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Lignin Modification (lignin + modification)
Selected AbstractsIn-situ oxygen profiling and lignin modification in guts of wood-feeding termitesINSECT SCIENCE, Issue 3 2010Jing Ke Abstract, Reports on the capability of wood-feeding termites (WFTs) in degrading wood particles and on the existence of aerobic environment in the localized guts suggest that their high efficiency of cellulose utilization is not only caused by cellulase, but also by biochemical factors that pretreat lignin. We thus extend the hypothesis that for highly efficient accessibility of cellulose, there should be direct evidence of lignin modification before the hindgut. The lignin degradation/modification is facilitated by the oxygenated environment in intestinal microhabitats. To test our hypothesis, we conducted experiments using a dissolved oxygen microelectrode with a tip diameter < 10 ,m to measure oxygen profiles in intestinal microhabitats of both Coptotermes formosanus (Shiraki) and Reticulitermes flavipes (Kollar). Lignin modification during passage through their three gut segments was also analyzed with pyrolysis gas chromatography/mass spectrometry. The data showed relatively high levels of oxygen in the midgut that could have promoted lignin oxidation. Consistent with the oxygen measurements, lignin modifications were also detected. In support of previously proposed hypotheses, these results demonstrate that lignin disruption, which pretreats wood for cellulose utilization, is initiated in the foregut, and continues in the midgut in both termites. [source] Multi-site genetic modification of monolignol biosynthesis in alfalfa (Medicago sativa): effects on lignin composition in specific cell typesNEW PHYTOLOGIST, Issue 3 2008Jin Nakashima Summary ,,Independent antisense down-regulation of 10 individual enzymes in the monolignol pathway has generated a series of otherwise isogenic alfalfa (Medicago sativa) lines with varying lignin content and composition. These plants show various visible growth phenotypes, and possess significant differences in vascular cell size and number. ,,To better understand the phenotypic consequences of lignin modification, the distributions of lignin content and composition in stems of the various alfalfa lines at the cellular level were studied by confocal microscopy after staining for specific lignin components, and by chemical analysis of laser capture dissected tissue types. ,,Although all antisense transgenes were driven by the same promoter with specificity for vascular, fiber and parenchyma tissues, the impact of down-regulating a specific transgene varied in the different tissue types. For example, reducing expression of ferulate 5-hydroxylase reduced accumulation of syringyl lignin in fiber and parenchyma cells, but not in vascular elements. ,,The results support a model for cell type-specific regulation of lignin content and composition at the level of the monolignol pathway, and illustrate the use of laser capture microdissection as a new approach to spatially resolved lignin compositional analysis. [source] | ||||||||||