黑龙江省北五味子一新变种

本文发表了黑龙江省产北五味子一新变种：白果五味子     

细叶黄芪叶肉原生质体发育早期几种细胞器的变化

在细叶黄芪叶肉原生质体发育早期,细胞器的变化较大。离体培养4h后,线粒体的嵴和基质物质开始增加。培养3—5天后,线粒体的数量增加5倍以上,此时可见大部分线粒体围绕细胞核分布。在培养24h后,高尔基体开始发育,它们主要分布在细胞质周边区域。多糖细胞化学染色表明,高尔基体内沉积着大量嗜银物质。培养1天后,粗面内质网开始发育。培养3天时,部分叶绿体边缘出现一些空隙结构。随着叶绿体内膜结构的消失,淀粉粒增大,叶绿体逐渐转变为造粉质体。     

腺苷及其类似物对猪血小板肌动蛋白聚合的抑制作用及可能机理

凝血酶和ADP刺激血小板肌动蛋白的聚合,腺苷、5′-氯-5′-脱氧腺苷及2′-脱氧腺苷抑制凝血酶和(或)ADP诱导的肌动蛋白聚合;腺苷和5′-氯-5′-脱氧腺苷对磷脂酰肌醇的磷酸化有抑制作用,且呈剂量效应关系;腺苷对凝血酶刺激的血小板中肌醇二磷酸的生成有抑制作用。本实验提示腺苷及其类似物对肌动蛋白聚合的抑制作用可能与它们对肌醇磷脂转换的抑制有关。     

人肝刺激因子对大鼠实验性慢性肝损伤的保护作用

从健康孕妇水囊引产４─６个月龄的胎儿取肝,采用ＬａＢｒｅｃｑｕｅ方法提取人肝刺激因子（ｈＨＳＳ）。经３Ｈ－胸腺嘧啶核苷参入肝ＤＮＡ法测定其生物活性。表明此ｈＨＳＳ可刺激肝细胞ＤＮＡ合成。采用皮下注射ＣＣｌ４和饮用１０％乙醇来制备慢性肝损伤动物模型,观察了ｈＨＳＳ的保护肝脏作用。结果表明：ｈＨＳＳ可使ＣＣｌ４－乙醇所致慢性肝损伤大鼠的死亡率、血清谷丙转氨酶水平、肝组织中羟脯氨酸含量的升高以及肝组织中丙二醛的含量降低。肝组织切片表明：ｈＨＳＳ能减轻肝组织的损伤程度,促进肝细胞再生,并能明显防止肝纤维化的形成和发展。可见,ｈＨＳＳ对ＣＣｌ４－乙醇所致的慢性肝损伤大鼠有明显的保护作用,其机制可能与促进肝细胞再生及抑制肝细胞膜的脂质过氧化有关。     

经颅多普勒超声对80例偏头痛病人的检测分析

经颅多普勒超声波对８０例偏头痛病人与１１０例正常对照组血流速度进行检测．结果发现病例组血流速度异常为８７．５％。根据血流速度改变,本组分为血流速度增快型与血流速度减慢型,这有助于偏头痛的临床诊断。     

“秦油2号”油菜植株内含物与萝卜蚜有翅率的关系

通过对Ｎ、Ｐ、Ｋ不同施肥条件下的“秦油２号”油菜植株内含物等与萝卜蚜有翅率关系的研究,建立了８个数学模型,结果表明可溶性糖、总Ｎ、糖与蛋白质之比和丝氨酸与萝卜蚜有翅率有密切关系,其次是天门冬氨酸、苏氨酸、谷氨酸、甘氨酸、丙氨酸、蛋氨酸、异亮氨酸、亮氨酸、酪氨酸、含水量、水溶性蛋白、酰胺氮和含Ｐ量等．     

用平截末端使大豆根瘤菌苹果酸脱氨酶基因插入失活及电激法转化

本实验用平截末端连接法把卡那霉素抗性基因插入到大豆根瘤菌（Ｂｒａｈｙｒｈ;ｚｏｂｉｕｍｊａｐｏｎｉｃｕｍ）１１０的苹果酸脱氢酶（ｍｄｈ）基因中,致使ｍｄｈ基因失活,再通过电激法把这一重组基因转入大豆根瘤菌（Ｂｒａｈｙｒｈｉｚｏｂｉｕｍｊａｐｏｎｉｃｕｍ）２１４３中,进而探讨ｍｄｈ基因失活对大豆固氮作用的影响。     

不同磷脂和糖脂对莱氏衣原体膜上Mg~（2＋）－ATPase活性的影响

莱氏衣原体膜上Ｍｇ~（２＋）－ＡＴＰａｓｅ用ＤＯＣ溶解后,经Ｓｅｐｈａｒｏｓｅ－６Ｂ和ＤＥＡＥ－ＣｅｌｌｕｌｏｓｅＤＥ－５２离子交换柱,得到了部分纯化的Ｍｇ~（２＋）ＡＴＰａｓｅ,并将此ＡＴＰａｓｅ与不同极性头部的磷脂和膜糖脂重组,研究了不同的极性头部的磷脂和膜糖脂对ＡＴＰａｓｅ活性的影响。此酶的活性不依赖酸性磷脂,ＰＧ、ＤＰＧ、大豆磷脂等明显抑制酶活性,中性磷脂ＤＭＰＣ、ＰＥ、ＰＣ则能增加酶活性,其中尤以非双层脂ＰＥ的作用最为明显。从莱氏衣原体膜上提取的糖脂（ＭＧＤＧ,ＤＧＤＧ）单独和ＡＴＰａｓｅ重组时,酶活性增加并不明显,当ＭＧＤＧ和ＤＧＤＧ以等比例混合时,能大大地增加酶活性。这表明Ｍｇ~（２＋）－ＡＴＰａｓｅ的活性很大程度上与磷脂的表面电荷及磷脂的组成相关。     

Carbohydrate moiety of the Petunia inflata S3 protein is not required for self-incompatibility interactions between pollen and pistil.

For Petunia inflata and Nicotiana alata, which display gametophytic self-incompatibility, S proteins (the products of the multiallelic S gene in the pistil) have been shown to control the pistil's ability to recognize and reject self-pollen. The biochemical mechanism for rejection of self-pollen by S proteins has been shown to involve their ribonuclease activity; however, the molecular basis for self/non-self recognition by S proteins is not yet understood. Here, we addressed whether the glycan chain of the S3 protein of P. inflata is involved in self/non-self recognition by producing a nonglycosylated S3 protein in transgenic plants and examining the effect of deglycosylation on the ability of the S3 protein to reject S3 pollen. The S3 gene was mutagenized by replacing the codon for Asn-29, which is the only potential N-glycosylation site of the S3 protein, with a codon for Asp, and the mutant S3 gene was introduced into P. inflata plants of the S1S2 genotype. Six transgenic plants that produced a normal level of the nonglycosylated S3 protein acquired the ability to reject S3 pollen completely. These results suggest that the carbohydrate moiety of the S3 protein does not play a role in recognition or rejection of self-pollen and that the S allele specificity determinant of the S3 protein and those S proteins that contain a single glycan chain at the same site as the S3 protein must reside in the amino acid sequence itself.