Effects of Weak Light on the Ultrastructural Variations of Phloem Tissues in Source Leaves of Three-Year-Old Nectarine Trees(Prunus persica L.var. nectarina Ait.)

Leaves from three_year_old solar greenhouse nectarine trees ( Prunus persica L. var. nectarina Ait. “Zao Hong Yan”) were used as materials in this study. It was the first time that the ultrastructural characteristics of phloem tissues of source leaves were observed and compared in normal and weak light intensities using the transmission electron microscopy. Results showed that the average diameters of companion cells (CC) and sieve elements (SE) of all kinds of veins were bigger in normal than that in weak light intensity, indicating that light could influence the cell development and growth. Dense cytoplasm with abundant mitochondria, endoplasmic reticulums, multivesicular bodies, vesicles and plastids were observed in normal light intensity. On the contrary, CC with small vacuolar structures and few mitochondrias, endoplasmic reticulums were shown in weak light. Misalignment of grana thylakoid margins of nectarine leaves also was seen in weak light. The sieve pores of SEs were obstructed in weak light. Chloroplasts with numerous starch grains and few mitochondrias were noticed in the mesophyll cell (MES) surrounding the bundle sheath in weak light. The storage of starch grains appeared to result from an unbalance between photosynthate production and export of photosynthates. This observation provided a strong support to the point that most leaves export the most of assimilates in the light time. Plasmodesmal densities between SE/CC, CC/PP (phloem parenchyma cell), PP/PP and PP/BSC (bundle_sheath cell) decreased in weak light. Plasmodesmata were observed between CC/SE (NS) (nacreous_walled sieve element), PP/BSC in branch veins in normal light intensity, but not in weak light. Thus apoplasmic pathway may be the main mode of transport of assimilates in weak light, however symplasmic pathway may be the main mode of transport of assimilates in normal light intensity. These results demonstrated that the solar greenhouse nectarine trees could be adapted to the weak light via the ultrastructure variation of phloem tissues of the source leaves.

灵武长枣果实维管束韧皮部及周围细胞的超微结构特征

为了探讨灵武长枣果实光合同化物韧皮部卸载和运输的途径,该研究采用透射电镜技术,对不同发育时期灵武长枣果实维管束韧皮部及其周围薄壁细胞的超微结构特征进行了分析。结果表明:筛管/伴胞复合体及其周围韧皮薄壁细胞间在果实膨大前期富含胞间连丝,而韧皮薄壁细胞与周围库细胞以及相邻库细胞间几乎不存在胞间连丝,形成共质体隔离;筛管/伴胞复合体及其与周围薄壁细胞间在果实快速膨大期也存在胞间连丝,但与果实膨大前期相比明显减少;果实着色期,SE/CC复合体及其与周围薄壁细胞间胞间连丝较少,并且出现阻塞现象;果实完熟期,筛管和伴胞之间几乎没有胞间连丝,有的筛管之间有少量胞间连丝,但却出现了阻塞现象,果肉库薄壁细胞与韧皮薄壁细胞间因胞间连丝阻塞现象而形成共质体隔离。综上结果认为,在果实发育的膨大前期阶段,光合同化物以共质体途径经筛分子卸出,卸出后可能以质外体途径进入液泡贮藏与利用;果实快速膨大期,光合同化物的卸出与运输采用共质体和质外体共存的途径;果实着色期和完熟期,光合同化物从筛分子卸出到贮藏薄壁细胞的运输均以质外体途径为主。

冬枣果实韧皮部及其周围薄壁细胞的超微结构观察和功能分析

利用透射电镜技术,对发育过程中的冬枣果实韧皮部及周围薄壁细胞的超微结构进行了观察研究。结果表明,果实发育早期筛管伴胞复合体与周围薄壁细胞之间存在少量胞间连丝,发育中期胞间连丝数量有所增加,筛分子和伴胞间及韧皮薄壁细胞间存在丰富的胞间连丝,显示了从筛管伴胞复合体卸出到周围薄壁细胞的同化物的卸载路径可能发生了变化。果实发育的各个时期伴胞胞质致密,富含线粒体、内质网和高尔基体,液泡化程度不等;果实发育前期,筛分子伴胞复合体与邻近的薄壁细胞质膜存在囊泡结构,果实韧皮部薄壁细胞胞质中含有丰富的线粒体、内质网、高尔基体、多泡体和小囊泡,到后期线粒体开始降解,显示了伴随果实发育薄壁细胞内的物质代谢和运转功能经历了由活跃到下降的过程。

杨树筛管/伴胞复合体细胞程序性死亡的超微结构分析

利用电镜技术研究美洲黑杨次生韧皮部筛管和伴胞发育过程中细胞超微结构的动态变化,观察到筛管和伴胞由同一个次生韧皮部衍生细胞分裂分化形成。筛管的发育历经未成熟期、成熟期和衰退期的变化。未成熟期筛管分子表现为细胞的径向扩展、壁的增厚、筛管质体和P-蛋白质的产生;成熟期筛管分子细胞组分发生选择性自溶,细胞核核质弥散状,核膜不清晰,或核膜清晰而核物质降解,最后细胞核完全解体转化为P-蛋白质类的物质;衰退期筛管分子细胞质完全解体消失,失去功能。在筛管成熟期间,伴胞的细胞质较浓,内含丰富的核糖核蛋白体、线粒体等细胞器,与筛管相连的细胞壁上具有胞间连丝。随着筛管功能的衰退,伴胞表现出典型的细胞程序性死亡特征,细胞质内质网库槽膨大,细胞核核周腔出现,染色质凝聚边缘化,最后细胞完全解体消失。总之,美洲黑杨次生韧皮部筛管发育首先经历了细胞去核化的过程,在维持一段时间的生理功能后细胞质逐渐解体消失,与此同时伴胞细胞核、细胞质降解。笔者推测筛管与伴胞一起作为功能复合体共同完成各自的细胞程序性死亡过程。

金黄色葡萄球菌肠毒素基因与MLST及spa分子克隆相关性研究

目的检测不同来源金黄色葡萄球菌18种肠毒素基因(se)携带率,并进行spa分型,研究se基因在MLST、spa分子克隆中的分布特征。方法对518株不同来源金黄色葡萄球菌分离株进行spa分型及肠毒素基因测定,同时对其中250株进行MLST分子分型并分析其与spa型别的关系。结果 518株金黄色葡萄球菌中,有7个基因sea、seb、seg、seo、sem、seq和sel出现的频率最高,共形成115个不同基因簇(谱)。人源、动物源和食源性菌株se基因携带状况与环境源菌株有较大差异。食源和人源分离株经典se基因sea、seb、sec、sed、see携带率显著高于动物源分离株,而人源、动物源和食源株的egc基因簇基因seg、sei、sem、sen、seo和/或selu携带率相似。大约78%的菌株可以spa分型并产生103种spa型。所有克隆复合体(CC)239菌株主要的spa型为t030和t037,与sea-sek-seq基因簇高度相关。而CC630菌株主要spa型为t4547、t2196和t377,只携带少数se基因。egc基因簇主要存在于CC5、CC9、CC1281、CC1301和ST25中。结论不同来源金黄色葡萄球菌肠毒素基因携带状况及多样性与其分子克隆ST克隆、CCs、spa型别高度相关;非经典肠毒素基因是人类食物中毒的新的潜在危害。

ABA信号转运调节的基因表达与源库动力学分析

通过对拟南芥NCED3、AAO3及SDR1蛋白亚细胞定位分析及根系和叶片ABA池的动态库变化研究,结果表明气孔运动的有效ABA信号来自于保卫细胞之外,SDR与ABA前体加工和运输有关。胁迫处理后根系合成酶基因转录水平显著高于叶片,但叶片ABA水平是根系的10倍以上,离体叶片和附体叶片ABA含量测定表明,叶片ABA池的形成主要决定于根源ABA的输入。氟啶酮药剂阻断和遮荫实验说明根系ABA池受叶源类胡萝素前体供应影响。叶片ABA水平受根源ABA和叶源类胡萝素前体库双向转运调节,维管束组织系统可能协同和整合了这一复杂调节机制。该结论为逆境ABA信号转递机制研究和操纵内源ABA含量增强植物抗逆性的应用提供相关资料。