electron transport chain

Cinchona-based liquid formulation exhibits antifungal activity through Tryptophan starvation and disruption of mitochondrial respiration in Rhizoctonia Solani

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Researchers found that an extract from Cinchona bark, containing the compound quinine, effectively kills rice-damaging fungus Rhizoctonia solani through two mechanisms: starving the fungus of the amino acid tryptophan and disrupting its energy-producing mitochondria. This natural plant-based treatment could serve as an eco-friendly alternative to synthetic fungicides, reducing crop losses from fungal diseases while avoiding the environmental damage and resistance problems associated with chemical pesticides.

Cinchona-based liquid formulation exhibits antifungal activity through Tryptophan starvation and disruption of mitochondrial respiration in Rhizoctonia Solani

mycolabadmin

Scientists tested a plant-based extract from Cinchona bark as a natural fungicide against a serious fungus that damages rice crops. The active ingredient, quinine, works by two methods: it blocks the fungus from getting the amino acid tryptophan it needs to survive, and it damages the fungus’s energy-producing structures. When researchers added tryptophan back to the treated fungus, it recovered, confirming this is how the treatment works. This natural fungicide could offer farmers an eco-friendly alternative to chemical pesticides.

Cinchona-based liquid formulation exhibits antifungal activity through Tryptophan starvation and disruption of mitochondrial respiration in Rhizoctonia Solani

mycolabadmin

Scientists discovered that a liquid extract from Cinchona bark, which contains quinine, can effectively kill a fungus that damages rice crops. The treatment works by blocking the fungus’s ability to absorb tryptophan (an important amino acid) and damaging its energy-producing mitochondria. When tryptophan was added back to the treatment, the fungus recovered, confirming this is the main way the extract works. This natural, plant-based approach could provide an eco-friendly alternative to chemical fungicides while reducing the risk of the fungus developing resistance.

Asymmetric mitonuclear interactions trigger transgressive inheritance and mitochondria-dependent heterosis in hybrids of the model system Pleurotus ostreatus

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This research examines how mushroom hybrids inherit different combinations of genes from their parents, specifically looking at genes in the nucleus versus the mitochondria (cellular energy factories). When mushrooms with mismatched nuclear and mitochondrial genes are crossed, some grow slowly and show stress, while others surprisingly grow very well. The study identifies which genes are activated under these conditions and how they affect mushroom production quality and yield.

Carabrone inhibits Gaeumannomyces tritici growth by targeting mitochondrial complex I and destabilizing NAD⁺/NADH homeostasis

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Researchers identified how carabrone, a natural compound from plants, kills a fungus that causes wheat disease. The compound works by blocking a key energy-producing system (complex I) inside the fungus’s cells, which prevents it from producing enough energy to survive. This discovery is important because many current fungicides are losing effectiveness due to resistance, and this compound offers a new way to attack fungi. The findings could help develop new and more effective fungicides for protecting crops.

Impact of a Formulation Containing Chaga Extract, Coenzyme Q10, and Alpha-Lipoic Acid on Mitochondrial Dysfunction and Oxidative Stress: NMR Metabolomic Insights into Cellular Energy

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A new supplement formula combining Chaga mushroom extract, Coenzyme Q10, and alpha-lipoic acid was tested on nerve cells in the laboratory. The formula increased the cells’ energy production and protected them from harmful oxidative stress. This could potentially help people with conditions like fibromyalgia and neurodegenerative diseases that involve mitochondrial dysfunction.

Alternative oxidase gene induced by nitric oxide is involved in the regulation of ROS and enhances the resistance of Pleurotus ostreatus to heat stress

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Oyster mushrooms are commonly grown in controlled facilities but struggle with high summer temperatures. This study found that a molecule called nitric oxide helps mushroom cells survive heat stress by activating a special protein called alternative oxidase (AOX), which reduces harmful molecules called reactive oxygen species. By understanding this mechanism, growers may be able to improve mushroom cultivation and yield during hot weather.

Caged-hypocrellin mediated photodynamic therapy induces chromatin remodeling and disrupts mitochondrial energy metabolism in multidrug-resistant Candida auris

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Researchers developed a new photodynamic therapy treatment using a light-activated compound called COP1T-HA to fight drug-resistant Candida auris infections. The therapy works by reorganizing the fungal cell’s genetic material architecture and disrupting energy production in mitochondria, ultimately killing the fungal cells. This approach represents a novel strategy to overcome antibiotic resistance, as it targets multiple cellular processes rather than a single pathway that fungi can easily resist.

Research Keyword: electron transport chain