The transmembrane protein AaSho1 is essential for appressorium formation and secondary metabolism but dispensable for vegetative growth in pear fungal Alternaria alternata

The high-osmolarity glycerol response (HOG) pathway is pivotal in environmental stress response, differentiation and virulence of Alternaria alternata. The synthetic high osmolarity sensitive sensor Sho1 has been postulated to regulate the HOG pathway. To determine the regulatory role of transmembrane protein Sho1 on vegetative growth, secondary metabolism and infection structure formation, a gene (AaSho1) encoding Sho1 was cloned and characterized from A. alternata (JT-03). Sequence analysis showed that AaSho1 has all four characteristic transmembrane domains and the SH3 domain present in another Sho1 gene from several filamentous fungal. The quantitative RT-PCR analysis showed that fruit wax extract significantly up-regulated AaSho1 gene expression in vitro. Pharmacological experiments showed that A. alternata treated with nystatin, a specific AaSho1 inhibitor, had no significant effect on the morphology of A. alternata and the invasive growth in pear fruit. However, nystatin treatment signifi-cantly reduced spore germination rates on different wax-coated hydrophobic surfaces, with 58.00, 46.70 and 83.72% reduced for fruit wax, beeswax and paraffin coated. Meanwhile, the secondary metabolism altenuene (ALT), tentoxin (TEN) toxin, and melanin content were also affected by nystatin treatment. These findings suggest that AaSho1 is required for the infection structure differentiation and secondary metabolism of A. alternata in response to physiochemical signals on the host surfaces.