单克隆抗体与抗血清联合应用建立血清CMLC测定方法的研究

单克隆抗体(McAb)和抗血清各有特点。本文提纯人心肌肌球蛋白轻链(CMLC)并制备其单克隆抗体和抗CMLC兔血清(下称抗血清),试建立测定血清CMLC的酶联免疫(ELISA)方法。通过比较,McAb和抗血清联合应用可提高测定方法的灵敏度和特异性;并对各反应试剂的工作浓度进行确定,建立了McAb(1C_(11)-D_7株)为铺底抗体,抗血清为覆盖抗体,碱性磷酸酶标记的羊抗兔IgG为第三抗体的三抗体酶联免疫夹心测定血清CMLC的方法(MP-ELISA)。血清CMLC最小可测浓度为2.5ng/mL。     

乌鳢血清免疫球蛋白IgM的分离纯化及其兔抗血清的制备

目的 分离纯化乌鳢血清免疫球蛋白,并制备其兔抗血清。方法 用Protein A亲和层析的方法纯化乌鳢血清免疫球蛋白,通过SDS-聚丙烯酰胺凝胶电泳检测蛋白的纯度,测定其重链、轻链的分子量,免疫大耳白兔制备抗血清,利用免疫双扩散检测抗血清的效价。结果 纯化了乌鳢血清免疫球蛋白,SDS-PAGE测定其重链和轻链的相对分子质量分别为78×10^3和27×10^3左右,免疫双扩散法测定兔抗乌鳢免疫球蛋白抗血清效价为1∶32。结论 成功纯化了乌鳢免疫球蛋白,制备了兔抗乌鳢IgM抗血清,为研究乌鳢的免疫机制、建立乌鳢的血清学检测系统奠定了基础。     

Ezrin多克隆抗体制作及应用

构建Ezrin原核重组表达载体pET-28a(+)-ezrin,将其转化至大肠杆菌BL21(DE3)中,诱导获得Ezrin蛋白,将经镍柱亲和层析纯化后的蛋白分别免疫新西兰大耳兔和昆明小鼠(KM),获得抗血清,采用ELISA和Western blotting,免疫荧光测定其效价和特异性。ELISA对抗血清进行效价测定表明抗血清可与抗原发生特异性免疫反应;通过Western blotting对抗血清进行鉴定表明抗血清可以识别几种细胞株内的特异性条带,其相对分子量为82 kD,与预测分子量相符;免疫荧光试验表明抗血清可以识别细胞内的Ezrin蛋白,且定位情况与文献报道相符。最后通过protein G对抗血清进行了纯化。结果表明用该方法制备的Ezrin多克隆抗体有较高的特异性和灵敏度。     

抗人DR5多克隆抗体的制备与纯化

目的:分离纯化融合蛋白GST-eDR5,免疫小鼠制备抗人DR5多克隆抗体.方法:用GST纯化试剂盒和电泳两次纯化的融合蛋白GST-eDR5免疫小鼠,制备抗CST-eDR5抗血清,然后用GST纯化得到抗人DR5抗血清.通过Westem blot、ELISA方法鉴定抗血清特异性和效价.结果:通过亲和纯化得到了高纯度的融合蛋白GST-eDR5,其浓度为0.65μg/μl.免疫产生的DR5抗血清特异性高,且效价高达1:25600,纯化后的抗人DR5抗血清不再识别GST,只识别人DR5.结论:成功制备了高特异性、高效价的抗人DR5多克隆抗体,为深入研究其对肿瘤细胞的生长抑制和凋亡作用提供了实验工具.     

p16基因的原核表达及抗P16抗血清的制备

采用基因重租技术,将野生型p16 cDNA通过中间载体pVL1392最后载入表达载体pGEX-5T,IPTG诱导重组质粒转化的大肠杆菌,蛋白质印迹证实42×10~3的融合蛋白GST-P16的表达。表达了GST-P16的重组菌经加热破菌后行SDS-PAGE,将GST-P16蛋白条带切下后经反复冻融于皮内多点注射免疫家兔。所收获的兔血清经蛋白质印迹法检测到抗P16抗体滴度为1:625。结果表明通过pGEX-5T融合蛋白表达系统能方便地提供制备抗P16抗血清的免疫原,该免疫原未经纯化并未影响抗P16抗血清的产生。     

黄鳝IgM的分离纯化及兔抗黄鳝IgM抗血清的制备

目的 分离纯化黄鳝血清免疫球蛋白,制备其兔抗血清,并检测抗血清的特异性。方法 用Protein A亲和层析的方法纯化黄鳝血清免疫球蛋白,通过SDS-聚丙烯酰胺凝胶电泳检测蛋白的纯度,免疫大耳白兔制备抗血清,利用免疫双扩散检测抗血清的效价,通过western blotting检测抗血清的特异性。结果 纯化了黄鳝血清免疫球蛋白,免疫双扩散法测定兔抗黄鳝免疫球蛋白血清效价为1∶32,western blotting结果显示抗血清具有很好的特异性。结论 成功纯化了黄鳝免疫球蛋白,制备了兔抗黄鳝IgM抗血清,为建立黄鳝的血清学检测系统奠定了基础。     

兔抗人热激蛋白70样蛋白1多克隆抗体的制备与初步鉴定

目的：制备兔抗人热激蛋白70样蛋白1（HSP70L1）的多克隆抗体并进行初步鉴定。方法：在大肠杆菌中重组表达融合蛋白GST-HSP70L1和His-HSP70L1并纯化;将GST-HSP70L1融合蛋白用于免疫新西兰大耳白兔获得多克隆抗体,用His-HSP70L1对抗血清进行分离纯化,得到抗HSP70L1多克隆抗体,用Western印迹、免疫沉淀对其进行初步鉴定。结果：获得了高表达的GST-HSP70L1和His-HSP70L1重组融合蛋白;纯化获得抗HSP70L1抗体,此抗体可用于Western印迹和免疫沉淀实验。结论：获得了兔抗人HSP70L1的多克隆抗体,为进一步研究HSP70L1的生物功能提供了有用的工具。     

人白血病细胞癌性促凝物(CP)的分离纯化及其特性的初步研究

用三步纯化法从人M_3型白血病细胞中分离纯化出人类肿瘤癌性促凝物(CP)。促凝活性回收率为24％,CP纯化倍数为2481倍。纯化CP在SDS-PAGE上为单一区带,其理化和酶学特性类似于动物肿瘤CP,分子量约为70 000,PI为4.8,在FVⅡ缺乏血浆中以及在含有组织因子(TF)抑制剂情况下仍能激活FX。CP促凝活性能被半胱氨酸蛋白酶抑制剂HgCl_2抑制,纯化CP能与抗动物肿瘤CP抗体形成免疫沉淀反应。     

人copine Ⅴ蛋白多克隆抗体的制备

目的:制备兔抗人copine Ⅴ多克隆抗体.方法:将copineⅤ N端423 bp(626～1 048 bp)构建到原核表达载体pET28a( ),转化大肠杆菌BL21(DE3),在IPTG诱导下进行蛋白表达;以镍柱纯化后的蛋白为抗原,与等体积佐剂混合后免疫家兔3次;用ELISA和Western印迹检测抗血清,用(NH4)2SO4沉淀法初步纯化抗体.结果:表达并纯化了copine Ⅴ N端蛋白,ELISA检测表明抗血清具有高亲和性,Western印迹检测表明抗体能特异性识别内源性和过表达的copine Ⅴ.结论:制备了具有高亲和性和特异性的抗人copine Ⅴ多克隆抗体.     

重组鹦鹉热衣原体主要外膜蛋白的抗原性研究

构建了鹦鹉热衣原体主要外膜蛋白的原核表达载体,并对其进行了诱导表达,经过纯化,复性,获得了重组蛋白。用Westen-blotting和胶体金方法检测,此蛋白具有衣原体的免疫原性。经兔免疫接种实验,获得了多抗血清,用ELISA方法检测,其抗体滴度为1：2000。     

用ELISA法测定抗人心肌肌球蛋白轻链(CMLC)单克隆抗体的K_D值

人心肌肌球蛋白由轻链（ｃａｒｄｉａｃｍｙｏｓｉｎｌｉｇｈｔｃｈａｉｎｓ,ＣＭＬＣ）和重链（ｃａｒｄｉａｃｍｙｏｓｉｎｈｅａｖｙｃｈａｉｎｓ,ＣＭＨＣ）组成．当心肌细胞遭到破坏时,ＣＭＬＣ释放入血,可致血中ＣＭＬＣ浓度增高．血中ＣＭＬＣ的测定是一种高度...     

Mammalian skeletal muscle myosin light chain kinases. A comparison by antiserum cross-reactivity

Purified myosin light chain kinases from skeletal muscle are reported to be significantly smaller (Mr = 75,000-90,000) than the kinases purified from smooth muscle (Mr = 130,000-155,000). It has been suggested that the smaller kinases from striated muscle are proteolytic fragments of a larger enzyme which is homologous, if not identical, to myosin light chain kinase from smooth muscle. Therefore, we have used an antiserum to rabbit skeletal muscle myosin light chain kinase and Western blot analysis to compare the subunit molecular weight of the kinase in skeletal muscle extracts of several mammalian species. In rabbit skeletal muscle, the antiserum only recognized a polypeptide of Mr = 87,000, with no indication that this polypeptide was a proteolyzed fragment of a larger protein. The apparent molecular weights observed in different animal species were 75,000 (mouse), 83,000 (guinea pig), 82,000 (rat), 87,000 (rabbit), 100,000 (dog), and 108,000 (steer). The molecular weight of myosin light chain kinase was constant within an animal species, regardless of skeletal muscle fiber type. The antiserum inhibited the catalytic activity of skeletal muscle myosin light chain kinase. Similar antibody dilution curves for inhibition of myosin light chain kinase activity in extracts were observed for all animal species (rabbit, rat, mouse, guinea pig, dog, cat, steer, and chicken) and different fibers (slow twitch oxidative, fast twitch oxidative glycolytic, and fast twitch glycolytic) tested. The antiserum did not inhibit the activity of rabbit smooth muscle myosin light chain kinase. These results suggest that there may be at least two classes of muscle myosin light chain kinase represented in skeletal and smooth muscles, respectively.     

Purification of a HeLa cell high molecular weight action binding protein and its identification in HeLa cell plasma membrane ghosts and intact HeLa cells

The high molecular weight protein (HMWP) which was previously observed to be a major component of the actin based gels formed by incubating cytoplasmic extracts of HeLa cells at 25 degrees C [Weihing, R. R. (1977) J. Cell Biol. 75, 95-103] has now been purified by gel filtration of 0.6 M KCl extracts of precipitated gels. A few hundred micrograms of HMWP, which is about 90% pure, can be isolated from 4 X 10(9) cells. HMWP can gel muscle actin and cross-link it into filament bundles. Its subunit molecular weight is 250 0000, its Stokes radius is 125 A, and its sedimentation coefficient is 9 S. A native molecular weight of 480 000 was calculated by using the latter two parameters, and therefore the native molecule is a dimer. Its amino acid analysis is nearly indistinguishable from that of macrophage actin binding protein and of mammalian and avian filamins. All of these findings indicate that HMWP is homologous to the latter proteins. However, HeLa cell HMWP and avian filamin must differ in their primary sequences because their partial peptide maps are distinct and because an antiserum against HMWP reacts only weakly with filamin. For studies on the intracellular location of HMWP, a goat antiserum against purified HMWP was prepared and characterized and then used to localize HMWP in suspension grown cells. The technique of immunoblotting revealed that the antiserum reacted virtually exclusively with the high molecular weight polypeptide that comigrates with HMWP in cell lysates and in ZnCl2-stabilized plasma membrane ghosts prepared from HeLa cells [Gruenstein, E., Rich, A., & Weihing, R. R. (1975) J. Cell Biol. 64, 223-234] and that it did not react with rabbit myosin heavy chain, microtubule proteins (MAPS and tubulin) from HeLa cells and calf brain, or the proteins of human erythrocyte ghosts including spectrin. Suspension-grown cells which were stained with the antiserum by the technique of indirect immunofluorescence showed bright fluorescence at the rim of the cells and less intense generalized fluorescence. If preimmune serum or immune serum treated with HMWP was substituted for the immune serum, then staining at the rim was not observed, but the generalized fluorescence was only slightly reduced; unpermeabilized cells were not stained. These results indicate that HMWP is a component of the cortical cytoplasm of HeLa cells. Possible functions of cortical HMWP are discussed briefly.     

C-protein from rabbit soleus (red) muscle.

A new form of skeletal-muscle C-protein has been isolated from rabbit soleus (red) muscle. This new form of C-protein has been purified to homogeneity by a procedure similar to that used to purify C-protein from white skeletal muscle. In soleus muscle, only this new form of C-protein could be detected, whereas in psoas (white) muscle, only the previously identified form of C-protein was detected. The content of C-protein in rabbit soleus muscle is comparable with that found in psoas muscle. Other rabbit skeletal muscles composed of a mixture of fibre types contained at least two forms of C-protein. C-Protein derived from red skeletal muscle bound to myosin isolated from either red or white tissue, with maximum binding occurring at a ratio of approximately 13 microgram of red C-protein/100 microgram of myosin. Polyacrylamide-gel electrophoresis in the presence of sodium dodecyl sulphate indicated that C-protein isolated from red skeletal muscle has a molecular weight approx. 7% greater than that of C-protein isolated from white skeletal muscle. The amino acid content of both forms of C-protein was similar but major differences in the mol % of isoleucine and threonine were found. Antiserum against C-protein from white rabbit skeletal muscle formed a single precipitin line with rabbit C-protein on double in agar. This antiserum did not form a precipitin line when diffused against red C-protein from rabbit skeletal muscle. Also, this antiserum bound specifically to the A-band region of myofibrils isolated from psoas (white) muscle, but it did not bind to myofibrils prepared from soleus (red) muscle.     

Cardiac contractile protein phosphatases. Purification of two enzyme forms and their characterization with subunit-specific antibodies

Two forms of protein phosphatase which dephosphorylate cardiac myosin or myosin light chains and the inhibitory subunit of cardiac troponin were purified from bovine cardiac muscle. The enzymes were composed of subunits of Mr = 63,000, 55,000, and 38,000 in a 1:1:1 molar ratio (PT-1) or Mr = 63,000 and 38,000 in a 1:1 molar ratio (PT-2). Native gel electrophoresis and sucrose gradient sedimentation indicated that activity toward all three substrates was due to a single enzyme species. A monoclonal antibody and polyclonal antiserum directed against an Mr = 38,000 protein phosphatase from this tissue specifically reacted with the Mr = 38,000 subunit of PT-1 and PT-2. The specificity of antibodies for the Mr = 38,000 subunit indicated that it was distinct from the other subunits. The Mr = 63,000 subunits of PT-1 and PT-2 were identical based on mobility on sodium dodecyl sulfate gels and one-dimensional peptide maps. Specificity of antiserum against the Mr = 55,000 subunit of PT-1 showed that this subunit was a distinct protein and not derived from the Mr = 63,000 subunit by proteolysis. PT-2 but not PT-1 could interact with antiserum against the Mr = 38,000 catalytic subunit in competitive immunoassays indicating that the presence of the Mr = 55,000 subunit may alter or mask antigenic site(s). Analysis of the enzymatic properties of PT-1 and PT-2 showed that PT-2 had higher activity with myosin, myosin light chains, and phosphorylase while PT-1 had higher activity with troponin. The results indicate that the presence of the Mr = 55,000 subunit may alter the enzymatic properties of the catalytic subunit.     

Evidence suggesting the presence of common antigenic determinant between dynein and tubulin.

The present experiments showed that the guinea pig antiserum prepared against the main polypeptides of 14 S dynein from Tetrahymena cilia reacted with sea urchin sperm flagellar dynein and with bovine brain high molecular weight protein to give rise to a precipitin line confluent with that formed between the antiserum and Tetrahymena dynein. Furthermore, it was found that this antiserum also reacted with tubulins from Tetrahymena cilia, sea urchin sperm flagella and bovine brain to give rise to the confluent precipitin line. Among muscle proteins, only actin preparation from rabbit skeletal muscle reacted with the anti-Tetrahymena dynein serum, whereas neither rabbit skeletal muscle myosin, chicken skeletal muscle tropomyosin nor chicken skeletal muscle troponin reacted with the antiserum. These results suggest that dynein and tubulin and probably actin share an antigenic determinant regardless of different protein species and of different animal species. The common antigenic determinant was detected only when the proteins denatured with urea/sodium dodecyl sulfate/beta-mercaptoethanol/N-ethylmaleimide were used, but it was not detected at all when the native proteins were used. This implies that a certain common antigenic determinant which is involved in the precipitin line formation exists in the primary structures of dyneins and tubulins and probably actin, and is hidden inside the tertiary structures of the native protein molecules.     

Cytoplasmic myosin from Drosophila melanogaster

Myosin is identified and purified from three different established Drosophila melanogaster cell lines (Schneider's lines 2 and 3 and Kc). Purification entails lysis in a low salt, sucrose buffer that contains ATP, chromatography on DEAE-cellulose, precipitation with actin in the absence of ATP, gel filtration in a discontinuous KI-KCl buffer system, and hydroxylapatite chromatography. Yield of pure cytoplasmic myosin is 5-10%. This protein is identified as myosin by its cross-reactivity with two monoclonal antibodies against human platelet myosin, the molecular weight of its heavy chain, its two light chains, its behavior on gel filtration, its ATP-dependent affinity for actin, its characteristic ATPase activity, its molecular morphology as demonstrated by platinum shadowing, and its ability to form bipolar filaments. The molecular weight of the cytoplasmic myosin's light chains and peptide mapping and immunochemical analysis of its heavy chains demonstrate that this myosin, purified from Drosophila cell lines, is distinct from Drosophila muscle myosin. Two-dimensional thin layer maps of complete proteolytic digests of iodinated muscle and cytoplasmic myosin heavy chains demonstrate that, while the two myosins have some tryptic and alpha-chymotryptic peptides in common, most peptides migrate with unique mobility. One-dimensional peptide maps of SDS PAGE purified myosin heavy chain confirm these structural data. Polyclonal antiserum raised and reacted against Drosophila myosin isolated from cell lines cross-reacts only weakly with Drosophila muscle myosin isolated from the thoraces of adult Drosophila. Polyclonal antiserum raised against Drosophila muscle myosin behaves in a reciprocal fashion. Taken together our data suggest that the myosin purified from Drosophila cell lines is a bona fide cytoplasmic myosin and is very likely the product of a different myosin gene than the muscle myosin heavy chain gene that has been previously identified and characterized.     

Characterization of human muscle myosins with respect to the light chains.

Isolated myosins from human predominantly fast and slow muscles, human neonatal and foetal muscle were examined for light chain composition by one- and two-dimensional electrophoresis. The LC1F, LC2F and LC3F light chains were identical with their counterparts from rabbit fast myosin. Human LC1S was identified by correlative criteria as a single component having a molecular weight slightly lower than, but an electric charge similar to, that of rabbit LC1Sb. Consequently, human LC1S appears to be much less heterogeneous relative to LC1F than is the case with other mammalian species. A high immunological cross-reactivity was likewise observed, with antibody specific to rabbit LC1F, between the isolated myosins from several human mixed muscles and rabbit fast myosin, though reactivity was highest with foetal myosin (having a pure-fast-light-chain pattern).     

Purifications of Rat Adrenal Dopamine-β-Hydroxylase: Immunological Analysis of Its Soluble and Membrane-Bound Forms with the Use of an Antibody Raised Against the Soluble Form

Soluble and membrane-bound dopamine-beta-hydroxylases (sDBH and mDBH, respectively) from rat adrenal glands have been purified through concanavalin A-Sepharose chromatography, gel filtration, and ion-exchange high-performance chromatographies. Both sDBH and mDBH were composed by four subunits of apparent molecular weight of 75,000 and showed a native molecular weight of 300,000. This procedure has not allowed us to obtain a sufficient amount of enzyme to immunize a rabbit. A second, more rapid procedure was designed to isolate sDBH, including concanavalin A-Sepharose chromatography and preparative sodium dodecyl sulfate-polyacrylamide gel electrophoresis. A rabbit antiserum was raised against this purified protein. The specificity of the antiserum was demonstrated by neutralization of rat adrenal gland DBH activity, labeling of rat adrenal medulla on histological sections, and, after Western blot, labeling of the 75,000-molecular-weight band in the different fractions associated with DBH activity during purification. The antiserum had a higher affinity for the sDBH denatured by sodium dodecyl sulfate than for the native protein. It had a higher affinity for sDBH than for mDBH. These results strongly suggest the presence of specific hydrophilic epitopes on the sDBH, revealing structural differences between the two hydroxylase forms. Two protein bands were stained on Western blots of crude rat adrenal gland extract. One band had an apparent molecular weight of 75,000, and the other of 82,000. Our results showed that the two proteins contained similar epitopes, an observation suggesting a close structural relationship. The higher-molecular-weight protein could be the 75,000 protein before covalent modifications and cleavage.