Research Topic: Carotenoid biosynthesis

Light-responsive transcription factor CmOzf integrates conidiation, fruiting body development, and secondary metabolism in Cordyceps militaris

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Scientists studied a medicinal fungus called Cordyceps militaris and discovered that a protein called CmOzf acts as a master controller of several important processes. When light shines on the fungus, it activates CmOzf, which helps the fungus produce spores for reproduction through a specific genetic pathway. Interestingly, when CmOzf is blocked, the fungus produces fewer spores but makes more pigments and beneficial compounds. This discovery could help improve the production of medicinal compounds from this fungus and its use as a natural pest control agent.

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Molecular Regulation of Carotenoid Accumulation Enhanced by Oxidative Stress in the Food Industrial Strain Blakeslea trispora

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Researchers studied how stressful conditions can make a fungus called Blakeslea trispora produce more carotenoids, which are natural pigments used to color food products. When exposed to chemical stressors like rose bengal or hydrogen peroxide, the fungus produced significantly more carotenoids – up to four times more in some cases. The study identified specific genes and cellular pathways responsible for this increased production, which could help food companies produce natural food colorants more efficiently.

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Adaptive laboratory evolution of Blakeslea trispora under acetoacetanilide stress leads to enhanced β-carotene biosynthesis

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Scientists used a technique called adaptive laboratory evolution to make a fungus called Blakeslea trispora produce much more beta-carotene, a natural compound that converts to vitamin A in the body and has health benefits. By gradually exposing the fungus to increasing levels of a chemical stressor over 16 months, they helped it evolve to produce 45% more beta-carotene. The adapted fungus showed changes in its genes, physical structure, and fat composition that helped it thrive under stress while making more of this valuable compound.

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