Vershinin Zlata, Zaretsky Marianna, Eichler Jerry
Dept. of Life Sciences, Ben-Gurion University of the Negev, Beersheva, Israel.
BBA Adv. 2024 Aug 29;6:100120. doi: 10.1016/j.bbadva.2024.100120. eCollection 2024.
While performed by all three domains of life, N-glycosylation in Archaea is less well described than are the parallel eukaryal and bacterial processes. Still, what is known of the archaeal version of this universal post-translational modification reveals numerous seemingly domain-specific traits. Specifically, the biosynthesis of archaeal N-linked glycans relies on distinct pathway steps and components, rare sugars and sugar modifications, as well as unique lipid carriers upon which N-linked glycans are assembled. At the same time, Archaea possess the apparently unique ability to simultaneously modify their glycoproteins with very different N-linked glycans. In addition to these biochemical aspects of archaeal N-glycosylation, such post-translational modification has been found to serve a wide range of roles possibly unique to Archaea, including allowing these microorganisms to not only cope with the harsh physical conditions of the niches they can inhabit but also providing the ability to adapt to transient changes in such environments.
虽然生命的三个域都能进行N-糖基化,但与真核生物和细菌的平行过程相比,古菌中的N-糖基化描述得较少。尽管如此,关于这种普遍的翻译后修饰的古菌版本的已知信息揭示了许多看似特定域的特征。具体而言,古菌N-连接聚糖的生物合成依赖于不同的途径步骤和成分、稀有糖和糖修饰,以及组装N-连接聚糖的独特脂质载体。同时,古菌具有明显独特的能力,能够同时用非常不同的N-连接聚糖修饰其糖蛋白。除了古菌N-糖基化的这些生化方面,这种翻译后修饰已被发现发挥了一系列可能是古菌独有的作用,包括使这些微生物不仅能够应对它们可以栖息的生态位的恶劣物理条件,还能提供适应此类环境中瞬态变化的能力。