OPPORTUNITIES & LIMITS TO PERTURBING FORAGE PLANT BIOCHEMISTRY, GROWTH, & DEVELOPMENT FOR IMPROVING FORAGE NUTRITIONAL BENEFITS IN DAIRY SYS
Location: Cell Wall Biology and Utilization Research
Title: Incorporation of Monolignol Conjugates into Lignin for Improved Processing
Research conducted cooperatively with:
| Seneca Foods Corporation|
Submitted to: International Symposium on Wood and Pulping Chemistry
Publication Type: Proceedings
Publication Acceptance Date: December 1, 2008
Publication Date: June 15, 2009
Citation: Ralph, J., Grabber, J.H., Lu, F., Kim, H., Marita, J.M., Hatfield, R.D. 2009. Incorporation of Monolignol Conjugates into Lignin for Improved Processing. In: Proceedings of the Fifteenth International Symposium on Wood, Fiber, and Pulping Chemistry, June 15-18, 2009, Oslo, Norway. Paper O-014.
Lignin remains one of the most significant barriers to the efficient utilization of cellulosic substrates, either for pulping or for biofuels production. Now that monomer substitution in the lignification process is now well authenticated in various transgenic plants, it is opportune to begin explorations into designing lignins to improve the ease with which they can be removed from the cell wall. Here we reveal the logic behind our approach to utilize coniferyl and sinapyl ferulate (CA/SA-FA) as lignin ‘monomers’. These conjugates, ferulate analogs of the monolignol p-coumarates that are incorporated naturally into grass lignins, result in ester linkages connecting polymer moieties; unlike p-coumarates, ferulates incorporate integrally into the polymer by the combinatorial array of radical coupling reactions that typify lignification. The resulting ‘zips’ in the polymer are then readily cleaved by alkaline or acidolytic processes. Incorporation of 25% CA-FA into lignin in suspension-cultured corn cell walls allows delignification at just 100 °C to the same level as requires 160 °C on normally-lignified material; at 65% CA-FA (a probably unrealistic level) just 30 °C is required. Engineering plants to incorporate such monomer conjugates therefore has the potential to vastly reduce the energy demands of processing; plants with such lignins appear to be ideally suited for AFEX pretreatment. With the gene required to biosynthesize the conjugate in hand, the next step is to attempt the plant engineering.