Maaheimo H, Renkonen R, Turunen J P, Penttilä L, Renkonen O
Institute of Biotechnology, University of Helsinki, Finland.
Eur J Biochem. 1995 Dec 1;234(2):616-25. doi: 10.1111/j.1432-1033.1995.616_b.x.
The recognition of cell-surface L-selectin by its carbohydrate ligands causes lymphocytes to roll on capillary endothelium at sites of inflammation. As this primary contact is a prerequisite for extravasation of the leukocytes to the tissue, its inhibition by free oligosaccharides capable of competing with the natural L-selectin ligands in an attractive therapeutic possibility. The exact structures of the biological ligands of L-selectin are not yet known, but the principal carbohydrate epitopes share some structural features: they are O-glycosidically linked mucin-type oligosaccharides with N-acetyllactosamine backbone, which is 3'-sialylated or 3'-sulfated, 3-fucosylated and sometimes 6- or 6'-sulfated at the distal N-acetyllactosamine termini. Multivalency of the ligand, which is believed to enhance the binding, is achieved by a branched polylactosamine backbone or by a clustered array of O-glycans. We report here enzymic synthesis of a large oligosaccharide fulfilling several of the features characteristic to the L-selectin ligands: it is a dodecameric O-glycosidic core-2-type oligosaccharide alditol with a branched polylactosamine backbone carrying two distal alpha-2,3'-sialylated and alpha-1,3-fucosylated N-acetyl-lactosamine groups (sialyl Lewis x, sialyl Le(x)). The structure of each saccharide on the synthesis route from disaccharide Gal beta 1-3GalNAc to the dodecasaccharide alditol was established by several methods including one- and two-dimensional 1H-NMR spectroscopy. The last step of the synthesis, the alpha-1,3-fucosylation of the 6-linked arm proceeded sluggishly, and was associated with a noticeable shift in H1 resonance of the GlcNAc residue of the branch-bearing N-acetyllactosamine unit. The final synthesis product and its analogs lacking one or both of the fucose residues were tested as inhibitors of L-selectin-mediated lymphocyte-endothelium interaction in vitro in rejecting rat kidney transplant. While the non-fucosylated O-glycosidic oligosaccharide alditol did not possess any inhibitory activity, the mono-fucosylated one (i.e. monovalent sialyl Le(x)) prevented the binding significantly and the difucosylated dodecasaccharide alditol (i.e. divalent sialyl Le(x)) was a very potent inhibitor (IC50, inhibitory concentration preventing 50% of binding = 0.15 microM). Besides the multivalency, also the Gal beta 1-3GalNAc-ol sequence of the O-glycosidic core appeared to increase the affinity of the glycan to L-selectin. This was indicated by parallel inhibition experiments, where a disialylated and difucosylated branched polylactosamine decasaccharide, similar to the divalent dodecasaccharide alditol, but lacking the reduced O-glycosidic core, was a less effective inhibitor (IC50 = 0.5 microM) than the O-glycosidic dodecasaccharide alditol.
细胞表面的L-选择素被其碳水化合物配体识别,可使淋巴细胞在炎症部位的毛细血管内皮上滚动。由于这种初始接触是白细胞向组织外渗的前提条件,因此,能够与天然L-选择素配体竞争的游离寡糖对其进行抑制是一种有吸引力的治疗可能性。L-选择素的生物配体的确切结构尚不清楚,但主要的碳水化合物表位具有一些结构特征:它们是O-糖苷键连接的粘蛋白型寡糖,具有N-乙酰乳糖胺主链,该主链在3'-位被唾液酸化或硫酸化,在3-位被岩藻糖基化,有时在远端N-乙酰乳糖胺末端的6-或6'-位被硫酸化。配体的多价性被认为可增强结合,它通过分支的聚乳糖胺主链或O-聚糖的簇状排列来实现。我们在此报告一种大寡糖的酶促合成,该寡糖具有L-选择素配体的几个特征:它是一种十二聚体O-糖苷核心2型寡糖糖醇,具有分支的聚乳糖胺主链,带有两个远端α-2,3'-唾液酸化和α-1,3-岩藻糖基化的N-乙酰乳糖胺基团(唾液酸化Lewis x,唾液酸化Le(x))。从二糖Galβ1-3GalNAc到十二糖糖醇的合成路线上每个糖的结构通过多种方法确定,包括一维和二维1H-NMR光谱。合成的最后一步,6-连接臂的α-1,3-岩藻糖基化进行缓慢,并与带有分支的N-乙酰乳糖胺单元的GlcNAc残基的H1共振发生明显位移有关。最终合成产物及其缺少一个或两个岩藻糖残基的类似物在体外大鼠肾移植排斥反应中作为L-选择素介导的淋巴细胞-内皮细胞相互作用的抑制剂进行了测试。虽然非岩藻糖基化的O-糖苷寡糖糖醇没有任何抑制活性,但单岩藻糖基化的寡糖(即单价唾液酸化Le(x))可显著阻止结合,而双岩藻糖基化的十二糖糖醇(即二价唾液酸化Le(x))是一种非常有效的抑制剂(IC50,抑制50%结合的抑制浓度 = 0.15μM)。除了多价性外,O-糖苷核心的Galβ1-3GalNAc-ol序列似乎也增加了聚糖对L-选择素的亲和力。平行抑制实验表明了这一点,其中一种双唾液酸化和双岩藻糖基化的分支聚乳糖胺十糖,与二价十二糖糖醇类似,但缺少还原的O-糖苷核心,是一种比O-糖苷十二糖糖醇效果更差的抑制剂(IC50 = 0.5μM)。
