荧光探针Bis-ANS和磷酸丙糖异构酶的相互作用

研究了极性荧光探针Bis-ANS和磷酸丙糖异构酶的相互作用。我们发现由磷酸丙糖异构酶(TIM)中Trp残基和结合在TIM分子上的Bis-ANS之间的能量传递引起的Trp残基荧光的淬灭呈双相性,表明Bis-ANS在TIM分子上可能有2个不相同的结合位点,其结合的解离平衡常数Kd分别为3.3μM和17.0μM。底物GDP引起已结合的Bis-ANS荧光强度进一步增强和荧光谱的蓝移说明GDP可影响Bis-ANS在TIM分子上结合部位的构象,使其疏水性增强。我们还观察到由于结合在同一TIM分子上的Bis-ANS之间的能量传递引起的退偏振,进一步证明Bis-ANS有2个结合部位在1—2800bar压力范围里,增高压力引起结合在TIM分子上的Bis-ANS荧光进一步增强和光谱蓝移,说明TIM在压力下解离成亚基的过程中发生了Weber提出的"conformationaldrift。     

雄激素对大鼠储精囊分泌蛋白mRNA的调节作用

本文报道了应用DNA重组和分子克隆技术研究雄激素与大鼠储精囊分泌蛋白基因的相互作用。大鼠储精囊总mRNA在逆转录酶作用下合成dsc-DNA,并克隆于pBR322/X1776中。经原位杂交法筛选含有互补于雄激素调节的mRNA的三个克隆株,其中二株经信使选择杂交翻译法证实它们是编码54K和16.6K道尔顿的分泌蛋白质的基因。同时应用后者的cDNA作为探针进一步研究雄激素对处于不同生理态状下的大鼠储精囊mRNA水平的影响。     

地高辛标记反意RNA探针检测脑组织切片生长抑素mRNA

本实验采用含大鼠生长抑素基因的ｐＳＰ６５ｃＤＮＡ质位通过转化至噬菌体内大量扩增,经提取,纯化后,用限制性内切酶进行酶切使质枝线性化,并将其作为模板,用地高辛（ＤｉｇｏｘｉｇｅｎｉｎＤｉｇ）作为标记物,体外转录合成生长抑素反意ＲＮＡ（ｃＲＮＡ）探针。实验动物选用ｗｉｓｔａｒ新生大鼠。冰冻切片,端、间脑切片经杂交前用Ｄｉｇ－ＵＴＰ标记的ｃＲＮＡ探针杂交,杂交后用抗Ｄｉｇ－碱性磷酸酶复合物进行酶联免疫反应。Ｘ－磷酸盐－ＮＢＴ显色。结果显示新生大鼠脑内生长抑素ｍＲＮＡ神经元着紫蓝色。杂交反应物集中于核周的胞浆及短小的突起内。胞核不着色。胞体轮廓清晰,周围背底浅淡。结果表明Ｄｉｇ标记ｃＲＮＡ探针不仅具备非同位素标记探针的优点而且能快速和准确检测组织细胞内ｍＲＮＡ的表达。     

一例智力低下患者7q~ 标记染色体的来源鉴定

以人类染色体显微切割、PCR技术构建的现有人类染色体特异性和染色体区带特异性探针池作为绘画探针,采用正向染色体绘画技术,结合染色体筛查方法,查明了一例7q~ 标记染色体患者的染色体附加片段来源于3q26→3qter。确定该患者的核型为46,XX,-7, der(7)t(7;3)(7pter→7q32::3q26→3qter)。应用这个策略,能够快速有效地鉴定标记染色体的来源。     

改进的免疫胶体铁细胞化学染色

本文以改进的方法制备了胶体铁。该胶体制备简单,稳定性高,易于抗体标记,在PH7.4时,胶体与抗体IgG稳定结合形成胶体抗体复合物的经以CM-Sephadex C-50代替AmberlightCG50进行标记物的纯化,方法可靠,所制备的胶体铁标记抗体用于免疫细胞化学染色,普鲁士蓝反应清晰地显示出标记抗体与相应抗原的特异性结合部位,与传统的免疫酶及免疫金银方法比较,具有敏感性高,背景干净,呈色鲜明等优点,结合免疫酶及免疫金银染色可用于抗原的双标及多标记。     

酶标HBV DNA探针的研制与应用

本实验采用一种非放射性物质——碱性磷酸酶标记乙肝病毒HBV DNA制备分子探针。碱性磷酸酶在苯醌作用下与单链DNA联结,形成DNA和酶的共价复合物,即酶标探针。此探针通过分子杂交与待测DNA结合,与酶的底物作用显色,几小时内可观察结果,其最低检测量约为10pg。用此探针检测乙肝病人血清中的HBV DNA,与~(32)P标记的探针比较,酶标探针可检测出~(32)P标记探针检出率的95.7％。结果表明,所合成的酶标探针具有准确、简便、快速、安全而经济的优点,具有应用前景。     

稻瘟病菌株的DNA指纹分析及小种鉴别

基于对稻瘟病菌(Pyricularia oryzae)基因文库的分析,我们找到了一套含重复顺序的克隆。其中POR6和POR7被证实具有高度的多态性并随机散布于稻瘟病菌生理小种的致病性时,可以获得可分辨的基因组特异的杂交带型。我们还分析了致病性与8个稻瘟病菌株DNA指纹图谱之间的关系,结果表明各个小种组合间的百分相似率S_xy,值与该小种组合间共同侵染的鉴别品种数目有正相关性。     

Penetration of soil aggregates of finite size

Summary Maximum penetrometer pressure was measured on artificial soil aggregates of finite size (2–29 mm) using blunt probes (total cone angle 60°) driven at 3 mm min⁻¹. Maximum penetrometer pressure increased asymptotically with increase in dimensionless aggregate radius,b/a, wherea andb are the probe and aggregate radii, respectively. A theory was developed for penetration of blunt probes into soil aggregates of finite size. The theory assumed that plastic failure occurs out to a radius,R, and that beyond this only elastic straining occurs. This theory can be applied to estimate the radial and tangential stresses adjacent to a blunt probe. The estimated radial and tangential stresses increased with increase in dimensionless aggregate radius,b/a. The radius of the plastic front,R, around the probe is predicted to increase with increased aggregate size. The results also demonstrate the effect of soil shear cohesion and internal friction angle onR. The results are discussed with reference to root penetration.     

Characterization of the first adult de novo case of 46,X,der(Y)t(X;Y)(p22.3;q11.2)

Herein, we describe a case of an infertile man detected in postnatal diagnosis with FISH characterization and array-CGH used for genome-wide screening which allowed the identification of a complex rearrangement involving sex chromosomes, apparently without severe phenotypic consequences. The deletion detected in our patient has been compared with previously reported cases leading us to propose a hypothetical diagnostic algorithm that would be useful in similar clinical situations, with imperative multi disciplinary approach integrated with genetic counseling. Our patient, uniquely of reproductive age, is one of six reported cases of duplication of Xp22.3 (~ 8.4 Mb) segment and contemporary deletion of Yq (~ 42.9 Mb) with final karyotype as follows:

46,X,der(Y),t(X;Y)(Ypter → Yq11.221::Xp22.33 → Xpter).ish der(Y) (Yptel+,Ycen+,RP11-529I21+,RP11-506M9-Yqtel −,Xptel +). arrXp22.33p22.31(702–8,395,963, 8,408,289x1), Yq11.221q12 (14,569,317x1, 14,587,321–57,440,839x0)