Abstract
Grass lignins are differentiated from other lignin types by containing relatively large amounts of p-coumaric acid (pCA) acylating the C-9 position of lignin subunits. In the case of a mature corn (Zea mays L.) stems, pCA constitutes 15–18% of a dioxane soluble enzyme lignin. The major portion of the pCA is specifically attached to syringyl residues. Studies with isolated corn wall peroxidases show that pCA readily undergoes radical coupling in the presence of hydrogen peroxide, whereas sinapyl alcohol radical coupling proceeds more slowly. Analysis of corn wall peroxidases did not reveal specific enzymes that would lead to the preferred incorporation of sinapyl alcohol as seen in other plants. The addition of ethyl ferulate, methyl p-coumarate, or sinapyl p-coumarate conjugates to a reaction mixture containing peroxidase, sinapyl alcohol, and hydrogen peroxide stimulated the rate of sinapyl alcohol radical coupling by 10–20-fold. Based on spectral analysis it appears that pCA and ferulate radicals form rapidly, but the radical is readily transferred to sinapyl alcohol. The newly formed sinapyl alcohol radicals undergo coupling and cross-coupling reactions. However, sinapyl alcohol radicals do not cross-couple with pCA radicals. As long as hydrogen peroxide is limiting pCA remains uncoupled. Ferulates have similar reaction patterns in terms of radical transfer though they appear to cross-couple in the reaction mixture more readily then pCA. The role of pCA may be to internally provide a radical transfer mechanism for optimizing radical coupling of sinapyl alcohol into the growing lignin polymer. Attachment of some pCA to sinapyl alcohol ensures localization of the radical transfer mechanism in areas where sinapyl alcohol is being incorporated into lignin.
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Abbreviations
- FA:
-
Ferulate
- pCA:
-
p-Coumarate
- CoA:
-
Coenzyme A
- SA-pCA:
-
Sinapyl p-coumarate
- Et-FA:
-
Ethyl ferulate
- Me-pCA:
-
Methyl p-coumarate
- CA:
-
Coniferyl alcohol
- SA:
-
Sinapyl alcohol
References
Allerdings E, Ralph J, Steinhart H, Bunzel M (2006) Isolation and structural identification of complex feruloylated heteroxylan side-chains from maize bran. Phytochemistry 67:1276–1286
Aoyama W, Sasaki S, Matsumura S, Mitsunaga T, Hirai H, Tsutsumi Y, Nishida T (2002) Sinapyl alcohol-specific peroxidase isoenzyme catalyzes the formation of the dehydrogenative polymer from sinapyl alcohol. Mokuzai Gakkaishi 48:497–504
Bunzel M, Ralph J, Steinhart H (2004) Phenolic compounds as cross-links of plant derived polysaccharides. Czech J Food Sci 22:39–42
Church DL, Galston AW (1988) 4-Coumarate: coenzyme A ligase and isoperoxidase expression in Zinnia mesophyll cells induced to differentiate into tracheary elements. Plant Physiol 88:679–684
Demos EK, Woolwine M, Wilson RH, McMillan C (1975) The effects of ten phenolic compounds on hypocotyl growth and mitochondrial metabolism of mung bean. Am J Bot 62:97–102
Ford CW, Hartley RD (1990) Cyclodimers of p-coumaric and ferulic acids in the cell walls of tropical grasses. J Sci Food Agric 50:29–43
Grabber JH, Lu FC (2007) Formation of syringyl-rich lignins in maize as influenced by feruloylated xylans and p-coumaroylated monolignols. Planta 226:741–751
Grabber JH, Hatfield RD, Ralph J, Zon J, Amrhein N (1995) Ferulate cross-linking in cell walls isolated from maize cell suspensions. Phytochemistry 40:1077–1082
Grabber JH, Quideau S, Ralph J (1996) p-Coumaroylated syringyl units in maize lignin; implications for b-ether cleavage by thioacidolysis. Phytochemistry 43:1189–1194
Grabber JH, Hatfield RD, Ralph J (1998a) Diferulate cross-links impede the enzymatic degradation of nonlignified maize walls. J Sci Food Agric 77:193–200
Grabber JH, Ralph J, Hatfield RD (1998b) Ferulate cross-links limit the enzymatic degradation of synthetically lignified primary walls of maize. J Agric Food Chem 46:2609–2614
Grabber JH, Ralph J, Hatfield RD (2000) Cross-linking of maize walls by ferulate dimerization and incorporation into lignin. J Agric Food Chem 48:6106–6113
Grabber JH, Ralph J, Hatfield RD (2002) Model studies of ferulate-coniferyl alcohol cross-product formation in primary maize walls: implications for lignification in grasses. J Agric Food Chem 50:6008–6016
Grabber JH, Mertens DR, JR, HK, Funk C, Lu F (2008) Cell wall fermentatin kinetics impacted more by lignin content and ferulate cross-linking than by lignin composition. J Sci Food Agric (in press)
Harris PJ, Hartley RD (1980) Phenolic constituents of the cell walls of monocotyledons. Biochem Syst Ecol 8:153–160
Hatfield R, Marita JM, Frost K (2008) Characterization of p-coumarate accumulation, p-coumaroyl transferase, and cell wall changes during the development of corn stems. J Sci Food Agric (in press)
Humphreys JM, Chapple C (2002) Rewriting the lignin roadmap. Curr Opin Plant Biol 5:224–229
Ishii T (1991) Isolation and characterization of a diferuloyl arabinoxylan hexasaccharide from bamboo shoot cell-walls. Carbohydr Res 219:15–22
Lam TBT, Iiyama K, Stone BA (1992) Cinnamic acid bridges between cell wall polymers in wheat and phalaris internodes. Phytochemistry 31:1179–1183
Lu F, Ralph J (1998a) Facile synthesis of 4-hydroxycinnamyl p-coumarates. J Agric Food Chem 46:2911–2913
Lu F, Ralph J (1998b) Highly selective syntheses of coniferyl and sinapyl alcohols. J Agric Food Chem 46:1794–1796
Lu F, Ralph J (1999) Detection and determination of p-coumaroylated units in lignins. J Agric Food Chem 47:1988–1992
Lu F, Ralph J (2002) Preliminary evidence for sinapyl acetate as a lignin monomer in kenaf. Chem Commun 7:90–91
Lu F, Ralph J, Morreel K, Messens E, Boerjan W (2004) Preparation and relevance of a cross-coupling product between sinapyl alcohol and sinapyl p-hydroxybenzoate. Org Biomol Chem 2:2888–2890
Marita JM, Vermerris W, Ralph J, Hatfield RD (2003) Variations in the cell wall composition of maize brown midrib mutants. J Agric Food Chem 51:1313–1321
Morrison TA, Jung HG, Buxton DR, Hatfield RD (1998) Cell-wall composition of maize internodes of varying maturity. Crop Sci 38:455–460
Mueller-Harvey I, Hartley RD, Harris PJ, Curzon EH (1986) Linkage of p-coumaryl and feruloyl groups to cell wall polysaccharides of barley straw. Carbohydr Res 148:71–85
Önnerud H, Zhang L, Gellerstedt G, Henriksson G (2002) Polymerization of monolignols by redox shuttle-mediated enzymatic oxidation: a new model in lignin biosynthesis I. Plant Cell 14:1953–1962
Ralph J, Hatfield RD, Quideau S, Helm RF, Grabber JH, Jung H-JG (1994a) Pathway of p-coumaric acid incorporation into maize lignin as revealed by NMR. J Am Chem Soc 116:9448–9456
Ralph J, Quideau S, Grabber JH, Hatfield RD (1994b) Identification and synthesis of new ferulic acid dehydrodimers present in grass cell walls. J Chem Soc Perkin Trans 1:3485–3498
Ralph J, Grabber JH, Hatfield RD (1995) Lignin-ferulate crosslinks in grasses: active incorporation of ferulate polysaccharide esters into ryegrass lignins. Carbohydr Res 275:167–178
Ralph J, Bunzel M, Marita JM, Hatfield RD, Lu F, Kim H, Schatz PF, Grabber JH, Steinhart H (2004) Peroxidase-dependent cross-linking reactions of p-hydroxycinnamates in plant cell walls. Phytochem Rev 3:79–96
Santiago R, Butron A, Arnason JT, Reid LM, Souto XC, Malvar RA (2006) Putative role of pith cell wall phenylpropanoids in Sesamia nonagrioides (Lepidoptera : Noctuidae) resistance. J Agric Food Chem 54:2274–2279
Sato Y, Sugiyama M, Komamine A, Fukuda H (1995) Separation and characterization of the isozymes of wall-bound peroxidase from cultured Zinnia cells during tracheary element differentiation. Planta 196:141–147
Serjiades R, Dean JF, Gamble GR, Himmelsbach DS, Eriksson K-EL (1993) Extracellular laccases and peroxidases from sycamore maple (Acer pseudoplatanus) cell-suspension cultures. Planta 190:75–87
Takahama U (1995) Oxidation of hydroxycinnamic acid and hydroxycinnamyl alcohol derivatives by laccase and peroxidase––interactions among p-hydroxyphenyl, guaiacyl and syringyl groups during the oxidation reactions. Physiol Plant 93:61–68
Takahama U, Oniki T (1994) Effects of ascorbate on the oxidation of derivatives of hydroxycinnamic acid and the mechanism of oxidation of sinapic acid by cell wall-bound peroxidases. Plant Cell Physiol 35:593–600
Takahama U, Oniki T (1997) Enhancement of peroxidase-dependent oxidation of sinapyl alcohol by an apoplastic component, 4-coumaric acid ester isolated from epicotyls of Vigna angularis L. Plant Cell Physiol 38:456–462
Takahama U, Oniki T, Shimokawa H (1996) A Possible Mechanism for the oxidation of sinapyl alcohol by peroxidase-dependent reactions in the apoplast: enhancement of the oxidation by hydroxycinnamic acids and components of the apoplast. Plant Cell Physiol 37:499–504
Terashima N, Fukushima K, He L-F, Takabe K (1993) Comprehensive model of the lignified plant cell wall. In: Jung HG, Buxton DR, Hatfield RD, Ralph J (eds) Forage cell wall structure and digestibility. ASA-CSSA-SSSA, Madison, pp 247–270
Thakur PS, Singh G, Rai VK (1981) Peroxidase isozymes in relation to developing water deficits in two Zea mays L. cultivars. New Phytol 89:25–32
Tsutsumi Y, Matsui K, Sakai K (1998) Substrate-specific peroxidases in woody angiosperms and gymnosperms participate in regulating the dehydrogenative polymerization of syringyl and guaiacyl type lignins. Holzforschung 52:275–281
Acknowledgments
The authors thank Hoon Kim and Fachuang Lu for synthesis of monolignols and the SA-pCA used in these experiments. This work was supported in part by USDA-NRI (2004-35318-15020). Mention of a trademark or proprietary product does not constitute a guarantee or warranty of product by the USDA and does not imply its approval to the exclusion of other products that may also be suitable.
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Hatfield, R., Ralph, J. & Grabber, J.H. A potential role for sinapyl p-coumarate as a radical transfer mechanism in grass lignin formation. Planta 228, 919–928 (2008). https://doi.org/10.1007/s00425-008-0791-4
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DOI: https://doi.org/10.1007/s00425-008-0791-4