氨甲喋呤-人血清白蛋白-单抗79结合物的制备及其体外细胞毒作用

 本研究采用间接连接法,应用异型双功能连接剂SPDP,形成以酰胺键和二硫键连接的氮甲喋吟-人血清白蛋白-单抗79(MTX-HSA-McAb79)结合物。其中McAb79与HSA克分子比有效地控制在1:1～2,且结合物的纯度及产率均较高,有一定的制备价值。 对靶细胞Nalm-6的体外细胞毒试验结果表明:MTX-HSA-McAb 79的杀伤活性显著强于MTX-HSA-nIgG,但较游离MTX的杀伤活性为弱。且MTX-HSA-McAb 79的杀伤作用依赖于McAb 79与靶抗原CALLA的抗原抗体反应。     

从蝉花虫草提取的N6-(2-羟乙基)腺苷的降压活性及其与人血清白蛋白的相互作用

从蝉花虫草中提取分离了N ⁶-(2-羟乙基)腺苷[N ⁶-(2-hydroxyethyl) -adenosine,HEA],对其降压机制及其与人血清白蛋白的相互作用进行了研究,揭示了降压机制以及在体内的传输机制。研究结果表明使用水沉醇提法提取HEA,HEA的纯度达到95%以上。HEA低（2.5mg/kg）、中（5mg/kg）、高（7.5mg/kg）浓度组腹腔注射高血压大鼠体内,HEA具有显著降压效果,中浓度组表现出较稳定的降压作用,其机制可能是激活腺苷A1受体。在HEA 与人血清白蛋白结合过程中,范德华力、氢键和疏水作用力是结合过程中的主要作用力,HEA在位点I与人血清白蛋白进行结合,结合过程轻微地改变人血清白蛋白的结构和微环境。分子对接结果表明,Ser-192、Lys-195、Arg-257、Ser-287和Arg-291是HEA与人血清白蛋白结合过程中重要的氨基酸残基。     

HBV感染中抗-(抗-HBs)独特型抗体的研究

1.75％聚乙二醇(MW6000)沉淀血清免疫复合物后,采用ELISA法检测上清中抗独特型抗体〔抗-(抗-HBs)〕。56例急性HBV感染患者血清IgM抗-(抗-HBs),第一周检出率最高(60.00％),1个月后大部分阴性,IgG抗-(抗-HBs)维持时间略长。IgM抗-(抗-HBs)较HBsAg/IgM和IgM抗-HBc消失早,将有利于急性HBV感染的诊断。27例CAH和29例CPH,IgM和IgG抗-(抗-HBs)阳性率约为38～52％,两型间无显著差异(p>0.5)。3例无症状HBsAg携带者和12例HBsAg血清疫苗接受者血清,抗-(抗-HBs)阴性。115例HBV感染者中,IgM抗-(抗-HBs)阳性者HBsAg阳性率(93.62)显著高于IgM抗-(抗-HBs)阴性者(52.31％),p<0.005;反之,HBsAg阳性血清IgM抗-(抗-HBs)阳性率(55.5S％)显著高于HBsAg阴性血清(9.68％),p<0.005;IgM抗-(抗-HBs)阳性和阴性血清的HBVDNA阳性率有显著差异(p<0.025),IgG反应到类似的结果。以上资料表明,抗-(抗-HBs)提示了一些HBV感染患者体内可能存在一种缺陷的反馈机制,导致抗-HBs产生不足而容许更活跃的HBV复制。本文证明了HBV感染患者血清中存在的抗-(抗-HBs)可能是共同决定簇“a”特异性的,还表明抗-HBs人抗-Id反应可能被纯化人血清HBsAg抑制,提示人抗-(抗-HBs)与抗-HBs结合的位点可能在HBsAg与抗-HBs结合位点内或在其附近,这和一些动物抗-(抗-HBs)的研究结果是一致的。     

类胰岛素生长因子-1的C结构域不影响胰岛素二硫键的热力学稳定性

胰岛素和类胰岛素生长因子-1(IGF-1)都属于胰岛素超家族,两者不但一级、三级结构有较高的同源性,而且生理功能也有少量交叉.然而两者的折叠行为却有很大的差别：胰岛素及其重组前体(PIP)只折叠成一种热力学稳定的二硫键配对,而IGF-1却折叠成两种热力学稳定的二硫键异构体.为了了解两者折叠行为差异的分子机制,制备了由胰岛素的A,B链和IGF-1的C结构域构成的单链杂交分子——[B10Glu]Ins/IGF-1(C),研究了该杂交分子二硫键的热力学稳定性以及它在含有少量巯基试剂的变性剂中的解折叠程度,同时还纯化了该杂交分子一种主要的非天然二硫键异构体,并研究了它的再折叠情况. 观察到IGF-1中C结构域的引入并未改变胰岛素分子的折叠热力学,但是影响了折叠的动力学过程.     

酶解转变的人红细胞输注大鼠的实验研究

目的：利用大鼠评价酶解转变的人红细胞的安全性。方法：人红细胞与大鼠血清进行常规配血,检测二者之间的相容性;将人B型红细胞酶解后输注大鼠,流式细胞术检测人红细胞在大鼠体内的存活率。结果：人红细胞与大鼠血清不凝集,但人红细胞输注大鼠体内很快被排斥,1h下降至50％以下,18h被完全排斥。结论：仅依靠红细胞配血实验来选择人红细胞输血动物模型是不全面的,大鼠不适合作为酶解转变的人红细胞安全性评价的动物模型。     

6A型肺炎球菌结合物分子大小对小鼠免疫原性的影响

目的 比较不同分子大小的6A型肺炎球菌(serotype 6A Streptococcus Pneumoniae )结合物和佐剂吸附在小鼠体内免疫原性的影响。方法 通过乙酸水解降低6A型荚膜多糖的相对分子质量制备成水解物,水解物经1-氰基-4-二甲胺基吡啶四氟硼酸盐(CDAP)活化并与破伤风类毒素己二酸酰肼衍生物TT AH 结合,制备成结合物。用Sepharose 4 Fast Flow 纯化结合物,并根据化学检测结果将结合物分为 K D 0.0~0.2、 K D 0.2~0.4、 K D 0.4~0.6等3个组分,每个组分分别以磷酸铝佐剂吸附,将吸附前后的各个组分按照每针次每只小鼠0.2 μg分别免疫小鼠,并采用ELISA检测结合物在小鼠体内的抗体水平。结果 3种不同相对分子质量吸附前后的结合物在小鼠体内均能产生较高水平的抗体,各组2、3针之间具有明显的加强效应。在吸附组和未吸附组中,3种不同分子大小的结合物在小鼠体内产生抗体水平无明显差异。各组分佐剂吸附后的结合物血清抗体滴度高于未吸附组,但这种差异无统计学意义( P > 0.05)。结论 结合物的分子大小对小鼠体内抗体水平的产生没有明显影响;磷酸铝佐剂吸附对于不同分子大小的结合物在小鼠体内的免疫原性有一定的增强效应,但这种增强效应差异无统计学意义。     

脂质活性信号分子鞘氨醇-1-磷酸及其生物学特性

鞘氨醇-1-磷酸(sphingosine-1-phosphate,S1P)是目前颇受关注的脂质信号分子.体内S1P主要由红细胞内鞘氨醇激酶催化鞘氨醇合成,后经由ATP结合盒式转运子释放入血浆.血浆S1P超过半数存在于高密度脂蛋白和血清白蛋白上.S1P可通过直接胞内作用和激活其特异性G蛋白偶联受体产生多种重要生物学效应.S1P1-5型受体在体内各类型组织和细胞表达水平不同,参与包括细胞增殖、存活、迁移等多种生物学过程.     

糖尿病肾脏病与血纤溶酶原激活物抑制剂-1的相互影响

目的:观察糖尿病肾脏病进展过程中血纤溶酶原激活物抑制剂-1的水平变化及应用药物干预其变化后产生的对糖尿病肾脏病的影响。方法:选择于聊城市人民医院就诊的糖尿病肾脏病患者88例,DKDⅢ期43例,DKDⅣ期45例。分别检测各期患者血PAI-1水平,观察其变化趋势。针对DKDⅢ期患者分为对照组(DKDⅢ-C组)和观察组(DKDⅢ-O组),对照组给予常规降糖、保护肾脏及血管紧张素转化酶抑制剂等药物治疗。观察组在对照组治疗的基础上给予尿激酶5万U加入100ml生理盐水静脉滴注,每天1次,共14d。比较两组治疗前后血PAI-1水平、24 h尿白蛋白量、血肌酐、空腹血糖和凝血酶原时间的变化。结果:DKDⅣ期患者血PAI-1水平明显高于DKDⅢ期患者(P<0.001)。DKDⅢ-O组患者治疗后血PAI-1水平下降(P<0.01),且尿白蛋白减少程度有统计学意义(P<0.01),空腹血糖、血肌酐、凝血酶原时间影响无统计学差异(P>0.05)。DKDⅢ-C组治疗前、后血PAI-1、24h尿白蛋白量、空腹血糖、血肌酐、凝血酶原时间变化均无统计学差异(P>0.05)。结论:随糖尿病肾脏病进展,血PAI-1水平呈上升趋势,应用药物降低其水平后可减少早期DKD患者尿白蛋白量,对保护肾功能、延缓肾脏病进展有积极意义。     

重组人干扰素α-2b滴鼻剂的研制

重组人干扰素α-2b(rIFNα-2b)滴鼻剂的试制及临床前工作研究.进行了理化和生物学性质试验、稳定性试验、鼻腔局部刺激性试验、急性毒性试验、长期毒性试验和动物体内抗病毒试验等.本品连续三批工艺稳定,检定合格,性质稳定,2～8℃保存24个月后生物学活性无明显下降,使用安全,无不良反应.其它各项试验均符合现行<中国药典>的要求.表明该制剂具有比较好的开发与应用前景.     

A群奈瑟氏脑膜炎球菌荚膜多糖-破伤风类毒素结合疫苗的制备及其免疫原性研究

采用溴化氰(CNBr)活化多糖,以无水己二酸二肼(ADH)作为连接剂,1乙基13(3二甲基氨基丙基)碳化二亚胺(EDAC)为偶联剂制备A群奈瑟氏脑膜炎球菌荚膜多糖(GAMP)与破伤风类毒素(TT)的结合物,经皮下免疫NIH小鼠,用ELISA检测小鼠血清中抗GAMP及抗载体蛋白的IgG抗体水平。用补体介导的体外杀菌试验检测血清中GAMP抗体的杀菌活性。结果显示,实验中制备的多糖衍生物和多糖蛋白质结合物都具有GAMP抗原特异活性。结合物免疫小鼠后可诱生比多糖单独免疫更高水平的GAMP血清IgG抗体,并能形成免疫记忆,产生再次应答。结合物免疫小鼠所诱生的血清GAMP抗体较之多糖组具有更强的体外杀菌活性。表明此方法制备的结合物可获得优于多糖的、稳定的特异免疫原性。     

Interposition of different chemical linkages between antibody and 111In-DTPA to accelerate clearance from non-target organs and blood

Two chemically labile linkages, disulfide and diester, and two stable linkages, thioether and hydrocarbon, were introduced between antibody and ¹¹¹In-DTPA in order to modify their biodistributions. The biodistributions of the new linkages were evaluated in rats with target antigens localized in lungs. For a comparison purpose, the antibody-DTPA conjugate with a peptide linkage was used as a control conjugate. The antibody conjugates with the stable linkages produced the biodistributions similar to that of the peptide linked conjugate during a 48 h period. The disulfide and diester conjugates, however, cleared from blood much faster and are retained in normal organs much lower than the peptide conjugate. The disulfide and the diester conjugate amplified the lung (target) to blood ratio by 15 and 6 times, respectively at 48 h, as compared to the corresponding target to blood ratio of the control conjugate. Compared to the control conjugate, a 3 times higher target to liver ratio was also obtained by the disulfide conjugate and a 4 times higher target to kidney ratio was obtained by the diester conjugate at 48 h.     

Disulfide-linked antibody-maytansinoid conjugates: optimization of in vivo activity by varying the steric hindrance at carbon atoms adjacent to the disulfide linkage

In this report, we describe the synthesis of a panel of disulfide-linked huC242 (anti-CanAg) antibody maytansinoid conjugates (AMCs), which have varying levels of steric hindrance around the disulfide bond, in order to investigate the relationship between stability to reduction of the disulfide linker and antitumor activity of the conjugate in vivo. The conjugates were first tested for stability to reduction by dithiothreitol in vitro and for plasma stability in CD1 mice. It was found that the conjugates having the more sterically hindered disulfide linkages were more stable to reductive cleavage of the maytansinoid in both settings. When the panel of conjugates was tested for in vivo efficacy in two human colon cancer xenograft models in SCID mice, it was found that the conjugate with intermediate disulfide bond stability having two methyl groups on the maytansinoid side of the disulfide bond and no methyl groups on the linker side of the disulfide bond (huC242-SPDB-DM4) displayed the best efficacy. The ranking of in vivo efficacies of the conjugates was not predicted by their in vitro potencies, since all conjugates were highly active in vitro, including a huC242-SMCC-DM1 conjugate with a noncleavable linkage which showed only marginal activity in vivo. These data suggest that factors in addition to intrinsic conjugate potency and conjugate half-life in plasma influence the magnitude of antitumor activity observed for an AMC in vivo. We provide evidence that bystander killing of neighboring nontargeted tumor cells by diffusible cytotoxic metabolites produced from target cell processing of disulfide-linked antibody-maytansinoid conjugates may be one additional factor contributing to the activity of these conjugates in vivo.     

Transcellular processing of disulfide- and thioether-linked peroxidase--polylysine conjugates in cultured MDCK epithelial cells

Horseradish peroxidase (HRP) was conjugated to nondegradable polycationic poly(D-lysine) (PDL) through either a thioether (HRP-S-PDL) or a disulfide (HRP-SS-PDL) linkage. The binding and transcytosis of these conjugates was studied in Madin-Darby canine kidney (MDCK) cell monolayers grown on 3-microns microporous polycarbonate filters. Conjugation of HRP to PDL with both linkages markedly increased the binding of this protein onto the cell monolayers. However, an enhancement of the transcellular transport of HRP in both apical-to-basal and basal-to-apical directions was observed only in HRP-SS-PDL, but not in HRP-S-PDL. HRP-SS-PDL transport was inhibited by colchicine and by 4 degrees C incubation. The transport of 14C-sucrose was not affected by the presence of conjugates. These results indicate that the transport of the conjugate across the cell monolayers was due to a transcellular process rather than to any leakage of the cell junction caused by polycations. The disulfide linkage between HRP and PDL was cleaved rapidly at the basal and, to a lesser extent, at the apical surface of the cell. Neuraminidase treatment decreased the binding of the conjugates onto the cell surface, but did not decrease the transcellular transport, suggesting that not all surface-bound conjugates were available for transcytosis. These results demonstrate that disulfide linkages can be cleaved during transcytosis in MDCK cells. The cleavage, however, occurs mostly at the binding site on the cell surface, which may prevent the cellular uptake of the intact conjugate.     

Fixation of various aldehydic dextrans onto human hemoglobin: Study of conjugate stability

Formation and stability of different aldehydic dextran-hemoglobin conjugates were studied. Two types of polymers were used: sulfated or unsulfated oxidized dextrans and 4-carboxamidobenzaldehyde dextran. Periodate-oxidized dextran forms imine and ketoamine linkages by reaction with hemoglobin and the obtained conjugates are not completely stable, as their molecular size increases with time or decreases after incubation with lysine. The sulfated conjugates are more sensitive to lysine action than the unsulfated ones, which is consistent with the decreased possibilities of Amadori rearrangement. Therefore, this proves the importance of ketoamines for ensuring the cohesion of oxidized dextran-based conjugates. Carboxamidobenzaldehyde dextran forms only imine linkages with hemoglobin and the corresponding conjugates possess a marked instability in the absence of reductive treatment. The different types of conjugates could be stabilized by a sodium borohydride treatment in a satisfying manner.     

Cleavage of disulfide-linked fetuin-bisphosphonate conjugates with three physiological thiols

An effective therapeutic agent for treatment of bone diseases is expected to exhibit a high affinity to bone. Conjugating proteins to bisphosphonates (BPs), a class of molecules with an exceptional affinity to bone mineral hydroxyapatite (HA), is a feasible means to impart such a bone affinity. Protein-BP conjugates with cleavable linkages, which allow protein release from the mineral, are preferable over conjugates with stable linkages. To this end, 2-(3-mercaptopropylsulfanyl)-ethyl-1,1-bisphosphonic acid (thiolBP) was conjugated onto fetuin, a model protein, using N-succinimidyl-3-(2-pyridyldithio)propionate to create disulfide-linked conjugates. Although the fetuin-thiolBP conjugates were stable under aqueous conditions, the disulfide linkage was readily cleaved in the presence of the physiological thiols l-cysteine, dl-homocysteine, and l-glutathione. dl-Homocysteine exhibited the highest cleavage of the disulfide linkage among these thiols. The imparted bone affinity as a result of thiolBP conjugation, as assessed by HA binding in vitro, was eliminated upon cleavage of the disulfide linkage. The cleavage of the conjugates bound to HA was as effective as the conjugate cleavage in solution, and even more so at high concentrations of l-glutathione. In conclusion, disulfide-linked fetuin-thiolBP conjugates exhibited a high affinity to HA, which was readily lost upon cleavage with thiols found in physiological milieu.     

Conjugates of a novel 7-substituted camptothecin with RGD-peptides as α(v)β₃ integrin ligands: An approach to tumor-targeted therapy

Eight conjugates of a novel camptothecin derivative (Namitecan, NMT) with RGD peptides have been synthesized and biologically evaluated. This study focused on factors that optimize the drug linkage to the transport vector. The different linkages investigated consist of heterofunctional glycol fragments and a lysosomally cleavable peptide. The linkage length and conformation were systematically modified with the purpose to understand their effect on receptor affinity, systemic stability, cytotoxicity, and solubility of the corresponding conjugates. Among the new conjugates prepared, C6 and C7 showed high receptor affinity and tumor cell adhesion, acceptable stability in murine blood, and high cytotoxic activity (IC?? = 8 nM). The rationale, synthetic strategy, and preliminary biological results will be presented.     

Detection of disulfide bonds in bovine brain tubulin and their role in protein folding and microtubule assembly in vitro: a novel disulfide detection approach

Cysteine residues in tubulin are actively involved in regulating ligand interactions and microtubule formation both in vivo and in vitro. These cysteine residues are sensitive reporters in determining the conformation of tubulin. Although some of the cysteines are critical in modulating drug binding and microtubule assembly, it is not clear how many of these normally exist as disulfides. The controversy regarding the disulfide bonds led us to develop a disulfide detection assay to reexamine the presence of the disulfide linkages in purified alphabeta tubulin and explore their possible biological functions in vitro. The accessible cysteine residues in alphabeta tubulin were alkylated with an excess of iodoacetamide to prevent artifactual generation of disulfide linkages in tubulin. After removal of excess iodoacetamide, tubulin was unfolded in 8 M urea. Half of the unfolded tubulin was treated with dithiothreitol to reduce any disulfide bonds present. The aliquots were then treated with iodo[(14)C]acetamide and the incorporation of radioactivity was measured. We also used the same approach to detect the disulfide linkages in the tubulin in a whole-cell extract. We found in both cases that the samples which were not treated with dithiothreitol had little or no incorporation of iodo[(14)C]acetamide, while the others that were treated with dithiothreitol had significant amounts of (14)C incorporation into tubulin. Moreover, the reduction of the disulfide linkages in tubulin resulted in inhibition of microtubule assembly (29-54%) and markedly affected refolding of the tubulin from both an intermediate and a completely unfolded state. All these data therefore suggest that tubulin has intrachain disulfide bonds in the alpha- and beta-subunits and that these disulfides assist in correct refolding of tubulin from the intermediate unfolded state or help to recover the hydrophobic domains from the completely unfolded state. These disulfides also regulate microtubule assembly and the stability of tubulin in vitro. Our results suggest that tubulin disulfides may play a role in tubulin folding and that thiol-disulfide exchange in tubulin could be a key regulator in microtubule assembly and dynamics of tubulin in vivo.     

Determination of the glycosylation patterns, disulfide linkages, and protein heterogeneities of baculovirus-expressed mouse interleukin-3 by mass spectrometry.

The primary structure of mouse interleukin-3 (IL-3) expressed by recombinant baculovirus-infected silkworm (Bombyx mori) larvae was analyzed by subjecting isolated IL-3 derived peptides to liquid secondary ion mass spectrometry. Two species of IL-3 were isolated from the silkworm hemolymph by reverse-phase high-pressure liquid chromatography. The major component has M(r)20-22 x 10(3) as determined by SDS-PAGE. Liquid secondary ion mass spectrometric analysis was carried out on the reduced tryptic and endopeptidase lysyl-C peptides of glycosylated and deglycosylated IL-3. These studies provided evidence that (1) Asn-16 is heterogeneously glycosylated with four different oligosaccharides, (2) Asn-86 is either nonglycosylated or has attached to it one oligosaccharide, (3) the N-glycosylation sites Asn-44 and Asn-51 are not glycosylated, and (4) there is no O-glycosylation. Liquid secondary ion mass spectrometric analysis of the unreduced tryptic peptides provided evidence for disulfide linkages between Cys-140 and Cys-79 or Cys-80 and between Cys-17 and Cys-79 or Cys-80. In comparison to the major component, a minor IL-3 species (M(r) 17-19 x 10(3) by SDS-PAGE) isolated from the hemolymph showed no difference with respect to the glycosylation pattern or the disulfide linkages, but it was cleaved between Ala-127 and Ser-128, and only a disulfide linkage between Cys-140 and Cys-79 or Cys-80 held the molecule together.(ABSTRACT TRUNCATED AT 250 WORDS)     

Oxidation of indole-3-acetic Acid-amino Acid conjugates by horseradish peroxidase

The stability of 21 amino acid conjugates of indole-3-acetic acid (IAA) toward horseradish peroxidase (HRP) was studied. The IAA conjugates of Arg, Ile, Leu, Tyr, and Val were oxidized readily by peroxidase. Those of Ala, β-Ala, Asp, Cys, Gln, Glu, Gly, and Lys were not degraded and their recovery was above 92% after 1 hour incubation with HRP. A correlation between the stability of IAA conjugates toward peroxidase-catalyzed oxidation and the hydrophobicity of the amino acid moiety conjugated to IAA was demonstrated. Polar amino acid conjugates of IAA are more resistant to HRP-catalyzed oxidation.