Nutritional quality and expression of lignifications genes of Panicum maximum genotypes harvested at three stages of maturity

The rapid decline of nutritional quality of P. maximum with advanced maturity is an important limiting factor for animal performance in pastures. Because of the apomitic reproduction of the species, genetic engineering arises as an important tool for development of new cultivars. Therefore, the identification of genes responsible for the decline in fiber digestibility is an important step towards generating transgenic cultivars. The objective of this study was to determine the yield, chemical composition, in vitro digestibility of leaf and stem fractions of 11 P. maximum genotypes harvested at three stages: 30, 60 and 90 days of regrowth, as well as to quantify the expression of six enzymes from the cell-wall lignification pathway. Another objective was to classify the genotypes in groups according to their productive and nutritional characteristics. A randomized block design in a split plot arrangement with three replications was used, in which the experimental plot was composed of six lines with 4 m length, spaced 0.5 m, being the harvest age the plot and the genotypes the sub-plots. The DM production differed between genotypes only after 90 days of regrowth. There was variation among genotypes in the percentage of leaves, stems and dead material. The genotypes did not differ in chemical composition and digestibility of the leaf fraction, but there was great variation in chemical composition and digestibility of the stem fraction. The stem fraction had higher NDF, ADF and lignin content, and lower CP content than the leaf fraction. However, the stem fraction had higher DM digestibility with 60 days of regrowth, and higher NDF digestibility after 30 and 60 days. The clustering procedure separated the genotypes in four groups cording to DM yield, stem NDF digestibility and percentage of leaves. The accessions PM39 and PM47 stood out for their good productivity and high stem NDF digestibility, while the cultivars Milênio and Mombaça had high DM yield but lower stem NDF digestibility. For quantification of gene expression, the Massai cultivar and the accessions PM39 and PM47 were selected as genotypes with good maintenance of fiber digestibility (SLOW), while the genotypes Tanzânia, Milênio and Mombaça were selected as ones with fast decline in stem fiber digestibility (FAST). The relative expression of six genes of interest (CCR, COMT, C4H, 4CL, CAD and PAL), and one control gene (GAPDH) was determined in the three harvested ages. There was a treatment age interaction for the C4H and COMT genes, with an increase in gene expression from 30 to 60 days of regrowth only in the group with FAST decline in digestibility. In the group with SLOW decline in digestibility, there was no difference in expression from 30 to 60 days of regrowth. The gene PAL had similar profile of expression; however the treatment age interaction was not significant. These characteristics place these three genes as possible modulators of stem digestibility in P. maximum. We conclude that maturity has a great effect over the stem nutritional quality than over leaves, and there was great variation among genotypes in the effect of maturity on stem fiber digestibility, indicating the possibility to select cultivars with higher stem digestibility, and also the difficulty to select genotypes with higher leaf digestibility. We identified the genes C4H, COMT and PAL as possible candidates for genetic engineering aiming the production of transgenic cultivars. (AU)