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Review

New Insights into Chemical and Biological Properties of Funicone-like Compounds

1
Department of Chemical Sciences, University of Naples Federico II, 80126 Naples, Italy
2
Institute for Sustainable Plant Protection, National Research Council, 80055 Portici, Italy
3
BAT Center—Interuniversity Center for Studies on Bioinspired Agro-Environmental Technology, University of Naples Federico II, 80055 Portici, Italy
4
Department of Agricultural Sciences, University of Naples Federico II, 80055 Portici, Italy
5
Council for Agricultural Research and Economics, Research Center for Olive, Fruit, and Citrus Crops, 81100 Caserta, Italy
*
Author to whom correspondence should be addressed.
Toxins 2022, 14(7), 466; https://doi.org/10.3390/toxins14070466
Submission received: 10 June 2022 / Revised: 1 July 2022 / Accepted: 4 July 2022 / Published: 8 July 2022

Abstract

:
Funicone-like compounds are a homogeneous group of polyketides that, so far, have only been reported as fungal secondary metabolites. In particular, species in the genus Talaromyces seem to be the most typical producers of this group of secondary metabolites. The molecular structure of funicone, the archetype of these products, is characterized by a γ-pyrone ring linked through a ketone group to a α-resorcylic acid nucleus. This review provides an update on the current knowledge on the chemistry of funicone-like compounds, with special emphasis on their classification, occurrence, and diverse biological activities. In addition, their potential relevance as mycotoxins is discussed.
Key Contribution: This review describes recent progress on the occurrence, detection, chemical diversity, and bioactivities of the funicone-like compounds.

1. Introduction

Research on fungal secondary metabolites is mainly driven by remarks concerning their bioactive properties, which can either be inherent to their role in biocenotic interrelations or their effects on human health, the latter depending on either their possible accumulation in foodstuffs as mycotoxins, or eventual pharmaceutical relevance.
Funicones and structurally related compounds represent a homogeneous group of fungal polyketides that were initially characterized as determinants of the antagonistic abilities by the producers against other microorganisms, but were later found to possess remarkable biological properties that have promoted their consideration as drug prospects. Considering that these properties are partly based on observations concerning cytostatic and antiproliferative effects on human cells, these products should be also evaluated with reference to toxicological aspects related to possible contamination of foodstuffs by the producing fungi.
In light of the novel knowledge developed in over a decade since the publication of a previous review [1], this paper offers an update on the state of the art concerning occurrence, bioactivities, structural, synthetic, and biosynthetic aspects of funicone-like compounds.

2. Structures and Chemical Properties

Funicone-like compounds include natural products characterized by a molecular structure that is built on a γ-pyrone ring linked through a ketone group to a α-resorcylic acid nucleus. A total of 34 chemically defined compounds, which are referable to this basic structural model, have been identified and characterized so far. Among them, 13 can be considered true funicones because the typical moieties are present without alterations. The other compounds, showing modifications on the α-resorcylic acid nucleus, on the γ-pyrone ring, or on both moieties, are grouped in three subclasses, namely phthalide, furopyrone, and pyridone types, depending on peculiar substructural variations (Table 1).

2.1. True Funicones

In temporal terms, funicone [benzoic acid, 2-[[5-hydroxy-4-oxo-6-(1E)-1-propenyl-4H-pyran-3-yl]carbonyl]-3,5-dimethoxy, methyl ester] (1) is the founder of this group of compounds, originally characterized from a culture of Penicillium funiculosum [2]. Subsequently, a structural isomer, namely isofunicone (9) [16], and several derivatives, which differ from the parent compound by few substitutions, were identified (Figure 1). This subclass also includes some epoxide derivatives (47) on the γ-pyrone ring, two of them (5,6) isolated from co-cultures of a strain of Penicillium sp. with the actinomycete Streptomyces fradiae [14]. Pinophilones A and B (12 and 13) are the only funicone-like compounds presenting a dihydrofuran fragment obtained from the cyclization of the hydroxyl group on the γ-pyrone ring and the double bond on the propenyl chain [28].
The rising interest of the scientific community in these substances has led to the development of approaches for their synthesis. In particular, deoxyfunicone (3), 3-O-methylfunicone (10) [52], and rapicone (11) [53] were efficiently prepared by carbonylative Stille cross-coupling reactions between methyl 2-iodo-3,5-dimethoxybenzoate and functionalized γ-pyrone (Figure 2). 5-Stannane derivatives were prepared starting from commercially available kojic acid in four steps [52,53].

2.2. Furopyrone Type

Penifupyrone (14) is the only member of the furopyrone type carrying a 5H-furo[3,2-b]pyran-7(6H)-one moiety instead of a γ-pyrone ring (Figure 3). It was isolated for the first time from an endophytic strain of Talaromyces sp., along with funicone, deoxyfunicone, and 3-O-methylfunicone [5].

2.3. Phthalide Type

The molecular structure of compounds in this subclass includes a 4,6-dimethoxyphthalide moiety (Figure 4). Vermistatin (15) is the reference compound of this group, deriving its name from a strain of Talaromyces flavus identified in anamorphic-stage Penicillium vermiculatum [47]. This metabolite was later isolated as a product of Pseudocercospora (=Mycosphaerella) fijiensis and wrongly reported as a new compound with the name fijiensin [30]. This is not surprising because the attribution of different names to the same chemical structure represents a recurring nomenclatural issue in natural product research [54].
Based on the currently available data, vermistatin represents the most frequent funicone-like compound, having been extracted as a product of at least 15 species. It is frequently extracted along with some derivatives, such as hydroxy- (21) and methoxyvermistatin (22), 6-demethylvermistatin (17), 14,15-dihydrovermistatin (18), hydroxy- (20) and acetoxy-dihydrovermistatin (16), and penisimplicissin (25) [6,7,21,28,33,34,45,49].
Neosarphenol (24) is an isomer of hydroxyvermistatin, which was named on the basis of the producing fungus, Neosartorya glabra (currently reclassified as Aspergillus neoglaber), rather than with reference to its chemical structure [40].

2.4. Pyridone Type

This series includes compounds containing a γ-pyridone moiety. The molecular structures of penicidone A and B (30,31) are characterized by the presence of an α-resorcylic acid moiety linked through a ketone group to a γ-pyridone, whereas penicidone C, D and talarodone A (3234) contain the typical 4,6-dimethoxyphthalide moiety of vermistatin replacing the α-resorcylic acid nucleus (Figure 5). Nevertheless, Murakami et al. [18] represented penicidone D (33) in γ-pyridol form, instead of γ-pyridone form.

3. Fungal Sources

The data summarized in Table 2 show that the fungi reported as funicone producers have been recovered from various substrates, often in association with plants or other organisms, and in diverse environments, both terrestrial and marine. They are also quite heterogeneous in taxonomic terms, as they belong to two Ascomycetes classes: the Dothideomycetes and Eurotiomycetes. Members in the first class are sparse, being ascribed to five orders, with each of them represented by a single strain. Even considering the approximate taxonomic identification of three strains, which were only identified at the genus level, it is clear that funicone biosynthetic aptitudes occur among Dothideomycetes, and might be more widespread than currently known. Conversely, the Eurotiomycetes look to be much more abiding producers and taxonomically homogeneous, with about 31 strains belonging to three genera in two families. Again, some uncertainty in identification is to be noted, deriving from the absence of adequate support by sequencing of valid DNA markers, and by the provisional ascription to Penicillium sp. of some strains prior to the formal separation of the biverticillate Penicillium species and their assignment to the genus Talaromyces [55]. In this respect, the identification of strain IFM53375 as Penicillium simplicissimum was considered unreliable by leading taxonomists of these fungi based on a secondary metabolite profile more respondent to Talaromyces [55]. In another case, the producing strain (AF1-2) was not identified at all [26]; however, the image provided by the authors showing its bright yellow mycelium and the overlying green sporulation in culture on agar medium unequivocally allows its ascription to Talaromyces. In any case, species in the genus Talaromyces are the most typical producers of funicone-like compounds; with reference to the recent affirmation of the horizontal gene transfer concept [56,57], it cannot be excluded that the other fungal species may have occasionally acquired their funicone-biosynthetic abilities through this intriguing biological mechanism.
Recently, some independent studies have reported that production of funicone-like compounds may occur in co-cultures of various microbial strains (Table 3). Again, the Eurotiomycetes are more represented in these few studies, and can be thought to provide the genetic base for biosynthesis, which is eventually stimulated by the co-cultured strain in the course of an antibiotic struggle, as clearly demonstrated in the case of the pairing between Talaromyces siamensis and Phomopsis sp. (Sordariomycetes, Diaporthaceae) [43]. In two cases, the partner microbe was represented by Streptomyces strains (Actinomycetota), which are well-known for their capacity to modulate the metabolic potential of fungi [60].

4. Biosynthesis

The potential biosynthetic pathways of funicone-like compounds have been investigated by two independent research groups [21,28]. Figure 6 shows a possible scheme for each type of compound proposed in the previous section. Funicone-like compounds are epta and octaketides, originating from units of acetate-mevalonate. The main structural differences can be caused by the folding of the eptaketidic and octaketidic chains, which produce structures with a methyl or a propenyl group, respectively, on the γ-pyrone ring. The presence of an amino group in compounds belonging to the pyridone type suggests a possible transamination process during the biosynthesis of γ-pyridone. The origin of the phthalide type can be attributed to the lactonization of the carboxylic group in the α-resorcylic ring, with the hydroxyl group produced through the reduction of the exocyclic ketone group.
Subsequent functional modifications (e.g., reduction, epoxydation, hydroxylation, methylation, and acetylation) are responsible for the ample structural variability observed in the group of funicone-like compounds.

5. Bioactivities

As previously introduced, the biological activity of funicones was initially evaluated with reference to antibiotic properties, generally evidencing poor effects against bacteria and yeasts, and more relevant activities against filamentous fungi. Subsequent investigations on antiproliferative properties against human cells line have become prevalent, underlining the potential of these compounds as antitumor drugs. Additional data have been gathered on the antiviral and the insecticidal properties, and the inhibitory effects toward several enzymes; moreover, some minor bioactivities have been described. The outcomes of this wide-ranging investigational work, as assessed in quantitative terms, are summarized in Table 4.

6. Potential Role of Funicone-like Compounds as Mycotoxins

The applicative aspects of studies concerning fungal bioactive secondary metabolites involve their accumulation in food products and ensuing possible impact on consumers’ health. Within the multitude of such compounds described so far, a very small number have been considered mycotoxins, based on the results of toxicological studies that noted their noxious effects on humans and animals [69]. This implies that a high number of compounds yet to be examined for these aspects may represent a potentially underestimated concern [70,71].
Funicones are one of the classes of fungal secondary metabolites for which very limited assessments have been carried out in this regard so far. Most of the producing species are not established pathogens of crops, with the exception of Pseudocercospora (=Mycosphaerella) fijiensis, a vermistatin producer that is known as the agent of black sigatoka disease of banana [72]. However, this is a leaf pathogen that is not known to spread to fruit, implying that it is unlikely that bananas can be contaminated with vermistatin. Nevertheless, a search for this compound in some fruit products carried out in Nigeria evidenced its presence at low levels (0.30 µg kg−1) in pineapple and mixed juices [73]. This is not at all surprising, as several Talaromyces spp. are commonly found in association with both healthy and diseased pineapples, including T. purpureogenus, T. funiculosus, and T. flavus, which may even survive pasteurization [74,75,76,77]. Conversely, a preliminary search carried out in Italy on marketed pineapple juices yielded negative results with reference to the eventual presence of 3-O-methylfunicone [78]. Recently, vermistatin was also detected in the analysis of grains used as cattle and poultry feed in Kenya [79], indicating that it may also occur as a cereal contaminant. Moreover, the finding of vermistatin as a product in co-cultures of strains of Alternaria alternata and Streptomyces exfoliatus [37] deserves to be further investigated, particularly in view of verifying the biosynthetic capacities by the first species. It is known as a pathogen of many crops and a saprophyte able to proliferate in several kinds of foodstuffs, with very important implications as a mycotoxin producer [80].
Considering the widespread endophytic occurrence of Talaromyces spp. [23,81], which are the dominant producers of funicones, the possible release of these compounds in plant products may arise during the postharvest phase, where the biosynthetic aptitudes can be boosted along with the saprophytic development. Recent reports of these fungi as postharvest pathogens concern T. albobiverticillius on pomegranate [82], T. rugulosus on grapes [83], T. minioluteus on onion bulbs and quince, orange, and tomato fruit [84], and both of the latter two species on pears [85]. Although none of these species are known to produce funicones, it is quite possible that other Talaromyces spp. producers of these compounds may affect fruit and other crop products, likewise documented for pineapple. This conclusion is supported by the finding of T. funiculosus as an agent of fruit core rot of peach [86].
Among the other funicone sources, Ramichloridium apiculatum, generally recorded as a soil saprophyte and only known as a producer of rapicone [27], was reported as an agent of sooty blotch and flyspeck of apples and pears in China [87], which may represent an indication for possible contamination of these fruits and their derived transformation products.

7. Conclusions

The present review provides an update on the recent developments concerning the distribution, chemical diversity, bioactivity and implications of occurrence of funicone-like compounds. The structures and properties of 34 funicone-like compounds extracted from different fungal species were reviewed. In particular, species in the genus Talaromyces seem to be the most typical producers of this group of secondary metabolites, soliciting consideration in view of possible chemotaxonomic implications.
In addition to outlining the general anti-inflammatory, antifungal, antiviral, and cytotoxic activities of these compounds, the available data indicate vermistatin as the most credited candidate to be added to the list of mycotoxins currently considered as food contaminants, with reference to its more common occurrence amongst the known funicone producers. The majority of these taxonomically heterogeneous fungi can perform its biosynthesis, implying that its presence in crop products may be more than just occasional. Whether this represents a threat or, conversely, can eventually be beneficial to consumers’ health based on the described bioactivities, deserves thorough further assessments.

Author Contributions

Conceptualization, R.N. and A.A.; writing—original draft preparation, M.M.S. and R.N.; writing—review and editing, M.M.S., M.DG., R.N. and A.A. All authors have read and agreed to the published version of the manuscript.

Funding

This research received no external funding.

Institutional Review Board Statement

Not applicable.

Informed Consent Statement

Not applicable.

Data Availability Statement

Not applicable.

Conflicts of Interest

The authors declare no conflict of interest.

References

  1. Nicoletti, R.; Manzo, E.; Ciavatta, M.L. Occurence and bioactivities of funicone-related compounds. Int. J. Mol. Sci. 2009, 10, 1430–1444. [Google Scholar] [CrossRef] [PubMed]
  2. Merlini, L.; Nasini, G.; Selva, A. The structure of funicone: A new metabolite from Penicillium funiculosum Thom. Tetrahedron 1970, 26, 2739–2749. [Google Scholar] [CrossRef]
  3. Yilmaz, N.; Visagie, C.M.; Houbraken, J.; Frisvad, J.C.; Samson, R.A. Polyphasic taxonomy of the genus Talaromyces. Stud. Mycol. 2014, 78, 175–341. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  4. Komai, S.; Hosoe, T.; Itabashi, T.; Nozawa, K.; Okada, K.; de Campos Takaki, G.M.; Chikamori, M.; Yaguchi, T.; Fukushima, K.; Miyaji, M.; et al. A new funicone derivative isolated from Talaromyces flavus IFM52668. Mycotoxins 2004, 54, 15–19. [Google Scholar] [CrossRef] [Green Version]
  5. Chen, M.J.; Fu, Y.W.; Zhou, Q.Y. Penifupyrone, a new cytotoxic funicone derivative from the endophytic fungus Penicillium sp. HSZ-43. Nat. Prod. Res. 2014, 28, 1544–1548. [Google Scholar] [CrossRef]
  6. Komai, S.I.; Hosoe, T.; Itabashi, T. New vermistatin derivatives isolated from Penicillium simplicissimum. Heterocycles 2005, 65, 2771–2776. [Google Scholar]
  7. Wu, C.; Zhao, Y.; Chen, R.; Liu, D.; Liu, M.; Proksch, P.; Guo, P.; Lin, W. Phenolic metabolites from mangrove-associated Penicillium pinophilum fungus with lipid-lowering effects. RSC Adv. 2016, 6, 21969–21978. [Google Scholar] [CrossRef]
  8. Jiao, Y.; Zhang, X.; Wang, L.; Li, G.; Zhou, J.C.; Lou, H.X. Metabolites from Penicillium sp.; An endophytic fungus from the liverwort Riccardia multifida (L.) S. Gray. Phytochem. Lett. 2013, 6, 14–17. [Google Scholar] [CrossRef]
  9. Arai, M.; Tomoda, H.; Okuda, T.; Wang, H.; Tabata, N.; Masuma, R.; Yamaguchi, Y.; Omura, S. Funicone-related compounds, potentiators of antifungal miconazole activity, produced by Talaromyces flavus FKI-0076. J. Antibiot. 2002, 55, 172–180. [Google Scholar] [CrossRef] [Green Version]
  10. Sassa, T.; Nukina, M.; Suzuki, Y. Deoxyfunicone, a new γ-pyrone metabolite from a resorcylide-producing fungus (Penicillium sp.). Agric. Biol. Chem. 1991, 55, 2415–2416. [Google Scholar]
  11. Singh, S.B.; Jayasuriya, H.; Dewey, R.; Polishook, J.D.; Dombrowski, A.W.; Zink, D.L.; Guan, Z.; Collado, J.; Platas, G.; Pelaez, F.; et al. Isolation, structure, and HIV-1-integrase inhibitory activity of structurally diverse fungal metabolites. J. Ind. Microbiol. Biotechnol. 2003, 30, 721–731. [Google Scholar] [PubMed]
  12. Rusman, Y. Isolation of New Secondary Metabolites from Sponge-Associated and Plant-Derived Fungi; Heinrich-Heine-Universität-Düsseldorf: Dusseldorf, Germany, 2006. [Google Scholar]
  13. Ha, T.M.; Kim, D.C.; Sohn, J.H.; Yim, J.H.; Oh, H. Anti-inflammatory and protein tyrosine phosphatase 1b inhibitory metabolites from the antarctic marine-derived fungal strain Penicillium glabrum SF-7123. Mar. Drugs 2020, 18, 247. [Google Scholar] [CrossRef] [PubMed]
  14. Wang, Y.; Wang, L.; Zhuang, Y.; Kong, F.; Zhang, C.; Zhu, W. Phenolic polyketides from the co-cultivation of marine-derived Penicillium sp. WC-29-5 and Streptomyces fradiae 007. Mar. Drugs 2014, 12, 2079–2088. [Google Scholar] [CrossRef] [PubMed]
  15. De Stefano, S.; Nicoletti, R.; Zambardino, S.; Milone, A. Structure elucidation of a novel funicone-like compound produced by Penicillium pinophilum. Nat. Prod. Lett. 2002, 16, 207–211. [Google Scholar] [CrossRef]
  16. Kimura, Y.; Yoshinari, T.; Shimada, A.; Hamasaki, T. Isofunicone, a pollen growth inhibitor produced by the fungus, Penicillium sp. Phytochemistry 1995, 40, 629–631. [Google Scholar] [CrossRef]
  17. Liu, Y.; Yang, Q.; Xia, G.; Huang, H.; Li, H.; Ma, L.; Lu, Y.; He, L.; Xia, X.; She, Z. Polyketides with α-glucosidase inhibitory activity from a mangrove endophytic fungus, Penicillium sp. HN29-3B1. J. Nat. Prod. 2015, 78, 1816–1822. [Google Scholar] [CrossRef]
  18. Murakami, S.; Hayashi, N.; Inomata, T.; Kato, H.; Hitora, Y.; Tsukamoto, S. Induction of secondary metabolite production by fungal co-culture of Talaromyces pinophilus and Paraphaeosphaeria sp. J. Nat. Med. 2020, 74, 545–549. [Google Scholar] [CrossRef]
  19. De Stefano, S.; Nicoletti, R.; Milone, A.; Zambardino, S. 3-O-Methylfunicone, a fungitoxic metabolite produced by the fungus Penicillium pinophilum. Phytochemistry 1999, 52, 1399–1401. [Google Scholar] [CrossRef]
  20. Salvatore, M.M.; DellaGreca, M.; Nicoletti, R.; Salvatore, F.; Vinale, F.; Naviglio, D.; Andolfi, A. Talarodiolide, a new 12-membered macrodiolide, and GC/MS investigation of culture filtrate and mycelial extracts of Talaromyces pinophilus. Molecules 2018, 23, 950. [Google Scholar] [CrossRef] [Green Version]
  21. Liu, Y.; Xia, G.; Li, H.; Ma, L.; Ding, B.; Lu, Y.; He, L.; Xia, X.; She, Z. Vermistatin derivatives with α -glucosidase inhibitory activity from the mangrove endophytic fungus Penicillium sp. HN29-3B1. Planta Med. 2014, 80, 912–917. [Google Scholar] [CrossRef] [Green Version]
  22. Lacatena, F.; Marra, R.; Mazzei, P.; Piccolo, A.; Digilio, M.C.; Giorgini, M.; Woo, S.L.; Cavallo, P.; Lorito, M.; Vinale, F. Chlamyphilone, a novel Pochonia chlamydosporia metabolite with insecticidal activity. Molecules 2019, 24, 750. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  23. Vinale, F.; Nicoletti, R.; Lacatena, F.; Marra, R.; Sacco, A.; Lombardi, N.; D’Errico, G.; Digilio, M.C.; Lorito, M.; Woo, S.L. Secondary metabolites from the endophytic fungus Talaromyces pinophilus. Nat. Prod. Res. 2017, 31, 1778–1785. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  24. Stammati, A.; Nicoletti, R.; De Stefano, S.; Zampaglioni, F.; Zucco, F. Cytostatic properties of a novel compound derived from Penicillium pinophilum: An in vitro study. Altern. Lab. Anim. 2002, 30, 69–75. [Google Scholar] [CrossRef] [PubMed]
  25. Nicoletti, R.; De Stefano, M.; De Stefano, S.; Trincone, A.; Marziano, F. Antagonism against Rhizoctonia solani and fungitoxic metabolite production by some Penicillium isolates. Mycopathologia 2004, 158, 465–474. [Google Scholar] [CrossRef] [PubMed]
  26. Mizushina, Y.; Motoshima, H.; Yamaguchi, Y.; Takeuchi, T.; Hirano, K.; Sugawara, F.; Yoshida, H. 3-O-methylfunicone, a selective inhibitor of mammalian Y-family DNA polymerases from an Australian sea salt fungal strain. Mar. Drugs 2009, 7, 624–639. [Google Scholar] [CrossRef] [Green Version]
  27. Nozawa, K.; Nakajima, S.; Kawai, K.I.; Udagawa, S.I. A γ-pyrone derivative, rapicone from Ramichloridium apiculatum. Phytochemistry 1992, 12, 4177–4179. [Google Scholar] [CrossRef]
  28. He, F.; Li, X.; Yu, J.H.; Zhang, X.; Nong, X.; Chen, G.; Zhu, K.; Wang, Y.Y.; Bao, J.; Zhang, H. Secondary metabolites from the mangrove sediment-derived fungus Penicillium pinophilum SCAU037. Fitoterapia 2019, 136, 104177. [Google Scholar] [CrossRef]
  29. Massias, M.; Molho, L.; Rebuffat, S.; Cesario, M.; Guilhen, J.; Pascard, C.; Bodo, B. Vermiculinol and mermiculidiol, macrodiolides from the fungus Penicillium vermiculatum. Phytochemistry 1989, 28, 1491–1494. [Google Scholar] [CrossRef]
  30. Upadhyay, R.K.; Strobel, G.A.; Coval, S.J.; Clardy, J. Fijiensin, the first phytotoxin from Mycosphaerella fijiensis, the causative agent of Black Sigatoka disease. Experientia 1990, 46, 982–984. [Google Scholar] [CrossRef]
  31. Murtaza, N.; Husain, S.A.; Sarfaraz, T.B.; Sultana, N.; Faizi, S. Isolation and identification of vermistatin, ergosterol, stearic acid and mannitol, metabolic products of Penicillium verruculosum. Planta Med. 1997, 63, 191. [Google Scholar] [CrossRef]
  32. Komai, S.I.; Hosoe, T.; Itabashi, T.; Nozawa, K.; Yaguchi, T.; Fukushima, K.; Kawai, K.I. New penicillide derivatives isolated from Penicillium simplicissimum. J. Nat. Med. 2006, 60, 185–190. [Google Scholar] [CrossRef] [PubMed]
  33. Dethoup, T.; Manoch, L.; Kijjoa, A.; Pinto, M.; Gales, L.; Damas, A.M.; Silva, A.M.S.; Eaton, G.; Herz, W. Merodrimanes and other constituents from Talaromyces thailandiasis. J. Nat. Prod. 2007, 70, 1200–1202. [Google Scholar] [CrossRef] [PubMed]
  34. Xia, X.K.; Huang, H.R.; She, Z.G.; Cai, J.W.; Lan, L.; Zhang, J.Y.; Fu, L.W.; Vrijmoed, L.L.P.; Lin, Y.C. Structural and biological properties of vermistatin and two new vermistatin derivatives isolated from the marine-mangrove endophytic Guignardia sp. No. 4382. Helv. Chim. Acta 2007, 90, 1925–1931. [Google Scholar] [CrossRef]
  35. Bai, M.; Zheng, C.J.; Tang, D.Q.; Zhang, F.; Wang, H.Y.; Chen, G.Y. Two new secondary metabolites from a mangrove-derived fungus Cladosporium sp. JS1-2. J. Antibiot. 2019, 72, 779–782. [Google Scholar] [CrossRef]
  36. Gubiani, J.R.; Wijeratne, E.M.K.; Shi, T.; Araujo, A.R.; Arnold, A.E.; Chapman, E.; Gunatilaka, A.A.L. An epigenetic modifier induces production of (10’S)-verruculide B, an inhibitor of protein tyrosine phosphatases by Phoma sp. nov. LG0217, a fungal endophyte of Parkinsonia microphylla. Bioorganic Med. Chem. 2017, 25, 1860–1866. [Google Scholar] [CrossRef] [Green Version]
  37. He, X.P. Secondary metabolites of co-culture of Alternaria alternate YX-25 and Streptomyces exfoliatus YX-32. Chinese Tradit. Herb. Drugs 2018, 24, 5772–5779. [Google Scholar]
  38. Hong, X.; Guan, X.; Lai, Q.; Yu, D.; Chen, Z.; Fu, X.; Zhang, B. Characterization of a bioactive meroterpenoid isolated from the marine—Derived fungus Talaromyces sp. Appl. Microbiol. Biotechnol. 2022, 106, 2927–2935. [Google Scholar] [CrossRef]
  39. Liu, G.; Huo, R.; Niu, S.; Song, F.; Liu, L. Two new cytotoxic decalin derivatives from marine-derived fungus Talaromyces sp. Chem. Biodivers. 2022, 19, 1–8. [Google Scholar] [CrossRef]
  40. Liu, W.; Zhao, H.; Li, R.; Zheng, H.; Yu, Q. Polyketides and meroterpenoids from Neosartorya glabra. Helv 2015, 98, 515–519. [Google Scholar] [CrossRef]
  41. Luo, X.W.; Gao, C.H.; Han, F.H.; Chen, X.Q.; Lin, X.P.; Zhou, X.F.; Wang, J.J.; Liu, Y.H. A new naphthopyranone from the sponge-associated fungus Penicillium sp. XWS02F62. Magn. Reson. Chem. 2019, 57, 982–986. [Google Scholar] [CrossRef]
  42. Liu, Z.; Xia, G.; Chen, S.; Liu, Y.; Li, H.; She, Z. Eurothiocin a and B, sulfur-containingbenzofurans from a soft coral-derived fungus Eurotium rubrum SH-823. Mar. Drugs 2014, 12, 3669–3680. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  43. Nonaka, K.; Iwatsuki, M.; Horiuchi, S.; Shiomi, K.; Omura, S.; Masuma, R. Induced production of BE-31405 by co-culturing of Talaromyces siamensis FKA-61 with a variety of fungal strains. J. Antibiot. 2015, 68, 573–578. [Google Scholar] [CrossRef] [PubMed]
  44. Stierle, A.A.; Stierle, D.B. Bioactive secondary metabolites from acid mine waste extremophiles. Nat. Prod. Commun. 2014, 9, 1037–1044. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  45. Stierle, A.A.; Stierle, D.B.; Girtsman, T. Caspase-1 inhibitors from an extremophilic fungus that target specific leukemia cell lines. J. Nat. Prod. 2012, 75, 344–350. [Google Scholar] [CrossRef] [Green Version]
  46. Sun, J.; Zhu, Z.X.; Song, Y.L.; Ren, Y.; Dong, D.; Zheng, J.; Liu, T.; Zhao, Y.F.; Tu, P.F.; Li, J. Anti-neuroinflammatory constituents from the fungus Penicillium purpurogenum MHZ 111. Nat. Prod. Res. 2017, 31, 562–567. [Google Scholar] [CrossRef]
  47. Fuska, J.; Fuskova, A.; Nemec, P. Vermistatin, an antibiotic with cytotoxic effects, produced from Penicillium vermiculatum. Biologia 1979, 34, 735–739. [Google Scholar]
  48. Fuska, J.; Uhrín, D.; Proksa, B.; Votický, Z.; Ruppeldt, J. The structure of vermistatin, a new metabolite from Penicillium vermiculatum. J. Antibiot. 1986, 39, 1605–1608. [Google Scholar] [CrossRef] [Green Version]
  49. Xia, X.K.; Liu, F.; She, Z.G.; Yang, L.G.; Li, M.F.; Vrijmoed, L.L.P.; Lin, Y.C. 1H and 13C NMR assignments for 6-demethylvermistatin and two penicillide derivatives from the mangrove fungus Guignardia sp. (No. 4382) from the South China Sea. Magn. Reson. Chem. 2008, 46, 693–696. [Google Scholar] [CrossRef]
  50. Ciavatta, M.L.; Manzo, E.; Contillo, R.; Nicoletti, R. Methoxyvermistatin production by Penicillium pinophilum isolate LT4. In Proceedings of the 4th FEMS Congress of European Microbiologists, Geneva, Switzerland, 26–30 June 2011; pp. 26–30. [Google Scholar]
  51. Ge, H.M.; Shen, Y.; Zhu, C.H.; Tan, S.H.; Ding, H.; Song, Y.C.; Tan, R.X. Penicidones A-C, three cytotoxic alkaloidal metabolites of an endophytic Penicillium sp. Phytochemistry 2008, 69, 571–576. [Google Scholar] [CrossRef]
  52. Ehrlich, M.; Carell, T. Total syntheses and biological evaluation of 3-O-methylfunicone and its derivatives prepared by TMPZnCl·LiCl-mediated halogenation and carbonylative stille cross-coupling. European J. Org. Chem. 2013, 2013, 77–83. [Google Scholar] [CrossRef]
  53. Manzo, E.; Ciavatta, M.L.; Nicoletti, R. Process for the Synthesis of Funicone Analogues. WO2012042482A1, 28 September 2012. [Google Scholar]
  54. Salvatore, M.M.; Andolfi, A.; Nicoletti, R. The genus Cladosporium: A rich source of diverse and bioactive natural compounds. Molecules 2021, 26, 3959. [Google Scholar] [CrossRef] [PubMed]
  55. Samson, R.A.; Yilmaz, N.; Houbraken, J.; Spierenburg, H.; Seifert, K.A.; Peterson, S.W.; Varga, J.; Frisvad, J.C. Phylogeny and nomenclature of the genus Talaromyces and taxa accommodatedin Penicillium subgenus Biverticillium. Stud. Mycol. 2011, 70, 159–183. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  56. Fitzpatrick, D.A. Horizontal gene transfer in fungi. FEMS Microbiol. Lett. 2012, 329, 1–8. [Google Scholar] [CrossRef]
  57. Tiwari, P.; Bae, H. Horizontal gene transfer and endophytes: An implication for the acquisition of novel traits. Plants 2020, 9, 305. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  58. Vinale, F.; Nicoletti, R.; Borrelli, F.; Mangoni, A.; Parisi, O.A.; Marra, R.; Lombardi, N.; Lacatena, F.; Grauso, L.; Finizio, S.; et al. Co-culture of plant beneficial microbes as source of bioactive metabolites. Sci. Rep. 2017, 7, 1–12. [Google Scholar] [CrossRef] [Green Version]
  59. Locci, R.; Merlini, L.; Nasini, G.; Locci, J.R. Mitorubrinic acid and related compounds from a strain of Penicillium funiculosum Thom. G. Microbiol. 1967, 15, 93. [Google Scholar]
  60. Peng, X.Y.; Wu, J.T.; Shao, C.L.; Li, Z.Y.; Chen, M.; Wang, C.Y. Co-culture: Stimulate the metabolic potential and explore the molecular diversity of natural products from microorganisms. Mar. Life Sci. Technol. 2021, 3, 363–374. [Google Scholar] [CrossRef]
  61. Nakajima, S.; Watashi, K.; Kamisuki, S.; Tsukuda, S.; Takemoto, K.; Matsuda, M.; Suzuki, R.; Aizaki, H.; Sugawara, F.; Wakita, T. Specific inhibition of hepatitis C virus entry into host hepatocytes by fungi-derived sulochrin and its derivatives. Biochem. Biophys. Res. Commun. 2013, 440, 515–520. [Google Scholar] [CrossRef]
  62. Fiorito, F.; Cerracchio, C.; Salvatore, M.M.; Serra, F.; Pucciarelli, A.; Amoroso, M.G.; Nicoletti, R.; Andolfi, A. Antiviral property of the fungal metabolite 3-O-methylfunicone in bovine Herpesvirus 1 infection. Microorganisms 2022, 10, 188. [Google Scholar] [CrossRef]
  63. Buommino, E.; Nicoletti, R.; Gaeta, G.M.; Orlando, M.; Ciavatta, M.L.; Baroni, A.; Tufano, M.A. 3-O-methylfunicone, a secondary metabolite produced by Penicillium pinophilum, induces growth arrest and apoptosis in HeLa cells. Cell Prolif. 2004, 37, 413–426. [Google Scholar] [CrossRef]
  64. Buommino, E.; Boccellino, M.; De Filippis, A.; Petrazzuolo, M.; Cozza, V.; Nicoletti, R.; Ciavatta, M.L.; Quagliuolo, L.; Tufano, M.A. 3-O-methylfunicone produced by Penicillium pinophilum affects cell motility of breast cancer cells, downregulating αvβ5 integrin and inhibiting metalloproteinase-9 secretion. Mol. Carcinog. 2007, 46, 930–940. [Google Scholar] [CrossRef] [PubMed]
  65. Buommino, E.; Tirino, V.; de Filippis, A.; Silvestri, F.; Nicoletti, R.; Ciavatta, M.L.; Pirozzi, G.; Tufano, M.A. 3-O-methylfunicone, from Penicillium pinophilum, is a selective inhibitor of breast cancer stem cells. Cell Prolif. 2011, 44, 401–409. [Google Scholar] [CrossRef] [PubMed]
  66. Baroni, A.; De Luca, A.; De Filippis, A.; Petrazzuolo, M.; Manente, L.; Nicoletti, R.; Tufano, M.A.; Buommino, E. 3-O-methylfunicone, a metabolite of Penicillium pinophilum, inhibits proliferation of human melanoma cells by causing G2 + M arrest and inducing apoptosis. Cell Prolif. 2009, 42, 541–553. [Google Scholar] [CrossRef] [PubMed]
  67. Buommino, E.; Paoletti, I.; De Filippis, A.; Nicoletti, R.; Ciavatta, M.L.; Menegozzo, S.; Menegozzo, M.; Tufano, M.A. 3-O-Methylfunicone, a metabolite produced by Penicillium pinophilum, modulates ERK1/2 activity, affecting cell motility of human mesothelioma cells. Cell Prolif. 2010, 43, 114–123. [Google Scholar] [CrossRef]
  68. Buommino, E.; De Filippis, A.; Nicoletti, R.; Menegozzo, M.; Menegozzo, S.; Ciavatta, M.L.; Rizzo, A.; Brancato, V.; Tufano, M.A.; Donnarumma, G. Cell-growth and migration inhibition of human mesothelioma cells induced by 3-O-methylfunicone from Penicillium pinophilum and cisplatin. Invest. New Drugs 2012, 30, 1343–1351. [Google Scholar] [CrossRef]
  69. Pleadin, J.; Frece, J.; Markov, K. Mycotoxins in food and feed. Adv. Food Nutr. Res. 2019, 89, 297–345. [Google Scholar]
  70. Madariaga-Mazón, A.; Hernández-Alvarado, R.B.; Noriega-Colima, K.O.; Osnaya-Hernández, A.; Martinez-Mayorga, K. Toxicity of secondary metabolites. Phys. Sci. Rev. 2019, 4, 1–11. [Google Scholar] [CrossRef]
  71. Drakopoulos, D.; Sulyok, M.; Krska, R.; Logrieco, A.F.; Vogelgsang, S. Raised concerns about the safety of barley grains and straw: A Swiss survey reveals a high diversity of mycotoxins and other fungal metabolites. Food Control 2021, 125, 107919. [Google Scholar] [CrossRef]
  72. Noar, R.D.; Thomas, E.; Daub, M.E. Genetic characteristics and metabolic interactions between Pseudocercospora fijiensis and banana: Progress toward controlling black Sigatoka. Plants 2022, 11, 948. [Google Scholar] [CrossRef]
  73. Ayeni, K.I.; Sulyok, M.; Krska, R.; Ezekiel, C.N. Fungal and plant metabolites in industrially-processed fruit juices in Nigeria. Food Addit. Contam. Part B Surveill. 2020, 13, 155–161. [Google Scholar] [CrossRef]
  74. Barral, B.; Chillet, M.; Doizy, A.; Grassi, M.; Ragot, L.; Léchaudel, M.; Durand, N.; Rose, L.J.; Viljoen, A.; Schorr-Galindo, S. Diversity and toxigenicity of fungi that cause pineapple fruitlet core rot. Toxins 2020, 12, 339. [Google Scholar] [CrossRef] [PubMed]
  75. Vignassa, M.; Meile, J.C.; Chiroleu, F.; Soria, C.; Leneveu-Jenvrin, C.; Schorr-Galindo, S.; Chillet, M. Pineapple mycobiome related to fruitlet core rot occurrence and the influence of fungal species dispersion patterns. J. Fungi 2021, 7, 175. [Google Scholar] [CrossRef] [PubMed]
  76. Müller, W.A.; Silva, P.R.S. Da Modelagem e simulação do crescimento de Talaromyces flavus em abacaxi: Uma integração entre modelos cinéticos e de fenômenos de transporte. Brazilian J. Food Technol. 2019, 22, 1–15. [Google Scholar] [CrossRef]
  77. Evelyn, E.; Muria, S.R.; Chairul, C.; Fozla, D.; Khoirunnisa, F.K. Thermal inactivation of Talaromyces flavus ascospores in pineapple juice as influenced by temperature, soluble solids, and spore age. J. Adv. Res. Fluid Mech. Therm. Sci. 2020, 69, 111–119. [Google Scholar] [CrossRef]
  78. Nicoletti, R.; Carella, A. Composti a scheletro funiconico prodotti da specie di Penicillium. Petria 2004, 14, 1–11. [Google Scholar]
  79. Kemboi, D.C.; Ochieng, P.E.; Antonissen, G.; Croubels, S.; Scippo, M.L.; Okoth, S.; Kangethe, E.K.; Faas, J.; Doupovec, B.; Lindahl, J.F.; et al. Multi-mycotoxin occurrence in dairy cattle and poultry feeds and feed ingredients from Machakos Town, Kenya. Toxins 2020, 12, 762. [Google Scholar] [CrossRef]
  80. Chen, A.; Mao, X.; Sun, Q.; Wei, Z.; Li, J.; You, Y.; Zhao, J.; Jiang, G.; Wu, Y.; Wang, L.; et al. Alternaria mycotoxins: An overview of toxicity, metabolism, and analysis in food. J. Agric. Food Chem. 2021, 69, 7817–7830. [Google Scholar] [CrossRef]
  81. Nicoletti, R.; Salvatore, M.M.; Andolfi, A. Secondary metabolites of mangrove-associated strains of Talaromyces. Mar. Drugs 2018, 16, 12. [Google Scholar] [CrossRef] [Green Version]
  82. Mincuzzi, A.; Sanzani, S.M.; Garganese, F.; Ligorio, A.; Ippolito, A. First report of Talaromyces albobiverticillius causing postharvest fruit rot on pomegranate in Italy. J. Plant Pathol. 2017, 99, 303. [Google Scholar]
  83. Yang, Q.; Wang, H.; Zhang, H.; Zhang, X.; Apaliya, M.T.; Zheng, X.; Mahunu, G.K. Effect of Yarrowia lipolytica on postharvest decay of grapes caused by Talaromyces rugulosus and the protein expression profile of T. rugulosus. Postharvest Biol. Technol. 2017, 126, 15–22. [Google Scholar] [CrossRef]
  84. Stošić, S.; Ristić, D.; Gašić, K.; Starović, M.; Grbić, M.L.; Vukojević, J.; Živković, S. Talaromyces minioluteus: New postharvest fungal pathogen in Serbia. Plant Dis. 2020, 104, 656–667. [Google Scholar] [CrossRef] [PubMed]
  85. Stošić, S.; Ristić, D.; Savković, Ž.; Grbić, M.L.; Vukojević, J.; Živković, S. Penicillium and Talaromyces species as postharvest pathogens of pear fruit (Pyrus communis) in Serbia. Plant Dis. 2021, 105, 3510–3521. [Google Scholar] [CrossRef] [PubMed]
  86. Mukhtar, I.; Quan, X.; Chou, T.; Huang, Q.; Yan, J.; Chen, B.; Jiang, S.; Liu, F.; Wen, Z.; Xie, B. First report of Talaromyces funiculosus causing fruit core rot of peach (Prunus persica) in China. Plant Dis. 2019, 103, 2124. [Google Scholar] [CrossRef]
  87. Wang, L.; Du, Y.; Ju, L.; Zhao, Y.; Zhang, R.; Sun, G.; Gleason, M.L. Ramichloridium apiculatum, a new record for China, causing sooty blotch and flyspeck. Mycotaxon 2014, 127, 121–127. [Google Scholar] [CrossRef]
Figure 1. Structures of true funicones (113): funicone, actofunicone, deoxyfunicone, 9,14-epoxy-11-deoxyfunicone, 9R,14S-epoxy-11-deoxyfunicone, 9S,14R-epoxy-11-deoxyfunicone, 3-O-methyl-5,6-epoxyfunicone, 6-hydroxyl-deoxyfunicone, isofunicone, 3-O-methylfunicone, rapicone, pinophilone A, and pinophilone B.
Figure 1. Structures of true funicones (113): funicone, actofunicone, deoxyfunicone, 9,14-epoxy-11-deoxyfunicone, 9R,14S-epoxy-11-deoxyfunicone, 9S,14R-epoxy-11-deoxyfunicone, 3-O-methyl-5,6-epoxyfunicone, 6-hydroxyl-deoxyfunicone, isofunicone, 3-O-methylfunicone, rapicone, pinophilone A, and pinophilone B.
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Figure 2. General procedures for synthesis of funicones.
Figure 2. General procedures for synthesis of funicones.
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Figure 3. Structure of penifupyrone (14).
Figure 3. Structure of penifupyrone (14).
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Figure 4. Structures of compounds from the phthalide type (1529): vermistatin, acetoxydihydrovermistatin, 6-demethylvermistatin, 14,15-dihydrovermistatin, 2″-epihydroxydihydrovermistatin, hydroxydihydrovermistatin, hydroxyvermistatin, 5′-O-methyldihydrovermistatin, methoxyvermistatin, neosarphenol A, penisimplicissin, 6-demethylpenisimplicissin, 5′-hydroxypenisimplicissin, pinophilone C, and pinophilone D.
Figure 4. Structures of compounds from the phthalide type (1529): vermistatin, acetoxydihydrovermistatin, 6-demethylvermistatin, 14,15-dihydrovermistatin, 2″-epihydroxydihydrovermistatin, hydroxydihydrovermistatin, hydroxyvermistatin, 5′-O-methyldihydrovermistatin, methoxyvermistatin, neosarphenol A, penisimplicissin, 6-demethylpenisimplicissin, 5′-hydroxypenisimplicissin, pinophilone C, and pinophilone D.
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Figure 5. Structures of compounds from the pyridone type (3034): penicidone A–D and talarodone A.
Figure 5. Structures of compounds from the pyridone type (3034): penicidone A–D and talarodone A.
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Figure 6. Proposed biosynthetic schemes of funicone-like compounds.
Figure 6. Proposed biosynthetic schemes of funicone-like compounds.
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Table 1. List of funicone-like compounds gathered from the literature.
Table 1. List of funicone-like compounds gathered from the literature.
CodeNameFormulaNominal Mass (U)Source
True Funicones
1FuniconeC19H18O8374[2,3,4,5,6,7,8]
2ActofuniconeC21H22O9418[9]
3DeoxyfuniconeC19H18O7358[5,7,9,10,11,12,13,14]
49,14-Epoxy-11-deoxyfuniconeC19H18O8374[4]
59R,14S-Epoxy-11-deoxyfuniconeC19H18O8374[14]
69S,14R-Epoxy-11-deoxyfuniconeC19H18O8374[14]
73-O-Methyl-5,6-epoxyfuniconeC20H20O9404[15]
86-Hydroxyl-deoxyfuniconeC19H18O8374[8]
9IsofuniconeC19H18O8374[16]
103-O-MethylfuniconeC20H20O8388[5,7,17,18,19,20,21,22,23,24,25,26]
11RapiconeC17H16O7332[27]
12Pinophilone AC19H18O8374[28]
13Pinophilone BC19H18O8374[28]
Furopyrone type
14PenifupyroneC19H18O8374[5,17,18]
Phthalide type
15Vermistatin (=fijiensin)C18H16O6328[3,4,6,7,9,12,20,21,28,29,30,31,32,33,34,35,36,37,38,39,40,41,42,43,44,45,46,47,48]
16AcetoxydihydrovermistatinC20H20O8388[6,33]
176-DemethylvermistatinC17H14O6314[8,21,28,40,49]
1814,15-DihydrovermistatinC18H18O6330[6,8,12,28,33,36,38,41,44,45,46]
192″-epihydroxydihydrovermistatinC18H18O7346[21,28]
20HydroxydihydrovermistatinC18H18O7346[6,33]
21HydroxyvermistatinC18H16O7344[7,21,28,34]
225′-O-methyldihydrovermistatinC19H20O7360[28]
23MethoxyvermistatinC19H18O7358[6,7,21,28,34,40,42,50]
24Neosarphenol AC18H16O6344[40]
25PenisimplicissinC16H14O6302[3,6,20,21,28,33,44,45]
266-DemethylpenisimplicissinC15H12O6288[21,28]
275′-HydroxypenisimplicissinC16H14O7318[21]
28Pinophilone CC17H16O6316[28]
29Pinophilone DC18H18O7346[28]
Pyridone type
30Penicidone AC18H17NO5327[51]
31Penicidone BC17H15NO5313[51]
32Penicidone CC19H19NO6357[18,21,28,51]
33Penicidone DC20H21NO7387[17,18,28]
34Talarodone AC20H23NO8405[18]
Table 2. Fungal species/strains reported as producers of funicone-like compounds.
Table 2. Fungal species/strains reported as producers of funicone-like compounds.
SpeciesSource/Lifestyle/SubstrateLocationCompoundsRef.
Dothideomycetes, Pleosporales, Didymellaceae
Phoma sp. nov. LG0217Endophytic in Parkinsonia microphyllaTucson
(Arizona, USA)
15, 18[36]
Dothideomycetes, Botryosphaeriales, Phyllostictaceae
Guignardia sp. No. 4382Endophytic in Kandelia candelHong Kong (China)17[49]
Dothideomycetes, Mycosphaerellales, Mycosphaerellaceae
Pseudocercospora (=Mycosphaerella) fijiensisBanana plantHonduras15[30]
Dothideomycetes, Capnodiales, Dissoconaceae
Ramichloridium apiculatum NHL2956Air in bakeryNagoya (Japan)11[27]
Dothideomycetes, Cladosporiales, Cladosporiaceae
Cladosporium sp. JS1-2endophytic in Ceriops tagalHainan (China)15[35]
Eurotiomycetes, Eurotiales, Aspergillaceae
Aspergillus neoglaber (identified as
Neosartorya glabra) CGMCC 32286
UnknownChina24[40]
Aspergillus ruber
(identified as Eurotium rubrum) SH-823
Soft coral (Sarcophyton sp.) Xuwen (China) 15, 23[42]
Penicillium citreonigrum PAI 1/1 CSponge
(Pseudoceratina purpurea)
Bali (Indonesia)3, 15, 18[12]
Penicillium glabrum SF-7123SedimentRoss Sea
(Antarctica)
3[13]
Penicillium simplicissimum IFM53375UnknownJapan1, 15, 16, 18, 20, 25[6]
Penicillium sp.Endophytic in Riccardia multifidaMaoer Mountain (China)8, 17, 1[8]
Penicillium sp.UnknownJapan3[10]
Penicillium sp.UnknownJapan9[16]
Penicillium sp.AshMount Pinotubo (Philippines)3[11]
Eurotiomycetes, Eurotiales, Trichocomaceae
Talaromyces flavus 15[29]
Talaromyces flavus CCM-F748 Slovakia15[47]
Talaromyces flavus FKI-0076SoilHiroo (Japan)2, 3, 15[9]
Talaromyces flavus IFM52668UnknownJapan1, 4, 15[4]
Talaromyces pinophilus F36CFEndophytic in Arbutus unedoFavignana Isle
(Italy)
10[58]
Talaromyces pinophilus H608Mangrove sedimentXiamen (China)1, 3, 10, 15, 21, 23[7]
Talaromyces sp. IPV2
(identified as Penicillium funiculosum)
Apple rootSondrio Province (Italy)1[2,59]
Talaromyces pinophilus LT4, LT6Soil from rhizosphere of Nicotiana tabacumLecce Province
(Italy)
7, 10[15,19]
Talaromyces pinophilus SCAU037Soil from rhizosphere of Rhizophora stylosaTecheng Isle (China)10, 12, 13, 15, 17, 18, 19, 21, 22, 23, 25, 26, 28, 29, 32, 33[28]
Talaromyces pinophilus ST2Soil from rhizosphere of Nicotiana tabacumScafati (Italy)10[25]
Talaromyces purpureogenus MHZ 111SoilMohe (China)15, 18[46]
Talaromyces ruber (identified as Penicillium rubrum)WaterBerkeley Pit lake (USA)15, 18, 25[45]
Talaromyces sp. ZHS32Marine sedimentZhejiang (China)15[39]
Talaromyces sp. AF1-2
(unidentified in original report)
Salt panAustralia10[26]
Talaromyces sp. HM6-1-1SeawaterDongshan Isle (China)15, 18[38]
Talaromyces sp. HN29-3B1
(identified as Penicillium sp.)
Endophytic in Cerbera manghasHainan (China)15, 17, 19, 21 23, 25, 26, 27[21]
Talaromyces sp. HSZ-43
(identified as Penicillium sp.)
Endophytic in Trypterigium wilfordiiShanxi (China)1, 3, 10, 14[5]
Talaromyces sp. IFB-E022
(identified as Penicillium sp.)
Endophytic in Quercus variabilisZijin Mountain (China)30, 31, 32[51]
Talaromyces sp. XWS02F62
(identified as Penicillium sp.)
Sponge (Callyspongia sp.)Xuwen County (China)15, 18[41]
Talaromyces thailandiasis KPFC 3399SoilThailand15, 20, 25[33]
Talaromyces verruculosus CMI294548UnknownPakistan15[31]
Table 3. Microbial species/strains reported as producers of funicone-like compounds in co-cultures.
Table 3. Microbial species/strains reported as producers of funicone-like compounds in co-cultures.
Species 1Species 2Source/SubstrateLocationCompoundsRef.
Alternaria alternata
YX-25
Streptomyces exfoliatus
YX-32
mangrove mudYunxiao (China)15[37]
Penicillium sp.
WC-29-5
Streptomyces fradiae
007
rhizosphere of Aegiceras corniculatum/sedimentHainan (China)
Jiaozhou Bay (China)
3, 5, 6, 15[14]
Talaromyces pinophilus
17F4103
Paraphaeosphaeria sp.
17F4110
soilMiyazaki (Japan)10, 14, 32, 33, 34[18]
Talaromyces siamensis
FKA-61
Phomopsis sp.
FKA-62
soilJapan15[43]
Table 4. Main bioactivities of funicone-like compounds.
Table 4. Main bioactivities of funicone-like compounds.
Name (Code)BioactivityConcentrationBioassayRef.
Actofunicone (2)Reinforcement of miconazole3.7 µMCandida albicans (IC50)[9]
6-Demethylpenisimplicissin (26)Enzyme inhibitory9.5 µMα-glucosidase (IC50)[21]
Deoxyfunicone (3)Anticholesterol10 µMEfflux from RAW264.7[7]
Antiviral4.6 µMHCV (IC50 on Huh-7.5.1)[61]
Cytotoxic22.6 µMKB (IC50)[5]
Enzyme inhibitory24.3 µMProtein tyrosine phosphate 1B (IC50)[13]
1.1–4.4 µMHIV-1-integrase (IC50)[11]
Lipid inhibitory10 µMAccumulation in HepG2[7]
Downregulation of FAS, ACC, HMGR
Decrease in oxLDL in RAW264.7
NO inhibitory10.6 µM
40.1 µM
LPS-stimulated BV2 (IC50)
LPS-stimulated RAW264.7 (IC50)
[13]
PGE2 inhibitory32.3 µMLPS-stimulated BV2 (IC50)[13]
Reinforcement of miconazole1.6 µMC. albicans (IC50)[9]
2″-epiHydroxydihydrovermistatin (19)Enzyme inhibitory8 µMα-glucosidase (IC50)[21]
9,14-Epoxy-11-deoxyfunicone (4)Antifungal0.53 µmol/disc Aspergillus niger[4]
9R,14S-Epoxy-11-deoxyfunicone (5)Cytotoxic3.97 µMH1975 (IC50)[14]
9S,14R-Epoxy-11-deoxyfunicone (6)Cytotoxic3.73 µM
5.73 µM
HL-60 (IC50)
H1975 (IC50)
[14]
Funicone (1)Anticholesterol10 µMEfflux from RAW264.7[7]
Antifungal0.27 µmol/discAspergillus fumigatus[4]
Cytotoxic13.2 µMKB (IC50)[5]
Lipid inhibitory10 µMAccumulation in HepG2[7]
Downregulation of FAS, ACC, HMGR
Isofunicone (9)Pollen growth inhibitory8.02 mMCamellia sinensis (84%)[16]
Hydroxyvermistatin (21)Anticholesterol10 µMEfflux from RAW264.7[7]
Upregulation of PPARγ, LXRα, ABCG1
Decrease scavenger receptors CD36, SR-1
Enzyme inhibitory20.3 µMα-glucosidase (IC50)[21]
Lipid inhibitory10 µMAccumulation in HepG2[7]
Decrease in FAS, ACC, HMGR
Decrease in oxLDL in RAW264.7
Methoxyvermistatin (23)Anticholesterol10 µMDecrease scavenger receptors CD36, SR-1[7]
Cytotoxic0.056 mM
0.042 mM
KB (IC50)
KBv200 (IC50)
[34]
Enzymatic inhibitory236 µMα-glucosidase (IC50)[42]
Lipid inhibitory10 µMDecrease in oxLDL in RAW264.7[7]
3-O-Methylfunicone (10)Anticholesterol10 µMEfflux from RAW264.7[7]
Antifungal0.27 mMRhizoctonia solani, Fusarium solani,
Cylindrocladium scoparium, Alternaria alternata (IC100)
[19]
Antiviral5 µMdecreased mortality of MDBK infected by BoHV-1[62]
6.2 µMHCV (IC50 on Huh-7.5.1)[61]
Cytotoxic/
antiproliferative/
proapoptotic
35.3 µMKB (IC50)[5]
10 µMMDBK (IC50)[62]
63.8 µM
63.3 µM
HCT116 (LD50)
HeLa (LD50)
[26]
0.16 mMHEp-2; inhibition colony formation, decrease neutral red uptake, inhibition O2 consumption (IC50)[24]
0.07 mMHeLa (44%); promotion p21; downregulation cyclin D1/Cdk4 complex[63]
0.21 mMMCF-7; downregulates αvβ5 integrin, MMP-9 inhibitor, impairs microtubule assemblage, inhibitor of survivin, hTERT and Nanog-1 expression, reduces mammospheres[64,65]
0.21 mMA375M (IC85, 48 h)[66]
0.14 mMNCI-H2452; decreases αvβ5 integrin, MMP-2, VEGF, ERK1/2; synergism with cisplatin[67,68]
Enzyme Inhibitory12.5 µM
50.1 µM
34.3 µM
DNA polymerase κ
DNA polymerase η
DNA polymerase ι
[26]
5 mMDNA polymerase κ and η[52]
Insecticidal0.14 mMAcyrthosiphon pisum (26.2%)[23]
Lipid inhibitory10 µMAccumulation in HepG2[7]
Decrease in FAS, ACC, HMGR
Decrease in oxLDL in RAW264.7
Penicidone A (30)Cytotoxic60.1 µM
54 µM
46.5 µM
41.5 µM
SW116 (IC50)
K562 (IC50)
KB (IC50)
HeLa (IC50)
[51]
Penicidone B (31)Cytotoxic54.2 µM
21.1 µM
29.6 µM
35.1 µM
SW116 (IC50)
K562 (IC50)
KB (IC50)
HeLa (IC50)
[51]
Penicidone C (32)Cytotoxic80.8 µM
54.3 µM
44.3 µM
54.7 µM
SW116 (IC50)
K562 (IC50)
KB (IC50)
HeLa (IC50)
[51]
Enzyme inhibitory51.9 µMα-glucosidase (IC50)[28]
Penifupyrone (14)Cytotoxic4.7 µMKB (IC50)[5]
Penisimplicissin (25)Cytotoxic−6.70
−5.83
CCRF-CEM (log10 GI50)
HL-60 (log10 GI50)
[45]
Enzyme inhibitory0.66 mM
0.33 mM
IL-1β (IC100)
caspase 1 (IC100)
[44]
Rapicone (11)Enzyme inhibitory5 mMDNA polymerase κ[52]
Vermistatin (15)Antibacterial0.076 mMStaphylococcus aureus, Bacillus cereus (MIC)[35]
Anticholesterol10 µMEfflux from RAW264.7[7]
Decrease scavenger receptors CD36, SR-1
Cytotoxic0.28 mMKB (IC50)[34]
33.9 µMB16 (IC50)[39]
Enzyme inhibitory29.2 µMα-glucosidase (IC50)[21]
107.1 µMα-glucosidase (IC50)[42]
Insecticidal0.46 mMHelicoverpa armigera (IC50)[35]
Lipid inhibitory10 µMaccumulation in HepG2[7]
Decrease in FAS, ACC, HMGR
Decrease in oxLDL in RAW264.7
NO inhibitory52.7 µMLPS-stimulated BV2 (IC50)[46]
Phytotoxic3.1–6.1 mMBanana leaves[30]
Reinforcement of miconazole2.1 µMC. albicans (IC50)[9]
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MDPI and ACS Style

Salvatore, M.M.; DellaGreca, M.; Andolfi, A.; Nicoletti, R. New Insights into Chemical and Biological Properties of Funicone-like Compounds. Toxins 2022, 14, 466. https://doi.org/10.3390/toxins14070466

AMA Style

Salvatore MM, DellaGreca M, Andolfi A, Nicoletti R. New Insights into Chemical and Biological Properties of Funicone-like Compounds. Toxins. 2022; 14(7):466. https://doi.org/10.3390/toxins14070466

Chicago/Turabian Style

Salvatore, Maria Michela, Marina DellaGreca, Anna Andolfi, and Rosario Nicoletti. 2022. "New Insights into Chemical and Biological Properties of Funicone-like Compounds" Toxins 14, no. 7: 466. https://doi.org/10.3390/toxins14070466

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