Judd Heather N, Sanchez Karol M, Dublino Leah S, Zhang Gabriel J, Gal Daniel, Couto-Rodríguez Ricardo L, Maupin-Furlow Julie A
Department of Microbiology and Cell Science, Institute of Food and Agricultural Sciences, University of Florida, Gainesville, FL, USA.
Genetics Institute, University of Florida, Gainesville, FL, USA.
bioRxiv. 2025 May 28:2025.05.27.656527. doi: 10.1101/2025.05.27.656527.
Lysine acetylation is a widespread post-translational modification (PTM) involved in regulating key biological processes including central metabolism and chromatin dynamics, yet its roles in archaea remain poorly understood. Here, we investigated two GNAT (Gcn5-related N-acetyltransferase) family homologs, and , in the halophilic archaeon (Hv). We found that a mutant exhibited impaired growth and premature cell death on glycerol, a phenotype not observed in the parent strain, mutant, or during growth on glucose. Complementation with plasmid-expressed restored growth on glycerol, confirming this biological role. assays demonstrated that HvPat2 catalyzes the lysine acetylation of HvGlpK, a glycerol kinase essential for glycerol metabolism. Computational modeling predicted that HvPat2 residues E105, Y154, V110, and N147 may form hydrogen bonds with acetyl-CoA. To assess the functional importance of these residues, alanine substitutions were introduced at each site. Growth assays revealed that E105A and Y154A variants failed to restore growth on glycerol, while V110A and N147A had no significant effect. , HvPat2 Y154A, E105A, and V110A lacked acetyltransferase activity toward GlpK, whereas N147A retained partial activity. HvPat2 Y154A co-purified with a protein partner, potentially explaining the discrepancy between and results. These findings highlight the critical role of the GNAT HvPat2 in mediating lysine acetylation in regulating glycerol metabolism in archaea and offer mechanistic insight into GNAT family acetyltransferases.
赖氨酸乙酰化是一种广泛存在的翻译后修饰(PTM),参与调节包括中心代谢和染色质动力学在内的关键生物学过程,但其在古菌中的作用仍知之甚少。在此,我们研究了嗜盐古菌(Hv)中的两个GNAT(与Gcn5相关的N - 乙酰转移酶)家族同源物,即 和 。我们发现一个 突变体在甘油上生长受损且细胞过早死亡,这一表型在亲本菌株、 突变体或在葡萄糖上生长时未观察到。用质粒表达的 进行互补恢复了在甘油上的生长,证实了这一生物学作用。 实验表明,HvPat2催化HvGlpK的赖氨酸乙酰化,HvGlpK是甘油代谢所必需的甘油激酶。计算模型预测,HvPat2的E105、Y154、V110和N147残基可能与乙酰辅酶A形成氢键。为了评估这些残基功能的重要性,在每个位点引入了丙氨酸替代。生长实验表明,E105A和Y154A变体未能恢复在甘油上的生长,而V110A和N147A没有显著影响。此外,HvPat2 Y154A、E105A和V110A对GlpK缺乏乙酰转移酶活性,而N147A保留了部分活性。HvPat2 Y154A与一个蛋白质伴侣共纯化,这可能解释了 和 结果之间的差异。这些发现突出了GNAT HvPat2在介导赖氨酸乙酰化以调节古菌甘油代谢中的关键作用,并为GNAT家族乙酰转移酶提供了机制上的见解。
