1) intracellular degradation

胞内降解
2) Intracellular proteolysis

细胞内蛋白质降解
4) cell wall degrading enzymes

胞壁降解酶
1.
Damage of cell wall degrading enzymes produced by Rhizoctonia solani to rice tissue and cells;
纹枯病菌胞壁降解酶对水稻组织和细胞的破坏作用
2.
The cell wall degrading enzymes(CWDEs) such as polygalacturonase(PG),cellulase(Cx),pectin methylgalacturonase(PMG),polygalacturonic acid trans-eliminase(PGTE) and pectin methyl trans-eliminase(PMTE) were produced in improved Marcus′s medium by Rhizoctonia solani Kühn causing rice sheath blight.
水稻纹枯病菌(Rhizoctonia solaniKühn)在改良的Marcus培养液中能产生多聚半乳糖醛酸酶(PG)、纤维素酶(Cx)、果胶甲基半乳糖醛酸酶(PMG)、多聚半乳糖醛酸反式消除酶(PGTE)和果胶甲基反式消除酶(PMTE)5种胞壁降解酶,其中PG、Cx和PMG活性较高,而PGTE和PMTE活性很低。
3.
In order to enhance rice resistance against fungal pathogens by applying the synergistic interaction of different cell wall degrading enzymes from Trichoderma, three different cell wall degrading enzyme genes from Trichoderma harzianum P1 were placed respectively downstream of Act1 promoter.
为提高水稻的抗病性,利用哈茨木霉(Trichodermahazianum)P1菌株的3个胞壁降解酶基因ech42、nag70与gluc78构建了7个植物表达载体,每个基因受独立的Act1启动子调控。
5) cell wall decomposabili

细胞壁降解
1.
On the base of brief intruduction of physiology and molecular biology in fruit maturation, advances in controlling fruit maturation, including controlling cell wall decomposability, ethylene and pigment biosynthesis with antisense RNA technology at home and abroad are dealt with in details, meanwhile, the prospects are preliminarily discussed.
简要回顾反义 RNA技术的产生与发展 ;并在介绍果实成熟的生理学和分子生物学的基础上 ,着重综述利用反义 RNA技术控制果实成熟 ,包括控制乙烯产生、细胞壁降解、色素生物合成等 3个方面的国内外研究进展 ,并对今后的研究方向进行了初步探讨 。
补充资料:可降解淀粉微球和生物降解白蛋白微球阻滞法
可降解淀粉微球和生物降解白蛋白微球阻滞法
介入放射学技术。介入性局部化疗之前,把二者注入靶动脉,可暂时减少动脉血流,再行化疗药物灌注,以减少血液冲刷,保持局部化疗药物浓度的技术。与其他中期和长期栓塞微球不同,DSM和BAM仅造成数十分钟的血流量减少,待其被降解后血流可恢复至以前水平。
说明:补充资料仅用于学习参考,请勿用于其它任何用途。
参考词条