HIF-1α-mediated glycolytic reprogramming facilitates decapod iridescent virus 1 pathogenesis in Macrobrachium rosenbergii: Central role of hexokinase in viral metabolic hijacking

IF 2.4 3区农林科学 Q1 FISHERIES

Developmental and comparative immunology Pub Date : 2025-07-12 DOI:10.1016/j.dci.2025.105414

Yu-Kun Jie , Jing-Wen Hao , Cui Liu , Jun-Jun Yan , Tian-Tian Ye , Ji-Lun Meng , Guo Li , Yu-Tong Zheng , Hong-Tuo Fu , Zhi-Min Gu

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引用次数: 0

Abstract

Decapod iridescent virus 1 (DIV1) poses a severe threat to global aquaculture, yet the mechanisms underlying its metabolic hijacking of host pathways remain poorly understood. Here, we demonstrate that DIV1 infection in Macrobrachium rosenbergii induces a hypoxia-inducible factor 1α (HIF-1α)-mediated Warburg-like metabolic reprogramming, with hexokinase (MrHK) serving as a central metabolic hub. Proteomic profiling of DIV1-infected shrimp hemocytes identified 902 differentially expressed proteins (DEPs), revealing striking upregulation of glycolysis pathway. The temporal analysis confirmed stage-specific induction of MrHK and synchronized activation of downstream glycolytic enzymes, mirroring full-pathway metabolic hijacking. Evolutionary and structural analyses revealed MrHK's conservation across crustaceans and identified two functional HK domains. Targeting MrHK with the inhibitor 2-deoxy-D-glucose (2-DG) reduced viral copies and improved survival rates from 21.21 % to 43.33 %. Mechanistically, DIV1 stabilizes HIF-1α under normoxia to transactivate MrHK via three hypoxia-response elements (HREs), with mutagenesis of the core HRE motif abolishing promoter activity. Silencing MrHIF-1α attenuated MrHK expression and activity, viral copies, and improved survival, highlighting the axis's therapeutic potential. These findings establish HIF-1α-driven glycolytic reprogramming as a deliberate viral strategy, advancing our understanding of the molecular mechanisms behind DIV1 infection and offering actionable targets for metabolic interventions and host-directed therapies to combat DIV1 outbreaks in aquaculture.

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hif -1α介导的糖酵解重编程促进了罗氏螯虾彩虹十足病毒1的发病机制：己糖激酶在病毒代谢劫持中的核心作用

十足类彩虹病毒1 （DIV1）对全球水产养殖构成严重威胁，但其劫持宿主代谢途径的机制尚不清楚。在这里，我们证明了罗氏沼虾中DIV1感染诱导了缺氧诱导因子1α (HIF-1α)介导的Warburg-like代谢重编程，其中己糖激酶（MrHK）作为中心代谢枢纽。对感染div1的虾血细胞进行蛋白质组学分析，鉴定出902个差异表达蛋白（DEPs），揭示糖酵解途径的显著上调。时间分析证实了MrHK的阶段特异性诱导和下游糖酵解酶的同步激活，反映了全途径的代谢劫持。进化和结构分析揭示了MrHK在甲壳类动物中的保守性，并确定了两个功能性HK结构域。用抑制剂2-脱氧-d -葡萄糖（2-DG）靶向MrHK可以减少病毒拷贝数，并将存活率从21.21%提高到43.33%。在机制上，DIV1在常氧条件下稳定HIF-1α，通过三个缺氧反应元件（HREs）激活MrHK，核心HRE基序的突变消除启动子活性。沉默MrHIF-1α可降低MrHK的表达和活性，降低病毒拷贝数，并改善存活，突出了该轴的治疗潜力。这些发现确立了hif -1α驱动的糖酵解重编程是一种蓄意的病毒策略，促进了我们对DIV1感染背后的分子机制的理解，并为代谢干预和宿主定向治疗提供了可操作的靶点，以对抗水产养殖中DIV1的爆发。

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来源期刊

Developmental and comparative immunology 医学-动物学

CiteScore

6.20

自引率

6.90%

发文量

206

审稿时长

49 days

期刊介绍： Developmental and Comparative Immunology (DCI) is an international journal that publishes articles describing original research in all areas of immunology, including comparative aspects of immunity and the evolution and development of the immune system. Manuscripts describing studies of immune systems in both vertebrates and invertebrates are welcome. All levels of immunological investigations are appropriate: organismal, cellular, biochemical and molecular genetics, extending to such fields as aging of the immune system, interaction between the immune and neuroendocrine system and intestinal immunity.