Functional analyses and integrated mechanisms of cellular destruction by L-amino acid oxidase

bioRxiv - Cell Biology Pub Date : 2024-09-16 DOI:10.1101/2024.09.16.613219

Krisna Prak, Christin Luft, Eliona Tsefou, Carlos Chavez-Olortegui, Janos Kriston-Vizi, Robin Ketteler, Vania Braga

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Abstract

Snakebite accidents are prevalent worldwide and cause a spectrum of severe clinical manifestations and reduction of patient quality of life and economic income. L-amino acid oxidase (LAAO) is a highly toxic enzyme present in various venoms that causes tissue necrosis, oedema, coagulopathies, and organ failure. Here we investigate the mechanisms of LAAO cytotoxicity preceding cell death using recombinant LAAO and a catalytic inactive LAAO mutant. Wild-type LAAO uptake by cells leads to a decrease in lysosome number and size and inhibition of autophagy flux. Mitochondria function is also impaired by severe proton leakage leading to mitochondrial fission. Despite engulfment by autophagosomes, clearance of mitochondria is prevented by the lysosomal defects. The coordinate multi-organelle dysfunction strongly perturbs energy production, cell metabolism and clearance of defective organelles by autophagy, thereby triggering an irreversible destructive path. Considering the fast organelle impairment, strategies to reduce multi-organelle injury after LAAO exposure may be effective to maintain critical cell functions and strengthen adaptive responses against cytotoxicity.

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L- 氨基酸氧化酶破坏细胞的功能分析和综合机制

毒蛇咬伤事故在全球范围内普遍存在，会导致一系列严重的临床表现，降低患者的生活质量和经济收入。L-氨基酸氧化酶（LAAO）是存在于各种毒液中的一种剧毒酶，可导致组织坏死、水肿、凝血障碍和器官衰竭。在这里，我们利用重组 LAAO 和催化活性不高的 LAAO 突变体研究了细胞死亡前 LAAO 的细胞毒性机制。细胞吸收野生型 LAAO 会导致溶酶体数量和大小的减少，并抑制自噬通量。线粒体功能也因质子严重泄漏而受损，导致线粒体分裂。尽管线粒体被自噬体吞噬，但溶酶体缺陷阻碍了线粒体的清除。协调的多细胞器功能障碍强烈干扰了能量生产、细胞新陈代谢和自噬对缺陷细胞器的清除，从而引发了不可逆转的破坏路径。考虑到细胞器的快速损伤，减少LAAO暴露后多细胞器损伤的策略可能会有效维持细胞的关键功能，并加强对细胞毒性的适应性反应。

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bioRxiv - Cell Biology

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