Kaori Itto-Nakama scite author profile

As a result of the relatively few available antifungals and the increasing frequency of resistance to them, the development of novel antifungals is increasingly important. The plant natural product poacic acid (PA) inhibits β‐1,3‐glucan synthesis in Saccharomyces cerevisiae and has antifungal activity against a wide range of plant pathogens. However, the mode of action of PA is unclear. Here, we reveal that PA specifically binds to β‐1,3‐glucan, its affinity for which is ~30‐fold that for chitin. Besides its effect on β‐1,3‐glucan synthase activity, PA inhibited the yeast glucan‐elongating activity of Gas1 and Gas2 and the chitin–glucan transglycosylase activity of Crh1. Regarding the cellular response to PA, transcriptional co‐regulation was mediated by parallel activation of the cell‐wall integrity (CWI) and high‐osmolarity glycerol signaling pathways. Despite targeting β‐1,3‐glucan remodeling, the transcriptional profiles and regulatory circuits activated by caspofungin, zymolyase, and PA differed, indicating that their effects on CWI have different mechanisms. The effects of PA on the growth of yeast strains indicated that it has a mode of action distinct from that of echinocandins, suggesting it is a unique antifungal agent.

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Are droplets really suitable for single-cell analysis? A case study on yeast in droplets

Nakagawa

Ohnuki

Kondo

et al. 2021

Lab Chip

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High-throughput platform for yeast morphological profiling predicts the targets of bioactive compounds

et al. 2022

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Morphological profiling is an omics-based approach for predicting intracellular targets of chemical compounds in which the dose-dependent morphological changes induced by the compound are systematically compared to the morphological changes in gene-deleted cells. In this study, we developed a reliable high-throughput (HT) platform for yeast morphological profiling using drug-hypersensitive strains to minimize compound use, HT microscopy to speed up data generation and analysis, and a generalized linear model to predict targets with high reliability. We first conducted a proof-of-concept study using six compounds with known targets: bortezomib, hydroxyurea, methyl methanesulfonate, benomyl, tunicamycin, and echinocandin B. Then we applied our platform to predict the mechanism of action of a novel diferulate-derived compound, poacidiene. Morphological profiling of poacidiene implied that it affects the DNA damage response, which genetic analysis confirmed. Furthermore, we found that poacidiene inhibits the growth of phytopathogenic fungi, implying applications as an effective antifungal agent. Thus, our platform is a new whole-cell target prediction tool for drug discovery.

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