梅PGIP基因的启动子克隆及生物信息学分析

根据梅PGIP基因(GenBank登录号:DQ364056.1)5′端序列设计特异反向引物,利用染色体步行法获得了该基因上游1 037 bp的启动子序列.启动子结构分析表明,梅PGIP基因启动子序列与中国李PGIP基因启动子显著相似,相似度达89%~96%,较中国李PGIP基因启动子多一个100 bp的区段,与水稻和豆的启动子序列均无Blast比对结果.转录调控元件预测结果表明,克隆序列与豆相应序列的保守区存在着能调控抗病基因转录的GT1结合位点.     

2个果梅品种雌蕊分化进程及相关生化指标分析

为了解果梅(Prunus mume Sieb.et Zucc.)雌蕊分化进程及其败育机制,采用石蜡切片法观察了不同时期果梅品种‘龙眼’(‘Longyan’)和‘大嵌蒂’(‘Daqiandi’)花芽纵切面的解剖结构,并对2个品种不同时期花器官发育状况、花芽百分率、花芽纵径和横径以及花芽中的可溶性糖、可溶性蛋白质和淀粉含量进行了测定分析.结果显示:雌蕊分化期、雌蕊分化末期及盛花期,品种‘龙眼’的不完全花比例均显著小于品种‘大嵌蒂’,其中,盛花期‘龙眼’不完全花比例仅为5.0％,而‘大嵌蒂’不完全花比例高达76.3％.品种‘龙眼’雌蕊分化过程经历未分化期、分化初期、分化期及分化末期4个阶段,且最终有95.0％的花芽在分化末期能顺利形成完全花;品种‘大嵌蒂’雌蕊分化过程则包含未分化期、分化初期、分化期、解体期、解体后修复期和分化末期6个阶段,且仅有23.7％的花芽能形成完全花.雌蕊分化的不同阶段2个品种花芽纵径和横径的变化与其分化进程基本一致.品种‘龙眼’完全花的可溶性糖和可溶性蛋白质含量均高于品种‘大嵌蒂’的完全花和不完全花、淀粉含量则低于后两者;品种‘大嵌蒂’不完全花的可溶性糖和可溶性蛋白质含量最低、淀粉含量则最高,与2个品种的完全花有显著差异.综合分析结果表明:品种‘大嵌蒂’的花芽在12月中上旬停止伸长生长、雌蕊分化停滞直至逐渐解体,这一时期即为品种‘大嵌蒂’雌蕊败育的关键时期;导致果梅雌蕊选择性败育的原因可能与花芽中大分子营养物质的分解代谢有关.     

基于AFLP标记的野生梅种质的鉴定

梅Prunus mume是我国原产的名花佳果。为有效保护和利用野生种质资源,文中采用了AFLP标记技术,结合形态表型特征分析,对65份野梅种质进行试验分析。首先从64对引物中筛选出MseⅠ-EcoRⅠ8对引物组合,扩增出1 002条多态性条带。按照Nei’72距离系数进行聚类,在Nei’72=0.26处,可区分西山野梅原变种、西山野梅原种、西山毛梅、厚叶梅、南大坪桃梅、嵩明小梅、曲梗常绿梅、蜡叶梅以及匍匐梅,这与形态学上变种或变型的划分一致。群体内变种单株样本遗传多样性丰富。基于梅花种质资源的遗传变异,建议今后需要对所有变种与变型进行有效的保护。     

梅花‘南京红’花色色素花色苷的分子结构

经特殊颜色反应、纸层析、紫外 -可见光谱、高效液相色谱、气相色谱和核磁共振波谱分析表明 :梅花‘南京红’花色色素的 3种主要花色苷分别是 :花青素 3 氧 (6″ 氧 α 吡喃型鼠李糖基 β 吡喃型葡萄糖 )苷 ,花青素 3 氧 (6″ 氧 没食子酰 β 吡喃型葡萄糖 )苷和花青素 3 氧 (6″ 氧 反式阿魏酰 β 吡喃型葡萄糖 )苷。花青苷在根本上决定着‘南京红’的粉红色花色 ,并可能强化‘南京红’的耐寒能力 ,也奠定了开发和利用该种花色色素的基础。     

理化因子导致梅花'南京红'花色色素的颜色变化

梅花是中国的候选国花之一。属于花色苷的梅花'南京红'花色色素用含1％浓盐酸(v／v)的甲醇提取,并呈现纯净的紫红色。体外试验表明:该色素在pH0-3范围内颜色稳定,因不同光质、热、氧化剂、还原剂、螯合剂而呈现无色、墨绿色或黄绿色,因不同金属离子、离子的不同浓度而呈现程度不同的红色、紫色、黑黄色、红中带黑或微蓝绿色,葡萄糖和低浓度苯甲酸钠几乎不影响其色泽,蔗糖使颜色变淡,柠檬酸却使其颜色变深。该文可为梅花红色花色的机理探索、梅花花色苷的分子结构鉴定、梅花红色花色色素的开发利用提供参考和前提。     

梅树早期落叶原因及预防研究

梅树早期落叶原因及预防研究刘超,吴方正,傅柳松（浙江农业大学环境保护系,杭州３１００２９）ＣａｕｓｅｓｏｆＥａｒｌｙＬｅａｆＦａｌｌｏｆＰｒｕｎｕｓＭｕｍｅａｎｄＭｅｔｈｏｄｆｏｒＩｔｓＰｒｅｖｅｎｔｉｏｎ．￥ＬｉｕＣｈａｏ;ＷｕＦａｎｇｚｈｅｎｇ;...     

Architecture of Alkaline-soluble and Bioactive Polysaccharide from the Kernels of Prunus mume SIEB. et ZUCC. Assessed by Anti P-1 Antibody

P-1 was partially hydrolyzed with 0.01, 0.05, and 0.1 M trifluoroacetic acid (TFA), successively, and the dialyzable (E-1, E-2, and E-3) and non-dialyzable (I-1,I-2, and I-3) fractions were prepared and analyzed chemically and immunochemically. Either I-1 or E-1 reacted with anti P-1 serum as strongly as P-1 and were mitogenic. The cross-reactivity of I-2 and I-3 was less than I-1 with anti P-1 serum. However, they were as mitogenic as I-1. The cross-reactivity of E-2 and E-3 to anti P-1 serum was also very weak, and they were not mitogenic. The E-1 fraction had a similar sugar composition to I-1 and P-1. E-2 was a monosaccharide, all of Ara, and would be from the linkage of furanosyl residues in P-1. The composition of E-3 was free from Ara and the structure of E-3 was similar to that of I-3. E-3 would be considered to be deleted arabinofuranose from E-1. These results suggest that the mitogenic activity measured by the alkaline phosphatase assay is a property of the core part, I-3, but that P-1 contains several epitopes other than the core part by the immunochemical analysis.     

Characterization of a New (R)-Hydroxynitrile Lyase from the Japanese Apricot Prunus mume and cDNA Cloning and Secretory Expression of One of the Isozymes in Pichia pastoris

PmHNL, a hydroxynitrile lyase from Japanese apricot ume (Prunus mume) seed was purified to homogeneity by ammonium sulfate fractionation and chromatographic steps. The purified enzyme was a monomer with molecular mass of 58 kDa. It was a flavoprotein similar to other hydroxynitrile lyases of the Rosaceae family. It was active over a broad temperature, and pH range. The N-terminal amino acid sequence (20 amino acids) was identical with that of the enzyme from almond (Prunus dulcis). Based on the N-terminal sequence of the purified enzyme and the conserved amino acid sequences of the enzymes from Pr. dulcis, inverse PCR method was used for cloning of a putative PmHNL (PmHNL2) gene from a Pr. mume seedling. Then the cDNA for the enzyme was cloned. The deduced amino acid sequence was found to be highly similar (95%) to that of an enzyme from Pr. serotina, isozyme 2. The recombinant Pichia pastoris transformed with the PmHNL2 gene secreted an active enzyme in glycosylated form.     

模拟酸雨对3种果树的胁迫效应

以青梅(Prunus mume Sieb.&Zucc.)、龙眼(Dimocarpus longan Lour.)和杨桃(Averrvhoa carambola L.)3种南方果树为材料,研究不同pH值的模拟酸雨对其生理胁迫的效应.在酸雨胁迫下3种果树的叶片叶绿素含量均随pH值的降低有不同程度的下降,叶片伤害率、细胞质膜透性、脯氨酸及丙二醛(MDA)含量则随pH值的降低而上升.抗性较强的龙眼的生理生化指标的变幅最小,其次是杨桃,对酸雨胁迫反应较敏感的青梅变幅最大.     

梅花"粉皮宫粉"花色色素的花青苷实质和花色的动态变化

特征颜色反应和紫外-可见光谱分析初步表明梅花"粉皮宫粉"的粉红色花色色素为花青素-3-糖苷.用分光光度法检测梅花"粉皮宫粉"不同花发育时期、在树冠不同着生部位花朵花瓣的相对花青苷含量,结果表明"粉皮宫粉" 的花色主要存在着花发育时期而导致的时间变化.花色在蕾期最浓艳,花瓣展开后便逐渐变淡;在整个花发育时期,同一朵花不同层次花瓣的颜色浓淡均为外层花瓣>中层花瓣>内层花瓣,且不同层次花瓣颜色的变化趋势几乎一致.虽然树冠下部单花的花色浓于上部的、树冠内层的浓于外层的,但花朵在树冠的着生部位导致的花色差异并不显著.花青苷除了导致"粉皮宫粉"的粉红花色外,还可能增强其花的抗寒性,为花的凌寒而开创造了条件.本文可为梅花的美学鉴赏、梅花红色花色的机理探索及其色素的分子结构鉴定提供参考.