肝素6位羧基修饰对抑制P?鄄选择素介导的A375细胞粘附活性的影响

已有的研究表明,肝素可以作为P-选择素的配体,显著抑制肿瘤转移过程中P-选择素介导的肿瘤细胞与血小板间的粘附.但是,肝素被P-选择素识别所必需的确切寡糖结构信息仍很缺乏.通过选择性化学修饰方法制备了2种低抗凝血肝素衍生物,即羧基还原肝素(CR-肝素)和羧基还原后再硫酸化肝素(SCR-肝素),系统地研究了它们对P-选择素介导的A375细胞粘附的抑制.研究结果表明,显著失去抗凝血活性的CR-肝素仍能有效地抑制P-选择素介导的A375细胞粘附,说明肝素的C6羧基并不是被P-选择素识别所必需的.而SCR-肝素所发生的C6羧基向羟甲硫酸酯基的转化却显著降低了抗粘附活性,说明P-选择素对肝素的识别并不只依赖于肝素的电荷密度.研究结果为深入阐明拮抗P-选择素介导的肿瘤细胞粘附的分子机制提供了有价值的实验基础.     

P－选择素研究进展

Ｐ－选择素是粘附分子选择素家族的重要成分之一,参与细胞间、细胞与基质间的粘附,在炎症、栓塞及肿瘤转移中起重要作用．本文着重介绍了Ｐ－选择素的结构特点、配体、表达调控及检测方面的研究进展．     

P—选择素研究进展

Ｐ－选择素是粘附分子选择素家族的重要成分之一,参与细胞间、细胞与基质间的粘附,在炎症,栓塞及肿瘤转移中起重要作用,本文着重介绍了Ｐ－选择素的结构特点,配体,表达调控及检测方面的研究进展。     

白细胞与内皮细胞的粘附

白细胞与内皮细胞相互作用由粘附分子介导.整合素、免疫球蛋白及选择素家族的粘附分子在这两种细胞的粘附中起关键作用.粘附的起始阶段由选择素介导,随后由CD11/CD18复合物与ICAM-1形成更为紧密的结合.多种细胞因子及炎症反应可诱导粘附.抗粘附分子单抗、药物等可抑制粘附.     

选择素与肿瘤转移研究进展

晚近发现的粘附分子受体（选择素）,能介导血小板、内皮细胞与中性粒细胞、单核细胞及肿瘤细胞的粘附,它们在炎症、血栓形成及肿瘤转移过程中起重要作用。本文练过了选择素的结构与功能特点,在正常组织中分布以及与肿瘤转移方面的有关研究进展。     

P-选择素糖蛋白配体1与白细胞的起始黏附

P-选择素糖蛋白配体1（P—selectin glycoprotein ligand 1,PSGL-1）是20世纪90年代初期发现的一种具同源二聚体结构的跨膜糖蛋白,表达于几乎所有白细胞表面,是迄今为止阐述得最为详尽的选择素配体。PSGL-1是以P-选择素为亲和探针分离得到的,与P-选择素有高度的亲和性。近年来,越来越多的研究证明了PSGL-1同时也是L-选择素和E-选择素的生理配体。通过PSGL-1与选择素分子间的相互作用,白细胞在血管内皮细胞上产生滚动（即起始黏附）,进而使白细胞逐步活化并稳定黏附于血管内皮。现从PSGL-1的结构、分布、表达调控、信号转导、生理病理角色、临床应用等方面进行综述。     

T-钙粘附素在肿瘤发生发展中的作用

T-钙粘附素是钙粘附素家族中的一个特殊成员,缺乏跨膜区和胞浆区,是通过糖基磷脂酰肌醇附着于细胞膜上．T-钙粘附素的异常表达参与到多种肿瘤的发生发展过程中,如肿瘤细胞的凋亡、增殖、侵袭和转移等过程．T-钙粘附素还可能参与肿瘤新生血管的形成和胞内外的信号传导过程．本文就T 钙粘附素在肿瘤发生发展过程中的作用及分子机制作一综述,该蛋白有可能成为肿瘤治疗的新靶点.     

人血管生成抑制素抑瘤研究进展

肿瘤的发展和转移需要新生血管的形成。人血管生成抑制素是近年发现的能够专一性抑制血管内皮细胞的内皮抑制因子。大量研究表明,在体外用血管生成抑制素处理血管内皮细胞可以抑制新生血管的形成,在体内单独使用血管生成抑制素,或者将血管生成抑制素与其他物质如基质金属蛋白酶、尿激酶联合处理荷瘤小鼠,可以降低小鼠体内肿瘤组织新生血管密度,抑制肿瘤的生长和肿瘤细胞的迁移。简要综述了血管生成抑制素抑制肿瘤生长和转移及其作用机理。     

P—selectin表位结构与功能研究进展

P－selectin是细胞粘附分子选择素家族成员,作为血小板／内皮细胞活化标志和粘附分子,已证明其在介导活化血小板,内皮细胞与白细胞相互粘附作用,参与免疫扣伤,炎症反应,血栓形成及肿瘤转移等多种生理,病理过程中发挥重要作用,近年研究表明,P－selectin分子中不同结构域及其功能表位在其识别,粘附及信号传导中各具重要作用,进一步揭示这种分子构效关系,将有助于阐明P－selectin的生理,病理意义。     

肿瘤细胞粘附、迁移与转移的相关性

肿瘤细胞的粘附、迁移能力与癌转移密切相关. 细胞粘附分子选择素、整合素、免疫球蛋白超家族及钙粘素介导同型或异型细胞间以及细胞与基质间的粘附,其在肿瘤细胞表面表达数量或分布方式的改变直接或间接影响着转移潜能,是肿瘤细胞从原发瘤脱落以及着床的关键性环节.肿瘤细胞的迁移能力被认为是癌转移的限速环节.一般情况下,肿瘤细胞在体内或体外的迁移能力与其转移潜能呈正相关性,肿瘤细胞通过对迁移刺激物的趋化性及趋触性应答而完成向远离器官的转移,其具体分子机制目前还不清楚.     

Integrin VLA-4 enhances sialyl-Lewisx/a-negative melanoma adhesion to and extravasation through the endothelium under low flow conditions

During their passage through the circulatory system, tumor cells undergo extensive interactions with various host cells including endothelial cells. The capacity of tumor cells to form metastasis is related to their ability to interact with and extravasate through endothelial cell layers, which involves multiple adhesive interactions between tumor cells and endothelium (EC). Thus it is essential to identify the adhesive receptors on the endothelial and melanoma surface that mediate those specific adhesive interactions. P-selectin and E-selectin have been reported as adhesion molecules that mediate the cell-cell interaction of endothelial cells and melanoma cells. However, not all melanoma cells express ligands for selectins. In this study, we elucidated the molecular constituents involved in the endothelial adhesion and extravasation of sialyl-Lewis(x/a)-negative melanoma cell lines under flow in the presence and absence of polymorphonuclear neutrophils (PMNs). Results show the interactions of alpha(4)beta(1) (VLA-4) on sialyl-Lewis(x/a)-negative melanoma cells and vascular adhesion molecule (VCAM-1) on inflamed EC supported melanoma adhesion to and subsequent extravasation through the EC in low shear flow. These findings provide clear evidence for a direct role of the VLA-4/VCAM-1 pathway in melanoma cell adhesion to and extravasation through the vascular endothelium in a shear flow. PMNs facilitated melanoma cell extravasation under both low and high shear conditions via the involvement of distinct molecular mechanisms. In the low shear regime, beta(2)-integrins were sufficient to enhance melanoma cell extravasation, whereas in the high shear regime, selectin ligands and beta(2)-integrins on PMNs were necessary for facilitating the melanoma extravasation process.     

The role of cell adhesion molecules in the progression of colorectal cancer and the development of liver metastasis

Cell adhesion molecules (CAMs) play a significant role in the metastatic potential of colorectal cancer and thus mediate the prognosis of this common malignancy. The downregulation of cadherins and catenins facilitates tumour cell detachment from the primary site, while the expression of selectins, integrins and members of the immunoglobulin superfamily may support neoplastic progression, intravasation and malignant cell attachment to foreign tissue, leading to the development of metastases. The liver is the main host organ of colorectal metastatic lesions. The process of hepatic invasion originates in the sinusoids, where non-parenchymal cells interact with metastasising ones, through the expression of numerous CAMs, following complex molecular pathways. Concurrently, the selective expression of cell adhesion molecules on different organs and endothelia, in conjunction with the presence of dissimilar adhesion ligands on various colorectal cancer cell lines, suggest that CAMs may also mediate the selection of the host organ, for the development of distant colorectal metastases.     

Selectins: cell surface lectins which mediate the binding of leukocytes to endothelial cells.

The selectins are the most recently identified family of cell adhesion molecules. The three known members of this family (L-, E- and P-selectin) mediate the binding of leukocytes to endothelial cells and are involved in the homing of lymphocytes to lymph nodes, as well as the extravasation of neutrophilic granulocytes into inflamed tissues. The lectin character of these cell adhesion molecules (CAMs) makes the selectin protein family unique among all known CAM families. The review will summarize present knowledge about the structural organization, the ligands identified (carbohydrates and glycoproteins) and the different regulation mechanisms of the cell surface activity of the three selectins.     

Bacterial pathogenesis: exploiting cellular adherence

Cell adhesion molecules, such as integrins, cadherins, the immunoglobulin superfamily of cell adhesion molecules and selectins, play important structural roles and are involved in various signal transduction processes. As an initial step in the infectious process, many bacterial pathogens adhere to cell adhesion molecules as a means of exploiting the underlying signaling pathways, entering into host cells or establishing extracellular persistence. Often, bacteria are able to bind to cell adhesion molecules by mimicking or acting in place of host cell receptors or their ligands. Recent studies have contributed to our understanding of bacterial adherence mechanisms and the consequences of receptor engagement; they have also highlighted alternative functions of cell adhesion molecules.     

L-selectin-mediated lymphocyte-cancer cell interactions under low fluid shear conditions

Cell migration in blood flow is mediated by engagement of specialized adhesion molecules that function under hemodynamic shear conditions, and many of the effectors of these adhesive interactions, such as the selectins and their ligands, are well defined. However, in contrast, our knowledge of the adhesion molecules operant under lymphatic flow conditions is incomplete. Among human malignancies, head and neck squamous cell cancer displays a marked predilection for locoregional lymph node metastasis. Based on this distinct tropism, we hypothesized that these cells express adhesion molecules that promote their binding to lymphoid tissue under lymphatic fluid shear stress. Accordingly, we investigated adhesive interactions between these and other cancer cells and the principal resident cells of lymphoid organs, lymphocytes. Parallel plate flow chamber studies under defined shear conditions, together with biochemical analyses, showed that human head and neck squamous cell cancer cells express heretofore unrecognized L-selectin ligand(s) that mediate binding to lymphocyte L-selectin at conspicuously low shear stress levels of 0.07-0.08 dynes/cm(2), consistent with lymphatic flow. The binding of head and neck squamous cancer cells to L-selectin displays canonical biochemical features, such as requirements for sialylation, sulfation, and N-glycosylation, but displays a novel operational shear threshold differing from all other L-selectin ligands, including those expressed on colon cancer and leukemic cells (e.g. HCELL). These data define a novel class of L-selectin ligands and expand the scope of function for L-selectin within circulatory systems to now include a novel activity within shear stresses characteristic of lymphatic flow.     

Constitutive expression of E- and P-selectin cognate ligands in human endothelial cells.

On human endothelial cells from umbilical cord (HUVEC) are present, in addition to E- and P-selectins, their cognate ligands. Differently from selectins, the ligand expression is constitutive and not modulated by interleukin-1beta. Such ligands appear to be different from the ones present in promyelocytic cells in order to promote cell adhesion to immobilized selectins. The expression of selectin-ligands on HUVEC cells suggest that selectins can participate in endothelial signalling besides their role as adhesion molecules for circulating blood cells. However, despite their role in chemotaxis, selectins do not contribute to HUVEC tube formation in Matrigel.     

Carcinoembryonic antigen and CD44 variant isoforms cooperate to mediate colon carcinoma cell adhesion to E- and L-selectin in shear flow

Selectin-mediated adhesion of tumor cells to platelets, leukocytes, and endothelial cells may regulate their hematogenous dissemination in the microvasculature. We recently identified CD44 variant isoforms (CD44v) as functional P-, but not E- or L-, selectin ligands on colon carcinoma cells. Moreover, an approximately 180-kDa sialofucosylated glycoprotein(s) mediated selectin binding in CD44-knockdown cells. Using immunoaffinity chromatography and tandem mass spectrometry, we identify this glycoprotein as the carcinoembryonic antigen (CEA). Blot rolling assays and flow-based adhesion assays using microbeads coated with CEA immunopurified from LS174T colon carcinoma cells and selectins as substrate reveal that CEA possesses E- and L-, but not P-, selectin ligand activity. CEA on CD44-knockdown LS174T cells exhibits higher HECA-452 immunoreactivity than CEA on wild-type cells, suggesting that CEA functions as an alternative acceptor for selectin-binding glycans. The enhanced expression of HECA-452 reactive epitopes on CEA from CD44-knockdown cells correlates with the increased CEA avidity for E- but not L-selectin. Through the generation of stable knockdown cell lines, we demonstrate that CEA serves as an auxiliary L-selectin ligand, which stabilizes L-selectin-dependent cell rolling against fluid shear. Moreover, CEA and CD44v cooperate to mediate colon carcinoma cell adhesion to E- and L-selectin at elevated shear stresses. The novel finding that CEA is an E- and L-selectin ligand may explain the enhanced metastatic potential associated with tumor cell CEA overexpression and the supportive role of selectins in metastasis.     

The three members of the selectin receptor family recognize a common carbohydrate epitope, the sialyl Lewis(x) oligosaccharide

The selectins (lectin-EGF-complement binding-cell adhesion molecules [LEC-CAMs]) are a family of mammalian receptors implicated in the initial interactions between leukocytes and vascular endothelia, leading to lymphocyte homing, platelet binding, and neutrophil extravasation. The three known selectins, L-selectin (leukocyte adhesion molecule-1 [LECAM-1]), E-selectin (endothelial-leukocyte adhesion molecule-1 [ELAM-1]), and P-selectin (GMP-140) share structural features that include a calcium-dependent lectin domain. The sialyl Lewis(x) carbohydrate epitope has been reported as a ligand for both E- and P-selectins. Although L-selectin has been demonstrated to bind to carbohydrates, structural features of potential mammalian carbohydrate ligand(s) have not been well defined. Using an ELISA developed with a sialyl Lewis(x)-containing glycolipid and an E-selectin-IgG chimera, we have demonstrated the direct binding of the L-selectin-IgG chimera to sialyl Lewis(x). This recognition was calcium dependent, and could be blocked by Mel-14 antibody but not by other antibodies. Recognition was confirmed by the ability of cells expressing the native L-selectin to adhere to immobilized sialyl Lewis(x). These data suggest that the sialyl Lewis(x) oligosaccharide may form the basis of a recognition domain common to all three selectins.     

Endothelial cell E- and P-selectin up-regulation in murine contact sensitivity is prolonged by distinct mechanisms occurring in sequence

The selectins are adhesion molecules that mediate the tethering and rolling of leukocytes on vascular endothelium. Although E-selectin and P-selectin are known to be expressed by endothelial cells (EC) in response to proinflammatory stimuli, their pattern and mechanisms of expression in immune-mediated inflammation remain poorly understood. By quantifying luminal endothelial selectin expression via i.v. administration of radiolabeled mAb, we detected constitutive expression of P-selectin, but not E-selectin, in mouse skin. Both selectins were transiently up-regulated after intradermal TNF-alpha, IL-1alpha, or IL-1beta. In contrast, during a contact sensitivity response to oxazolone, expression of both selectins was prolonged, with distinct peaks at 6 and 48 h. Experiments with P-selectin gene-targeted mice showed that the P-selectin measured was exclusively expressed by EC rather than platelets. The early and late phases of selectin expression in contact sensitivity were differentiated in terms of their requirement for prior sensitization, and the action of IL-1. Whereas the early phase was a nonspecific 'irritant' response to oxazolone, the late phase was Ag specific and was partially IL-1 dependent. Therefore, persistence of both E- and P-selectin expression in vivo can occur as a result of sequential and distinct EC activation processes that appear to be at least partially different from those previously reported as stimulating ICAM-1 and VCAM-1 expression. The further elucidation of mechanisms of EC activation in this model may help determine the relative roles of selectins and ligands for leukocyte integrins in the sequential recruitment of T cells and other leukocyte subsets during ongoing immune-mediated inflammatory responses.