Takahashi Koji, Hirata Shinya, Kido Nobuo, Katou Kiyoshi
Laboratory of Plant Growth Physiology, Graduate School of Science, Nagoya University, Nagoya, 464-8602 Japan.
Plant Cell Physiol. 2006 Nov;47(11):1520-9. doi: 10.1093/pcp/pcl017. Epub 2006 Sep 30.
The wall-yielding properties of cell walls were examined using frozen-thawed and pressed segments (FTPs) obtained from the elongation zones of cucumber hypocotyls with a newly developed programmable creep meter. The rate of wall extension characteristically changed depending on both tension and pH. By treatment of the FTPs with acid, the yield tension (y) was shifted downward and the extensibility (phi) was increased. However, the downward shift of y was greatly suppressed and the increase in phi was partly inhibited in boiled FTPs. The boiled FTPs reconstituted with expansin fully recovered the acid-induced downward y shift as well as the increase in phi. Even under the tension below y, wall extension took place pH dependently. Such extension was markedly slower (low-rate extension) than that under the tension above y (high-rate extension). At a higher concentration (8 M), urea markedly inhibited the creep ascribable to the inhibition of the acid-induced downward y shift and increase in phi. Moderate concentrations (2 M) of urea promoted wall creep pH dependently. The promotion was equivalent to a 0.5 decrease in pH. The promotion of creep by 2 M urea was observed in boiled FTPs reconstituted with expansin but not in boiled FTPs. These findings indicated that the acid-facilitated creep was controlled by y as well as in cucumber cell walls. However, y and phi might be inseparable and mutually related parameters because the curve of the stress extension rate (SER) showed a gradual change from the low-rate extension to the high-rate extension. Expansin played a role in pH-dependent regulation of both y and phi. The physiological meaning of the pH-dependent regulation of wall creep under different creep tensions is also discussed with reference to a performance chart obtained from the SER curves.
使用从黄瓜下胚轴伸长区获得的冻融压榨段(FTPs),通过新开发的可编程蠕变仪来检测细胞壁的壁屈服特性。壁伸展速率根据张力和pH值的变化呈现出典型的改变。用酸处理FTPs后,屈服张力(y)向下移动,伸展性(phi)增加。然而,在煮沸的FTPs中,y的向下移动受到极大抑制,phi的增加也部分受到抑制。用扩展蛋白重构的煮沸FTPs完全恢复了酸诱导的y向下移动以及phi的增加。即使在低于y的张力下,壁伸展也会依赖pH值发生。这种伸展明显比在高于y的张力下(高速率伸展)的伸展慢(低速率伸展)。在较高浓度(8M)下,尿素显著抑制了归因于酸诱导的y向下移动和phi增加的蠕变。中等浓度(2M)的尿素依赖pH促进壁蠕变。这种促进作用相当于pH值降低0.5。在用扩展蛋白重构的煮沸FTPs中观察到2M尿素对蠕变的促进作用,但在未重构的煮沸FTPs中未观察到。这些发现表明,酸促进的蠕变在黄瓜细胞壁中受到y以及其他因素的控制。然而,y和phi可能是不可分割且相互关联的参数,因为应力伸展速率(SER)曲线显示从低速率伸展到高速率伸展是一个逐渐变化的过程。扩展蛋白在y和phi的pH依赖性调节中发挥作用。还参考从SER曲线获得的性能图表讨论了在不同蠕变张力下壁蠕变pH依赖性调节的生理意义。
