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Cell Wall Thickening (cell + wall_thickening)
Selected AbstractsInduction of Cell Wall Thickening by the Antifungal Compound Dihydromaltophilin Disrupts Fungal Growth and is Mediated by Sphingolipid BiosynthesisTHE JOURNAL OF EUKARYOTIC MICROBIOLOGY, Issue 2 2009SHAOJIE LI ABSTRACT. Dihydromaltophilin (heat-stable antifungal factor [HSAF]) is an antifungal metabolite produced in Lysobacter enzymogenes biocontrol strain C3. This compound induces cell wall thickening in Aspergillus nidulans. Here we show that the cell wall thickening is a general response to HSAF in diverse fungal species. In the A. nidulans model, the thickened cell wall negatively affects hyphal growth. Growth of HSAF-pre-treated hyphae failed to resume at hyphal tips with thick cell wall and the actin cable could not re-polarize at the thickened region of the cell wall, even after the treated hyphae were transferred to drug-free medium. Moreover, HSAF-induced cell wall thickening is mediated by sphingolipid synthesis: HSAF failed to induce cell wall thickening in the absence of ceramide synthase BarA and the sphingolipid synthesis inhibitor myriocin was able to suppress HSAF-induced cell wall thickening. The thickened cell wall could be digested by chitinase suggesting that chitin contributes to the HSAF-induced thickening. Furthermore, HSAF treatment activated the transcription of two chitin synthase encoding genes chsB and chsC. [source] Changes in mesophyll anatomy and sink,source relationships during leaf development in Quercus glauca, an evergreen tree showing delayed leaf greeningPLANT CELL & ENVIRONMENT, Issue 5 2003S.-I. MIYAZAWA ABSTRACT Changes in mesophyll anatomy, gas exchange, and the amounts of nitrogen and cell wall constituents including cellulose, hemicellulose and lignin during leaf development were studied in an evergreen broad-leaved tree, Quercus glauca, and in an annual herb, Phaseolus vulgaris. The number of chloroplasts per whole leaf in P. vulgaris increased and attained the maximal level around 10 d before full leaf area expansion (FLE), whereas it continued to increase even after FLE in Q. glauca. The increase in the number of palisade tissue cells per whole leaf continued until a few days before FLE in Q. glauca, but it had almost ceased by 10 d before FLE in P. vulgaris. The radius and height of palisade tissue cells in Q. glauca, attained their maximal levels at around FLE whereas the thickness of the mesophyll cell wall and concentrations of the cell wall constituents increased markedly after FLE. These results clearly indicated that, in Q. glauca, chloroplast development proceeded in parallel with the cell wall thickening well after completion of the mesophyll cell division and cell enlargement. The sink,source transition, defined to be the time when the increase in daily carbon exchange rate exceeds the daily increase in leaf carbon content, occurred before FLE in P. vulgaris but after FLE in Q. glauca. During leaf area expansion, the maximum daily increase in nitrogen content on a whole leaf basis (the maximum leaf areas were corrected to be identical for these species) in Q. glauca was similar to that in P. vulgaris. In Q. glauca, however, more than 70% of nitrogen in the mature leaf was invested during its sink phase, whereas in P. vulgaris it was 50%. These results suggest that Q. glauca invests nitrogen for cell division for a considerable period and for chloroplast development during the later stages. We conclude that the competition for nitrogen between cell division and chloroplast development in the area of expanding leaves can explain different greening patterns among plant species. [source] Induction of Cell Wall Thickening by the Antifungal Compound Dihydromaltophilin Disrupts Fungal Growth and is Mediated by Sphingolipid BiosynthesisTHE JOURNAL OF EUKARYOTIC MICROBIOLOGY, Issue 2 2009SHAOJIE LI ABSTRACT. Dihydromaltophilin (heat-stable antifungal factor [HSAF]) is an antifungal metabolite produced in Lysobacter enzymogenes biocontrol strain C3. This compound induces cell wall thickening in Aspergillus nidulans. Here we show that the cell wall thickening is a general response to HSAF in diverse fungal species. In the A. nidulans model, the thickened cell wall negatively affects hyphal growth. Growth of HSAF-pre-treated hyphae failed to resume at hyphal tips with thick cell wall and the actin cable could not re-polarize at the thickened region of the cell wall, even after the treated hyphae were transferred to drug-free medium. Moreover, HSAF-induced cell wall thickening is mediated by sphingolipid synthesis: HSAF failed to induce cell wall thickening in the absence of ceramide synthase BarA and the sphingolipid synthesis inhibitor myriocin was able to suppress HSAF-induced cell wall thickening. The thickened cell wall could be digested by chitinase suggesting that chitin contributes to the HSAF-induced thickening. Furthermore, HSAF treatment activated the transcription of two chitin synthase encoding genes chsB and chsC. [source] Cell wall biochemistry and biomechanics of harvested white asparagus shoots as affected by temperatureANNALS OF APPLIED BIOLOGY, Issue 3 2008W.B. Herppich Abstract The effects of temperature on the dynamics of changes in shoot mechanical properties, cell wall components, relevant soluble sugars and respiration activity of harvested white asparagus spears were investigated during a 7-day storage period. All functional cell wall components of asparagus spears increased closely temperature dependent. The content of soluble glucose declined with a similar temporal dynamics and to a comparable degree, indicating a major carbon flow of this storage sugar into cell walls (60,70%). Irrespective of temperature, the contents of stored soluble fructose and sucrose remained more or less constant. Lower temperatures reduced cell wall development but do not significantly affect the relative carbon flow from storage sugars into cell walls or maintenance respiration. Compared with cell walls, maintenance respiration is by far the smaller carbon sink in stored asparagus spears. Temperature differentially affects the absolute amount and the relative contribution of the different cell wall components and the temporal dynamics of changes in structural carbohydrate and lignin content. At higher temperatures, secondary cell wall thickening resulted mainly from a large increase in cellulose content. The pronounced increase in the fractions of cellulose and especially lignin may stress the important role of lignin in cell wall strengthening. While the fraction of cell wall proteins decreased, those of hemicellulose and the pectic components were not influenced. [source] The morphogenesis of lobed plant cells in the mesophyll and epidermis: organization and distinct roles of cortical microtubules and actin filamentsNEW PHYTOLOGIST, Issue 3 2005Emmanuel Panteris Summary The morphogenesis of lobed plant cells has been considered to be controlled by microtubule (MT) and/or actin filament (AF) organization. In this article, a comprehensive mechanism is proposed, in which distinct roles are played by these cytoskeletal components. First, cortical MT bundles and, in the case of pavement cells, radial MT arrays combined with MT bundles determine the deposition of local cell wall thickenings, the cellulose microfibrils of which copy the orientation of underlying MTs. Cell growth is thus locally prevented and, consequently, lobes and constrictions are formed. Arch-like tangential expansion is locally imposed at the external periclinal wall of pavement cells by the radial arrangement of cellulose microfibrils at every wall thickening. Whenever further elongation of the original cell lobes occurs, AF patches assemble at the tips of growing lobes. Intercellular space formation is promoted or prevented by the opposite or alternate, respectively, arrangement of cortical MT arrays between neighboring cells. The genes that are possibly involved in the molecular regulation of the above morphogenetic procedure by MT and AF array organization are reviewed. [source] | ||||||||||