A novel mechanism for centrosome expulsion ensures metabolic activity in polyploid cells

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The study investigates how physiological polyploid Drosophila acentrosomal salivary gland cells eliminate centrosomes, using genetic manipulation, live imaging, super-resolution microscopy with tissue clearing, and electron microscopy. The authors identify an in vivo centrosome elimination pathway requiring non-muscle myosin II activity and macroautophagic machinery, in which centrosomes are released into the gland lumen via autolysosomal exocytosis. When centrosomes fail to be eliminated, the mitochondria network is disrupted, leading to impaired respiration and ATP production. This paper does not explicitly discuss endometriosis or adenomyosis; it was included in the corpus via a keyword match in the upstream search index.

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Abstract

Programmed polyploidy is often linked to increase cell size to support enhanced metabolism, barrier function or regeneration. In certain polyploid cells, the cytoskeleton is drastically remodeled-most notably by eliminating centrosomes. However, the purpose and mechanisms underlying centrosome elimination have remained unclear. We investigated this question in Drosophila acentrosomal salivary glands (SGs), a physiological polyploid model where cells reach high chromosome content through endoreplication. Using genetic tools, live imaging approaches, super-resolution microscopy combined with tissue clearing and electron microscopy, our study uncovers a novel centrosome elimination pathway in vivo . This process requires non-muscle myosin II (MyoII) activity and the macroautophagic machinery to drive centrosome release into the lumen of the salivary glands via autolysosomal exocytosis. Failure to eliminate centrosomes disrupts the mitochondria network, impairing respiration and ATP production. Our findings reveal a previously unknown mechanism that removes centrosomes through the secretory autophagy pathway to protect mitochondrial function and support the high metabolic demands of polyploid cells.
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Abstract Programmed polyploidy is often linked to increase cell size to support enhanced metabolism, barrier function or regeneration. In certain polyploid cells, the cytoskeleton is drastically remodeled-most notably by eliminating centrosomes. However, the purpose and mechanisms underlying centrosome elimination have remained unclear. We investigated this question in Drosophila acentrosomal salivary glands (SGs), a physiological polyploid model where cells reach high chromosome content through endoreplication. Using genetic tools, live imaging approaches, super-resolution microscopy combined with tissue clearing and electron microscopy, our study uncovers a novel centrosome elimination pathway in vivo. This process requires non-muscle myosin II (MyoII) activity and the macroautophagic machinery to drive centrosome release into the lumen of the salivary glands via autolysosomal exocytosis. Failure to eliminate centrosomes disrupts the mitochondria network, impairing respiration and ATP production. Our findings reveal a previously unknown mechanism that removes centrosomes through the secretory autophagy pathway to protect mitochondrial function and support the high metabolic demands of polyploid cells. Competing Interest Statement The authors have declared no competing interest.

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