PMI-controlled mannose metabolism and glycosylation determines tissue tolerance and virus fitness.
Ronghui LiangZi-Wei YeZhenzhi QinYubin XieXiaomeng YangHaoran SunQiaohui DuPeng LuoKaiming TangBodan HuJianli CaoXavier Hoi-Leong WongGuang-Sheng LingHin ChuJiangang ShenFeifei YinDong-Yan JinJasper Fuk-Woo ChanKwok-Yung YuenShuo-Feng YuanPublished in: Nature communications (2024)
Host survival depends on the elimination of virus and mitigation of tissue damage. Herein, we report the modulation of D-mannose flux rewires the virus-triggered immunometabolic response cascade and reduces tissue damage. Safe and inexpensive D-mannose can compete with glucose for the same transporter and hexokinase. Such competitions suppress glycolysis, reduce mitochondrial reactive-oxygen-species and succinate-mediated hypoxia-inducible factor-1α, and thus reduce virus-induced proinflammatory cytokine production. The combinatorial treatment by D-mannose and antiviral monotherapy exhibits in vivo synergy despite delayed antiviral treatment in mouse model of virus infections. Phosphomannose isomerase (PMI) knockout cells are viable, whereas addition of D-mannose to the PMI knockout cells blocks cell proliferation, indicating that PMI activity determines the beneficial effect of D-mannose. PMI inhibition suppress a panel of virus replication via affecting host and viral surface protein glycosylation. However, D-mannose does not suppress PMI activity or virus fitness. Taken together, PMI-centered therapeutic strategy clears virus infection while D-mannose treatment reprograms glycolysis for control of collateral damage.
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