Abstract
With a high potential to generate biomass, maize stover arises as an outstanding feedstock for biofuel production. Maize stover presents the added advantage of being a multiple exploitation of the crop as a source of food, feed, and energy. In this study, contrasting groups of recombinant inbred lines (RILs) from a maize multiparent advanced generation intercross (MAGIC) population that showed variability for saccharification efficiency were screened by FTIR-ATR spectroscopy to explore compositional differences between high and low saccharification yielders. High and low saccharification efficiency groups differed in cell wall compositional features: high saccharification RILs displayed higher proportions of S subunits, aromatic compounds, and hemicellulose as opposed to low saccharification efficiency groups in which FTIR predicted higher proportions of lignin, more precisely lignin being richer in subunits G, and greater proportions of crystalline cellulose and acetyl methyl esters. The application of FTIR-ATR spectroscopy in this material allowed us to obtain a rapid and broad vision of cell wall compositional features in contrasting groups of saccharification efficiency. These results helped us to deepen our knowledge into the relationship between cell wall composition and biorefining potential; they also allowed us to establish new targets for future research regarding lignocellulosic bioconversion.
Highlights
Besides its uses as food and feed, maize stover after ear removal can have biorefinery applications
A subset of 408 recombinant inbred lines (RILs) from a maize multiparent advanced generation intercross (MAGIC) population were evaluated for saccharification efficiency and analyzed by FTIR-ATR spectroscopy in field experiments over two years
We observed a large influence of the year for saccharification efficiency, but we did not observe a yearxgenotype interaction, indicating that even though saccharification efficiency value ranges are different for each year, RILs that in one year present high saccharification efficiency would present high values in the other year
Summary
Besides its uses as food and feed, maize stover after ear removal can have biorefinery applications. Maize has a high biomass yield potential (5.2 tons of dry matter/ha; dry biomass yield) and has been proposed as an outstanding model for biofuel production [3,4]. Lignocellulosic feedstock, such as maize stover, is highly abundant and readily available as substrates for second-generation biofuel production [1,5]. It is typically composed of 39.4% cellulose, 33.1% hemicelluloses, and 14.9% lignin [6]. G and S lignin units are prevalent compared to H units with average ratios that are nearly equal to 35% and 4%, respectively [8]
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