丝裂素活化蛋白激酶参与内皮素刺激的兔主动脉平滑肌细胞增生

内皮素（ｅｎｄｏｔｈｅｌｉｎ,ＥＴ）是已知的体内活性最强的缩血管物质,其缩血管作用由Ｇ蛋白偶联受体所介导。但ＥＴ强大的促血管平滑肌细胞（ＶＳＭＣ）增生效应的机理尚未完全阐明。本研究选用培养的兔胸主动脉ＶＳＭＣ,探讨丝裂素活化蛋白激酶（ＭＡＰＫ）在ＥＴ促细胞增生中的作用。结果表明：ＥＴ－１呈时间和浓度依赖性地促进细胞摄取￣３Ｈ－ＴｄＲ和激活ＭＡＰＫ,此作用可被蛋白激酶Ｃ（ｐｒｏｔｅｉｎｋｉｎａｓｅＣ,ＰＫＣ）抑制剂Ｓｔａｕｒｏｓｐｏｒｉｎｅ（ＳＴＰ）,Ｈ－７和ＥＴ＿Ａ受体拮抗剂ＢＱ１２３所抑制,但不被酪氨酸激酶抑制剂ＨｅｒｂｉｍｙｃｉｎＡ（Ｈｅｒｂ）所抑制,用ＰＫＣ激动剂ＰＭＡ（Ｐｈｏｒｂｏｌｍｙｒｉｓｔａｔｅａｃｅｔａｔｅ）预处理ＶＳＭＣ,使其ＰＫＣ活性下调,可显著减弱ＥＴ－１对ＭＡＰＫ的激活能力。本结果提示：（１）ＭＡＰＫ参与ＥＴ－１所致的ＶＳＭＣ增生;（２）ＥＴ－１促细胞增生与激活ＭＡＰＫ的作用是由ＥＴ＿Ａ受体和ＰＫＣ介导的。     

急性低氧对大鼠血液中儿茶酚胺及血小板聚集性的影响

健康ＳＤ雄性大鼠,体重２５０－３００ｇ,麻醉、气管插管,用人工呼吸机经气袋供气,自发吸入氧浓度为９％的氧氮混合气,用高效液相色谱－电化学联合检测法及电阻法检测循环血液中儿茶酚胺及全血血小权聚集性的动态变化。结果：急性低氧１５ｍｉｎ时血液中肾肾上腺素（Ａ）浓度及全血血小板聚集性显著增加（Ｐ〈０．０１）,而去甲肾上腺素（ＮＡ）浓度虽有所增加,但无统计学意义（Ｐ〉０．０５）;复氧１５ｍｉｎ时血液中儿茶酚     

团藻目新资料

本文报道湖北省武汉市团藻目7个属的5个新种,2个新变种,2个中国新记录。     

细胞外Ca^2＋内流入胞质的机制

细胞外Ｃａ＾２＋主要是通过塌压依赖性Ｃａ＾２＋通道和钙池耗竭依赖性Ｃａ＾２＋通道而内流的。前者主要见于电兴奋细胞,这一过程比较清楚;后者主要见非兴奋细胞,情况远较复杂：外来信号激活内贮钙池,钙池在释放Ｃａ＾２＋同时通过目前尚不清楚的途径将直接或间接传至质膜Ｃａ＾２＋通道,而诱发Ｃａ＾２＋内流。     

小麦与玉米及鸭茅状摩擦禾远缘杂交的胚发育过程中同工酶和蛋白质的变化

通过比较小麦与玉米及鸭茅状摩擦禾属间杂交获得的胚与小麦正常自交的胚之间在不同发育时期过氧化物酶和酯酶的同工酶谱,发现过氧化物酶同工酶表现出时空顺序的特异性变化。在同一发育时期,远缘杂交的具胚子房和无胚子房之间存在过氧化物酶同工酶谱的差异,这可能涉及到与胚发育相关的同工酶的出现。远缘杂交的具胚子房和正常自交的小麦子房之间也有一定的酶谱差异。同时,同一材料还表现出不同发育时期的过氧化物酶酶谱差别。在远缘杂交后的胚发育期间,酯酶同工酶的时空表达不如过氧化物酶显著。此外,对远缘杂交后的胚中的水溶性蛋白质进行了SD S-PAGE分析,初步的分析结果表明,可能存在与胚发育相关的蛋白质。     

菜用大豆产量相关性状的遗传分析

对 19个菜用大豆品种与产量有关的10个农艺性状进行遗传分析的结果表明,生育期和主茎节数遗传力偏高;单株荚数、分枝数遗传力偏低;单株产量、单株荚数的遗传变异系数很大,其遗传进度的值也较大;生育期的遗传变异系数小, 遗传进度也小,遗传相关分析结果表明,产量与生育期、单株结荚数相关关系密切。菜用大豆遗传参数分析结果与前人对食用大豆的研究结果趋势一致。     

滇产薄荷的化学研究

研究了滇产３８个薄荷样品,测定了样品的得油率及化学成分。滇产薄荷的得油率在０．１８％￣０．５２％之间。从挥发油中鉴定出了１００多种化学成分,主要含醇、酮、酯、萜烯类化合物。栽培的家薄荷挥发油富含香芹酮、柠檬烯,其化学分类属于香芹酮系列。野生薄荷挥发油富含薄荷醇和薄荷酮,属于薄荷酮系列;部分野薄荷样品,富含香芹酮、环氧辣薄荷烯酮或芳樟醇,属于混合系列。     

Altered drug translocation mediated by the MDR protein: Direct,indirect, or both?

Overexpression of the MDR protein, or p-glycoprotein (p-GP), in cells leads to decreased initial rates of accumulation and altered intracellular retention of chemotherapeutic drugs and a variety of other compounds. Thus, increased expression of the protein is related to increased drug resistance. Since several homologues of the MDR protein (CRP, ltpGPA, PDR5, sapABCDF) are also involved in conferring drug resistance phenomena in microorganisms, elucidating the function of the MDR protein at a molecular level will have important general applications. Although MDR protein function has been studied for nearly 20 years, interpretation of most data is complicated by the drug-selection conditions used to create model MDR cell lines. Precisely what level of resistance to particular drugs is conferred by a given amount of MDR protein, as well as a variety of other critical issues, are not yet resolved. Data from a number of laboratories has been gathered in support of at least four different models for the MDR protein. One model is that the protein uses the energy released from ATP hydrolysis to directly translocate drugs out of cells in some fashion. Another is that MDR protein overexpression perturbs electrical membrane potential () and/or intracellular pH (pH_i) and therebyindirectly alters translocation and intracellular retention of hydrophobic drugs that are cationic, weakly basic, and/or that react with intracellular targets in a pH_i, or -dependent manner. A third model proposes that the protein alternates between drug pump and Cl^– channel (or channel regulator) conformations, implying that both direct and indirect mechanisms of altered drug translocation may be catalyzed by MDR protein. A fourth is that the protein acts as an ATP channel. Our recent work has tested predictions of these models via kinetic analysis of drug transport and single-cell photometry analysis of pH_i, , and volume regulation in novel MDR and CFTR transfectants that have not been exposed to chemotherapeutic drugs prior to analysis. This paper reviews these data and previous work from other laboratories, as well as relevant transport physiology concepts, and summarizes how they either support or contradict the different models for MDR protein function.