pod blight

The results showed that five bands including POD-1, POD-2, POD-3, POD-4 and POD-5 were detected in the gel of POD as well as EST-1, EST-2, EST-3, EST4 and EST-5 for EST. POD-3 and POD-4 were common in all the tissues, but most intensive in F. tartaricum. POD-2 was only discovered in the leaves of F. cymosum and caudex of F. cymosum 1. Although there was some difference between the location, POD-2 appeared in the caudexes of three buckwheat and root of F. tartaricum. POD-5 was detected in all leaves and caudx of F.

结果显示，POD和EST都检测到5条谱带，包括POD-1，POD-2，POD-3，POD-4及POD-5，其中POD-3及POD-4在所有组织中都存在，但在苦荞麦1号中的带最强；POD-1只在金荞麦叶片及金荞麦1号茎中出现；POD-2在茎组织及苦荞麦1号根中存在，但在金荞麦及苦荞麦中的位置不同；POD-5存在于叶片及苦荞麦1号茎中，在苦荞麦的带较强。

The results showed that POD activity increased at first and then decreased in the skin and flesh of root. The peak occurred at 40 d and 60 d in the skin and flesh, respectively. POD activity in the skin was higher than that in the flesh at 30 d and then contrary results were observed. The higher POD activity was, the more POD isoenzyme was. The pattern of POD isoenzymes was different between skin and flesh at different vegetative growth stages. POD isoenzymes in the skin were composed of five monomers and four dimers while five dimers or two monomers, two dimers and one tetramer in the flesh. POD isoenzymes in the root were mainly acidic. POD localized mainly in the cell walls of periderm, cambium, xylem ray, xylem vessels and primary xylem.

结果显示，心里美萝卜营养生长期肉质根的皮和肉中POD活性均先升高后降低，分别在播种后第40 d和60 d出现峰值，30 d时皮中POD活性高于肉，之后则相反，酶活性最高时同工酶数目也最多，不同时期，皮和肉中同工酶种类不同；皮中POD同工酶由5个单体和4个二聚体组成，而肉中由5个二聚体或2个单体、2个二聚体和1个四聚体组成，均以酸性同工酶为主；组化定位显示POD主要分布在肉质根的周皮、形成层、木射线、木质部导管和肉的初生木质部等的细胞壁附近。

The above facts indicated that silicon accumulation in the rice leaf sheath inside, the leaf surface and the sclerenchymatous cell, played the physical barrier role, delayed the hypha of sheath blight expansion.5、Analysing the physiological and biochemical mechanism of the resistance to rice sheath blight improved by silicon application in several respects.(1) After being inoculated with R.solani, O2 and POD activities disordered, CAT activities obviously declined. O2 producingvelocity in 91SP\'s leaves and leaf sheaths of Si+ rice plants were lower than those of Siriceplants, MDA content in leaves and leaf sheaths of Si+ rice plants were lower thanthose of Si- rice plants significantly in three days after inoculating, SOD、POD、CATactivities in leaf sheaths of Si+ rice plants were higher than those of Si- rice plantssignificantly in one day after inoculating, SOD、POD、CAT activities in leaves ofSi-treatment were higher than those of Si- rice plants significantly in three days afterinoculating. O2 producing velocity and MDA content in Lemont\'s leaves and leafsheaths of Si+ rice plants were lower than those of Si- rice plants significantly afterinoculating, and SOD、POD、CAT activities of Si+ rice plants were higher than those ofSi- rice plants significantly.

说明硅在水稻叶鞘内侧、叶表和厚壁细胞积累，起到了物理屏障的作用，延缓了纹枯病菌的扩展。5、阐明了施硅增强水稻抗纹枯病的生理生化机制(1)接种纹枯病菌后，两个水稻品种91SP和Lemont的叶鞘和叶片超氧阴离子自由基O2性紊乱，CAT活性明显下降；抗病品种91SP叶鞘和叶片施硅处理的O2产生速率小于缺硅处理，叶鞘和叶片MDA含量在接种第3 d后显著低于缺硅处理，叶鞘SOD、POD、CAT活性在接种1 d后一直显著高于缺硅处理，叶片SOD、POD、CAT活性在接种3 d后显著高于缺硅处理；感病品种Lemont叶鞘和叶片施硅处理的O2产生速率、MDA含量始终显著小于缺硅处理，SOD、POD、CAT活性始终显著大于缺硅处理。

pod assembly：推进包(包括螺旋桨传动

pod assembly 推进包 | pod assembly 推进包(包括螺旋桨传动 | pod cooling unit 舱内冷却装置

pod rot：荚果腐病

pod propulsion ==> 吊舱式推进器/发动机 | pod rot ==> 荚果腐病 | pod test in green house ==> 冬季盆栽试验

pod test in green house：冬季盆栽试验

pod rot ==> 荚果腐病 | pod test in green house ==> 冬季盆栽试验 | pod wall ==> 荚皮