La Santrer Emanoelle, Assunção Cláudia Barbosa, de Camargo Thiago Miguelito Navarro, Rodrigues Izabella, Campolina Sabrina Sidney, de Aguiar Edgar Lacerda, de Souza Rodrigues Thiago, Caligiorne Rachel Basques
Post-graduate Program in Medicine and Biomedicine, Faculdade de Saúde Santa Casa de Belo Horizonte, Belo Horizonte, Brazil.
Post-graduate Program in Modelagem Matemática Computacional, Centro Federal de Educação Tecnológica de Minas Gerais - CEFET-MG, Belo Horizonte, Brazil.
Front Microbiol. 2025 Aug 15;16:1630196. doi: 10.3389/fmicb.2025.1630196. eCollection 2025.
Protein Kinases (PKs) are a large family of enzymes that act as "molecular switches," playing fundamental role in cellular signaling through protein phosphorylation. This process consists in transfer a phosphate group (-PO₄) from ATP (adenosine triphosphate) to specific residues in target proteins; thereby, controlling vital cellular processes, such as (i) cell proliferation and differentiation, (ii) response to environmental stimuli (stress, nutrients, hormones), (iii) metabolism, (iv) cell cycle and apoptosis, and (v) signal transduction. Among fungi, adaptability is intrinsically connected to their ability to thrive under extreme environmental stress, being morphological plasticity an example of this adaptability. While many of these adaptive responses are regulated by diverse signaling pathways involving different kinase families, as mitogen-activated protein kinase (MAPK) for example, this review places a special focus on the General Control Nonderepressible 2 kinase (GCN2), a highly conserved sensor of amino acid scarcity in many fungi, as well as the species , , and . Amino acid deprivation triggers the accumulation of uncharged tRNAs, which directly activate GCN2, and this activation leads to the phosphorylation of the eukaryotic initiation factor 2 alpha () at the serine in the position 51, initiating the Integrated Stress Response (ISR). Phosphorylated suppresses global translation initiation while selectively enhancing the translation of stress-responsive genes, notably GCN4, which encodes a transcription factor that promotes amino acid biosynthesis and stress adaptation. In , GCN2 emerges as the sole kinase responsible for phosphorylation, a unique role in modulating translational responses to environmental and host-induced stressors. Previous studies have shown that the absence of GCN2 disrupts phosphorylation, impairing stress responses and reducing pathogenicity, therefore being an important target for development of new generation antifungals. To better understand the mechanistic role of GCN2 and related kinases in amino acid sensing and stress response, we present a review based on studying the central role of kinases in fungal stress adaptation, discussing how the high conservation of their catalytic kinase domains makes them valuable as phylogenetic markers and therapeutic targets.
蛋白激酶(PKs)是一类庞大的酶家族,起到“分子开关”的作用,通过蛋白质磷酸化在细胞信号传导中发挥重要作用。这个过程包括将磷酸基团(-PO₄)从三磷酸腺苷(ATP)转移到靶蛋白的特定残基上;从而控制重要的细胞过程,如(i)细胞增殖和分化,(ii)对环境刺激(应激、营养物质、激素)的反应,(iii)新陈代谢,(iv)细胞周期和细胞凋亡,以及(v)信号转导。在真菌中,适应性与其在极端环境压力下茁壮成长的能力内在相关,形态可塑性就是这种适应性的一个例子。虽然许多这些适应性反应是由涉及不同激酶家族的多种信号通路调节的,例如丝裂原活化蛋白激酶(MAPK),但本综述特别关注通用控制非抑制性2激酶(GCN2),它是许多真菌中高度保守的氨基酸缺乏传感器,以及物种 、 和 。氨基酸剥夺会触发无电荷tRNA的积累,后者直接激活GCN2,这种激活会导致真核起始因子2α( )在第51位丝氨酸处磷酸化,从而启动综合应激反应(ISR)。磷酸化的 抑制全局翻译起始,同时选择性增强应激反应基因的翻译,特别是GCN4,它编码一种促进氨基酸生物合成和应激适应的转录因子。在 中,GCN2成为负责 磷酸化的唯一激酶,在调节对环境和宿主诱导应激源的翻译反应中具有独特作用。先前的研究表明,GCN2的缺失会破坏 磷酸化,损害应激反应并降低致病性,因此是新一代抗真菌药物开发的重要靶点。为了更好地理解GCN2和相关激酶在氨基酸感知和应激反应中的机制作用,我们基于对激酶在真菌应激适应中的核心作用的研究进行了综述,讨论了它们催化激酶结构域的高度保守性如何使其成为有价值的系统发育标记和治疗靶点。
