Kazuyuki Wakabayashi

Hypergravity induces reorientation of cortical microtubules and modifies growth anisotropy in azuki bean epicotyls

We examined the changes in the orientation of cortical microtubules during the hypergravity-induced modification of growth anisotropy (inhibition of elongation growth and promotion of lateral growth) in azuki bean (Vigna angularis Ohwi et Ohashi) epicotyls. The percentage of cells with transverse microtubules was decreased, while that with longitudinal microtubules was increased, in proportion to the logarithm of the magnitude of gravity. The percentage of cells with longitudinal microtubules showed an increase within 0.5xa0h of transfer of the 1g-grown seedlings to a 300g-hypergravity condition. Lanthanum and gadolinium, blockers of calcium channels, nullified the modification of growth anisotropy and reorientation of microtubules by hypergravity. Horizontal and acropetal hypergravity modified growth anisotropy and reorientation of microtubules, as did basipetal hypergravity, and these changes were not seen in the presence of lanthanum or gadolinium. These results suggest that hypergravity changes activities of lanthanum- and gadolinium-sensitive calcium channels independently of its direction, which may lead to reorientation of cortical microtubules and modification of growth anisotropy in azuki bean epicotyls.

Cell wall-bound peroxidase activity and lignin formation in azuki bean epicotyls grown under hypergravity conditions

The effects of accelerated gravity stimuli on the cell wall-bound peroxidase activity and the lignin content were investigated along epicotyls of azuki bean (Vigna angularis) seedlings. The endogenous growth occurred primarily in the upper regions of the epicotyl, but no growth was detected in the middle or basal regions. Hypergravity treatment at 300g for 6h suppressed elongation growth and stimulated lateral expansion of the upper regions. The content of acetyl bromide-soluble lignin increased gradually from the apical to the basal regions of epicotyls. Hypergravity treatment stimulated the increase in the lignin content in epicotyls, particularly in the middle and basal regions. The peroxidase activity in the protein fraction extracted with a high ionic strength buffer from the cell wall preparation also increased gradually toward the basal region, and hypergravity treatment increased the activity in all epicotyl regions. There was a close correlation between the lignin content and the enzyme activity. These results suggest that hypergravity increases the activity of cell wall-bound peroxidase followed by increases of the lignin formation in epicotyl cell walls, which may contribute to increasing the rigidity of cell walls against the gravitational force.

Transient increase in the transcript levels of γ-tubulin complex genes during reorientation of cortical microtubules by gravity in azuki bean (Vigna angularis) epicotyls

By hypergravity treatment, the percentage of cells with transverse microtubules was decreased, while that with longitudinal microtubules was increased in azuki bean (Vigna angularis) epicotyls. The expression of genes encoding γ-tubulin complex (VaTUG and VaGCP3) was increased transiently in response to changes in the gravitational conditions. Lanthanum and gadolinium ions, potential blockers of mechanosensitive calcium ion-permeable channels (mechanoreceptors), nullified reorientation of microtubules as well as up-regulation of expression of VaTUG and VaGCP3 by hypergravity. These results suggest that mechanoreceptors may perceive the gravity signal, which leads to a transient increase in the transcript levels of γ-tubulin complex genes and reorientation of cortical microtubules.

Effects of hypergravity on expression of XTH genes in azuki bean epicotyls

Hypergravity produced by centrifugation caused inhibition of elongation growth and a decrease in the cell wall extensibility in azuki bean epicotyls (Vigna angularis Ohwi et Ohashi). Also, hypergravity increased the molecular mass of xyloglucans, whereas it decreased xyloglucan-degrading activity in epicotyls. When the expression profiles of three xyloglucan endotransglucosylase/hydrolase (XTH) genes, VaXTHS4, VaXTH1 and VaXTH2, were analyzed under hypergravity conditions, the expression of VaXTHS4, which shows only hydrolase activity, was downregulated in proportion to the logarithm of the magnitude of gravity (R = -0.94). However, the gene expression of VaXTH1 or VaXTH2, which shows only transglucosylase activity, was not affected by gravitational conditions. When the seedlings that had been grown at 1 g were transferred to hypergravity conditions at 300 g, the downregulation of VaXTHS4 expression was detected within 1 h. By removal of hypergravity stimulus, VaXTHS4 expression was increased within 1 h. These results suggest that azuki bean epicotyls promptly regulate the expression level of only VaXTHS4 in response to gravity stimuli. The regulation of xyloglucan-hydrolyzing activity as a result of changes in VaXTHS4 expression may be involved in the regulation by gravity of molecular mass of xyloglucans, leading to modifications of cell wall mechanical properties and cell elongation. Lanthanum and gadolinium, potential blockers of mechanosensitive calcium ion permeable channels (mechanoreceptors), nullified the suppression of VaXTHS4 expression, suggesting that mechanoreceptors are responsible for inhibition by hypergravity of VaXTHS4 expression.

Cellular basis of growth suppression by submergence in azuki bean epicotyls

BACKGROUND AND AIMSnComplete submergence severely reduces growth rate and productivity of terrestrial plants, but much remains to be elucidated regarding the mechanisms involved. The aim of this study was to clarify the cellular basis of growth suppression by submergence in stems.nnnMETHODSnThe effects of submergence on the viscoelastic extensibility of the cell wall and the cellular osmotic concentration were studied in azuki bean epicotyls. Modifications by submergence to chemical properties of the cell wall; levels of osmotic solutes and their translocation from the seed to epicotyls; and apoplastic pH and levels of ATP and ethanol were also examined. These cellular events underwater were compared in etiolated and in light-grown seedlings.nnnKEY RESULTSnUnder submergence, the osmotic concentration of the cell sap was substantially decreased via decreased concentrations of organic compounds including sugars and amino acids. In contrast, the viscoelastic extensibility of the cell wall was kept high. Submergence also decreased ATP and increased the pH of the apoplastic solution. Alcoholic fermentation was stimulated underwater, but the resulting accumulated ethanol was not directly involved in growth suppression. Light partially relieved the inhibitory effects of submergence on growth, osmoregulation and sugar translocation.nnnCONCLUSIONSnA decrease in the levels of osmotic solutes is a main cause of underwater growth suppression in azuki bean epicotyls. This may be brought about by suppression of solute uptake via breakdown of the H(+) gradient across the plasma membrane due to a decrease in ATP. The involvement of cell wall properties in underwater growth suppression remains to be fully elucidated.

β-1,3 : 1,4-Glucan Synthase Activity in Rice Seedlings under Water

BACKGROUND AND AIMSnThe metabolism of beta-1,3 : 1,4-glucan regulates the mechanical properties of cell walls, and thereby changes the elongation growth of Poaceae plants. A previous study has shown that elongation growth of rice coleoptiles under water is enhanced by increased activity of beta-1,3 : 1,4-glucan hydrolases; however, the involvement of beta-1,3 : 1,4-glucan synthase activity in elongation growth under water has not yet been clarified.nnnMETHODSnThe beta-1,3 : 1,4-glucan synthase activity in a microsomal fraction prepared from rice seedlings grown under water was compared with that from control seedlings grown in air. The change under water in the relative expression level of CslF6, a major isoform of the beta-1,3 : 1,4-glucan synthase genes, was examined by quantitative reverse-transcriptase PCR.nnnKEY RESULTSnThe level of beta-1,3 : 1,4-glucan synthase activity in submerged seedlings decreased to less than 40 % of that of the control seedlings and was accompanied by a significant reduction in the amount of beta-1,3 : 1,4-glucan in the cell walls. Under water, the expression of CslF6 was reduced to less than 20 % of the unsubmerged control. Bubble aeration partially restored both beta-1,3 : 1,4-glucan synthase activity and the expression of CslF6 under water, correlating with suppression of the submergence-induced elongation growth of coleoptiles.nnnCONCLUSIONSnSubmergence down-regulates the expression of the CslF6 gene, leading to a decreased level of beta-1,3 : 1,4-glucan synthase activity. Together with the increased activity of beta-1,3 : 1,4-glucan hydrolases, the decreased activity of beta-1,3 : 1,4-glucan synthase contributes to the decrease in the amount of beta-1,3 : 1,4-glucan in the cell walls under water. The suppression of beta-1,3 : 1,4-glucan synthesis under water may be mainly due to oxygen depletion.