Volenec J J, Boyce P J, Hendershot K L
Department of Agronomy, Purdue University, West Lafayette, Indiana 47907.
Plant Physiol. 1991 Jul;96(3):786-93. doi: 10.1104/pp.96.3.786.
Our objective was to identify amylases that may participate in starch degradation in alfalfa (Medicago sativa L.) taproots during winter hardening and subsequent spring regrowth. Taproots from field-grown plants were sampled at intervals throughout fall, winter, and early spring. In experiment 1, taproots were separated into bark and wood tissues. Concentrations of soluble sugars, starch, and buffer-soluble proteins and activities of endo- and exoamylase were determined. Starch concentrations declined in late fall, whereas concentrations of sucrose increased. Total amylolytic activity (primarily exoamylase) was not consistently associated with starch degradation but followed trends in soluble protein concentration of taproots. This was especially evident in spring when both declined as starch degradation increased and shoot growth resumed. Activity of endoamylase increased during periods of starch degradation, especially in bark tissues. In experiment 2, a low starch line had higher specific activity of taproot amylases. This line depleted its taproot starch by late winter, after which taproot sugar concentrations declined. As in experiment 1, total amylolytic activity declined in spring in both lines, whereas that of endoamylase increased in both lines even though little starch remained in taproots of the low starch line. Several isoforms of both amylases were distinguished using native polyacrylamide electrophoresis, with isoforms being similar in bark and wood tissues. The slowest migrating isoform of endoamylase was most prominent at each sampling. Activity of all endoamylase isoforms increased during winter adaptation and in spring when shoot growth resumed. Endoamylase activity consistently increased at times of starch utilization in alfalfa taproots (hardening, spring regrowth, after defoliation), indicating that it may serve an important role in starch degradation.
我们的目标是鉴定在苜蓿(紫花苜蓿)主根冬季硬化及随后春季再生长过程中可能参与淀粉降解的淀粉酶。在整个秋季、冬季和早春期间,定期采集田间种植植株的主根。在实验1中,将主根分为韧皮部和木质部组织。测定了可溶性糖、淀粉、缓冲液可溶性蛋白的浓度以及内切淀粉酶和外切淀粉酶的活性。淀粉浓度在秋末下降,而蔗糖浓度上升。总淀粉酶活性(主要是外切淀粉酶)与淀粉降解并无始终一致的关联,而是遵循主根可溶性蛋白浓度的变化趋势。这在春季尤为明显,此时随着淀粉降解增加和地上部生长恢复,二者均下降。内切淀粉酶活性在淀粉降解期间增加,尤其是在韧皮部组织中。在实验2中,一个低淀粉品系的主根淀粉酶比活性较高。该品系在冬末时主根淀粉耗尽,此后主根糖浓度下降。与实验1一样,两个品系的总淀粉酶活性在春季均下降,而内切淀粉酶活性在两个品系中均增加,尽管低淀粉品系的主根中几乎没有淀粉残留。使用非变性聚丙烯酰胺电泳区分了两种淀粉酶的几种同工型,韧皮部和木质部组织中的同工型相似。内切淀粉酶迁移最慢的同工型在每次采样时最为突出。在冬季适应期间以及春季地上部生长恢复时,所有内切淀粉酶同工型的活性均增加。苜蓿主根在淀粉利用时(硬化、春季再生长、去叶后)内切淀粉酶活性持续增加,表明它可能在淀粉降解中起重要作用。
