RNAi downregulation of three key lignin genes in sugarcane improves glucose release without reduction in sugar production

Bewg, William Patrick; Poovaiah, Charleson R.; Lan, Wu; Ralph, John; Coleman, Heather D.

doi:10.1186/s13068-016-0683-y

Cited by 37 publications

(34 citation statements)

References 67 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…We have previously published work describing the downregulation of both the F5H and CCoAOMT in sugarcane, with the result being increased glucose release by enzymatic hydrolysis but with no decrease in lignin. In the F5H lines this was attributed to a change in the lignin monomer ratio (Bewg et al 2016) The final gene assessed in our study, C3H, had the highest expression level in Section B, immediately below the most juvenile Section A. C3H catalyzes the second aromatic hydroxylation reaction in the lignin biosynthesis pathway and is an important hub in controlling metabolic flux into G and S lignin monomer synthesis (Barriere et al 2004;Weng & Chapple 2010). CCoAOMT, along with C3H, are hypothesized to be important control points for cell wall lignification by acting as part of the ferulate production pathway (Barriere et al 2004).…”

Section: Discussionmentioning

confidence: 98%

Peer Review #2 of "Cell wall composition and lignin biosynthetic gene expression along a developmental gradient in an Australian sugarcane cultivar (v0.1)"

Brito¹

2017

View full text Add to dashboard Cite

Section: Discussionmentioning

confidence: 98%

Peer Review #2 of "Cell wall composition and lignin biosynthetic gene expression along a developmental gradient in an Australian sugarcane cultivar (v0.1)"

Brito¹

2017

View full text Add to dashboard Cite

“…The increased expression of COMT in young tissue in this research may be to ensure S monomer production during the availability of the initial metabolic flux. Previous work has shown that the RNAi suppression of COMT in sugarcane resulted in decreased lignin and altered S:G ratio ( Bewg et al, 2016 ).…”

Section: Discussionmentioning

confidence: 99%

Cell wall composition and lignin biosynthetic gene expression along a developmental gradient in an Australian sugarcane cultivar

Bewg

Coleman

2017

PeerJ

Self Cite

View full text Add to dashboard Cite

Sugarcane bagasse is an abundant source of lignocellulosic material for bioethanol production. Utilisation of bagasse for biofuel production would be environmentally and economically beneficial, but the recalcitrance of lignin continues to provide a challenge. Further understanding of lignin production in specific cultivars will provide a basis for modification of genomes for the production of phenotypes with improved processing characteristics. Here we evaluated the expression profile of lignin biosynthetic genes and the cell wall composition along a developmental gradient in KQ228 sugarcane. The expression levels of nine lignin biosynthesis genes were quantified in five stem sections of increasing maturity and in root tissue. Two distinct expression patterns were seen. The first saw highest gene expression in the youngest tissue, with expression decreasing as tissue matured. The second pattern saw little to no change in transcription levels across the developmental gradient. Cell wall compositional analysis of the stem sections showed total lignin content to be significantly higher in more mature tissue than in the youngest section assessed. There were no changes in structural carbohydrates across developmental sections. These gene expression and cell wall compositional patterns can be used, along with other work in grasses, to inform biotechnological approaches to crop improvement for lignocellulosic biofuel production.

show abstract

“…For the COMT gene, one line presented lower lignin content and, along with another line, elevated levels of glucose were observed during enzymatic hydrolysis. Two of the improved glucose release lines (F5H‐2 and COMT‐2) also showed reduced S : G ratios …”

Section: Sugarcane Genetic Engineering and Genes Rolementioning

confidence: 99%

“…Two of the improved glucose release lines (F5H-2 and COMT-2) also showed reduced S : G ratios. 43 Research has shown that it is possible to reduce sugarcane lignification successfully through RNA interference, despite its highly complex and polyploid genome. Suppression of COMT expression by 67% to 97% reduced the lignin content by 3.9% to 13.7%, respectively.…”

Section: Sugarcane Genetic Engineering and Genes Rolementioning

confidence: 99%

Sugarcane biomass conversion influenced by lignin

Schmatz

Tyhoda

Brienzo

2019

Biofuels Bioprod Bioref

View full text Add to dashboard Cite

Plant biomass residues are renewable sources for the production of biofuels and high‐value macromolecules. Sugarcane bagasse is one such plant biomass residue that is available from the sugar‐processing industry. It is used as a raw material for biobased ethanol production. However, some of its properties and its behavior during processing have a major inhibitory effect on its successful conversion. Chief among these inhibitory properties are the lignin content, its distribution in plant tissues, and its chemical properties. These make the materials naturally resistant to bioconversion processes. Further, lignin and carbohydrate degradation products can be formed during acid pretreatment, which is one of the major steps during biomass conversion to bioethanol. These products negatively affect the liberation of fermentable sugars and the yield of ethanol during the fermentation stage of the conversion process. Other factors that also have an influence on the production of fermentable sugar are related to the different structural arrangement of plant tissues (cane fractions of the node, internode, and external fraction), as well as biomass variety. Biomass varieties with low lignin content result in an improved yield of fermentable sugars, which in turn contributes to improved viability of the second‐generation bioethanol production processes. By selecting sugarcane varieties with the best properties, ethanol production can be increased without increasing the total area under cultivation. Efforts have been dedicated to reducing biomass recalcitrance by classical and precision breeding. Genetic modification of sugarcane alters the genes responsible for the encoding enzymes for lignin biosynthesis, generating sugarcane with low recalcitrance. © 2019 Society of Chemical Industry and John Wiley & Sons, Ltd

show abstract

RNAi downregulation of three key lignin genes in sugarcane improves glucose release without reduction in sugar production

Cited by 37 publications

References 67 publications

Peer Review #2 of "Cell wall composition and lignin biosynthetic gene expression along a developmental gradient in an Australian sugarcane cultivar (v0.1)"

Peer Review #2 of "Cell wall composition and lignin biosynthetic gene expression along a developmental gradient in an Australian sugarcane cultivar (v0.1)"

Cell wall composition and lignin biosynthetic gene expression along a developmental gradient in an Australian sugarcane cultivar

Sugarcane biomass conversion influenced by lignin

Contact Info

Product

Resources

About