Cardoso J , Nakayama DG , Sousa E , Pinto E .

POCI-01-0145-FEDER-028736, PTDC/SAU- PUB/28736/2017 Fundação para a Ciência e a Tecnologia

	Figure 1. Mechanism of action of antifungal classes.
	Figure 2. Historical evolution of antifungal agents.
	Figure 3. Structure of aurantosides G–J (1–4).
	Figure 4. Structure of aurantoside K (5).
	Figure 5. Structures of woodylides A–C (6–8).
	Figure 6. Structure of theonellamide G (9).
	Figure 7. Structures of compounds 10–21.
	Figure 8. Structures of aaptamines (22–29).
	Figure 9. Structures of poecillastrosides A–G (30–36).
	Figure 10. Structure of haliscosamine (37).
	Figure 11. Structure of epi-ilimaquinone (38).
	Figure 12. Structures of compounds 39–45.
	Figure 13. Structures of compounds 46–48.
	Figure 14. Structure of forazoline A (49).
	Figure 15. Structures of 13-membered macrolides (50–56).
	Figure 16. Structures of compounds 57–62.
	Figure 17. Structures of pimarane diterpenes (63–66).
	Figure 18. Structures of compounds 67–70.
	Figure 19. Structure of didymellamide A (71).
	Figure 20. Structures of xanthones and structurally related compounds (72–78).
	Figure 21. Structures of dithiodiketopiperazine derivatives (79–82).
	Figure 22. Structures of compounds 83–90a/90b.
	Figure 23. Structures of compounds 91–97.
	Figure 24. Structures of compounds 98 and 99.
	Figure 25. Structures of dolastatin 10 (100) and analogues 101–104.
	Figure 26. Structures of sorbicillin (105) and 3-methyl-N-(2′-phenelethyl)-butyrylamide (106).
	Figure 27. Structures of efflux pumps inhibitors: unnarmicin A (107) and unnarmicin C (108).

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