Molecular basis for thermogenesis and volatile production in the titan arum

The titan arum ( ), commonly known as the corpse flower, produces the largest unbranched inflorescence in the world. Its rare blooms last only a few days and are notable both for their burst of thermogenic activity and for the odor of rotting flesh by which they attract pollinators. Studies on the t...

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Veröffentlicht in:PNAS nexus 2024-11, Vol.3 (11), p.pgae492
Hauptverfasser: Zulfiqar, Alveena, Azhar, Beenish J, Shakeel, Samina N, Thives Santos, William, Barry, Theresa D, Ozimek, Dana, DeLong, Kim, Angelovici, Ruthie, Greenham, Kathleen, Schenck, Craig A, Schaller, G Eric
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Sprache:eng
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Zusammenfassung:The titan arum ( ), commonly known as the corpse flower, produces the largest unbranched inflorescence in the world. Its rare blooms last only a few days and are notable both for their burst of thermogenic activity and for the odor of rotting flesh by which they attract pollinators. Studies on the titan arum can therefor lend insight into the mechanisms underlying thermogenesis as well as the production of sulfur-based volatiles, about which little is known in plants. Here, we made use of transcriptome and metabolite analyses to uncover underlying mechanisms that enable thermogenesis and volatile production in the titan arum. The ability to perform thermogenesis correlated with the expression of genes involved in bypass steps for the mitochondrial electron transport chain, in particular alternative oxidase expression, and through our analysis is placed within the context of sugar transport and metabolism. The major odorants produced by the titan arum are dimethyl disulfide and dimethyl trisulfide, and we identified pathways for sulfur transport and metabolism that culminate in the production of methionine, which our analysis identifies as the amino acid substrate for production of these odorants. Putrescine, derived from arginine, was identified as an additional and previously unrecognized component of the titan arum's odor. Levels of free methionine and putrescine were rapidly depleted during thermogenesis, consistent with roles in production of the titan arum's odor. Models for how tissues of the titan arum contribute to thermogenesis and volatile production are proposed.
ISSN:2752-6542
2752-6542
DOI:10.1093/pnasnexus/pgae492