New insight into the mechanism of cellulose and callose biosynthesis: proteases may regulate callose biosynthesis upon wounding

Using a silver-enhanced, gold-secondary antibody immuno-location approach, we investigated the mechanisms for the switch from -1,4- to -1,3-glucan biosynthesis upon wounding. Antibodies against -1,4- and -1,3-glucan synthases were used to locate these synthases before and after wounding of Mung bean (Vigna radiata var Berken) hypocotyls. Within 5 min of wounding, -1,4-glucan synthases which were densely localized on plasma membranes adjacent to the secondary walls at the wound site completely disappeared, and -1,3-glucan synthases became labeled. The immuno-location of the -1,3-glucan synthases in the secondary walls was in good accordance with the region where the -1,4-glucan synthases were localized before wounding. Aniline blue was also utilized to visualize the deposition of callose upon wounding. Within 5 min of wounding, callose had accumulated in the corresponding region where the immuno-labeling of -1,3-glucan synthase was detected after wounding. The -1,3-glucan synthases were always detected from the sieve plate and plasmodesmata which are known to have constitutive synthesis of callose regardless of wounding. Secondary walls located distantly into the tissue away from the wound site were consistently labeled by the -1,4-glucan synthase antibody even after wounding. Immuno-blot analysis clearly shows that the levels of -1,4-glucan synthase subunit Ces A decreased dramatically within 30 min, whereas the -1,3-glucan synthase subunit CFL1 levels increased significantly after wounding. The intensity of labeling reached a maximum at the wound site, and gradually decreased in correspondence with the distance from the wound site. When a protease inhibitor cocktail was applied upon wounding, neither the -1,3-glucan synthase appeared nor callose was deposited during the first 5 min of wounding. On the other hand, -1,4-glucan synthase was detected at the wound site, implying that activation of -1,3-glucan synthase may rely on the degradation of the -1,4-glucan synthase. Our study may provide new insight into -glucan synthesis in higher plants.     

Facile synthesis of Ti-TUD-1 for catalytic oxidative desulfurization of model sulfur compounds

A facile synthesis route for Ti-TUD-1 at room temperature employing silatrane and titanium glycolate as Si and Ti sources (2?C8 mol%), respectively, over a triethanolamine template is proposed. XRD, N₂ adsorption?Cdesorption isotherms, and TEM analysis confirmed disordered mesoporous structures with high surface area (715?C824 m²/g). According to the UV?Cvisible spectroscopy of the calcined materials, titanium species of ca. 2.7 mol% Ti loading were present mostly in tetrahedral coordination for a sample prepared with 4 mol% Ti in the substrate mixture. Ti-TUD-1 showed catalytic activity in cyclohexene epoxidation, which depended on the amount of tetrahedrally coordinated Ti species. The hydrophilic nature of the surface of Ti-TUD-1 was confirmed by the effect of oxidant such that tert-butyl hydroperoxide (TBHP, 5?C6 M in decane) was superior to other oxidants in water (cyclohexene conversion: TBHP in decane 36.5% vs. TBHP in water 30.6%). Ti-TUD-1 was more active in oxidative desulfurization (ODS) reaction than Ti-MCM-41 at the same Ti loading; the former produced 4,6-dimethyldibenzothiophene (4,6-DMDBT) conversion near 100% after reacting for 15 min, whereas Ti-MCM-41 produced final conversion of 4,6-DMDBT of 89% after reacting for 180 min. ODS over Ti-TUD-1 was influenced both by electron density and steric hindrance in model sulfur compounds. Partially polymerized Ti sites seemed to also contribute to the reaction.