4-hydroxylase (C4H) activities and lignin monomer composition in soybean (Glycine max) roots. The results revealed that exogenously applied cinnamic acid inhibited root growth and increased IAA oxidase and C4H activities. The allelochemical increased the total lignin content, thus altering the sum and ratios of the p-hydroxyphenyl (H), guaiacyl (G), and syringyl (S) lignin monomers. When applied alone or with cinnamic acid, piperonylic acid (PIP, a quasi-irreversible inhibitor of C4H) reduced C4H activity, lignin and the H, G, S monomer content compared to the cinnamic acid treatment. Taken together, these results indicate that exogenously applied cinnamic acid can be channeled into the phenylpropanoid pathway via the C4H reaction, resulting in an increase in H lignin. In conjunction with enhanced IAA oxidase activity, these metabolic responses lead to the stiffening of the cell wall and are followed by a reduction in soybean root growth.     

An accurate and non-labor intensive method for the determination of syringyl to guaiacyl ratio in lignin

The syringyl to guaiacyl (S:G) ratio of hardwood lignin has long been identified as a significant parameter in delignification processes and more recent results have shown that it is also important in determining the amount of ethanol that can be obtained from fermentation of hydrolyzed wood. Acidolysis of Klason or acid insoluble lignin in dioxane/water/HCl was being investigated when syringyl and guaiacyl nuclei with a diketone-containing sidechain were observed as the major products. The area ratio of the two gas chromatogram peaks appeared to be indicative of the S:G ratio. After optimization of the method the relative standard deviation was found to be in the range of 0.3–3.76% for Klason lignin from a wide range of Eucalyptus grandis grown in South Africa. The method was then compared to nitrobenzene oxidation (NBO) using 13 poplars in a double-blind study. The respective S:G ratios were used to calculate percentages of S units and when these values were plotted against each other a linear correlation was obtained with a slope of approximately 1.0 (R² = 0.86). The largest discrepancy for any poplar was 6.9% (62% vs. 58% S units). Both methods convincingly demonstrated a significant decrease in lignin content with an increase in the S:G ratio. Discussion is presented on a series of reaction that could lead to the formation of the two diketones.     

Lignin-Modifying Enzymes of the White Rot Basidiomycete Ganoderma lucidum

Ganoderma lucidum, a white rot basidiomycete widely distributed worldwide, was studied for the production of the lignin-modifying enzymes laccase, manganese-dependent peroxidase (MnP), and lignin peroxidase (LiP). Laccase levels observed in high-nitrogen (HN; 24 mM N) shaken cultures were much greater than those seen in low-nitrogen (2.4 mM N), malt extract, or wood-grown cultures and those reported for most other white rot fungi to date. Laccase production was readily seen in cultures grown with pine or poplar (100-mesh-size ground wood) as the sole carbon and energy source. Cultures containing both pine and poplar showed 5- to 10-fold-higher levels of laccase than cultures containing pine or poplar alone. Since syringyl units are structural components important in poplar lignin and other hardwoods but much less so in pine lignin and other softwoods, pine cultures were supplemented with syringic acid, and this resulted in laccase levels comparable to those seen in pine-plus-poplar cultures. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis of concentrated extracellular culture fluid from HN cultures showed two laccase activity bands (M_r of 40,000 and 66,000), whereas isoelectric focusing revealed five major laccase activity bands with estimated pIs of 3.0, 4.25, 4.5, 4.8, and 5.1. Low levels of MnP activity (~100 U/liter) were detected in poplar-grown cultures but not in cultures grown with pine, with pine plus syringic acid, or in HN medium. No LiP activity was seen in any of the media tested; however, probing the genomic DNA with the LiP cDNA (CLG4) from the white rot fungus Phanerochaete chrysosporium showed distinct hybridization bands suggesting the presence of lip-like sequences in G. lucidum.     

A comparative study of the biomass properties of Erianthus and sugarcane: lignocellulose structure,alkaline delignification rate,and enzymatic saccharification efficiency

A comprehensive understanding of the structure and properties of gramineous lignocelluloses is needed to facilitate their uses in biorefinery. In this study, lignocelluloses from fractionated internode tissues of two taxonomically close species, Erianthus arundinaceus and sugarcane (Saccharum spp.), were characterized. Our analyses determined that syringyl (S) lignins were predominant over guaiacyl (G) or p-hydroxyphenyl (H) lignins in sugarcane tissues; on the other hand, S lignin levels were similar to those of G lignin in Erianthus tissues. In addition, tricin units were detected in sugarcane tissues, but not in Erianthus tissues. Distributions of lignin inter-monomeric linkage types were also different in Erianthus and sugarcane tissues. Alkaline treatment removed lignins from sugarcane tissues more efficiently than Erianthus tissues, resulting in a higher enzymatic digestibility of sugarcane tissues compared with Erianthus tissues. Our data indicate that Erianthus biomass displayed resistance to alkaline delignification and enzymatic digestion.     

Lignification in poplar plantlets fed with deuterium-labelled lignin precursors

Lignification was investigated in wild-type (WT) and in transgenic poplar plantlets with a reduced caffeic acid O-methyl-transferase (COMT) activity. Coniferin and syringin, deuterated at their methoxyl, were incorporated into the culture medium of microcuttings. The gas chromatography-mass spectrometry (GC-MS) analysis of the thioacidolysis guaiacyl (G) and syringyl (S) lignin-derived monomers revealed that COMT deficiency altered stem lignification. GC-MS analysis proved that the deuterated precursors were incorporated into root lignins and, to a lower extent, in stem lignins without major effect on growth and lignification. Deuterium from coniferin was recovered in G and S lignin units, whereas deuterium from syringin was only found in S units, which further establishes that the conversion of G to S lignin precursors may occur at the level of p-OH cinnamyl alcohols.     

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

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.     

Enhanced Lignin Monomer Production Caused by Cinnamic Acid and Its Hydroxylated Derivatives Inhibits Soybean Root Growth

Cinnamic acid and its hydroxylated derivatives (p-coumaric, caffeic, ferulic and sinapic acids) are known allelochemicals that affect the seed germination and root growth of many plant species. Recent studies have indicated that the reduction of root growth by these allelochemicals is associated with premature cell wall lignification. We hypothesized that an influx of these compounds into the phenylpropanoid pathway increases the lignin monomer content and reduces the root growth. To confirm this hypothesis, we evaluated the effects of cinnamic, p-coumaric, caffeic, ferulic and sinapic acids on soybean root growth, lignin and the composition of p-hydroxyphenyl (H), guaiacyl (G) and syringyl (S) monomers. To this end, three-day-old seedlings were cultivated in nutrient solution with or without allelochemical (or selective enzymatic inhibitors of the phenylpropanoid pathway) in a growth chamber for 24 h. In general, the results showed that 1) cinnamic, p-coumaric, caffeic and ferulic acids reduced root growth and increased lignin content; 2) cinnamic and p-coumaric acids increased p-hydroxyphenyl (H) monomer content, whereas p-coumaric, caffeic and ferulic acids increased guaiacyl (G) content, and sinapic acid increased sinapyl (S) content; 3) when applied in conjunction with piperonylic acid (PIP, an inhibitor of the cinnamate 4-hydroxylase, C4H), cinnamic acid reduced H, G and S contents; and 4) when applied in conjunction with 3,4-(methylenedioxy)cinnamic acid (MDCA, an inhibitor of the 4-coumarate:CoA ligase, 4CL), p-coumaric acid reduced H, G and S contents, whereas caffeic, ferulic and sinapic acids reduced G and S contents. These results confirm our hypothesis that exogenously applied allelochemicals are channeled into the phenylpropanoid pathway causing excessive production of lignin and its main monomers. By consequence, an enhanced stiffening of the cell wall restricts soybean root growth.     

The suppression of AtPrx52 affects fibers but not xylem lignification in Arabidopsis by altering the proportion of syringyl units

Lignins result from the oxidative polymerization of three hydroxycinnamyl (p‐coumaryl, coniferyl and sinapyl) alcohols in a reaction mediated by peroxidases (EC 1.11.1.7) and laccases (EC 1.10.3.2), yielding H, G and S units, respectively. Although both acidic and basic peroxidases can oxidize p‐coumaryl and coniferyl alcohol, only basic peroxidases are able to oxidize sinapyl alcohol. The AtPrx52 from Arabidopsis is a basic peroxidase that has been reported to be highly homologous to the basic peroxidase of Zinnia elegans, the only peroxidase which has been unequivocally linked to lignin formation. Here, we show how the suppression of AtPrx52 causes a change in lignin composition, mainly at the level of stem interfascicular fibers. Quantification of lignins in two different atprx52 knock‐out mutants revealed a decrease of lignin amount compared with wild type. The S/G ratio, obtained by both nitrobenzene oxidation and thioacidolysis, indicated a decrease in S units in the atprx52 mutants. As deduced from Wiesner and mainly Mäule staining, this reduction in S unit content appears to be restricted to the interfascicular fibers. Moreover, quantitative polymerase chain reaction analysis in atprx52 plants showed a general downregulation of genes involved in lignin biosynthetic pathway, as well as genes related to secondary cell wall. On the other hand, other routes from phenylpropanoid metabolism were induced. Taken together, our results indicate that AtPrx52 is involved in the synthesis of S units in interfascicular fibers at late stages of the lignification process.     

The Effects on Lignin Structure of Overexpression of Ferulate 5-Hydroxylase in Hybrid Poplar1

Poplar (Populus tremula × alba) lignins with exceedingly high syringyl monomer levels are produced by overexpression of the ferulate 5-hydroxylase (F5H) gene driven by a cinnamate 4-hydroxylase (C4H) promoter. Compositional data derived from both standard degradative methods and NMR analyses of the entire lignin component (as well as isolated lignin fraction) indicated that the C4H∷F5H transgenic''s lignin was comprised of as much as 97.5% syringyl units (derived from sinapyl alcohol), the remainder being guaiacyl units (derived from coniferyl alcohol); the syringyl level in the wild-type control was 68%. The resultant transgenic lignins are more linear and display a lower degree of polymerization. Although the crucial β-ether content is similar, the distribution of other interunit linkages in the lignin polymer is markedly different, with higher resinol (β-β) and spirodienone (β-1) contents, but with virtually no phenylcoumarans (β-5, which can only be formed from guaiacyl units). p-Hydroxybenzoates, acylating the γ-positions of lignin side chains, were reduced by >50%, suggesting consequent impacts on related pathways. A model depicting the putative structure of the transgenic lignin resulting from the overexpression of F5H is presented. The altered structural features in the transgenic lignin polymer, as revealed here, support the contention that there are significant opportunities to improve biomass utilization by exploiting the malleability of plant lignification processes.In the continuing search for improved biomass utilization in processes including chemical pulping, natural ruminant digestibility, and biomass conversion to ethanol, considerable attention has focused on improving lignocellulosic feedstocks through genetic engineering. Perturbing plant biomass deposition by misregulating key genes/enzymes integral to major cell wall pathways can provide rich insights into cell wall development and architecture and also create significant opportunities for improved lignocellulosic utilization (Baucher et al., 2003; Boerjan et al., 2003; Ralph et al., 2004). Lignins comprise the second most abundant polymer class in the biosphere; however, their combinatorial biosynthesis renders them among the more complex biomacromolecules synthesized by plants. Alterations in plant cell wall chemistry or ultrastructure, including lignin content or structure, can have a profound effect on chemical or enzymatic degradability. For example, in chemical pulping, lignin structure and content have been shown to significantly impact delignification efficiency (both pulp yield and residual lignin [RL] content) and pulp bleachability (Chang and Sarkanen, 1973; Huntley et al., 2003; Stewart et al., 2006). Similarly, improvements in fermentable sugar yields have been reported in lignin-engineered Medicago sativa (Chen and Dixon, 2007).In recent years, the genes encoding enzymes specific to the lignin branch of the phenylpropanoid pathway have been cloned and their roles evaluated using a combination of forward and reverse genetics (Franke et al., 2002; Baucher et al., 2003; Boerjan et al., 2003). The down-regulation of genes early in the pathway may limit the overall flux of metabolites to lignin synthesis. In contrast, the genes common to the latter part of the pathway generally affect the distribution of p-hydroxyphenyl (H), guaiacyl (G), and syringyl (S) lignin units resulting from the primary monomers (the three monolignols p-coumaryl, coniferyl, and sinapyl alcohols). And, in several cases when the biosynthesis of a normal monolignol is severely curtailed, lignins appear to incorporate unique phenolics (e.g. 5-hydroxyconiferyl alcohol, hydroxycinnamaldehydes, and ferulic acid) that have not traditionally been considered lignin monomers (Sederoff et al., 1999; Boerjan et al., 2003; Ralph et al., 2004, 2008a, 2008b).Ferulate 5-hydroxylase (F5H), also referred to coniferaldehyde 5-hydroxylase to reflect one of its preferred substrate (Humphreys et al., 1999; Osakabe et al., 1999), is a key enzyme involved in synthesizing the monolignol sinapyl alcohol and, ultimately, S lignin moieties. F5H therefore affects the partitioning between the two major traditional monolignols, coniferyl and sinapyl alcohols, and is fundamental to the evolutionary differences between gymnosperms (with no S components) and angiosperms (with compositions favoring the S monomers). For example, the fah1 Arabidopsis (Arabidopsis thaliana) mutant, deficient in F5H, has little to no S lignin (Meyer et al., 1998; Marita et al., 1999). Like gymnosperms, it produces G-rich lignins, derived almost exclusively from coniferyl alcohol. In contrast, the overexpression of F5H in the mutant background produces plants displaying substantially higher than normal sinapyl alcohol-derived S units and is consequentially severely depleted in coniferyl alcohol-derived G units. Wet chemical analyses of cell wall lignins estimated S contents of up to about 92% in F5H-up-regulated Arabidopsis (Meyer et al., 1998), up to 84% in tobacco (Nicotiana tabacum; Franke et al. 2000), and as high as 93.5% in hybrid poplar (Populus tremula × Populus alba; Huntley et al., 2003; Li et al., 2003). These engineered cell walls, rich in S units, exceed the highest reported in nature to date (Baucher et al., 1998), with kenaf (Hibiscus cannabinus) bast fiber lignin, at 85% S, being among the highest (Ralph, 1996; Morrison et al., 1999). In poplars, the final methylation step, catalyzed by caffeic acid 3-O-methyl transferase (COMT), appears to adequately accommodate the increased flux from coniferaldehyde to 5-hydroxyconiferaldehyde to produce sinapaldehyde and ultimately sinapyl alcohol (Li et al., 2000, 2003). In Arabidopsis, however, evidence suggests that the COMT is not able to keep pace with the increased 5-hydroxyconiferaldehyde generated by F5H overexpression, since the ensuing lignins comprise a significant component derived from 5-hydroxyconiferyl alcohol (Ralph et al., 2001a). Novel 5-hydroxyguaiacyl benzodioxane structures, which result from incorporation of 5-hydroxyconiferyl alcohol into the lignification scheme, were the same as those noted in COMT-deficient plants (Ralph et al., 2001a, 2001b; Marita et al., 2001, 2003).The availability of woody plant material possessing an extreme S lignin concentration affords unique opportunities to explore the mechanisms and consequences of pushing plants toward compositional limits and has both major fundamental and industrial consequences. Engineering lignin composition to extreme levels provides rare and novel insights into the ramifications on the structure of the lignin component and on other cell wall characteristics. Here, we investigate the nature of the chemical modifications to the lignin polymer in up-regulated cinnamate 4-hydroxylase (C4H)∷F5H poplar and propose a model for how such gene perturbation impacts lignin biosynthesis.