Schlupmann H., Bacic A., Read S. M.
Plant Cell Biology Research Centre, School of Botany, University of Melbourne, Parkville, Victoria 3052, Australia.
Plant Physiol. 1994 Jun;105(2):659-670. doi: 10.1104/pp.105.2.659.
Membrane preparations from cultured pollen tubes of Nicotiana alata Link et Otto contain a Ca2+ -independent (1-3)-[beta]-D-glucan (callose) synthase activity that has a low affinity for UDP-glucose, even when activated by treatment with trypsin (H. Schlupmann, A. Basic, S.M. Read [1993] Planta 191: 470-481). Therefore, we investigated whether UDP-glucose was a likely substrate for callose synthesis in actively growing pollen tubes. Deposition of (1-3)-[beta]-glucan occurred at a constant rate, 1.4 to 1.7 nmol glucose min-1, in tubes from 1 mg of pollen from 3 h after germination; however, the rate of incorporation of radioactivity from exogenous [14C]-sucrose into wall polymers was not constant, but increased until at least 8 h after germination, probably due to decreasing use of internal reserves. UDP-glucose was a prominent ultraviolet-absorbing metabolite in pollen-tube extracts, with 1.6 nmol present in tubes from 1 mg of pollen, giving a calculated cytoplasmic concentration of approximately 3.5 mM. Radioactivity from [14C]-sucrose was rapidly incorporated into sugar monophosphates and UDP-glucose by the growing tubes, consistent with a turnover time for UDP-glucose of less than 1 min; the specific radioactivity of extracted UDP-[14C]glucose was equal to that calculated from the rate of incorporation of [14C]sucrose into wall glucans. Large amounts of less metabolically active neutral sugars were also present. The rate of synthesis of (1-3)-[beta]-glucan by nontrypsin-treated pollen-tube membrane preparations incubated with 3.5 mM UDP-glucose and a [beta]-glucoside activator was slightly greater than the rate of deposition of (1-3)-[beta]-glucan by intact pollen tubes. These data are used to assess the physiological significance of proteolytic activation of pollen-tube callose synthase.
来自烟草(Nicotiana alata Link et Otto)培养花粉管的膜制剂含有一种不依赖Ca2+的(1-3)-β-D-葡聚糖(胼胝质)合成酶活性,该活性对UDP-葡萄糖的亲和力较低,即使在用胰蛋白酶处理激活后也是如此(H. Schlupmann, A. Basic, S.M. Read [1993] Planta 191: 470-481)。因此,我们研究了UDP-葡萄糖是否可能是活跃生长的花粉管中胼胝质合成的底物。在萌发3小时后,来自1毫克花粉的花粉管中,(1-3)-β-葡聚糖以1.4至1.7纳摩尔葡萄糖每分钟的恒定速率沉积;然而,外源[14C]-蔗糖的放射性掺入壁聚合物的速率并不恒定,而是持续增加直至萌发后至少8小时,这可能是由于内部储备的利用减少。UDP-葡萄糖是花粉管提取物中一种显著的紫外线吸收代谢物,1毫克花粉的花粉管中含有1.6纳摩尔,计算得出的细胞质浓度约为3.5毫摩尔。生长中的花粉管将[14C]-蔗糖的放射性迅速掺入单糖磷酸酯和UDP-葡萄糖中,这与UDP-葡萄糖的周转时间小于1分钟一致;提取的UDP-[14C]葡萄糖的比放射性与根据[14C]蔗糖掺入壁葡聚糖的速率计算得出的比放射性相等。还存在大量代谢活性较低的中性糖。用3.5毫摩尔UDP-葡萄糖和β-葡糖苷激活剂孵育的未经胰蛋白酶处理的花粉管膜制剂合成(1-3)-β-葡聚糖的速率略高于完整花粉管中(1-3)-β-葡聚糖的沉积速率。这些数据用于评估花粉管胼胝质合成酶蛋白水解激活的生理意义。