Pseudaminic acid是一種唾液酸的衍生物,也是許多革蘭氏陰性菌細胞表面的醣聚合物的成分之一。不同革蘭氏陰性菌的細胞表面,有些含有pseudaminic acid,有些則是含有pseudaminic acid的衍生物,而衍生物就是原本pseudaminic acid的架構在碳五或碳七的胺基上做不同的官能基改變。許多研究指出pseudaminic acid與細菌是否能感染宿主細胞因而致病有關,而常見的革蘭氏陰性菌例如:大腸桿菌、弧菌、綠膿桿菌…等。這些革蘭氏陰性菌都具有致病性,並且對人體有害,而大多數的抗生素都不能有效抑制此類細菌,所以對於pseudaminic acid在感染宿主機制上所扮演的角色的研究是非常重要的,但由於目前無法藉由培養細菌大量純化取得pseudaminic acid,因此如何以人工合成pseudaminic acid便顯得十分重要,有鑑於現行發表的數種合成方法有著低總產率及步驟繁複等缺點。在本論文中,我們設計了新的合成路徑,除了能使用較便宜的D-glucosamine和L-ascorbic acid (俗稱維他命C)作為起始物,還能在較少合成的步驟中能將pseudaminic acid的碳五與碳七位置上的疊氮選擇以不同官能基去修飾,形成不同胺的官能基,這對於在pseudaminic acid及相關衍生物的合成是尤為重要的。;The nonulosonic acid class of sugars consists of 9-carbon α-keto acid carbohydrate monomers. Unique to bacterial species are the recently identified sialic acid derivatives, which are an important sub-class of nonulosonic acids. Pseudaminic acid and legionaminic acid occur as several derivatives with changes in the nature of the amide groups attached to C-5 and C-7. Pseudaminic acid with the L-glycero-L-manno configuration differs from sialic acid in configuration at both the C-5 and C-7 positions in addition to the deoxygenation at C-9 and the N for O substitution at C-7. Pseudaminic acid is found coating the surface of various bacterial human pathogens. Protein glycosylation is an essential post-translational modification in bacteria that has emerged as a new entry to study bacterial pathogenesis and develop novel therapeutic intervention. In particular, Pseudaminylation of proteins has been the subject of significant interest owing to their importance in Gram-negative bacterial pathogens. To date, several synthetic routes have been reported to synthesize pseudaminic acid and its derivatives. All these efforts resulted in poor overall yield and low stereo- and regioselectivity through a number of steps total synthesis. Herein we present two facile de novo synthetic routes toward pseudaminic acid and its functionalized derivatives from easily available D-glucosamine and L-ascorbic acid (vitamin C), respectively. The key reactions in our de novo synthesis involve the diastereoselective azide-based SN2 reaction to create the 2,4-anti-diamino skeleton, followed by the reduction and aldol-type allylation.
