伴刀豆球蛋白A和层粘连蛋白与膜受体结合下膜分子运动及微丝组装变化的比较

研究伴刀豆球蛋白A和层粘连蛋白分别与小鼠腹腔巨噬细胞膜受体结合下引起细胞膜分子运动的变化和对微丝组装的影响.结果表明,伴刀豆球蛋白A和层粘连蛋白作用下均导致膜表面蛋白分子的侧向扩散速率减慢,膜脂流动性降低,加快膜内微丝组装并使微丝含量增加.两配体作用下引起细胞上述反应有相似性.     

不同配体与同一膜受体结合的初步探讨

研究了伴刀豆球蛋白A(ConA)和层粘连蛋白(LN)与巨噬细胞膜受体竞争结合,初步推测两个配体与同一膜受体结合的可能性.结果表明,LN可以竞争抑制FTTC-ConA与巨噬细胞膜受体的结合,说明ConA和LN两种配体各自的巨噬细胞膜受体中有部分可能是共同的,而加入ConA反而增加巨噬细胞膜上结合的FITC-LN量,这可能是因为ConA和LN的分子特性导致的.     

伴刀豆球蛋白A与巨噬细胞膜受体结合引起膜蛋白和膜脂分子运动及电荷的变化

本文利用荧光漂白恢复,顺磁共振和细胞电泳等技术研究外源性配体伴刀豆球蛋白A与巨噬细胞膜受体结合后膜蛋白及膜脂分子运动以及细胞表面电荷变化,结果表明,细胞膜表面蛋白分子侧向扩散速度减慢;膜脂分子流动性减慢,烃链有序性增强;细胞电泳速度加快。此等对阐明伴刀豆球蛋白A作为外源信息导致细胞膜分子动力学变化以及电荷改变有重要的生物学意义。     

层粘连蛋白与顺铂对腹水肝癌细胞内微丝的共同作用关系

本文探讨在外源性层粘连蛋白与抗癌药物顺铂的共同作用下,癌细胞内微丝组装的变化。结果发现外源性层粘连蛋白与小鼠腹水型肝癌细胞膜受体结合后,促进肌动蛋白微丝组装,使其含量增加;而多靶性抗癌药物顺铂与肌动蛋白微丝的结合,抑制微丝组装过程,造成微丝含量减少;两种试剂共同作用于癌细胞时,肌动蛋白微丝的含量与对照组相比非常接近。本研究为上述两种物质对癌细胞内微丝组装的拮抗性作用提出直接证据。     

外源性层粘连蛋白对腹水型肝癌细胞内微丝组装和细胞游动的作用

本文研究外源性层粘连蛋白与癌细胞膜上受体结合调节胞内肌动蛋白微丝组装与改变细胞游动之间的关系,以及影响膜上层粘连蛋白受体的侧向扩散运动及膜脂分子流动性变化之间的关系.用各种荧光技术,如荧光显微米,荧光漂白恢复技术和荧光流式细胞术得到了明显的证据.层粘连蛋白与肝癌细胞膜有结合,使分散的腹水肝癌细胞粘连聚集,并膜下周动蛋白微丝增加,当把癌细胞分开则细胞从原位游动很大距离.如不分离粘连的细胞可减少其脱落和转移.层粘连蛋白与受体结合则受体的侧向扩散系数减小,膜脂流动性降低,使膜上分子运动受影响,对癌的生长不利.     

层粘连蛋白与膜受体结合下膜受体构象与膜脂有序性的研究

配体蛋白与细胞膜受体蛋白结合后,可引起膜受体的构象与膜脂的有序性变化.本文研究外源性层粘连蛋白与腹水肝癌细胞膜受体结合后膜热量变化,膜序参数改变和膜电荷及细胞迁移率的变更.就膜蛋白构象与膜脂有序性以及膜电荷等方面改变的生理意义与层粘连蛋白抗癌细胞脱落转移寻找理论关系.本文应用微量量热法、顺磁共振和细胞电泳等技术,得知层粘连蛋白与癌细胞膜作用后细胞膜有放热效应,膜流动性增大,细胞电泳动变慢.癌细胞膜的这些变化对于限制癌的恶性生长与脱落均起重要作用.     

伴刀豆蛋白A与活细胞膜作用的图像分析和多元统计

用图像分析与多元统计研究伴刀豆蛋白A(ConA)与活巨噬细胞膜受体结合时膜变形性随作用时间和ConA浓度的定量变化。结果表明膜面积增大,增大速率与ConA速度呈正相关。ConA浓度加大,膜园形系数减小,变形性增加,此等变化反应了细胞的活化。     

A型核纤层蛋白在氧化应激和DNA损伤反应中的作用

核纤层蛋白是一种存在于真核细胞核膜下的中间丝纤维蛋白,是细胞核中重要的骨架蛋白,对维持细胞核的结构和功能具有重要作用。其基因突变会引起一系列的遗传性疾病,称为核纤层蛋白病。这些疾病在细胞水平表现出氧化应激和DNA损伤的特征,提示核纤层蛋白在氧化应激和DNA损伤反应中具有重要作用。本文主要就A型核纤层蛋白在氧化应激、DNA损伤反应中的作用机制进行综述。     

催化淀粉样蛋白产生的γ分泌酶的组装

γ分泌酶可引起多种膜蛋白的跨膜剪切作用,尤其可导致淀粉样前体蛋白（APP）的跨膜剪切,产生淀粉样蛋白（Aβ）。Aβ易发生沉积而诱发阿尔茨海默氏病（AD）。γ分泌酶由四种组分PS、Aph-1、NCT及Pen-2构成,由于该酶的相对分子质量巨大以及结构复杂,所以研究进展比较缓慢,其结构与功能至今仍未完全揭示。本文概述了在催化Aβ产生时γ分泌酶组装过程的研究进展,包括各组分之间的调控及组装。     

ConA激活小鼠胸腺T淋巴细胞增殖过程中c-myc与核骨架蛋白的结合

采用DNA-蛋白质体外吸附的方法研究伴刀豆球蛋白激活小鼠胸腺T淋巴细胞增殖过程中c-myc与核骨架蛋白的结合.实验结果显示,c-myc与核骨架蛋白的结合具有特异性,在淋巴细胞激活过程中c-myc与P₃₄/P₃₆核骨架蛋白及核纤层蛋白结合,并发生动态变化.     

巨噬细胞吞噬过程中膜磷脂流动性和受体流动性的关系

本文用ＦＲＡＰ（ｆｌｕｏｒｅｓｃｅｎｃｅｒｅｃｏｖｅｒｙａｆｔｅｒｐｈｏｔｏｂｌｅａｃｈｉｎｇ）技术,测量了静息状态和刀豆素Ａ刺激不同时间后巨噬细胞膜磷脂、ＣｏｎＡ受体扩散系数和荧光恢复率的变化。结果显示ＣｏｎＡ刺激后膜磷脂和ＣｏｎＡ受体的扩散系数和荧光恢复率均较静息状态的巨噬细胞明显降低,磷脂流动性的变化与ＣｏｎＡ受体流动性的变化呈正相关。提示受体介导内吞导致的膜磷脂流动性的降低,可能是由于配体与细胞膜上受体结合形成配体－受体复合体,增加了受体的负荷,使受体的流动性降低,进而使膜磷脂的流动性降低。巨噬细胞内吞过程中膜磷脂和ＣｏｎＡ受体流动性的降低,可能还与ＣｏｎＡ刺激后巨噬细胞胞浆ｐＨ值有关。     

巨噬细胞细胞内吞过程中膜受体流动性的测量——两种标记受体方法的比较

本文首次实现了细胞内吞过程中膜受体流动性的测量。实验选择巨噬细胞膜和伴刀豆凝集素A(ConA),分别用Con A-Biotin Avi-din-FITC(ABC法)和Con A-FITC(直接法)两种方法标记巨噬细胞膜Con A受体,比较了这两种方法标记的巨噬细胞Con A受体的荧光强度;利用FRAP(Fluorescence RecoveryAfter Rhotobleaching)技术,分别用两种标记方法测量了巨噬细胞Con A受体的流动性。结果显示Con A-Biotin Avidin-FITC标记的巨噬细胞受体的平均荧光强度比用Con A-FITC标记的平均荧光强度高大约3倍;直接标记法应用于细胞内吞过程中受体流动性的测量在方法学上存在着很大的缺陷,ABC标记法适合于测量细胞内吞过程中膜表面受体的流动性的变化,且灵敏度高、误差小;ABC方法标记受体的测量结果显示,Con A刺激后巨噬细胞膜表面Con A受体的扩散系数和荧光恢复率与静息状态相比呈下降趋势。     

层粘连蛋白在正常和异常人滋养上皮的不同定位与功能

从正常人不同发育时期, 不明原因流产, 增殖型和侵蚀型葡萄胎滋养细胞角度, 用免疫组织化学方法观察层粘连蛋白（ＬＮ） 的显微定位, 比较研究其不同定位与滋养上皮增殖, 生长, 分化, 凋亡, 迁移和浸润的关系。结果显示： 正常人不同发育时期, ＬＮ主要在早孕滋养细胞基底膜呈阳性着色, 中期无合体结处滋养细胞基底膜呈阳性着色; 不明原因流产,ＬＮ在合体滋养细胞质和顶尖部呈阳性着色; ＬＮ 在增殖型葡萄胎滋养细胞接触处呈阳性着色; ＬＮ 在侵蚀型葡萄胎滋养细胞膜呈阳性着色。提示：ＬＮ基底膜定位与滋养细胞分化和迁移密切相关,ＬＮ 胞膜定位与滋养上皮侵蚀密切相关,ＬＮ 细胞接触处定位与滋养细胞增殖可能相关, ＬＮ 胞质和顶尖部定位与滋养细胞凋亡可能相关, ＬＮ阴性着色与合体结和足月滋养细胞衰老可能无关     

Topography and microfilament core association of a cell surface glycoprotein of ascites tumor cell microvilli

Membrane-microfilament interactions are being investigated in microvilli isolated from 13762 rat mammary ascites tumor cells. These microvilli are covered by a sialomucin complex, composed of the sialomucin ascites sialoglycoprotein-1 (ASGP-1) and the associated concanavalin A (Con A)-binding glycoprotein ASGP-2. Limited proteolysis of the microvilli releases large, highly glycosylated fragments of ASGP-1 from the microvilli and increases the association of ASGP-2 with the Triton-insoluble microvillar microfilament core (Vanderpuye OA, Carraway CAC, Carraway, KL: Exp Cell Res 178:211, 1988). To analyze the topography of ASGP-2 in the membrane and its association with the microfilament core, microvilli were treated with proteinase K for timed intervals and centrifuged. The pelleted microvilli were extracted with Triton X-100 for the preparation of microfilament cores and Triton-soluble proteins or with 0.1 M carbonate, pH 11, for the preparation of microvillar membranes depleted of peripheral membrane proteins. These microvilli fractions were analyzed by dodecyl sulfate gel electrophoresis, lectin blotting with Con A and L-phytohemagglutinin, and immunoblotting with anti-ASGP-2. The earliest major proteolysis product from this procedure was a 70 kDa membrane-bound fragment. At longer times a 60 kDa released fragment, 30-40 kDa Triton-soluble fragments, and 25-30 kDa membrane- and microfilament-associated fragments were observed. Phalloidin shift analysis of microfilament-associated proteins on velocity sedimentation gradients indicated that the 25-30 kDa fragments were strongly associated with the microfilament core. From these studies we propose that ASGP-2 has a site for indirect association with the microfilament core near the membrane on a 15-20 kDa segment.     

Microfilament association of ASGP-2, the concanavalin A-binding glycoprotein of the cell-surface sialomucin complex of 13,762 rat mammary ascites tumor cells

Microfilament-associated proteins and membrane-microfilament interactions are being investigated in microvilli isolated from 13,762 rat mammary ascites tumor cells. "Phalloidin shift" analyses on velocity sedimentation gradients of Triton X-100 extracts of [3H]-glucosamine-labeled microvilli identified a 120-kDa cell-surface glycoprotein associated with the microvillar microfilament core. The identification was verified by concanavalin A (Con A) blots of one- and two-dimensional (2D) electrophoresis gels of sedimented microfilament cores. By 2D-electrophoresis and lectin analyses the 120-kDa protein appeared to be a fraction of ASGP-2, the major Con A-binding glycoprotein of the sialomucin complex of the 13,762 cells. This identity was confirmed by immunoblot analyses using immunoblot-purified anti-ASGP-2 from anti-membrane serum prepared against microvillar membranes. Proteolysis of the microvilli with subtilisin or trypsin resulted in an increase in the amount of ASGP-2 associated with the microfilament cores. An increase was also observed with sialidase treatment of the microvilli, suggesting that negative charges, probably present on the highly sialated sialomucin ASGP-1 of the ASGP-1/ASGP-2 sialomucin complex, reduce ASGP-2 association with the microfilament core. Proteolysis of isolated microvillar membranes, which contain actin but not microfilaments, also increased the association of ASGP-2 with a Triton-insoluble, actin-containing membrane fraction. Purified ASGP-2 does not bind to microfilaments in sedimentation assays. Since the Triton-insoluble membrane residue is enriched in an actin-containing transmembrane complex, which contains a different glycoprotein, we suggest that the ASGP-2 is binding indirectly via this complex to the microfilament core in the intact microvilli.     

Microtubule and microfilament rearrangements during capping of concanavalin A receptors on cultured ovarian granulosa cells

Thin-section electron microscope analysis of rat and rabbit-cultured granulosa cells treated with concanavalin A (Con A) at 37 degrees C revealed coordinated changes in the cytoplasmic disposition of microfilaments, thick filaments, and microtubules during cap formation and internalization of lectin-receptor complexes. Con A-receptor clustering is accompanied by an accumulation of subplasmalemmal microfilaments which assemble into a loosely woven ring as patches of receptor move centrally on the cell surface. Periodic densities appear in the microfilament ring which becomes reduced in diameter as patches coalesce to form a single central cap. Microtubules and thick filaments emerge associated with the capped membrane. Capping is followed by endocytosis of the con A-receptor complexes. During this process, the microfilament ring is displaced basally into the cytoplasm and endocytic vesicles are transported to the paranuclear Golgi complex along microtubules and thick filaments. Eventually, these vesicles aggregate near the cell center where they are embedded in a dense meshwork of thick filaments. Freeze-fracture analysis of Con A-capped granulosa cells revealed no alteration in the arrangement of peripheral intramembrane particles but large, smooth domains were conspicuous in the capped region of the plasma membrane. The data are discussed with reference to the participation of microtubules and microfilaments in the capping process.     

Facilitation of adenylate cyclase stimulation in macrophages by lectins.

Preincubation of guinea pig peritoneal macrophages with concanavalin A (Con A) markedly enhanced the accumulation of 3′,5′-cyclic-adenosine monophosphate (cAMP) in response to the adenylate cyclase (AC) stimulators prostaglandin E₁ (PGE₁) and isoproterenol (IP). Basal cAMP levels were not altered. Maximal enhancement of cAMP accumulation was induced by preincubation with 50–100 μg/ml Con A for 10 min at 37 °C. Con A-induced facilitation of macrophage responsiveness was prevented by α-methyl-d-mannoside (αMM). No facilitation was induced by the divalent derivative, succinyl-Con A or by Con A immobilized on Sepharose beads. Con A-induced facilitation developed normally in macrophages treated with the microfilament blocking agent, cytochalasin B. The responsiveness of macrophages to PGE₁ and IP was also augmented by phytohemagglutinin (PHA) but wheat germ agglutinin (WGA), soy bean agglutinin (SBA), pokeweed mitogen (PWM), and Lotus tetragonolobus lectin (LL) showed no enhancing effect. The effect of Con A on cAMP levels was the result of augmented cAMP synthesis and not of reduced degradation or a block in cAMP egress from the cells. Lectin-induced facilitation of AC stimulation could be mediated via one of the following mechanisms: (i) induction of receptor clustering; (ii) causing a conformational change in the receptors; (iii) inhibition of negative cooperativity; (iv) causing an increase in membrane fluidity; (v) disruption of microtubules by acting as a Ca²⁺ ionophore; or (vi) inactivation of a sugar-containing inhibitor of AC.     

两种人胃癌细胞M期与间期时相质膜表面Con A受体复合物分布及侧向运动

利用荧光标记和荧光漂白恢复方法研究了两种人胃腺癌细胞M期与间期时梠中,细胞膜表面ConA受体复合物分子的分布与侧向运动.结果表明:MGC80-3细胞M期时相与SGC7901细胞间期时相膜表面ConA受体复合物分布近似,其侧向运动方式呈扩散型;SGC 7901 M期时相细胞膜表面ConA受体复合物的分布与MGC80-3细胞间期时和相基本类似,其侧向运动主要是流动型.凡是受体复合物是流动型运动的细胞.其膜上可动分子的百分比都寓于扩散型运为的细胞,P值小于0.01.