Alcohol dehydrogenase 1 participates in the Crabtree effect and connects fermentative and oxidative metabolism in the Zygomycete Mucor circinelloides.

Mucor circinelloides is a dimorphic Zygomycete fungus that produces ethanol under aerobic conditions in the presence of glucose, which indicates that it is a Crabtree-positive fungus. To determine the physiological role of the alcohol dehydrogenase (ADH) activity elicited under these conditions, we obtained and characterized an allyl alcohol-resistant mutant that was defective in ADH activity, and examined the effect of adh mutation on physiological parameters related to carbon and energy metabolism. Compared to the Adh+ strain R7B, the ADH-defective (Adh-) strain M5 was unable to grow under anaerobic conditions, exhibited a considerable reduction in ethanol production in aerobic cultures when incubated with glucose, had markedly reduced growth capacity in the presence of oxygen when ethanol was the sole carbon source, and exhibited very low levels of NAD+-dependent alcohol de-hydrogenase activity in the cytosolic fraction. Further characterization of the M5 strain showed that it contains a 10-bp deletion that interrupts the coding region of the adhl gene. Complementation with the wild-type allele adh1+ by transformation of M5 remedied all the defects caused by the adh1 mutation. These findings indicate that in M. circinelloides, the product of the adh1 gene mediates the Crabtree effect, and can act as either a fermentative or an oxidative enzyme, depending on the nutritional conditions, thereby participating in the association between fermentative and oxidative metabolism. It was found that the spores of M. circinelloides possess low mRNA levels of the ethanol assimilation genes (adl2 and acs2), which could explain their inability to grow in the alcohol.

Fusarium oxysporum Adh1 has dual fermentative and oxidative functions and is involved in fungal virulence in tomato plants.

An alcohol dehydrogenase gene, adh1, has been identified in the vascular wilt fungus Fusarium oxysporum f. sp. lycopersici. Reverse transcription polymerase chain reaction (RT-PCR) analysis revealed that adh1 is highly expressed in mycelia grown in potato dextrose liquid medium (PDB) under hypoxic conditions, as compared to mycelia grown under aerobic conditions. One spontaneous allyl alcohol-resistant (Ally(R)) mutant exhibited insertion of an incomplete F.oxysporum transposable element, while another mutant contained a short (13 nucleotide) deletion, in both cases interrupting the coding region of the adh1 gene. These mutations caused deficiency in Adh activity due to loss of the main constitutive isoform of Adh1, as well as alteration of different physiological parameters related to carbon and energy metabolism, including the ability to use ethanol as a carbon source under aerobic conditions; impaired growth under hypoxic conditions with glucose as the carbon source; and diminished production of ethanol in glucose-containing medium. Interestingly, the adh1 mutations resulted in a significant delay in fungal disease development in tomato plants. Complementation with the wild-type adh1 allele repaired all defects caused by mutation, indicating that the product of the adh1 gene has dual enzymatic functions (fermentative and oxidative), depending on culture conditions, and is also required for full fungal virulence.