Metabolic Incorporation of N-Acetyl Muramic Acid Probes into Bacterial Peptidoglycan
Q3 Biochemistry, Genetics and Molecular Biology
Kristen E. DeMeester, Hai Liang, Junhui Zhou, Kimberly A. Wodzanowski, Benjamin L. Prather, Cintia C. Santiago, Catherine L. Grimes
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引用次数: 10
Abstract
Bacterial cells utilize small carbohydrate building blocks to construct peptidoglycan (PG), a highly conserved mesh-like polymer that serves as a protective coat for the cell. PG production has long been a target for antibiotics, and its breakdown is a source for human immune recognition. A key component of bacterial PG, N-acetyl muramic acid (NAM), is a vital element in many synthetically derived immunostimulatory compounds. However, the exact molecular details of these structures and how they are generated remain unknown due to a lack of chemical probes surrounding the NAM core. A robust synthetic strategy to generate bioorthogonally tagged NAM carbohydrate units is implemented. These molecules serve as precursors for PG biosynthesis and recycling. Escherichia coli cells are metabolically engineered to incorporate the bioorthogonal NAM probes into their PG network. The probes are subsequently modified using copper-catalyzed azide-alkyne cycloaddition to install fluorophores directly into the bacterial PG, as confirmed by super-resolution microscopy and high-resolution mass spectrometry. Here, synthetic notes for key elements of this process to generate the sugar probes as well as streamlined user-friendly metabolic labeling strategies for both microbiology and immunological applications are described. © 2019 by John Wiley & Sons, Inc.
Basic Protocol 1: Synthesis of peracetylated 2-azido glucosamine
Basic Protocol 2: Synthesis of 2-azido and 2-alkyne NAM
Basic Protocol 3: Synthesis of 3-azido NAM methyl ester
Basic Protocol 4: Incorporation of NAM probes into bacterial peptidoglycan
Basic Protocol 5: Confirmation of bacterial cell wall remodeling by mass spectrometry
n -乙酰基陶瓷酸探针在细菌肽聚糖中的代谢结合
细菌细胞利用小碳水化合物构建肽聚糖(PG),这是一种高度保守的网状聚合物,可作为细胞的保护层。PG的生产长期以来一直是抗生素的目标,其分解是人类免疫识别的来源。细菌PG的关键成分n -乙酰氨基乙酸(NAM)是许多合成衍生的免疫刺激化合物的重要元素。然而,由于缺乏围绕不结盟运动核的化学探针,这些结构的确切分子细节以及它们是如何产生的仍然未知。一个强大的合成策略,以产生生物正交标记NAM碳水化合物单位实施。这些分子作为PG生物合成和再循环的前体。大肠杆菌细胞通过代谢工程将生物正交NAM探针纳入其PG网络。随后使用铜催化叠氮化物-炔环加成修饰探针,将荧光团直接安装到细菌PG中,超分辨率显微镜和高分辨率质谱法证实了这一点。本文描述了该过程中生成糖探针的关键要素的合成笔记,以及用于微生物学和免疫学应用的简化用户友好的代谢标记策略。©2019 by John Wiley &基础方案1:合成过乙酰化2-叠氮基氨基葡萄糖;基础方案2:合成2-叠氮基氨基葡萄糖;基础方案3:合成3-叠氮基氨基甲酯;基础方案4:将NAM探针掺入细菌肽聚糖;基础方案5:用质谱法确认细菌细胞壁重塑
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