Shriver Z, Raman R, Venkataraman G, Drummond K, Turnbull J, Toida T, Linhardt R, Biemann K, Sasisekharan R
Division of Bioengineering and Environmental Health, Harvard-Massachusetts Institute of Technology, Biomedical Engineering, Cambridge, MA 02139, USA.
Proc Natl Acad Sci U S A. 2000 Sep 12;97(19):10359-64. doi: 10.1073/pnas.97.19.10359.
Heparin- and heparan sulfate-like glycosaminoglycans (HLGAGs) represent an important class of molecules that interact with and modulate the activity of growth factors, enzymes, and morphogens. Of the many biological functions for this class of molecules, one of its most important functions is its interaction with antithrombin III (AT-III). AT-III binding to a specific heparin pentasaccharide sequence, containing an unusual 3-O sulfate on a N-sulfated, 6-O sulfated glucosamine, increases 1,000-fold AT-III's ability to inhibit specific proteases in the coagulation cascade. In this manner, HLGAGs play an important biological and pharmacological role in the modulation of blood clotting. Recently, a sequencing methodology was developed to further structure-function relationships of this important class of molecules. This methodology combines a property-encoded nomenclature scheme to handle the large information content (properties) of HLGAGs, with matrix-assisted laser desorption ionization MS and enzymatic and chemical degradation as experimental constraints to rapidly sequence picomole quantities of HLGAG oligosaccharides. Using the above property-encoded nomenclature-matrix-assisted laser desorption ionization approach, we found that the sequence of the decasaccharide used in this study is DeltaU(2S)H(NS,6S)I(2S)H(NS, 6S)I(2S)H(NS,6S)IH(NAc,6S)GH(NS,3S,6S) (+/-DDD4-7). We confirmed our results by using integral glycan sequencing and one-dimensional proton NMR. Furthermore, we show that this approach is flexible and is able to derive sequence information on an oligosaccharide mixture. Thus, this methodology will make possible both the analysis of other unusual sequences in HLGAGs with important biological activity as well as provide the basis for the structural analysis of these pharamacologically important group of heparin/heparan sulfates.
肝素及类硫酸乙酰肝素糖胺聚糖(HLGAGs)是一类重要的分子,它们能与生长因子、酶和形态发生素相互作用并调节其活性。在这类分子的众多生物学功能中,其最重要的功能之一是与抗凝血酶III(AT-III)相互作用。AT-III与特定的肝素五糖序列结合,该序列在N-硫酸化、6-O-硫酸化的葡萄糖胺上含有一个不寻常的3-O-硫酸酯,可使AT-III抑制凝血级联中特定蛋白酶的能力提高1000倍。通过这种方式,HLGAGs在调节血液凝固中发挥着重要的生物学和药理学作用。最近,一种测序方法被开发出来,以进一步研究这类重要分子的结构-功能关系。该方法将一种属性编码命名方案与基质辅助激光解吸电离质谱以及酶促和化学降解相结合,作为实验限制条件,以快速对皮摩尔量的HLGAG寡糖进行测序。使用上述属性编码命名-基质辅助激光解吸电离方法,我们发现本研究中使用的十糖序列为DeltaU(2S)H(NS,6S)I(2S)H(NS, 6S)I(2S)H(NS,6S)IH(NAc,6S)GH(NS,3S,6S) (+/-DDD4-7)。我们通过完整聚糖测序和一维质子核磁共振证实了我们的结果。此外,我们表明这种方法具有灵活性,能够从寡糖混合物中获得序列信息。因此,这种方法将使分析具有重要生物活性的HLGAGs中的其他异常序列成为可能,并为这些具有重要药理学意义的肝素/硫酸乙酰肝素类的结构分析提供基础。