Effect of Phenolic Structures on the Degradability of Cell Walls Isolated from Newly Extended Apical Internode of Tall Fescue (<i>Festuca</i> <i>arundinacea</i> Schreb.)

Vailhé, Marie Andrée Bernard; Provan, Gordon J.; Scobbie, Lorraine; Chesson, Andrew; Maillot, Marie Paule; Cornu, A.; Besle, J.M.

doi:10.1021/jf9906329

Cited by 28 publications

(11 citation statements)

References 33 publications

(37 reference statements)

Supporting

Mentioning

Contrasting

Order By: Relevance

“…In cells, PCA is mainly esterified to the γ -position of phenylpropanoid sidechains of S units in lignin [33,59,60]. Although very small quantities of PCA are esterified to arabinoxylans in immature tissues, most PCA accretion occurs in tandem with lignification [61,62]. FA is intracellularly esterified to the C5-hydroxyl of α-L-arabinose sidechains of xylans and deposited into primary and secondary walls [43,63,64].…”

Section: Resultsmentioning

confidence: 99%

Is the basal area of maize internodes involved in borer resistance?

et al. 2011

View full text Add to dashboard Cite

BackgroundTo elucidate the role of the length of the internode basal ring (LIBR) in resistance to the Mediterranean corn borer (MCB), we carried out a divergent selection program to modify the LIBR using two maize synthetic varieties (EPS20 and EPS21), each with a different genetic background. We investigated the biochemical mechanisms underlying the relationship between the LIBR and borer resistance. Selection to lengthen or shorten the LIBR was achieved for each synthetic variety. The resulting plants were analyzed to determine their LIBR response, growth, yield, and borer resistance.ResultsIn the synthetic variety EPS20 (Reid germplasm), reduction of the LIBR improved resistance against the MCB. The LIBR selection was also effective in the synthetic variety EPS21 (non-Reid germplasm), although there was no relationship detected between the LIBR and MCB resistance. The LIBR did not show correlations with agronomic traits such as plant height and yield. Compared with upper sections, the internode basal ring area contained lower concentrations of cell wall components such as acid detergent fiber (ADF), acid detergent lignin (ADL), and diferulates. In addition, some residual 2,4-dihydroxy-7-methoxy-(2H)-1,4-benzoxazin-3-(4H)-one (DIMBOA), a natural antibiotic compound, was detected in the basal area at 30 days after silking.ConclusionWe analyzed maize selections to determine whether the basal area of maize internodes is involved in borer resistance. The structural reinforcement of the cell walls was the most significant trait in the relationship between the LIBR and borer resistance. Lower contents of ADF and ADL in the rind of the basal section facilitated the entry of larvae in this area in both synthetic varieties, while lower concentrations of diferulates in the pith basal section of EPS20 facilitated larval feeding inside the stem. The higher concentrations of DIMBOA may have contributed to the lack of correlation between the LIBR and borer resistance in EPS21. This novel trait could be useful in maize breeding programs to improve borer resistance.

show abstract

Section: Resultsmentioning

confidence: 99%

Is the basal area of maize internodes involved in borer resistance?

et al. 2011

View full text Add to dashboard Cite

show abstract

“…It has also been shown that CAD down-regulation in several species including maize, Medicago sativa , Pinus taeda , tobacco, and poplar, chemically alters lignin resulting in greater alkaline solubility with unchanged total lignin content and without compromising strength. In the case of poplar, the wood was more amenable to industrial delignification processes including kraft pulping (Hibino et al, 1995; Baucher et al, 1999; MacKay et al, 1999; Vailhe et al, 2000; Marita et al, 2003), while faster growth and higher wood density was observed in loblolly pine (Cavell et al, 1998). Thus, KNOX1 genes may be a useful tool for altering total lignin levels, as well as modulating the lignin chemical makeup to improve forage or processing properties.…”

Section: Discussionmentioning

confidence: 99%

KNOX1 genes regulate lignin deposition and composition in monocots and dicots

Townsley¹,

Sinha²,

Kang³

2013

Front. Plant Sci.

View full text Add to dashboard Cite

Plant secondary cell walls are deposited mostly in vascular tissues such as xylem vessels, tracheids, and fibers. These cell walls are composed of a complex matrix of compounds including cellulose, hemicellulose, and lignin. Lignin functions primarily to maintain the structural and mechanical integrity of both the transport vessel and the entire plant itself. Since lignin has been identified as a major source of biomass for biofuels, regulation of secondary cell wall biosynthesis has been a topic of much recent investigation. Biosynthesis and patterning of lignin involves many developmental and environmental cues including evolutionarily conserved transcriptional regulatory modules and hormonal signals. Here, we investigate the role of the class I Knotted1-like-homeobox (KNOX ) genes and gibberellic acid in the lignin biosynthetic pathway in a representative monocot and a representative eudicot. Knotted1 overexpressing mutant plants showed a reduction in lignin content in both maize and tobacco. Expression of four key lignin biosynthesis genes was analyzed and revealed that KNOX1 genes regulate at least two steps in the lignin biosynthesis pathway. The negative regulation of lignin both in a monocot and a eudicot by the maize Kn1 gene suggests that lignin biosynthesis may be preserved across large phylogenetic distances. The evolutionary implications of regulation of lignification across divergent species are discussed.

show abstract

“…p -Coumarate is mainly esterified to the γ–position of phenylpropanoid sidechains of S units in lignin [5–7]. Although very small quantities of p -coumarate are esterified to arabinoxylans in immature tissues, most p -coumarate accretion occurs in tandem with lignification [8,9], making p -coumarate accumulation a convenient indicator of lignin deposition. Ferulates are intracellularly esterified to the C5-hydroxyl of α- l -arabinose sidechains of xylans and deposited into primary and secondary walls of a variety of grass tissues [10–12].…”

Section: Introductionmentioning

confidence: 99%

Role of Dehydrodiferulates in Maize Resistance to Pests and Diseases

Santiago

Malvar

2010

IJMS

View full text Add to dashboard Cite

Phenolic esters have attracted considerable interest due to the potential they offer for peroxidase catalysed cross-linking of cell wall polysaccharides. Particularly, feruloyl residues undergo radical coupling reactions that result in cross-linking (intra-/intermolecular) between polysaccharides, between polysaccharides and lignin and, between polysaccharides and proteins. This review addresses for the first time different studies in which it is established that cross-linking by dehydrodiferulates contributes to maize’s defences to pests and diseases. Dehydrodiferulate cross-links are involved in maize defence mechanisms against insects such as the European, Mediterranean, and tropical corn borers and, storage pest as the maize weevil. In addition, cross-links are also discussed to be involved in genetic resistance of maize to fungus diseases as Gibberella ear and stalk rot. Resistance against insects and fungus attending dehydrodiferulates could go hand in hand. Quantitative trait loci mapping for these cell wall components could be a useful tool for enhancing resistance to pest and diseases in future breeding programs.

show abstract

Effect of Phenolic Structures on the Degradability of Cell Walls Isolated from Newly Extended Apical Internode of Tall Fescue (Festuca arundinacea Schreb.)

Cited by 28 publications

References 33 publications

Is the basal area of maize internodes involved in borer resistance?

Is the basal area of maize internodes involved in borer resistance?

KNOX1 genes regulate lignin deposition and composition in monocots and dicots

Role of Dehydrodiferulates in Maize Resistance to Pests and Diseases

Contact Info

Product

Resources

About