1. Introduction

The serendipitous discovery of penicillin by Alexander Fleming in 1928, as a bioactive principle from the culture broth of Penicillium notatum that inhibited the growth of Gram-positive bacteria, and its introduction in 1941 as an efficient antibacterial therapeutic without substantial side effects have been considered a hallmark of fungal bioactive compounds [1]. Furthermore, this extraordinary incident was followed by successive important events that strengthened the importance of terrestrial and marine-derived fungi as sources of useful bioactive compounds. Thus, in 1948, the Italian scientist Giuseppe Brotzu first observed the antibiotic properties of and then isolated a cephalosporin-producing fungus, Cephalosporium acremonium (which is known today as Acremonium), from a sewer on the Sardinian coast. However, it was only in 1962 that Dr. Abraham’s research team was able to produce cephalosporin C, the parent molecule of a new generation of antibiotics [2].

Fungi are also a source of cholesterol-lowering agents known as statins, which were blockbuster drugs in the 1990s. The story of statins started with the isolation of a hydroxymethyl glutaryl CoA reductase (HMGR) inhibitor, compactin (ML-236B), from the culture broth of a blue-green mold, Penicillium citrinum Pen-51, which was isolated from a rice sample by Akira Endo from Sankyo Research Laboratories in Tokyo. At the same time, Alfred Alberts and his colleagues at Merck Research Laboratories discovered a new natural product in a fermentation broth of Aspergillus terreus, which showed good HMGR inhibition; they named the product mevinolin, which later became known as lovastatin. Although Sankyo had discontinued the clinical development of compactin in 1980, its derivative, pravastatin, and lovastatin are natural statins of fungal origin [3]. Besides being important producers of valuable molecules in the field of drug discovery [4], fungi also play important roles in the environment and have the ability to exploit almost all niches, either natural or man-made. As such, some fungi are being used in the bioremediation of industrial waste [5,6]. Moreover, through industrial fermentation, they are also important components in industrial applications for the production of diverse ingredients (such as acidulants, enzymes, flavors, vitamins, colorants, and polyunsaturated fatty acids) used in food processing [7]. Fungi and fungal extracts are also being exploited in pest management programs to control pests and diseases [8].

Fungi are classified primarily based on the structures associated with sexual reproduction, which tend to be evolutionarily conserved. However, many fungi reproduce only asexually, and cannot easily be classified based on their sexual characteristics: some produce both asexual and sexual states. These problematic species are often members of the Ascomycota. Historically, Article 59 of the International Code of Botanical Nomenclature (Tokyo Code) permitted mycologists to give asexually reproducing fungi (anamorphs) separate names from their sexual states (teleomorphs). Thus, teleomorphic species belonging to the “Aspergillus fischeri series” of the A. fumigatus group (Raper and Fennell 1965) were placed in the genus Neosartorya (family Trichocomaceae) by Malloch and Cain (1972). While Neosartorya species produce both a sexual state with ascospores and an asexual state with conidiospores, the Aspergillus species produce only conidiospores [9]. The Fumigati include more than 20 Neosartorya species [10]. The dual naming system can be confusing and the separate names for the anamorphs of fungi with a pleomorphic life cycle have been an issue of debate since the phenomenon was recognized. In recent years, an increasing number of mycologists have recognized the urgent need for a transition to a single-name nomenclatural system for fungi, which resulted in the preparation of the “Amsterdam Declaration on Fungal Nomenclature”, under the auspices of the International Commission on the Taxonomy of Fungi (ICTF) during the symposium “One Fungus = One Name” held in Amsterdam in April 2011 [11]. The discontinuation of the dual nomenclature system was finally approved and adopted at the 18th International Botanical Congress in Melbourne in July 2011, during which the Vienna edition of the “International Code of Botanical Nomenclature” was replaced by the “International Code of Nomenclature for Algae, Fungi and Plants” (the Melbourne Code), published in December 2012. According to the Melbourne Code, one fungus can have only one name after 1 January 2013 [11,12]. Consequently, only the genus name Aspergillus was used for both sexual and asexual states after this rule was established. However, the genus name Neosartorya is still used for those fungi that had already been taxonomically classified before the new rule was in force.

Besides a small number of species (23 species) of the genus Neosartorya [9] when compared to the genus Aspergillus, which comprises a large number of species (339 species) [13], only half of them (N. fischeri, N. pseudofischeri, N. glabra, N. tsunodae, N. laciniosa, N. paulistensis, N. fenelliae, N. spinosa, N. quadricincta, N. takakii, N. hiratsukae, N. udagawae and N. siamensis) have been investigated for their secondary metabolites. Despite this, we have found great chemical diversity and numerous interesting biological/pharmacological activities in secondary metabolites produced by members of the genus Neosartorya. Although our group has previously reviewed the bioactive secondary metabolites from a Thai collection of soil and marine-derived fungi of the genera Neosartorya and Aspergillus [14], this review reports 213 secondary metabolites isolated from cultures of terrestrial, marine-derived and endophytic fungi of the members of the Neosartorya genus, covering the literature published from 1993 to 2021. The relevant biological and pharmacological activities of some metabolites are also highlighted when applicable. The search engines that were used to find the reports of compounds included in this review were PubMed, MEDLINE, Web of Science, and Scopus.

2. Secondary Metabolites Produced by the Cultures of Fungi of the Genus Neosartorya

Since Neosartorya is a teleomorph of the A. fumigatus group, it is a legitimate expectation that, in principle, secondary metabolites produced by members of the genus Neosartorya would resemble those produced by Aspergillus species. In fact, we have found common traits in the secondary metabolites produced by Neosartorya species and Aspergillus species, especially indoles [15], meroterpenoids [16], and polyketides [17]. Surprisingly, we have noted different types of metabolites within the same species, isolated from different environments. However, it is not possible to conclude whether the fungus isolated from different environments produced different metabolites or whether the culture media used also plays a role in this phenomenon.

In the following subsections, the secondary metabolites are categorized according to their biosynthetic origins and are then subdivided according to their structural features.

2.1. Indole Alkaloids

Indole alkaloids consist of the indole ring system, which is derived from the amino acid Trp. In order to facilitate the readability of this section, these compounds are subdivided into simple indoles, prenylated indoles, annelated indoles, and bis-indoles, according to Wibowo et al. [15].

2.1.1. Simple Indoles

Fiscalin B (1) (Figure 1), a simple indole having an isopropyl pyrazinoquinazolinone ring system, linked to an indole moiety by a methylene group, was first isolated in 1993 from the culture extract of N. fischeri, obtained from a plant rhizosphere that was collected near the We Fung Chi Cascade region of Taiwan. The fungus was cultured in a liquid medium containing glycerol, dextrin, Bacto-Soytone, yeast extract, (NH₄)₂SO₄, and CaCO₃ at pH 7.0 [18]. Later, this compound was also obtained from the extract of marine-derived N. fischeri, isolated from a marine mud collected in the intertidal zone of Hainan province, China, and cultured in a liquid medium (barley sugar, ajinomoto, glucose, yeast extract, steepwater, mannitol, KH₂PO₄, MgSO₄·7H₂O, CaCO₃, salt, with a pH of 6.5) [19].

Two pyrazinoquinazolinone-containing indoles, i.e., the unreported 3-methoxyglyantrypine (2) and the previously described glyantrypine (3) (Figure 1) were also obtained from a culture (cooked rice) extract of N. fischeri TJ 403-CA8, isolated from a medicinal insect, Cryptotympana atrata (Cicadidae), which was collected from the Pangquan Ditch National Nature Reserve of Lvliang City, Shanxi Province, China [20]. Fumiquinazoline F (4), a methyl pyrazinoquinazolinone-containing indole, and indolyl-3-acetic acid methyl ester (5) (Figure 1) were isolated from a liquid culture extract (glucose, peptone, yeast extract, CaCO₃, H₂O) of the marine-derived N. pseudofischeri, isolated from the inner tissue of a starfish (Acanthaster planci) that was collected from the Hainan Sanya Natural Coral Reef Reserve, China [21].

The extract of marine-derived N. pseudofischeri (collection no. 2014F27-1), isolated from the inner tissue of a sea star (A. planci), was collected from Hainan Sanya National Coral Reef Reserve, China, and cultured in glucose-peptone-yeast extract medium, furnishing N-methyl-1H-indole-2-carboxamide (6) (Figure 1) [22].

In addition, (3R)-3-(1H-indol-3-ylmethyl)-3, 4-dihydro-1H-1,4-benzodiazepine-2,5-dione (7) (Figure 1) was obtained from a culture extract of the marine sponge-associated fungus N. glabra KUFA 0702, isolated from the marine sponge Mycale sp., which was collected from the coral reef at Samaesarn Island in the Gulf of Thailand, Chonburi Province, and cultured in a cooked rice solid medium [23].

2.1.2. Prenylated Indoles

1,4-Benzodiazepene-2,5-dione-containing Prenylated Indoles

Aszonalenin (8) and acetylaszonalenin (9a) (Figure 2) are the most frequently isolated 1,4-benzodiazepene-2,5-dione-containing prenylated indoles from the genus Neosartorya. Compound 8 was isolated from a culture extract of: N. pseudofischeri IFM 52672, which was cultured in moist rice [24]; N. ficheri KUFC6344, isolated from coastal forest soil at Samaesarn island, Chonburi Province, Thailand, and cultured in a cooked rice solid medium [25]; N. fischeri CGMCC3.5378, obtained from the Chinese Academy of Science, and cultured in a solid medium containing moist corn germ [26]; N. fischeri JS0553, an endophytic fungus isolated from the plant Glehnia littoralis (family Apiaceae), which was collected in a swamp area of Suncheon, South Korea, and cultured in a solid rice medium [27]; N. tatenoi KKU-2NK23, collected from forest soil in Khon Kaen province, Thailand, and cultured in a liquid medium containing potato dextrose broth [28]; the marine-derived N. takakii KUFC 7898, isolated from the alga Amphiroa sp., which was collected in Samaesarn Island in the Gulf of Thailand and cultured in a cooked rice solid medium [29], the marine-derived N. glabra, isolated from a marine sponge Mycale sp., which was collected from the coral reef of Samaesarn Island, in the Gulf of Thailand, and cultured in a cooked rice solid medium [23]; and the marine sponge-associated N. fenelliae KUFA 0811, isolated from the marine sponge Clathria reinwardtii, which was collected from Samaesarn Island in the Gulf of Thailand and cultured in a cooked rice solid medium [30]. Compound 9a was reported only from N. ficheri KUFC6344 [25], N. fischeri CGMCC3.5378 [26], an endophytic fungus, N. fischeri JS0553 [27], and N. fischeri TJ 403-CA8 [20], whereas the unreported 6-hydroxyacetylaszonalenin (9b) (Figure 2) was also isolated from a culture extract of the insect-derived N. fischeri TJ403-CA8 [20]. The indole 6-Hydroxyaszonalenin (10) (Figure 2) was also isolated from a culture extract of N. fischeri CGMCC3.5378 [26] and the insect-derived N. fischeri TJ 403-CA8 [20], whereas 1-formyl-5-hydroxyaszonalenin (11) (Figure 2) was obtained from a culture extract of N. fischeri KUFC 6344 [25].

Tetracyclic 1,4-benzodiazepene-2,5-dione-containing prenylated indoles were also reported from the fungi of the genus Neosartorya. Whereas takakiamide (12) (Figure 2) was isolated from a culture extract of the marine-derived N. takakii KUFC 7898 [29] and later from a culture extract of the marine-derived N. glabra [23], fischeramides A (13) and B (14) (Figure 2) were also isolated from the insect-derived N. fischeri TJ 403-CA8 [20].

1,4-Diketopiperazine-containing Prenylated Indoles

The indole 1,4-diketopiperazine-containing prenylated indoles are a large group of indole alkaloids reported from members of the genus Neosartorya. Most of the isolated compounds are pentacyclic, but tetra- or hexacyclic compounds were also reported. They can be mono-, di- or triprenylated. Normally, the 1,4-diketopiperazine moiety is linearly fused with a pyrrolidine ring to form a hexahydropyrrolo [1,2-a]pyrazine-1,4-dione ring system, evidencing the incorporation of the amino acid proline in their biogenesis.

Tryprostatin B (15) (Figure 3), a tetracyclic 1,4-diketopiperazine-containing prenylated indole, was isolated from the insect-derived N. fischeri TJ 403-CA8 [20], while the pentacyclic analog, fumitremorgin C (16) (Figure 3) was reported as being sourced from culture extracts of N. fischeri CGMCC 3.5378 (from the Chinese Academy of Science), which were cultured in a wheat bran solid medium [31,32]. Analogs of fumitremorgin C (16), i.e., 12α,13α-dihydroxyfumitremorgin C (17), 12-hydroxyfumitremorgin C (18), 12-methoxyfumitremorgin C (19), cyclotrypostatin B (20), rel-(8S)-19,20-dihydro-8-methoxy-9,18-diepifumitremorgin C (21) and verruculagen TR-2 (22) (Figure 3) were also reported from N. fischeri CGMCC 3.5378 [32]. Compounds 18–20 were also isolated from the insect-derived N. fischeri TJ403-CA8 [20], while 12β-hydroxyverruculagen TR-2 (23) (Figure 3) was isolated from a culture extract of N. fischeri NRRL 181, purchased from DSMZ (DE-Braunschweig), and was cultured in potato dextrose agar medium [33]. Compound 20 was also isolated, together with fumitremorgin B (24) (Figure 3), from the endophytic fungus, N. fischeri JS0553 [27]. Compound 24 was also isolated from N. fischeri var. fischeri CBM-FA-0156, which was cultured in a solid rice medium [34], whereas 13-oxofumitremorgin B (25) (Figure 3) was isolated from a culture extract of the soil fungus N. fischeri KUFC 6344 [25], as well as from N. fischeri CGMCC 3.5378 [26].

Fumitremorgin A (26) (Figure 4), a hexacyclic 1,4-diketopiperazine-containing prenylated indole with a peroxide-containing eight-membered ring formed by two prenyl groups, was reported from the endophytic fungus N. fischeri JS0553 [27], N. fischeri NRRL 18 [33], and N. fischeri var. fischeri CBM-FA-0156 [34].

Three peroxide-containing hexacyclic prenylated indoles, including the previously reported verruculogen (27) and two undescribed neofipiperazines A (28) and B (29), together with an undescribed pentacyclic diprenylated indole, neofipiperazine C (30) (Figure 4) were isolated from a culture extract of N. fischeri CGMCC 3.5378 [32]. Compound 27 was also reported from N. fischeri CGMCC 3.5378 [26] and N. fischeri NRRL 181 [33]. Neofipiperazine D (31) (Figure 4), another undescribed pentacyclic diprenylated indole, was isolated from a culture extract of N. fischeri CGMCC 3.5378 [31].

Previously reported 6-methoxyspirotryprostatin B (32), spirotryprostatin C (33), spiro [5H,10H-dipyrrolo [1,2-a]:1′,2′-d]pyrazine-2-[3H], 2′[2H]indole]-3,5,10(1′H]trione (34), and the unreported spirotryprostatin M (35) (Figure 4) were isolated from a culture extract of the insect-derived N. fischeri TJ 403-CA8 [20].

Quinazolinone-Containing Prenylated Indoles

Pseudofischerine (36) (Figure 5), an unreported quinazolinone-containing prenylated indole, was isolated from a culture extract of N. pseudofischeri KUFC 6422 S. W. Peterson, obtained from soil planted with rose apples (Eugenia javanica, family Myrtaceae) from Angthong Province, Thailand, and cultured in a cooked rice solid medium [35]. The structure of the compound was established by the interpretation of high-resolution mass spectrum (HRMS) and 1-dimensional (1D) and 2-dimensional (2D) NMR data. The relative stereochemistry of 36 was established, based on the NOESY correlations from H-5a to OH-9a, H-12, Me-13, Me-14, H-6′, as well as via comparison with the structure of the previously described chaetominine, isolated from the endophytic fungus Chaetomium sp. IFB-E015, the stereochemistry of which was established by single-crystal X-ray analysis and the determination of the aminoacid L-Ala using Marfey’s method [36]. Later on, Liao et al. reported the isolation of isochaetominine C (37) from a culture extract of the marine-derived Aspergillus sp. (strain number F452). Surprisingly, the ¹H and ¹³C NMR data of 37 and 36 (both in DMSO-d₆) were nearly identical; however, the stereochemistry of 37 was enantiomeric of 36. Since the configurations of C-5a, C-8, C-9a and C-11 in 37 were determined by NOESY correlations and an identification of the amino acid L-Val using an advanced Marfey’s method [37], the absolute configurations of its stereogenic carbons were established. Therefore, 36 and 37 are the same compound. Later on, Lan et al. [21] reported the isolation of isochaetominine C (37) from a culture extract of N. pseudofischeri, isolated from the inner tissue of a starfish (A. planci) that was collected from the Hainan Sanya National Coral Reef Reserve, China, and cultured in a liquid medium. However, the stereochemistry of the structure of isochaetominine C reported in this paper is opposite to that reported by Liao et al. [37]. Compound 37 was also isolated from N. pseudofischeri [38] and also from N. hiratsukae [39]; both samples were collected from soil in the Chiang Mai forest, Thailand, and cultured in a potato dextrose liquid medium.

Three previously unreported reverse prenylated indole alkaloids analogs of (-)-ardeemins, sartoryglabrins A (38), B (39) and C (40) (Figure 5), were isolated from an extract of a solid culture medium (cooked rice) of N. pseudofischeri, which was collected from soil in Chonburi Province, Thailand. The structures of the compounds were elucidated by analysis of HRMS, 1D and 2D NMR data. The absolute structure of 38 was established by X-ray analysis, using CuKα radiation [40].

2.1.3. Anellated Indoles

Like prenylated indoles, anellated indoles also constitute a large group of specialized metabolites reported from both terrestrial and marine-derived Neosartorya species. Their structures vary from simple to complex, and some of them incorporate sulfur atoms to form a disulfide bridge.

β-Carboline Alkaloids

Two β-carboline analogs, 1-acetyl β-carboline (41) [21] and harmane (42) [30] (Figure 6) were isolated from a culture extract of the marine-derived N. pseudofischeri, isolated from the inner tissue of a starfish (A. planci) and the marine sponge-associated N. tsunodae KUFC 9213, respectively.

Pyrazino [1,2-a]indole-1,4-dione Derivatives

Two unreported 2,3-dihydropyrazino [1,2-a]indole-1,4-dione derivatives, neosartins A (43) and B (44), and the previously reported 1,2,3,4-tetrahydro-2-methyl-1,4-dioxopyrazino [1,2-a]indole (45), 1,2,3,4-tetrahydro-2-methyl-3-methylene-1,4-dioxopyrazino [1,2-a]indole (46), 1,2,3,4-tetrahydro-2-methyl-1,3,4-trioxopyrazino [1,2-a]indole (47), were isolated from a culture extract of the marine-derived N. pseudofischeri (collection no. 2014F27-1) [22], while the previously reported 6-hydroxy analog of 47, 1,2,3,4-tetrahydro-6-hydroxy-2-methyl-1,3,4-trioxopyrazino [1,2-a]indole (48), was isolated from a culture extract of the marine-derived N. pseudofischeri, isolated from the inner tissue of a starfish (A. planci) [21].

The sulfur-containing hexahydropyrazino [1,2-a]indole-1,4-dione analogs, gliotoxin (49), acetylgliotoxin (50), bis(dethio)bis(methylthio)gliotoxin (51), reduced gliotoxin (52), 6-acetylbis(methylthio)gliotoxin (53), didehydrobisdethiobis (methylthio)gliotoxin (54) and bis-N-norgliovictin (55) (Figure 6) were also reported from a culture extract of the marine-derived N. pseudofischeri (collection no. 2014F27-1) [22]. Compounds 49 and 51 were also reported from a culture extract of N. pseudofischeri, cultured in a solid rice medium [41].

Quinazolinone-Containing Anellated Indoles

A major group of quinazolinone-containing anellated indoles are the tryptoquivalines. The structural characteristic of tryptoquivalines is the presence of a quinazolinone moiety, connected to the 6-5-5-imidazoindolone ring system via a five-membered spirolactone. Tryptoquivaline (56) (Figure 7) was isolated from a solid culture (cooked rice) extract of N. siamensis KUFC 6349 obtained from forest soil on Samaesarn Island, Chonburi province in Thailand [42], the marine-derived N. siamensis KUFA 0017, isolated from a sea fan (Rumphella sp.) that was collected from the coral reef of the Similan Islands, Thailand [43], and N. spinosa KKU-1NK1, obtained from forest soil in Khon Kaen Province, Thailand [44], whereas nortryptoquivaline (57) (Figure 7) was isolated from a culture extract of N. pseudofischeri IFM 52672 [24], the marine-derived N. siamensis KUFCA0017 [43], and also from a soil-derived N. spinosa KKU-1NK1 [44].

The previously reported tryptoquivalines F (58), H (59), L (60), and the unreported tryptoquivaline O (61) (Figure 7) were also isolated from a culture extract of the soil-derived N. siamensis KUFC 6349. It is worth mentioning that Buttachon et al. [42] have established the absolute configurations of C-2, C-3, and C-12 of 60 as 2S, 3S, 12R by X-ray analysis using CuKα radiation, which was opposite to those previously reported by Yamazaki et al. [45], thus establishing unambiguously the stereostructures of the tryptoquivaline series. Another unreported tryptoquivaline analog, tryptoquivaline T (62), was isolated from a culture extract of the diseased coral-derived N. laciniosa KUFC 7896 [46]. Compounds 58–60 were also isolated from a culture extract of the marine sponge-associated N. paulistensis KUFC 7897 [46]. Compound 60 was the most common tryptoquivaline, being reported from various species and strains of Neosartorya, such as the marine-derived N. siamensis KUFCA0017 [43], the marine-derived N. laciniosa KUFC 7896 [25], and the soil-derived N. spinosa KKU-1NK1 [44]. Compound 59 was also reported from the marine-derived N. siamensis KUFA 0017 [43], the marine sponge-associated N. paulistensis KUFC 7897 [46]. Compounds 59 and 60 were isolated, together with a new tryptoquivaline analog, tryproquivaline U (63), from a culture extract of the algicolous fungus, N. takakii KUFC 7898 [29].

The unreported tryptoquivaline V (64) was isolated from a culture extract of the soil-derived N. pseudofischeri [38]. It is interesting to note that the stereochemistry at C-3 of the five-membered lactone was opposite to that of all the reported tryptoquivalines. The authors determined the absolute configuration of C-3 only by NOESY correlations between key protons, some of which were not well defined, and a sign of the optical rotation. However, the authors did not use any reliable methods, such as X-ray crystallography with CuKα radiation or chiroptical methods, to determine the absolute configuration of the stereogenic carbon.

Two tryptoquivaline derivatives, the tryptoquivalines P (65) and Q (66) (Figure 7), were isolated from the organic extract of Neosartorya sp. HN-M-3, obtained from a marine mud in the intertidal zone of Hainan Province, China, and cultured in a liquid medium containing barley sugar, ajinomoto, glucose, and yeast extract. The structures of 65 and 66 differ from other tryptoquivalines in that the five-membered lactone ring is hydrolyzed to give a hydroxy group on C-2 and a carboxylic acid on C-11. However, the absolute configurations at C-2 and C-3 were not determined [47].

The indole 3′-(4-Oxoquinazolin-3-yl)spiro [1H]-indole-3,5′]-2,2′-dione (67) (Figure 7), which contains a quinazolinone moiety connected to 2-oxindole instead of the 6-5-5-imidazoindolone ring system, via a five-membered spirolactone, was first isolated from a culture extract of N. siamensis KUFC 6349 [42] and, later, from the sea-fan-derived N. siamensis KUFA 0017 [43], the marine-derived N. laciniosa KUFC 7896 [25], the marine-derived N. paulistensis KUFC 7897 [46], and the marine-derived N. takakii KUFC7898 [29].

The undescribed quinazolinone-containing hexacyclic indole alkaloid consisting of an azepinone ring fused with the indole ring system, named sartorymensin (68) (Figure 7), was isolated from a culture extract of the soil-derived N. siamensis KUFC 6349. The structure of 68 was established by the interpretation of HRMS and 1D and 2D NMR data. The absolute configurations at C-10 and C-13 were established unequivocally as 10S and 13S by X-ray analysis using CuKα radiation [42].

Pyrazinoquinazolinone-Containing Anellated Indoles

The compounds of this group consist of a pyrazinoquinazolinone moiety connected to the 6-5-5-imidazoindolone ring system by a methylene bridge. A culture extract of the soil-derived N. siamensis KUFC 6349 furnished the previously reported fiscalin A (69) and its undescribed diastereomers, epi-fiscalin A (70), neofiscalin A (71), and epi-neofiscalin A (72), as well as the previously reported fiscalin C (73) and the undescribed epi-fiscalin C (74) (Figure 8). The structures of 69–74 were elucidated by extensive analysis of HRMS data and 1D and 2D NMR spectral analysis. The configuration of C-3 in 70 was evidenced by a W-type long-range coupling between NH-2 and H-14 in the COSY spectrum, while the configurations of C-20 and C-22 were proved to be the same as those of 69 by a NOESY correlation from H-20 to Me-21. The stereostructures of 71 and 72 were based on a W-type long-range coupling between NH-2 and H-14 in the COSY spectrum and the NOESY correlation from H-20 to Me-21 or H-22. The structures and configurations of the stereogenic carbons of 69–72 were corroborated by the stereostructure of 73 and 74, whose structures and the absolute configurations of the stereogenic carbons were established conclusively by X-ray analysis using CuKα radiation [42]. Compounds 69–74 were also isolated from a culture extract of the sea-fan-derived N. siamensis KUFA 0017 [43].

Compound 74 was also isolated, together with two unreported tryptoquivalines, E (75) and F (76) (Figure 8), from a culture extract of N. udagawae HDN 13-313 that was obtained from the root of a mangrove plant, Aricennia marina, collected from a mangrove conservation area in Hainan Province, China, and cultured in a liquid medium (composed of maltose, mannitol, glucose, monosodium glutamate, and yeast extract). The stereochemistry of 75 and 76 was established by a comparison of the calculated and experimental electronic circular dichroism (ECD) spectra. The structure and stereochemistry of 75 were also confirmed by X-ray analysis [48]. The previously reported fiscalin analog, quinadoline A (77) (Figure 8), was also isolated from the soil-derived N. spinosa KKU-1NK1 [44].

Pyridoquinazolinone-Containing Anellated Indoles

Wu et al. reported the isolation of an undescribed pyridoquinazolinone linked to 2-oxindole by a spirofuran ring, together with an undescribed pyridoquinazolinone linked to the imidazolindolone moiety by a spirofuran ring, which they have named tryptoquivalines U (78) and T (79) (Figure 8), respectively. These were from a culture extract of the marine-derived N. fischeri, isolated from a marine mud, which was collected in the intertidal zone of Hainan Province, China [19]. Interestingly, the authors were unaware of the existence of the previously reported tryptoquivaline T (62), isolated from a culture extract of the diseased coral-derived N. laciniosa KUFC 7896 [46], along with tryptoquivaline U (63), isolated from a culture extract of the algicolous fungus N. takakii KUFC 7898 [29], and they gave the same names to their compounds. Structurally, tryptoquivalines are a class of indole alkaloids, having a quinazolinone moiety connected to the 6-5-5-imidazoindolone ring system via a five-membered spirolactone and not a pyridoquinazolinone connected to the 6-5-5-imidazoindolone ring system via a five-membered spirolactone, which is the case with 78 and 79.

Later, Yu et al. reported the undescribed fiscalins E (80) and F (81), and two pyridoquinazolinones, linked to the imidazolindolone ring system by a spirofuran ring, which were named Neosartoryadins A (82) and B (83) (Figure 8), and were taken from a culture extract of N. udagawae HDN 13-313 [48]. The structures of both compounds were established by extensive analysis of HRMS and 1D and 2D NMR data. The absolute configurations of the stereogenic carbons in 80 and 81 were established by comparison of calculated and experimental ECD spectra. In the case of 80, the absolute structure was confirmed by X-ray analysis. The relative configurations of the stereogenic carbons in 82 and 83 were established by NOESY correlations of the key protons while the absolute configurations at C-1, C-14, C-16 and C-17 in 82 were determined as 1R, 14R, 16S, and 17R by comparison of the calculated and experimental ECD spectra. The absolute configurations at C-1, C-14, C-16 and C-17 in 83 are the same as those of 77, since both compounds displayed nearly identical ECD spectra. Interestingly, the structure of Neosartoryadin A (82) is the same as that of tryptoquivaline U (78), as reported by Wu et al. [19]. The only difference is that the configuration of C-12 in 78 is opposite to that of the same carbon (C-14) in 82. Since the configuration of C-12 in 78 was opposite to that of the same carbon of all other imidazolindolone-containing compounds isolated from members of this genus, this raises the possibility of a wrong assignment.

Shan et al. described the isolation of two undescribed norfumiquinazolines, cottoquinazolines E and F, from the ethanol extract of a solid culture (moist wheat) of N. fischeri NRRL 181 [49]. The structures of the compounds were elucidated by extensive analysis of 1D and 2D NMR and HRMS spectral data; however, the relative configurations of some stereogenic carbons were still undetermined by NOESY correlations. Recently, Lin et al. also obtained the cottoquinazolines E (84), F (85), and G (86) (Figure 9) from the organic extract of a solid rice culture of the insect-derived N. fischeri TJ 403-CA8. The structures of the compounds were established by analysis of HRMS and 1D and 2D NMR spectral data. The relative configurations of C-16, C-17 and C-19 were determined as 16S*, 17S*, and 19S* by NOESY correlations, while the absolute configurations of C-3, C-14, C-16, C-17, and C-19 were determined by X-ray analysis using CuKα radiation as 3S, 14S, 16S, 17S, and 19S, thus solving the structure and the absolute configurations of the stereogenic carbons in 84. The absolute configurations of the stereogenic carbons in 85 and 86 were determined by comparison of their calculated and experimental ECD spectra [50].

2.1.4. Bis-Indoles

Only three bis-indoles were isolated from fungi of the genus Neosartorya. Fellutamine A (87) and the unreported fellutamine A epoxide (88) (Figure 9) were isolated from a culture extract of the marine sponge-associated N. glabra KUFA 0702 [23]. The relative configurations of C-2′ and C-3′ in 88 were established by NOESY correlations, as well as by molecular modeling. Compound 87 was also isolated from the marine sponge-associated N. fenelliae KU0811 [30].

2.2. Dibenzylpiperazine Alkaloids

Although indole alkaloids are very copious in the fungi of the genus Neosartorya, dibenzylpiperazine alkaloids are very rare among the species investigated. Biosynthetically, dibenzylpiperazine alkaloids are derived from the coupling of Phe/Tyr.

Eamvijarn et al. [35] described the isolation of an enantiomeric rotamer (89) (Figure 10) of the previously reported brasiliamide B [51] via analysis of the chemical shift values of H-3, H-5, and the methyl groups of the N₄-acetamide, in addition to two rotamers of an undescribed 1,4-diacetyl-2,5-dibenzylpiperazine-3,7”-oxide (90a/90b) (Figure 10) from a culture extract of the soil-derived N. pseudofischeri. Compounds 90a/90b were later isolated, together with the unreported brasiliamide G (91) (Figure 10), from a culture extract of the soil-derived N. fischeri [38], while both rotamers of the undescribed brasiliamide H (92a/92b) (Figure 10) were isolated from a culture extract of the soil-derived N. hiratsukae (specimen EU06) [39].

2.3. Peptides

The previously reported dipeptide, (11aR)-2,3-dihydro-1H-pyrrolo [2,4-c][1,4]benzodiazepine-5,11 (10H,11aH)-dione (93), and two undescribed cyclic tetrapeptides, sartoryglabramides A (94) and B (95) (Figure 11) were isolated from a culture extract of the marine sponge-associated N. glabra KUFA 0702 [23]. The difference between 94 and 95 is that the Phe residue that linked with the anthranilic acid moiety in the former was replaced by Trp in the latter. The structures of both 94 and 95 were elucidated by extensive analysis of HRMS and 1D and 2D NMR data. The stereostructure of 94 was established by X-ray analysis using CuKα radiation, whereas the absolute configurations of the amino acid residues in 95 were determined by chiral HPLC analysis of its acidic hydrolysate, using appropriate D- and L-amino acid standards.

2.4. Terpenoids

Terpenoids were not commonly found in Neosartorya species. The previously reported triterpene hopan-3β, 22-diol (96) (Figure 12), was isolated from a culture extract of the marine sponge-associated fungus N. tsunodae KUFC 9213 [30], whereas the nortriterpene, helvolic acid (97) (Figure 12), was very common and was reported from culture extracts of the soil-derived N. fischeri KUFC 6344 [25], as well as from the marine sponge-associated N. tsunodae KUFC 9213 and N. fenelliae KUFC 0811 [30].

The cadinene sesquiterpene (98) (Figure 12) was isolated from culture extracts of the soil-derived N. pseudofischeri KUFC 6422 [35] and N. pseudofischeri [41]. Compound 98 was previously obtained by the selective degradation of a natural product, CJ-12662 [52]. Compound 98 and its deacetyl derivative (99) were isolated, together with an aromatized cadinene, 5-formyl-6-hydroxy-8-isopropyl-2-naphthoic acid (100) (Figure 12), from a culture extract of the starfish-associated N. pseudofischeri [21].

2.5. Meroterpenoids

Meroterpenoids constitute a large group of specialized metabolites from Neosartorya species. They are structurally diverse and can be grouped according to the type of terpenoids, such as sesquiterpenes and diterpenes. Within the terpenoid class, they can be grouped according to a non-terpenoid moiety.

2.5.1. Merosesquiterpenes

The first group of merosesquiterpenes is of the pyripyropenes and phenylpyripyropenes. In this group, the non-terpenoid moiety is derived from polyketides. The difference between these two groups is the presence of a pyridine ring in the former and a phenyl group in the latter. Several pyripyropenes with varying substituents have been reported from N. fischeri and N. pseudofischeri.

Pyripyropene A (101) (Figure 13) was reported from culture extracts of N. fischeri J80553 [27], N. fischeri NRRL 181 [33,49], the soil-derived N. pseudofischeri KUFC 6422 [35], the marine-derived N. fischeri [21], the sea-star-derived N. pseudofischeri [22], the soil-derived N. pseudofischeri [38] and N. pseudofischeri [41]. Several derivatives of pyripyropene A were also isolated from N. fischeri and N. pseudofischeri. In addition, 7-deacetylpyripyropene A (102) (Figure 13) was reported from culture extracts of the insect-derived N. fischeri [20], N. fischeri NRRL 181 [33], and the starfish-derived N. pseudofischeri [21], along with 11-deacetylpyripyropene A (103) (Figure 13) from the insect-derived N. fischeri [20], 1,11-dideacetylpyripyropene A (104) and 1,7,11-trideacetylpyripyropene A (105) (Figure 13) from N. fischeri NRRL 181 [33], and 13-dehydroxypyripyropene A (106) (Figure 13) from a starfish-derived N. pseudofischeri [21], while the unreported pyripyropene E (107) (Figure 13) was isolated from N. fischeri [41].

Two previously reported phenylpyripyropenes A (108) and B (109), and the unreported 5-olefin phenylpyripyropene A (110) (Figure 13) were also isolated from the starfish-derived N. pseudofischeri [21]. Finally, chrodrimanins A (111) and B (112) (Figure 13) were isolated from a culture extract of N. glabra CGMCC32286 [53].

The second group of merosesquiterpenes consists of a cadinene sesquiterpene linked to aniline derivatives by an ester linkage. The previously described eurochevalierine (113) (Figure 14) was isolated from culture extracts of the soil-derived N. pseudofischeri KUFC6422 [35], the soil-derived N. pseudofischeri [38], N. pseudofischeri [41], and the soil-derived N. hiratsukae [39]. The previously reported merosesquiterpenes containing a pyrrolobenzoxazine moiety linked to a cadinene sesquiterpene, CJ-12662 (114), and CJ-12663 (115) (Figure 14) were isolated from the soil-derived N. pseudofischeri [38], N. pseudofischeri [41], and the soil-derived N. hiratsukae [39].

A cadinene ester of a pyrroloindole, fischerindoline (116) (Figure 14) was first reported from N. fischeri [41] and later from the soil-derived N. pseudofischeri [38], while its unreported 7-chloro derivative, 7-chlorofischerindoline (117) (Figure 14) was isolated from the soil-derived N. hiratsukae [39].

Compound 113 can be hypothesized as a biosynthetic precursor of 115, as shown in Figure 15. The nucleophilic addition of the methylamino group on C-2′ to the aldehyde carbonyl (C-5), with a concomitant addition of the aldehyde oxygen to the carbonyl carbon attached to the benzene ring (C-4) in 113, leads to the formation of an intermediate containing a bicyclic structure, linked by an ether bridge. Cleavage of the C-5-N and C-3-O bonds with the formation of C-3-N and N-O bonds leads to a pyrrolobenzoxazine moiety in 115.

2.5.2. Meroditerpenes

All the meroditerpenes isolated from members of the genus Neosartorya have polyketides with a variable number of acetate units in a non-terpenoid moiety. The most common diterpenoid moiety is tricyclic, but bicyclic, monocyclic, or even linear diterpenes have also been reported. They can be divided into three subgroups, according to the structure of the polyketide moiety.

Meroditerpenes Containing 2-Pyrone

The most frequently isolated 2-pyrone-containing meroditerpene is aszonapyrone A (118) (Figure 16). Aszonapyrone A (118) consists of a tricyclic diterpene of a perhydrophenanthrene skeleton, linked to a 4-hydroxy-6-methyl-2H-pyran-2-one ring by a methylene bridge. Compound 118 was reported from a culture extract of the soil-derived N. fischeri KUFC 6433 and the marine-derived N. laciniosa KUFC 7896 [25], N. fischeri FO-5897 (cultured in sodden rice) collected from a soil sample from the city of Funabashi, Chiba, Japan [54], N. fischeri CGMCC3.5378 [26], the soil-derived N. tatenoi KKU-2NK23 [28], and the algicolous N. takakii KUFC 7898 [29]. Aszonapyrone B (119) (Figure 16), the deacetyl analog of 118, was reported from N. fischeri CGMCC3.5378 [26], N. fischeri FO-5897 [54], the marine-derived N. laciniosa KUFC 7896 [25], and the soil-derived N. tatenoi KKU-2NK23 [28]. Sartorypyrone C (120) (Figure 16), an isomer of 119 with an endocyclic double bond instead of an exocyclic double bond, was reported from a culture extract of the marine sponge-associated N. paulistensis KUFC 7897 [46].

Another subgroup of 2-pyrone-containing meroditerpenes are the pentacyclic compounds, which have the diterpenoid moiety linked to a 2-pyrone ring through a dihydropyran ring. Chevalone A (121) (Figure 16) was isolated from the soil-derived N. pseudofischeri [38], while its acetate derivative, chevalone B (122) (Figure 16), was isolated from the soil-derived N. siamensis KUFC 6349 [42], the soil-derived N. pseudofischeri [38], the marine-derived N. fenelliae KUFA 0811 [30], the algicolous N. takakii KUFC 7898 [29], and the soil-derived N. spinosa KKU-1NK1 [44]. The unreported chevalone G (123), with a ketone group on C-3 of a diterpene moiety, and the unreported aszonapyrone G (124) (Figure 16), which contains a bicyclic diterpene moiety, were reported from the soil-derived N. hiratsukae [39], while a 2-pyrone-containing monocyclic meroditerpene, sartorypyrone A (125) (Figure 16) was first isolated from the soil-derived N. fischeri KUFC 6344 [25] and, later, from N. fischeri FO-5897 [54] and the plant endophytic N. fischeri JS0553 [27]. Sartorypyrone D (126) (Figure 16), a deacetylated derivative of 125, was also isolated from N. fischeri JS0553 [27] and also from the soil-derived N. hiratsukae [39]. A 2-pyrone-containing meroditerpene with a linear diterpenoid bearing a vicinal diol function, sartorypyrone E (127) (Figure 16) was also isolated from N. fischeri JS0553. The absolute configuration of C-20 in 127 was established as 20S by ¹H NMR analysis of its S- and R-MTPA esters [27].

Meroditerpenes Containing 4-Pyrone

Meroditerpenes containing 4-pyrone, isolated from Neosartorya species, consist of a tricyclic diterpene skeleton, linked to a 4-pyrone ring through a dihydropyran moiety. Chevalone C (128) (Figure 17) was reported from a culture extract of N. siamensis KUFC 6349 [42], the marine-derived N. siamensis KUFA 0017 [43], the soil-derived N. spinosa KKU-1NK1 [44], the marine-derived N. tsunodae KUFC 9213 [30], the soil-derived N. pseudofischeri [38], and the soil-derived N. hiratsukae [39].

Several derivatives of chevalone C (128) have been reported from Neosartorya species. The unreported 1-hydroxychevalone C (129), 1-acetoxychevalone C (130), 11-hydroxychevalone C (131), 1,11-dihydroxychevalone C (132), and the previously reported chevalone E (133) (Figure 17) were isolated from a culture extract of the soil-derived N. spinosa KKU-1NK1 [44]. Compounds 131 and 133 were also isolated from N. pseudofischeri [38] and the soil-derived N. hiratsukae [39], while the unreported 11-hydroxychevalone E (134) (Figure 17) was also isolated from the soil-derived N. pseudofischeri [38]. The previously described sartorypyrone B (135) (Figure 17) was also isolated from the marine-derived N. tsunodae KUFC 9213 [25] and the marine-derived N. fenelliae KUFA 0811 [30]. The undescribed chevalone F (136), with a ketone group on C-3, was isolated from N. pseudofischeri [38] (Figure 17).

Meroditerpenes Containing a Linear Polyketide Moiety

The undescribed sartorenol (137) (Figure 17), a meroditerpene consisting of a tricyclic diterpene with an unusual (4Z)-5-hydroxy-3-oxohex-4-en-1-yl substituent, was isolated from a culture extract of the marine-derived N. takakii KUFC 7898 [29], while the unreported tatenoic acid (138) (Figure 17), the substituent of which is a carboxymethyl group, was isolated from the soil-derived N. tatenoi KKU-2NK23 [28].

2.6. Sterols and Sterones

Ergosterol (139) and its 5,8-endoperoxide (140) (Figure 18) were isolated from N. pseudofischeri CGMCC 3.5378 [31]. Compound 139 was also reported from N. fischeri NRRL 181 [33] and N. tatenoi KKU-2NK23 [28].

Ergosterol analogs, viz. (22E, 24R)-ergosta-7, 22-dien-3β, 5α, 6β, 9α-tetraol (141), (22E, 24R)-ergosta-7,22-dien-3β, 5α, 6β-triol (142), 3β, 5α,9α-trihydroxy (22E, 24R)-ergosta-7,22-dien-6-one (143) and 3β, 5α-dihydroxy (22E, 24R)-ergosta-7,22-dien-6-one (144) (Figure 18) were isolated from N. fischeri NRRL 181 [33]. Compound 144 was also isolated from the marine-derived N. tsunodae KUFA 0811 [30].

Sterones have been also reported from members of the genus Neosartorya. Sitostenone (145), ergosta-4,6,8(14),22-tetraen-3-one (146), cyathisterone (147) and dankasterone A (148) (Figure 19) were reported from the marine-derived N. fenelliae KUFA 0811 [30], while (14α,22E)-14-hydroxy-ergosta-7,12-dien-3,6-dione (149) (Figure 19) was reported from N. fischeri NRRL 181 [33].

2.7. Polyketides

Secondary metabolites derived from polyketides, which have diverse structural features, are the most abundant group produced by the Neosartorya species. Two previously reported cyclopentenone derivatives, terrein (150) and isoterrein (151) (Figure 20), were isolated from a culture extract of N. fischeri IFM 52672 cultured in moist rice [24]. Fischeacid (152) (Figure 20), a bis-decalin polyketide, was isolated from a culture extract of the marine-derived N. fischeri 1008F1 [55]. Fischerin (153) (Figure 20), possessing a decalin scaffold linked to a hydroxypyridone moiety by a carbonyl group, was first reported from N. fischeri var. fischeri CBM-FA-0156 [34] and, later, from a culture extract of N. fischeri JS0553 [27]. Fujimoto et al. proposed its biogenesis as being derived from Phe and a heptaketide [34]. A great number of microbial secondary metabolites containing decalin motif, with structural diversity and relevant biological activity, has been reported. Li et al. have presented an excellent review on natural products containing the decalin motif in the form of microorganisms [56].

Acetophenones were also reported from some species of Neosarirya. First, 2,6-Dihydroxy-3-methylacetophenone (154) (Figure 20) was isolated from a culture extract of the soil-derived N. siamensis KUFC 6349 [42], as well as from the marine-derived N. siamensis KUFA0017 [43]. The undescribed 2S, 4S-spinosate (155) and 2S, 4R-spinosate (156) (Figure 20) were isolated from a culture extract of N. spinosa KKU-1NK1. The absolute configurations at C-2 and C-4 in both compounds were established by the comparison of calculated and experimental ECD spectra [44].

Another group of polyketides comprises the benzofuranone derivatives. The unreported neosarphenol A (157), and the previously reported methoxyvermistatin (158), vermistatin (159), and 6-demethylvermistatin (160) (Figure 20) were isolated from a culture extract of N. glabra CGMCC32286. The absolute configuration at C-8 in 157 was determined via a comparison of the sign of its optical rotation with that of the known 158 [53]. The undescribed quadricinctone A (161) (Figure 20) was isolated from a solid rice culture extract of the marine sponge-associated fungus N. quadricincta KUFA0081. The absolute configurations at C-3 and C-10 were established as 3R, 10S by X-ray analysis using CuKα radiation [57]. A chromanol derivative (162) (Figure 20) was isolated from a culture extract of the marine sponge-associated fungus N. tsunodae KUFC 9213. The structure of the compound was elucidated via the analysis of HRMS and 1D and 2D NMR spectral data. The absolute configurations at C-1, C-8 and C-9 were determined as 1R, 8S, and 9R by X-ray analysis using CuKα radiation [30].

Isochromanones have been reported from both terrestrial and marine-derived Neosartorya species. (R)-6-Hydroxymellein (163) (Figure 21) was reported from a culture extract of the algicolous fungus N. takakii KUFC 7898 [29], as well as from a solid rice culture extract of the marine sponge-associated N. spinosa KUFA 1047 [58]. The undescribed quadricinctone C (164) (Figure 21) was isolated from a culture extract of the marine sponge-associated fungus N. quadricincta KUFA0081. The absolute configurations at C-3 and C-4 were established as 3S, 4R by X-ray analysis using CuKα radiation [57]. The unreported 6,8-dihydroxy-3-(1E,3E)-penta-1,3-dien-1-yl) isochroman-1-one (165) (Figure 21) was isolated from a culture extract of the starfish-derived N. pseudofischeri. Its structure was established by the interpretation of HRMS and 1D and 2D NMR data; however, their absolute configuration at C-3 was not determined [21]. The previously reported phialophoriol (166) (Figure 21) was isolated from a culture extract of N. glabra CGMCC32286 [53]. The unreported prenyl 4-hydroxybenzoic acid ester of a dihydrochromone, PF1223 (167) (Figure 21), was isolated from a culture extract of N. quadricincta strain PF1223, which was obtained from the Meiji Seika Kaisha collection and cultured in a solid medium containing raw rice and soybean meal. The structure of 167 was established by 1D and 2D NMR spectral analysis and HRMS data; however, the absolute configurations of the stereogenic carbons C-3 and C-4 were not determined [59].

The undescribed dihydrochromone dimer, paecilin E (168) (Figure 21), was isolated from the marine sponge-associated N. fenelliae KUFA 0811. The structure of 168 was established based on an extensive analysis of 1D and 2D NMR spectra and HRMS data. The absolute configurations of the stereogenic carbons, C-2, C-2′, C-10, C-10′, C-11, and C-11′ were determined as 2R, 2′R, 10S,10′S, 11R, 11′R by X-ray analysis using CuKα radiation [30].

The previously reported trichodermamide A (169) (Figure 21), whose structure consists of a coumarin nucleus linked to a tetrahydro 1,2-benzoxazine moiety through an amide linkage, was isolated from a culture extract of the starfish-derived N. pseudofischeri [21].

The previously reported anthraquinones, chrysophanol (170) and emodin (171) (Figure 22), were isolated from a culture extract of the marine-derived N. fischeri 1008F1 [55]. The previously reported acetylquestinol (172) was isolated as a 1:3 mixture with the undescribed acetylpenipurdin A (173), together with the previously reported penipurdin A (174) (Figure 22), from a culture extract of the marine sponge-associated N. spinosa KUFA1047 [58].

Polyhydroxylated xanthones and bis-xanthone derivatives were also reported from Neosartorya species, especially N. fischeri. The unreported fischexanthone (175) was isolated, together with the previously reported sydowinins A (176) and B (177), and AGI-B4 (178) (Figure 23) from a culture extract of N. fischeri 1008 F1 [55]. The undescribed bis-xanthone derivative, neosartorin (179) (Figure 23), was isolated from a liquid culture extract of N. fischeri, isolated from sediment from the River Vah in Slovakia. The structure of the compound was elucidated by extensive analysis of HRMS and 1D and 2D NMR data. The relative stereochemistry of 179 was determined on the basis of ¹H-¹H coupling constants of J_H-5/H-6ax (2.0 Hz) and J_H-5/H-6eq (4.0 Hz), J_{H-6′/H-7′ax} (10 Hz), as well as by observation of the nuclear Overhauser effects (NOEs) between H-2′ of the carboxymethyl group and OH-1 and OH-8, as well as between the methyl protons of COOMe on C-5′ and H-3 [60]. The previously reported secalonic acid A (180) (Figure 23) was isolated from a culture extract of the marine sponge-associated N. fenelliae KUFA 0811 [30].

Another group of polyketides is the biphenyl ethers and their derivatives. The previously described diorcinol (181) (Figure 24) was isolated from a culture extract of the soil-derived N. hiratsukae [39]. The previously reported tenellic acid (182), the undescribed neospinosic acid (183) and spinolactone (184), and the previously reported vermixocin A (185) (Figure 24) were isolated from a culture extract of the marine sponge-associated N. spinosa KUFA 1047 [58]. Since the absolute configuration at C-8 in 182 had not been established, de Sá et al. [58] determined the absolute configuration of C-8 in 182 as 8S by the comparison of its calculated and experimental ECD spectra. The structures of the unreported 183 and 184 were established by extensive analysis of their HRMS and 1D and 2D NMR data. The absolute configuration at C-8 in both compounds was determined as 8S by comparison of their calculated and experimental ECD spectra.

Two previously reported penicillide (186) and purpactin A (187) were isolated, together with the unreported neosarphenol B (188) (Figure 24), from a culture extract of N. glabra CGMCC32286 [53].

In their study, de Sá et al. [58] proposed the biosynthetic relationship of 182–185, as depicted in Figure 25. The biosynthesis of 182–185 starts with a cyclization of the octaketide (I) to form the intermediate II. Enolization, the reduction of a carbonyl group, and hydrolysis of acetyl CoA in II lead to the formation of the intermediate III. Decarboxylation, enolization, and prenylation by dimethylallyl pyrophosphate (DMAPP) give the intermediate IV, which, after enolization, gives rise to the prenylated anthraquinone V. Methylation of the phenolic hydroxyl group and oxidative cleavage of the ring of the anthraquinone intermediate V leads to the formation of VI. The nucleophillic addition of VI (=VII) by a hydroxyl group leads to VIII, which, after the addition of H₂O to the carbonyl group with cleavage of the bond between the benzene ring and the carbonyl group, followed by the enzymatic allylic oxidation of the prenyl group, leads to the formation of the biphenyl ether IX. Reduction of the double bond of the prenyl group in IX gives X. Acetylation of the hydroxyl group of the side chain (C-8) gives rise to 182, which, after oxidation of the carbonyl of the acetyl group, leads to the formation of 183.

The formyl group in X can be reduced to a primary alcohol in XI (=XII). Esterification of the carboxyl group by a primary alcohol in XI leads to the formation of 185, while esterification by a phenolic hydroxyl group in XII leads to the formation of 184.

Polyketides also originate hydroxybenzoic acid esters and lactones. 2,4-Dihydroxy-6-methylbenzoic acid ester (189) (Figure 26) was isolated from culture extracts of the soil-derived N. pseudofischeri KUFC 6422 [35], N. pseudofischeri [38], and N. hiratsukae [39]. A previously reported biphenyl lactone (190) and its unreported methylsulfonyl analog, neosartoryone A (191), and 3-methoxy-6-methyl-5-(methylsulfonyl)benzene-1,2,4-triol (192) (Figure 26) were isolated from a liquid culture extract of N. udagawae HDN13-313 with the addition of 5-azacytidine in the culture medium. It was proved that the methylsulfonyl substituent in 191 and 192 originated from dimethyl sulphoxide (DMSO), which was used as a solvent to dissolve 5-azacytidine [61].

Glabramycins A (193), B (194), and C (195) (Figure 26) are macrocyclic lactones, isolated from a solid culture extract of N. glabra (strain MF7030, F-155,700) obtained from a hot-water-pasteurized soil that was collected in Valdefresno Province in Spain. The structures of the compounds were elucidated by 1D and 2D NMR and HRMS data. However, the absolute configuration at C-20 was not determined [62].

2.8. Benzoic Acid Derivatives

Although secondary metabolites originating from benzoic acid are not ubiquitous in fungi such as indole alkaloids, meroterpenoids, and polyketides, some of them have been reported sporadically. The previously reported 3,4-dihydroxybenzoic acid (196) (Figure 27) was isolated from a culture extract of the marine-derived N. fischeri 1008F1 [55].

The unreported benzoic acid derivatives, quadricinctapyan A (197), quadricinctapyan B (198) and quadricinctoxepine (199), the previously reported 2,3-dihydro-6-hydroxy-2,2-dimethyl-4H-1-benzopyran-4-one (200), and the undescribed quadricinctone B (201), quadricinctone D (202), quadricinctafuran A (203), and quadricintafuran B (204) (Figure 27) were isolated from a solid rice culture extract of the marine sponge-associated N. quadricincta KUFA 0081 [57]. The structures of the compounds were established by extensive analysis of 1D and 2D NMR spectra and HRMS data. The absolute configurations of the stereogenic carbons, i.e., C-2 in 197, 202, and 203 were established as 2S, 2S, and 2R, respectively, by X-ray analysis using CuKα radiation. Moreover, the Ortep view also revealed the configuration of the sulfoxide group in 201 as R. However, the configuration of C-3 in 199 and C-1′ in 204 were still undetermined. It is worth mentioning that marine natural products with methyl sulfoxide substituents, such as in 201, are not very common.

The biosynthetic pathways for 197–204 were proposed to be of mixed origin, i.e., shikimic acid and mevalonic acid pathways, similar to that proposed for fomannoxin [63]. The biosynthetic pathways start with the formation of p-hydroxybenzoic acid by elimination of a pyruvate moiety from chorismate by chorismate pyruvate lyase. The prenylation of p-hydroxybenzoic acid by DMAPP leads to the formation of I, which, after epoxidation of the double bond of the prenyl group, forms II. Nucleophilic substitution of the epoxide by a phenolic hydroxyl group gives rise to 203 (route a) or III (route b). Hydroxylation of one of the methyl groups of the prenyl side chain in 203 leads to the formation of 204. Another pathway is the dehydration of III, resulting in the formation of V which, upon hydroxylation of one of the methyl groups, leads to the formation of 197. On the other hand, III can undergo dehydration, followed by regiospecific hydration and oxidation to give IV, which can be either hydroxylated at one of the methyl groups to give 202 or undergoes decarboxylation and aromatic hydroxylation to give 200. The introduction of a methyl sulphonyl group to the benzene ring results in the formation of 201 (Figure 28) [57].

Compound 199 is also derived from p-hydroxybenzoic acid but uses isopentenyl pyrophosphate (IPP) as a prenylating agent to form VI. The epoxidation of the terminal double bond of the isopentenyl group gives VII, which, upon the nucleophilic substitution of the epoxide by a phenolic hydroxyl group, leads to the formation of a hydroxyoxepine ring in VIII. Further desaturation of the hydroxyoxepine ring gives rise to 199 (Figure 29) [57].

2.9. Nucleosides

Only two nucleosides, adenosine (205) and 5′-deoxy-5′-methylaminoadenosine (206) (Figure 30), were reported from the marine-derived N. fischeri 1008 F1 [55].

2.10. Miscellaneous

Nanodrides are fungal metabolites containing a nine-membered ring fused to one or two maleic anhydride moieties. Although several nanodrides have been reported from the cultures of many fungal species, only byssochlamic acid (207) (Figure 30) was isolated from cultures of the marine sponge-associated N. fenelliae KUFA 0811 and N. tsunodae KUFC 9213 [30].

Dehydromevalonic acid (208) and lumichrome (209) (Figure 30) were also isolated from the marine sponge-associated N. tsunodae KUFC 9213 [30]. Lumichrome is a derivative of the vitamin riboflavin and was found to activate the LasR quorum-sensing (QS) receptor. LasR normally recognizes the N-acyl homoserine lactone (AHL) signal. Amino acid substitutions in the LasR residues required for AHL binding altered the responses to both AHLs and lumichrome/riboflavin. Bacteria, plants, and algae commonly secrete riboflavin and/or lumichrome, raising the possibility that these compounds could serve as either QS signals or as interkingdom-signal mimics capable of manipulating QS in bacteria with a LasRlike receptor [64]. It is of note that, although lumichrome is commonly found in bacteria, plants, and algae, it is rarely reported from fungi.

In addition, 4(3H)-quinazolinone (210) (Figure 30) was isolated from the marine sponge-associated N. paulistensis KUFC 7897 [46]. It is interesting to note that although many quinazolinone-containing indole alkaloids have been isolated from many Neosartorya species, this is the first isolation of a simple 4(3H)-quinazolinone from the fungus of the genus Neosartorya.

A 4(3H)-quinazolinone-containing non-indole alkaloid, 5,6-dimethoxycircumdatin C (211) (Figure 30), was isolated from the insect-derived N. fischeri TJ403-CA8. The structure of the compound was established by the analysis of HRMS and 1D and 2D NMR data. The absolute configuration at C-19 was determined as 19S by X-ray analysis using CuKα radiation [20].

Finally, 1-Methyl-4-quinolone (212) (Figure 30) was isolated from a culture extract of N. hiratsukae [39], whereas mannitol (213) (Figure 30) was reported from N. tatenoi KKU-2NK23 [28].

3. Biological Activity of Secondary Metabolites Produced by Fungi of the Genus Neosartorya

Some compounds isolated from members of the genus Neosartorya were tested for several biological/pharmacological activities, mostly in vitro. Like all other natural products, a majority of the compounds isolated from Neosartorya species were tested for in vitro anticancer/cytotoxic and antimicrobial activities. For practical aspect, they can be divided as follows:

3.1. Anticancer Activity/Cytotoxicity

Eamvijarn et al. have evaluated aszonalenin (8), acetylaszonalenin (9), 1-formyl-5-hydroxyaszonalenin (11) (Figure 2), 13-oxofumitremorgin B (25) (Figure 3), aszonapyrone A (118) and sartorypyrone A (125) (Figure 16) isolated from the soil-derived N. fischeri KUFC 6344, aszonapyrone B (119) (Figure 16) isolated from the marine-derived N. laciniosa KUFC 7896, and sartorypyrone B (135) (Figure 17) isolated from the marine-derived N. tsunodae KUFC 9213, for their capacity to inhibit the in vitro growth of MCF-7 (breast adenocarcinoma), NCI-H460 (non-small cell lung cancer), and A375-C5 (melanoma) cell lines, by the protein binding dye sulforhodamine B (SRB) method. Compound 119 was the most active, exhibiting strong growth inhibitory activity against the three cell lines, with GI₅₀ values of 13.6, 11.6, and 10.2 µM for MCF-7, NCI-H460, and A375-C5, respectively, while 118 was inactive at the highest concentration tested (150 µM). Compound 135 also exhibited strong growth inhibitory activity, although less actively than 118, with GI₅₀ values of 17.8, 20.5, and 25.0 µM for MCF-7, NCI-H460, and A375-C5, respectively. Interestingly, 125, which possesses a monocyclic diterpene core, was more selective, exhibiting similar inhibitory activity to 135 against A375-C5 (GI₅₀ = 1.5 µM), but less active against MCF-7 (GI₅₀ = 46.3 µM) and NCI-H460 (GI₅₀ = 37.3 µM) cell lines. On the other hand, all the three aszonalenin derivatives, 8, 9, and 11, were found to be inactive against all the three cell lines at the highest concentration tested (150 µM), whereas 25 exhibited only weak inhibitory activity against all the three cell lines, with GI₅₀ values of 115.0, 123.3, and 68.6 µM, for MCF-7, NCI-H460, and A375-C5, respectively [25].

A hydroxylated xanthone, AGI-B4 (178) (Figure 23), isolated from a culture extract of N. fischeri 1008 F1, exhibited inhibition of the proliferation of a human gastric cancer cell line SGC-7901, with an IC₅₀ value of 0.29 mmol/L, and hepatic cancer cell line BEL-7404, with an IC₅₀ value of 0.31 mmol/L, by the MTT (3-(4,5-dimethylthiazol-2-yl)-2,5-diphenyltetrazolium bromide) assay. The positive control, 5-fluorouracil, showed 85.6% and 83% cell proliferation inhibition against SGC-7901 and BEL 7404, respectively [55].

Fiscalin B (3) (Figure 1) and two anellated indoles 78 and 79, isolated from a culture extract of the marine-derived N. fischeri, exhibited cytotoxicity by apoptosis against HL-60 (human leukemia) cells with IC₅₀ values of 82.3, 90.0, and 8.88 µM, respectively [19].

Eamvijarn et al. evaluated the in vitro growth inhibitory activity of the cadinene sesquiterpene (98) (Figure 12) and eurochevalierine (113) (Figure 14), isolated from a culture extract of the soil-derived N. pseudofischeri against Hs683 (human glioblastoma), U373 (human glioblastoma), A549 (non-small cell lung cancer), MCF-7 (breast cancer), OE21 (esophageal cancer) and SKMEL28 (melanoma) cell lines. Compound 113 displayed in vitro anticancer activity in the range displayed by etoposide and carboplatin, whereas 98 exhibited less activity than 113 but was similar to that of carboplatin. Computer-assisted phase-contrast microscopy demonstrated that 113 displayed cytostatic and not cytotoxic effects in human U373 and A549 cells. Moreover, flow cytometry analysis confirmed the lack of cytotoxicity of 113, since no pro-apoptotic effects were observed with 113 in U373 and A549 cells. Flow cytometry analysis also showed that 113 did not modify cell cycle kinetics, such as the distribution of cells into the G1, S, and G2 phases of the cell cycle of A549 and U373 cells [35].

Masi et al. evaluated the in vitro growth inhibitory effect of fischerindoline (116) (Figure 14), isolated from a culture extract of N. pseudofischeri strain CBS 404.67, in six human and one mouse cancer cell lines, viz. A549, Hs683, MCF-7, SKMEL28, U373, B16F10 (melanoma). However, 116 was found to exhibit a similar activity to that of 113 and pyripyropene E (107) (Figure 13). Curiously, 113, 116, and 107 displayed less potent activity than gliotoxin (49) (Figure 6) in the tested cell lines [41].

Liang et al. screened the cytotoxic effects of 1,2,3,4-tetrahydro-2-methyl-3-methylene-1,4-dioxopyrazino [1,2-a]indole (46), 1,2,3,4-tetrahydro-2-methyl-1,3,4-trioxopyrazino [1,2-a]indole (47), gliotoxin (49), acetylgliotoxin (50), bis (dethio)bis(methylthio)gliotoxin (51), reduced gliotoxin (52), 6-acetyl bis(methylthio)gliotoxin (53), didehydrobisdethiobis (methylthio)gliotoxin (54) and bis-N-norgliovictin (55) (Figure 6), isolated from a culture extract of the marine-derived N. pseudofischeri (collection no. 2014F27-1), on HEK-29 (human embryonic kidney), HCT-116 (human colon cancer) and RKO (a poorly differentiated colon carcinoma) cell lines. However, only 46 and 49–52 exhibited potent cytotoxicity with IC₅₀ values ranging from 0.41 to 33.56 µM, against the three cancer cell lines. The positive control, 5-fluorouracil, showed IC₅₀ values of 2.04 and 45.86 µM against HCT-116 and RKO, respectively [22].

CJ 12663 (115) (Figure 14) and 116 (Figure 14), isolated from a culture extract of the soil-derived N. pseudofischeri, were assayed against KB (epidermal carcinoma of the mouth with HeLa cell contamination, ATCC CCL-17), and MCF-7 cancer cell lines. Compound 115 displayed weak cytotoxicity against KB and MCF-7 with IC₅₀ values of 36.11 and 28.31 µg/mL, respectively, while 116 showed weak cytotoxicity against KB cells with an IC₅₀ value of 35.23 µg/mL. Both 115 and 116 also exhibited weak cytotoxicity against Vero cells with IC₅₀ values of 30.89 and 21.24 µg/mL [38].

Sartoryglabrins A (38), B (39), and C (40) (Figure 5), isolated from a culture extract of the soil-derived N. glabra, were evaluated for their capacity to inhibit the in vitro growth of MCF-7, NCI-H460 and A375-C5 cell lines using the protein binding dye SRB method. Compound 38 displayed a strong growth inhibitory activity against the MCF-7 cell line (GI₅₀ = 27.0 μM) but weak inhibitory activity against the NCI-H460 cell line (G_I50 = 84.0 μM) and inactivity against the A375-C5 cell line at the highest concentration tested (150 μM), while 39 showed moderate growth inhibitory activity against MCF-7cells, with a GI₅₀ = 53.0 μM, and did not show any relevant activity (GI₅₀ > 150 μM) against both NCI-H460 and A375-C5 cell lines. On the other hand, 40 exhibited moderate growth inhibitory activity, with a GI₅₀ = 44.0 μM, against the MCF-7 cell line but showed weak activity against both the NCI-H460 and A375-C5 cell lines (GI₅₀ = 82.3 μM and 108.0 μM, respectively). The positive control, doxorubicin, showed GI₅₀ values of 42.8 nM for MCF-7; 94.0 nM for NCI-H460, and 79.5 nM for A375-C5. These results suggest that 39 is not cytotoxic since it showed selectivity toward the MCF-7 cell line [40].

Neosarphenol A (157) (Figure 20) and penicillide (186) (Figure 20), isolated from a culture extract of N. glabra CGMCC32286, exhibited selective and moderate cytotoxicity against the PANC-1 (human pancreatic cancer) cell line with IC₅₀ values of 14.38 and 10.93 µM, respectively. The positive control, paclitaxel, showed an IC₅₀ = 0.45 µM [53].

Tryptoquivaline (56), tryptoquivalines F (58), H (59), L (60), O (61), 3′-(4-oxoquinazolin-3-yl)spiro [1H]-indole-3,5′]-2,2′-dione (67), sartorymensin (68) and epi-fiscalin A (70), isolated from a culture extract of the soil-derived N. siamensis KUFC 6349, were evaluated for their in vitro growth inhibitory activity against Hs683, U373, A549, MCF-7, and SKMEL-28 by MTT assay. However, only 68 exhibited moderate growth inhibitory activity on the five human cancer cell lines with IC₅₀ values of 50, 44, 39, 43, 73 µM, respectively. Of the positive controls, etoposide showed IC₅₀ values of 4.0 µM (Hs683), 0.4 µM (U373), 4.2 µM (A549), 1.8 µM (SKMEL-28), while carboplatin showed IC₅₀ values of 46 µM (Hs683), 58 µM (U373), 54 µM (A549), 69 µM (SKMEL-28) [42].

Nortryptoquivaline (57), tryptoquivaline F (58), tryptoquivaline H (59) (Figure 7), fiscalin A (69), epi-fiscalin A (70), epi-neofiscalin A (72), epi-fiscalin C (74) (Figure 8), chevalone C (128) (Figure 17) and 2,4-dihydroxy-3-methylacetophenone (154) (Figure 20), isolated from the sea-fan-derived N. siamensis KUFA 0017, were tested for anti-proliferative activity by MTT assay, DNA damage induction by comet assay, and the induction of cell death by nuclear condensation assay on HCT116 (colon), HepG2 (liver) and A375 (melanoma) cancer cell lines. Compounds 57, 69, 70, 72, 74, and 128 displayed IC₅₀ values in the range of 124 to 153 µM in the selected cell lines, 74 being the most active compound with IC₅₀ values of 86, 24, and 75 µM for HCT116, HepG2 and A375, respectively. Doxorubicin, the positive control, showed IC₅₀ values of 0.13 µM for HCT116, 0.11 µM for HepG2, and 0.08 µM for A375. Compounds 57, 69, and 128 also induced cell death in HCT116, while 57, 69, 70, and 72 significantly induced cell death in HepG2. It was found that the induction of cell death is probably not related to genotoxicity since none of the compounds induced significant DNA damage [43].

Compounds isolated from a culture extract of the soil-derived N. spinosa KKU-1NK1 were also screened for cytotoxicity against KB, MCF-7, and NCI-H187 (human small lung cancer) cell lines. Tryptoquivaline L (60) (Figure 7), 1-hydroxychevalone C (129), and 1-acetoxychevalone C (130) (Figure 17) displayed cytotoxicity against the KB cell line with IC₅₀ values of 103.3, 100.7, and 92.0 µM, respectively. Compounds 60, 129, 130, and 1,11-dihydroxychevalone C (132) (Figure 17) displayed cytotoxicity against NCI-H187 with IC₅₀ values of 42.0, 40.0, 37.2, and 39.9 µM, respectively, while tryptoquivaline (56) (Figure 7), 60, 129, 130, and 132 showed cytotoxicity toward Vero cells with IC₅₀ values of 66.5, 40.7, 39.1, 28.9, and 78.2 µM, respectively. All the tested compounds were inactive against MCF-7 cells. Doxorubicin, the positive control, showed IC₅₀ values of 2.06 µM for KB, 0.16 µM for NCI-H187, and 1.39 µM for the Vero cell [44].

Brasiliamide H (92) (Figure 10), 7-chlorofischerindoline (117) (Figure 14), and aszonapyrone G (124) (Figure 16), isolated from a culture extract of the soil-derived N. hiratsukae, were assayed for their cytotoxicity against HeLa (human cervical carcinoma), KB, MCF-7, HepG2, HT-29 (colorectal adenocarcinoma) and Vero cell lines. Compound 117 exhibited weak cytotoxicity against all the tested cell lines with IC₅₀ values ranging from 45 to 63 µM, while 92 and 124 were inactive. The positive control, adriamycin, showed IC₅₀ values of 0.02, 2.44, 1.11, 0.37, 0.35 and 44.79 µM for HeLa, KB, MCF-7, HepG2, HT-29, and Vero cell lines, respectively [39]. Additionally, aszonapyrone A (118) (Figure 16), isolated from a culture extract of the soil-derived N. tatenoi KKU-2NK23, also exhibited cytotoxicity against NCI-H187 and KB cell lines with IC₅₀ values of 4.62 and 48.18 µg/mL, respectively. Doxorubicin, the positive control, showed IC₅₀ = 0.01 µg/mL against NCI-H187, and 0.33 µg/mL against KB cells [28].

3.2. Antibacterial and Antibiofilm Activities

Liang et al. evaluated the antibacterial activity of neosartin B (44), 1,2,3,4-tetrahydro-2-methyl-1,3,4-trioxopyrazino [1,2-a]indole (45), 1,2,3,4-tetrahydro-2,3-dimethyl-1,4-dioxopyrazino [1,2-a]indole (46), 1,2,3,4-tetrahydro-2-methyl-1,3,4-trioxopyrazino (1,2-a]indole (47), gliotoxin (49), acetylgliotoxin (50), bis(dethio)bis(methylthio)gliotoxin (51), reduced gliotoxin (52), 6-acetyl bis(methylthio)gliotoxin (53), didehydrobisdethiobis(methylthio)gliotoxin (54), and bis-N-norgliovictin (55) (Figure 6), isolated from a culture extract of the sea star-derived N. pseudofischeri, against three multidrug-resistant bacteria, i.e., the Gram-positive Staphylococcus aureus (ATCC 29213), the methicillin-resistant S. aureus (R3708), and the Gram-negative Escherichia coli (ATCC 25922), using a broth dilution method. However, only 49 and 52 exhibited significant inhibitory activity against these three bacteria with IC₅₀ values of 12.20, 1.53, 24.53 µM, and 48.78, 1.52, 97.56 µM, respectively, against S. aureus (ATCC 29213), MRSA S. aureus (R3708), and E. coli (ATCC 25922). The results suggested that a disulfide bridge or reduced disulfide bond is essential for inhibitory activity, since compounds containing alkyl sulfide, such as 51, 53, 54, and 55, are void of antibacterial activity [22].

Cottoquinazolines E (84), F (85), and G (86) (Figure 9), isolated from a culture extract of N. fischeri TJ 403-CA8, were evaluated for their antibacterial activity against Gram-negative extended-spectrum β-lactamase (ESBL)-producing E. coli, Acinetobacter baumannii, Pseudomonas aeruginosa, Klebsiella pneumoniae, Gram-positive methicillin-resistant S. aureus, and Enterococcus faecalis. However, only 85 showed significant antibacterial activity against ESBL-producing E. coli, A. baumannii, P. aeruginosa, and E. faecalis, with minimum inhibitory concentration (MIC) values of 8, 32, 32, and 16 μg/mL, respectively, while 84 and 85 were inactive against all the test bacteria (MIC ≥ 100 μg/mL) [50].

Eurochevalierine (113), CJ-12662 (114), CJ-12663 (115) (Figure 14) and chevalone C (128) (Figure 17), isolated from a culture extract of the soil-derived N. pseudofischeri, exhibited antibacterial activity against Bacillus cereus, with MIC values of 64, 64, 16, and 8 µg/mL, and S. aureus, with MIC values of 64, 64, 128, and 16 µg/mL, respectively [38].

Aszonapyrones A (118) and B (119), sartorypyrones A (125) and B (126) (Figure 16), isolated from a culture extract of a soil-derived N. fischeri FO-4897, were tested for their antibacterial activity against Gram-positive and Gram-negative bacteria. Compounds 118, 125, and 126 displayed antibacterial activity against all tested Gram-positive bacteria viz. B. subtilis, Kocuria rhizophila, and Mycobacterium smegmatis, while 119 displayed antibacterial activity against only M. smegmatis. None of the tested compounds were active against Gram-negative bacteria, E. coli, and Xanthomonas oryzae [54].

Tryptoquivalines F (58), H (59), L (60), 3′-(4-oxoquinazolin-3-yl)spiro [1H]-indole-3,5′]-2,2′-dione (67) (Figure 8), and sartorypyrone C (120) (Figure 16) from a culture extract of the marine-sponge-associated N. paulistensis KUFC 7897, tryptoquivaline T (62) (Figure 8), aszonapyrones A (118) and B (119) (Figure 16) from a diseased coral-derived N. laciniosa KUFC 7896, chevalone B (122) (Figure 16) and chevalone C (128) (Figure 17) from the soil-derived N. siamensis KUFC 6349, sartorypyrone A (125) (Figure 16) from a soil-derived N. fischeri KUFC 6344, and sartorypyrone B (135) (Figure 17) from the marine sponge-associated N. tsunodae KUFC 9213, were evaluated for their antibacterial activity against Gram-positive S. aureus ATCC 25923 and B. subtilis ATCC 6633, and against Gram-negative E. coli ATCC 25922 and Pseudomonas aeruginosa ATCC 27853, as well as multidrug-resistant isolates from the environment. The potential synergism between these compounds and antibiotics was also evaluated against multidrug-resistant bacteria, methicillin-resistant S. aureus (MRSA) and vancomycin-resistant Enterococci (VRE). Among the meroditerpenes tested, only aszonapyrone A (118) and sartorypyrone A (125) displayed significant MIC values against Gram-positive bacteria. Compound 118 showed MIC values of 8 μg/mL against S. aureus ATCC 25923 and B. subtilis ATCC 6633, while 125 showed MIC values of 32 and 64 μg/mL, respectively, against the same reference strains. Interestingly, while 118 was active against both S. aureus MRSA (S. aureus B1 and B2) and Enterococcus spp. VRE isolates (E. faecalis W1 and W5), 125 did not show any inhibition of the growth of Enterococcus spp. VRE isolates in the range of concentrations tested. Very interestingly, the checkerboard method, as represented by the fractional inhibitory concentration (FIC) index, showed that a combination effect of 118 with the antibiotics oxacillin and ampicillin against MRSA and VRE isolates, respectively, was indifferent (ΣFIC > 0.5); however, 118 was able to decrease the MIC of each antibiotic tested and, thus, it may be considered as a partial synergistic effect. The association of 118 with vancomycin showed a clear synergistic effect (ΣFIC < 0.5) against the two VRE isolates (E. faecalis W1 and W5) tested. The combination of 125 with oxacillin and ampicillin against MRSA isolates was also found to be indifferent. Since the MIC of 125 against VRE was higher than 256 μg/mL, no checkerboard method was performed for this compound against the VRE isolates [46].

The effect of 118 and 125 at different concentrations, ranging from 2× to 1/4×MIC, on the biofilm formation by S. aureus ATCC 25923, B. subtilis ATCC 6633, and S. aureus B1, as well as E. faecalis W1 (in the case of 118), was evaluated. All the strains tested showed no biofilm formation in the presence of 2×MIC and MIC of 118 and 125. However, S. aureus ATCC 25923 and S. aureus B1 produced more biofilm in the presence of a sub-inhibitory concentration (1/2×MIC) of 118. Furthermore, S. aureus ATCC 25923 produced a significantly higher amount of biofilm in the presence of 1/2×MIC of 118, when compared to the control. Microscopic visualization of the biofilm produced by S. aureus ATCC 25923, using live/dead staining, revealed that the majority of the cells within the biofilm were viable and that large aggregates embedded in a matrix could be observed after 24 h. Interestingly, no biofilm was formed; also, no growth was observed in the presence of 118 at a concentration equal to its MIC. However, at a concentration of 1/2×MIC, it was possible to observe more biofilm in comparison to the control [46].

Examination of the structures of the meroditerpenes tested suggests the existence of some common features necessary for the antibacterial activity of this class of compounds. Although aszonapyrone A (118), aszonapyrone B (119), sartorypyrone C (120), chevalone B (122), and sartorypyrone A (125) all contain a 4-hydroxy-6-methyl-2H-pyran-2-one ring, only aszonapyrone A (118), chevalone B (122), and sartorypyrone A (125) have the β-acetoxyl group at C-3. In contrast to 118, 119, and 120, where the 4-hydroxy-6-methyl-2H-pyran-2-one ring is linked to the methylene group (CH₂-15), this ring is connected to the perhydrophenanthrene portion by an ether bridge, forming a more rigid pentacyclic structure in chevalone B (122). Then again, both chevalone C (128) and sartorypyrone B (135) contain a 6-methyl-4H-pyran-4-one ring, also connected to the perhydrophenanthrene portion by an ether bridge. Therefore, it is apparent that the presence of a free 4-hydroxy-6-methyl-2H-pyran-2-one ring on C-15 and the β-acetoxyl group on C-3 of the perhydrophenanthrene portion are required for the antibacterial activity of this series of meroditerpenes [46].

Harmane (42) (Figure 6), hopan-3β,22-diol (96) (Figure 12), 3β, 5α-dihydroxy (22E, 24R)-ergosta-7,22-dien-6-one (144) (Figure 18), chromanol derivative (159) (Figure 20), lumichrome (209) (Figure 30), isolated from the marine sponge-derived N. tsunodae KUFC 9213, together with dankasterone A (148) (Figure 19) and paecilin E (168) (Figure 21), which were isolated from the marine sponge-derived N. fenelliae KUFA0811, were tested for their antibacterial activity against Gram-positive and Gram-negative bacteria, including four reference strains, a clinical isolate sensitive to the most commonly used antibiotic families, and four multidrug-resistant isolates from the environment. Compound 168 exhibited an inhibitory effect on both S. aureus ATCC 29213 and E. faecalis ATCC 29212, with MIC values of 32 µg/mL and 16 µg/mL, respectively. However, when tested in a vancomycin-resistant (VRE) strain that was sensitive to ampicillin (E. faecalis A5/102), the MIC obtained was higher than that of the reference strain (64 µg/mL as opposed to 16 µg/mL). In the range of concentrations tested, 168 was ineffective against a VRE strain that was also resistant to ampicillin (E. faecalis B3/101). In the case of S. aureus strains isolated from the environment, 168 did not inhibit the growth of the bacterial strain that is sensitive to the most commonly used antibiotic families (S. aureus 40/61/24) as well as of MRSA S. aureus 66/1. However, 148 was only effective against E. faecalis ATCC 29212 and VRE E. faecalis A5/102, with MIC values of 32 µg/mL and 64 µg/mL, respectively. Compounds 148 and 168 did not exhibit any inhibitory effect on biofilm production in the four reference strains at the concentrations tested [30].

Penipurdin A (174) (Figure 22), tenellic acid (182), neospinosic acid (183), spinolactone (184), and vermixocin A (185) (Figure 24), isolated from the marine sponge-associated N. spinosa KUFA 1047, were evaluated for their antibacterial activity against reference strains (S. aureus ATCC 29213 and E. faecalis ATCC 29212) and multidrug-resistant isolates (S. aureus 66/1 MRSA and E. faecalis B3/101 VRE). However, only 184 exhibited antibacterial activity against E. faecalis B3/101, with a MIC value of 64 µg/mL (the positive control ceftazidime showed MIC = 8 µg/mL against S. aureus ATCC 29213, while kanamycin showed MIC = 32 µg/mL against E. faecalis ATCC 29212). Since its minimum bactericidal concentration (MBC) was more than one-fold higher than the MIC, a bacteriostatic effect was suggested for this compound. Despite not having antibacterial activity, 182 and 183 significantly inhibited biofilm formation in three of the four reference strains used in this study, viz. E. coli ATCC 25922 (both 182 and 183), S. aureus ATCC 29213 (both 182 and 183), and E. faecalis ATCC 29212 (only 182). A more extensive effect was found for 183, which displayed the strongest inhibitory activity on S. aureus ATCC 29213 [58].

Investigation of the influence of 183 in both the biofilm and its matrix spatial arrangement revealed a 98% reduction in the viability of the biofilm of S. aureus ATCC 29213 after 8 h of incubation with 183. On the contrary, there was only a 10% viability reduction after 24h of incubation. An investigation of 183 on biofilm extracellular polymeric substances revealed that after 8 h of incubation, 183 increased the number of channels homogeneously distributed by the biofilm. However, after 24 h of incubation, this biofilm did not maintain its structure and appeared to be quite similar to that of the control [58].

1-Hydroxychevalone C (129) (Figure 17), isolated from the soil-derived N. spinosa KKU-1NK1, exhibited antimycobacterial activity against Mycobacterium tuberculosis, with a MIC value of 26.4 µM [44].

Glabramycins A (193), B (194), and C (195) (Figure 26), isolated from a soil-derived N. glabra (strains MF7030, F-155,700), were tested in the S. aureus antisense rpsD sensitized two-plate differential sensitivity assay. Compound 195 exhibited the most potent activity in this assay and showed a minimum detection concentration (MDC) of 62 µg/mL. Compound 193 was approximately four-fold less active and showed intermediate activity, with an MDC of 250 µg/mL. Compound 195 showed better activity against the panel of bacteria used in the assay, and the best activity was against Streptococcus pneumoniae, with a MIC value of 2 µg/mL, regardless of the medium used, while it inhibited the growth of S. aureus and B. subtilis with MIC values of 16 µg/mL but was less active against E. faecalis (MIC > 32 µg/mL). Compounds 193 and 194 were significantly less active than 195 [62].

Finally, 3-Methoxyglyantrypine (2), glyantrypine (3) (Figure 1), acetylaszonalenin (9a), 6-hydroxyacetylaszonalenin (9b), fischeramides A (13) and B (14) (Figure 2), tryprostatin B (15), 12-hydroxyfumitremorgin C (18), 12-methoxyfumitremorgin C (19), cyclotrypostatin B (20) (Figure 3), 6-methoxyspirotryprostatin B (32), spirotryprostatin C (33), spiro [5H,10H-dipyrrolo [1,2-a]:1′,2′-d]pyrazine-2-[3H], 2′[2H]indole]-3,5,10(1′H]trione (34) and spirotryprostatin M (35) (Figure 4), 7-deacetylpyripyropene A (102), 11-deacetylpyripyropene A (103) (Figure 13), and 5,6-dimethoxycircumdatin C (211) (Figure 30), isolated from the insect-derived N. fischeri TJ403-CA8, were screened for antibacterial activity against six drug-resistant microbial pathogens, including ESBL-producing E. coli, A. baumannii, P. aeruginosa, NDM-1-producing K. pneumoniae, methicillin-resistant S. aureus (MRSA), and E. faecalis. However, only 15, 18, 20, 32, 33, 102, and 211 displayed significant antibacterial activity against certain microbial pathogens, 211 being the most active against ESBL-producing E. coli, with a MIC value of 2.0 μg/mL, which was comparable to that of the clinically used antibiotic amikacin. The transmission electron microscopy (TEM) revealed that after 24 h of treatment of ESBL-producing E. coli with 211 at a concentration of 2 μg/mL, the cytoplasmic membranes of ESBL-producing E. coli cells were almost completely destroyed [20].

3.3. Antiviral Activity

Fischeacid (152) (Figure 20), fischexanthone (175), chrysophanol (170), emodin (171) (Figure 22), sydowinins A (176) and B (177), AGI-B4 (178) (Figure 23), 3,4-dihydroxybenzoic acid (196) (Figure 30), adenosine (205), and 5′-deoxy-5′-methylaminoadenosine (206) (Figure 30), isolated from the marine-derived N. fischeri 1008F1, were tested for their effects on the replication of tobacco mosaic virus (TMV) using the leaf-disc method. The tested compounds displayed a TMV replication inhibition ranging from 36.5 to 75.9% (ribavirin, the positive control, showed 45.2% inhibition). Compounds 178 and 196 showed IC₅₀ values of 0.26 and 0.63 mmol/mL, respectively [55].

Neosartoryadins A (82) and B (83) (Figure 8), isolated from the mangrove-derived N. udagawae HDN13-313, were evaluated for their activity against influenza A virus (H1N1) by cytopathic effect (CPE) inhibition assay. Compounds 82 and 83 exhibited inhibitory effects with IC₅₀ values of 66 and 58 µM, respectively. The positive control, ribavirin, showed an IC₅₀ = 94 µM [48].

3.4. Antiplasmodial Activity

Aszonapyrone A (118) (Figure 16) from the soil-derived N. tatenoi KKU-2NK23 [28], tryptoquivaline (56) (Figure 7), and 1-acetoxychevalone C (130) (Figure 17), from the soil-derived N. spinosa KKU-1NK1 [44], exhibited antimalarial activity against Plasmodium falciparum (K1, multidrug-resistant strain) with IC₅₀ values of 1.34, 2.65, and 6.67 µM, respectively.

3.5. Anti-Inflammatory Activity

The isolated compounds from the insect-derived N. fischeri TJ403-CA8 were screened for their anti-inflammatory potential by observing their inhibition of nitric oxide (NO) production, induced by lipopolysaccharides (LPS) in RAW264.7 cells. However, only fischeramide A (13) significantly inhibited LPS-induced NO production, with an IC₅₀ = 25 µM. Dexamethasone was used as a positive control [20].

3.6. Immunosuppressive Activity

The isolated compounds from the insect-derived N. fischeri TJ403-CA8 were also evaluated for their in vitro immunosuppressive activity in murine splenocytes stimulated by LPS and anti-CD3/anti-CD28 mAbs. Only fischeramide A (13) showed potential immunosuppressive activity in LPS and anti-CD3/anti-CD28 mAbs-activated murine splenocytes proliferation with IC₅₀ values of 7.08 and 6.31 μM, respectively, while the rest of the test compounds showed no activity at concentrations up to 40 μM [20].

3.7. Neuroprotective Activity

Glutamate is a well-known excitable neurotransmitter that can cause neuronal cell death during acute brain insults in neurodegenerative diseases. Fischerin (153) (Figure 20), from a culture extract of N. fischeri JS0553 at a concentration lower than 20 µM, was able to significantly recover the viability of mouse hippocampal neuronal (HT22) cells decreased by glutamate. Compound 153 also decreased a glutamate-induced increase in intracellular reactive oxygen species (ROS) and Ca⁺ concentration. Moreover, 153 also significantly decreased the percentage of glutamate-induced apoptotic cells, suggesting that 153 efficiently prevented glutamate-induced apoptotic HT22 cell death. Additionally, it was found that the phosphorylation of mitogen-activated protein kinases (MAPKs), i.e., ERK, JNK, and p38, as increased by glutamate, was significantly diminished by 153, thus indicating that the inhibition of the sustained phosphorylation of MAPKs could be a key molecular mechanism of protection mediated by 153 against glutamate-induced HT22 cell death [27].

3.8. Lipid-Lowering Activity

Neosartoryone A (191) (Figure 26), isolated from a liquid culture extract of N. udagawae HDN13-313 by adding 5-azacytidine at 10 µM to the culture medium, was found to decrease lipid accumulation in HepG2 liver cells that was provoked by oleic acid. The effect of 191 is comparable to that of the current cholesterol-lowering drug, simvastatin, which was used as a positive control [61].

3.9. Enzyme Inhibitory Activities

The NADH-fumarate reductase (NFRD) system uses fumarate as a terminal electron acceptor in the mitochondrial electron transport chain and can generate ATP in the absence of oxygen. The system allows helminths to live in anaerobic circumstances inside host mammals. Since mammals do not have NFRD in their mitochondria, it is expected that a selective NFRD inhibitor could be a good anthelmintic drug candidate. Therefore, aszonapyrones A (118) and B (119), and sartorypyrones A (125) and D (126) (Figure 16), isolated from N. fischeri FO-5897, were tested for their inhibitory activity against mitochondrial respiratory enzymes using a submitochondrial particle of Acaris suum and bovine heart. Compounds 125 and 126 potently inhibited NFRD with IC₅₀ values of 0.6 and 1.7 µM, respectively. They also inhibited mammalian NADH oxidase with IC₅₀ values of 1.3 and 3.0 µM, respectively. Compounds 118 and 119 displayed moderate activity against NFRD with IC₅₀ values of 8.7 and 72.5 µM, respectively [54].

Vermixocin A (185) (Figure 24), isolated from a culture extract of the marine sponge-associated N. spinosa KUFA 1047, exhibited anti-tyrosinase activity with a percentage inhibition of 50% at 200 µM. Since the IC₅₀ value of 177 µM was obtained at lower doses (i.e., 150 and 100 µM), 185 has a moderate anti-tyrosinase activity (the positive control, galantamine, showed a percentage inhibition of 94.82% at 80 mM, and IC₅₀ = 16.76 mM) [58].

3.10. Insecticidal Activity

PF1223 (167) (Figure 21), isolated from the N. quadricincta strain PF1223, was tested for its capacity as a non-competitive GABA receptor antagonist, which is a target for insecticide. At 2.2 µM, 164 inhibited the specific binding of [³H]EBOB to the housefly head membrane by 65%. It is worth mentioning that DBCPP, a non-competitive GABA receptor antagonist, displayed an IC₅₀ value of 3.41 µM for the GABA housefly receptor in the [³H]EBOB assay [59].

Isochaetominine C (37) (Figure 5), 1,2,3,4-tetrahydro-6-hydroxy-2-methyl-1,3,4-trioxopyrazino [1,2-a]indole (48) (Figure 6), cadinene sesquiterpene (98), its deacetyl derivative (99), 5-formyl-6-hydroxy-8-isopropyl-2-naphthoic acid (100) (Figure 12), pyripyropene A (101), 7-deacetylpyripyropene A (102), 13-dehydroxypyripyropene A (106), phenylpyripyropenes A (108) and B (109), 5-olefin phenylpyripyropene A (110) (Figure 13), and 6,8-dihydroxy-3 ((1E,3E)-penta-1,3-dien-1-yl) isochroman-1-one (165) (Figure 21), isolated from the starfish-derived N. pseudofischeri, exhibited significant in vitro cytotoxicity against Sf9 cells from the insect Spodoptera frugiperda. Compounds 37, 48, 98–100, 108 and 109, at a concentration of 50 µg/L, displayed a cell growth inhibition of >90% after 48 h of treatment [21].

3.11. Miscellaneous

Substance P (SP) is a potent agonist and an endogenous ligand for the neurokinin-1 (NK-1) receptor subtype. It induces a variety of physiological responses, such as salivation, vasodilation, and smooth muscle contraction, and is thought to be involved in pain transmission and the inflammatory response. Therefore, selective antagonists of SP might have potential as analgesics or anti-inflammatory agents. In this context, fiscalins A (69) (Figure 8), B (1) (Figure 1), and C (74) (Figure 8), isolated from N. fischeri, were assayed for their inhibitory activity on SP. Compounds 69, 1, and 74 inhibited the binding of ¹²⁵I-Bolton-Hunter SP to human astrocytoma U-373MG intact cells, with Ki values of 57, 174, and 68 µM, respectively [44].

The discussion of the secondary metabolites isolated from Neosartorya species, and their biological activities, are summarized in Table 1 and Table 2 to facilitate readers to localize the compounds of interest and to compare them between different strains of the same species or between different species. Table 1 also includes the production culture media, to allow the readers to compare not only the sources of the fungi but also the influence of the medium on the secondary metabolite profiles of the strains and species.

4. Conclusions and Future Perspective

The present review discusses the chemical investigation of the fungi belonging to the genus Neosartorya. From the literature search, 14 species (and one with no indication of a species level) have been investigated for the production of secondary metabolites. Among the most investigated species are N. fischeri (12 strains), followed by N. pseudofischeri (5 strains) and N. glabra (4 strains). Concerning the sources of fungi, 11 strains were isolated from the soil, 14 strains were marine-derived, one strain was insect-derived, one strain was plant-endophytic, one strain was mangrove-endophytic, and five strains were acquired from different collections. The first report of the chemical study was of N. pseudofischeri var. pseudofischeri, which was published in 1993; however, there is no indication of the source of this fungus. It is important to point out that in the early years of the chemical investigation of fungi, the identification of the fungal material was based primarily on morphological characterization. Therefore, many fungi were not identified at species level or were distinguished as different strains. It was only recently that the fungal material could also be identified by molecular techniques using internal transcribed spacer (ITS) primers. This allows taxonomists to distinguish different strains within a species level. Analysis of the literature showed an impressive chemical diversity since 213 compounds were isolated from 15 species of this genus. Moreover, the isolated compounds belong to different chemical classes and many of them possess chiral centers. The influence of the environments from which the fungi were obtained is not very clear-cut since, for the same species, marine-derived species can produce completely different metabolites from their terrestrial counterparts, as in the cases of N. quadricincta, N. glabra and N. spinosa, while others, such as N. siamensis, produced the same compounds irrespective of whether they were terrestrial or marine-derived. Besides the source of the fungi, the production culture medium can also play an important role in secondary metabolites production, as can be seen by the incorporation of dimethyl sulfoxide in the secondary metabolites by N. udagawae HDN13-313.

Interestingly, Voser et al., in their recent review using fingerprint cluster analysis, based on the MarineLit database, which covers compounds isolated from the marine environment between 1956 and 2020, and the NPAtlas database, which contains compounds isolated from microorganisms and published between 1877 and 2020, have found that marine fungal natural products (NPs) are nested with terrestrial fungal NPs at a relatively high proportion (74.6%). This indicates that marine and terrestrial fungi are more likely to share common biosynthetic gene clusters, or that marine sources of fungi are likely to be terrestrial “wash-ins” [65]. The authors have also found that most studies used potato dextrose or rice in sea water or sea salt as culture media for most of the marine-derived fungi. This is also true in the case of the culture media used to culture Neosartorya species, as shown in Table 1. Therefore, the production of unique and different NPs by terrestrial and marine-derived fungi in the future must rely on new culture techniques and new technologies such as genome mining.

Publisher’s Note: MDPI stays neutral with regard to jurisdictional claims in published maps and institutional affiliations.

Enlarge this image.

Figure 1. Structures of simple indoles 1–7.

Enlarge this image.

Figure 2. Structures of prenylated indoles 8–14.

Enlarge this image.

Figure 3. Structures of prenylated indoles 15–25.

Enlarge this image.

Figure 4. Structures of prenylated indoles 26–35.

Enlarge this image.

Figure 5. Structures of prenylated indoles 36–40.

Enlarge this image.

Figure 6. Structures of anellated indoles 41–55.

Enlarge this image.

Figure 7. Structures of anellated indoles 56–68.

Enlarge this image.

Figure 8. Structures of anellated indoles 69–83.

Enlarge this image.

Figure 9. Structures of indoles 84–88.

Enlarge this image.

Figure 10. Structures of alkaloids 89–92.

Enlarge this image.

Figure 11. Structures of peptides 93–95.

Enlarge this image.

Figure 12. Structures of terpenoids 96–100.

Enlarge this image.

Figure 13. Structures of merosesquiterpenes 101–112.

Enlarge this image.

Figure 14. Structures of merosesquiterpenes 113–117.

Enlarge this image.

Figure 15. Formation of merosesquiterpenes 115 from 113.

Enlarge this image.

Figure 16. Structures of meroditerpenes 118–127.

Enlarge this image.

Figure 17. Structures of meroditerpenes 128–138.

Enlarge this image.

Figure 18. Structures of sterols 139–144.

Enlarge this image.

Figure 19. Structures of sterones 145–149.

Enlarge this image.

Figure 20. Structures of polyketides 150–162.

Enlarge this image.

Figure 21. Structures of 163–169.

Enlarge this image.

Figure 22. Structures of 170–174.

Enlarge this image.

Figure 23. Structures of 175–180.

Enlarge this image.

Figure 24. Structures of 181–188.

Enlarge this image.

Figure 25. Proposed biosynthetic pathways to 182–185.

Enlarge this image.

Figure 26. Structures of 189–195.

Enlarge this image.

Figure 27. Structures of 196–204.

Enlarge this image.

Figure 28. Proposed biosynthetic pathways for 197, 198, 200–204.

Enlarge this image.

Figure 29. Proposed biosynthetic pathway for 199.

Enlarge this image.

Figure 30. Structures of 205–213.

References

1. Gaynes, R. The discovery of penicillin—New insights after more than 75 years of clinical use. Emerg. Infect. Dis.; 2017; 23, pp. 849-853. [DOI: https://dx.doi.org/10.3201/eid2305.161556]

2. Bo, G. Giuseppe Brotzu and the discovery of cephalosporins. Clin. Microbiol. Infect.; 2000; 6, pp. 6-8. [DOI: https://dx.doi.org/10.1111/j.1469-0691.2000.tb02032.x] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/11449655]

3. Endo, A. A historical perspective on the discovery of statins. Proc. Jpn. Acad. Ser. B; 2010; 86, pp. 484-493. [DOI: https://dx.doi.org/10.2183/pjab.86.484] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/20467214]

4. Aly, A.H.; Debbab, A.; Proksch, P. Fifty years of drug discovery from fungi. Fungal Divers.; 2011; 50, pp. 3-19. [DOI: https://dx.doi.org/10.1007/s13225-011-0116-y]

5. Harms, H.; Schlosser, D.; Wick, L.Y. Untapped potential: Exploiting fungi in bioremediation of hazardous chemicals. Nat. Rev. Microbiol.; 2011; 9, pp. 177-192. [DOI: https://dx.doi.org/10.1038/nrmicro2519]

6. Akerman-Sanchez, G.; Rojas-Jimenez, K. Fungi for the bioremediation of pharmaceutical-derived pollutants: A bioengineering approach to water treatment. Environ. Adv.; 2021; 4, 100071. [DOI: https://dx.doi.org/10.1016/j.envadv.2021.100071]

7. Copetti, M. Fungi as industrial producers of food ingredients. Curr. Opin. Food Sci.; 2019; 25, pp. 52-56. [DOI: https://dx.doi.org/10.1016/j.cofs.2019.02.006]

8. Eakjamnong, W.; Keawsalong, N.; Dethoup, T. Novel ready-to-use dry powder formulation of Talaromyces tratensis KUFA0091 to control dirty panicle disease in rice. Biol. Control; 2020; 152, 104454. [DOI: https://dx.doi.org/10.1016/j.biocontrol.2020.104454]

9. Frisvad, J.C.; Rank, C.; Nielsen, K.F.; Larsen, T.O. Metabolomics of Aspergillus fumigatus. Med. Mycol.; 2009; 47, pp. S53-S71. [DOI: https://dx.doi.org/10.1080/13693780802307720]

10. Samson, R.; Hong, S.; Peterson, S.; Frisvad, J.; Varga, J. Polyphasic taxonomy of Aspergillus section Fumigati and its teleomorph Neosartorya. Stud. Mycol.; 2007; 59, pp. 147-203. [DOI: https://dx.doi.org/10.3114/sim.2007.59.14]

11. Hawksworth, D.L. A new dawn for the naming of fungi: Impacts of decisions made in Melbourne in July 2011 on the future publication and regulation of fungal names. IMA Fungus; 2011; 2, pp. 155-162. [DOI: https://dx.doi.org/10.5598/imafungus.2011.02.02.06] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/22679600]

12. McNeill, J.; Turland, N.J.; Monro, A.M.; Lepschi, B.J. XVIII International Botanical Congress: Preliminary mail vote and report of Congress action on nomenclature proposals. TAXON; 2011; 60, pp. 1507-1520. [DOI: https://dx.doi.org/10.1002/tax.605034]

13. Samson, R.A.; Visagie, C.M.; Houbraken, J.; Hong, S.-B.; Hubka, V.; Klaassen, C.H.W.; Perrone, G.; Seifert, K.A.; Susca, A.; Tanney, J.B. et al. Phylogeny, identification and nomenclature of the genus Aspergillus. Stud. Mycol.; 2014; 78, pp. 141-173. [DOI: https://dx.doi.org/10.1016/j.simyco.2014.07.004] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/25492982]

14. Zin, W.W.M.; Prompanya, C.; Buttachon, S.; Kijjoa, A. Bioactive secondary metabolites from a thai collection of soil and marine-derived fungi of the genera Neosartorya and Aspergillus. Curr. Drug Deliv.; 2016; 13, pp. 378-388. [DOI: https://dx.doi.org/10.2174/1567201813666160303104641]

15. Wibowo, J.T.; Ahmadi, P.; Rahmawati, S.I.; Bayu, A.; Putra, M.Y.; Kijjoa, A. Marine-derived indole alkaloids and their biological and pharmacological activities. Mar. Drugs; 2021; 20, 3. [DOI: https://dx.doi.org/10.3390/md20010003]

16. El-Demerdash, A.; Kumla, D.; Kijjoa, A. Chemical diversity and biological activities of meroterpenoids from marine derived-fungi: A comprehensive update. Mar. Drugs; 2020; 18, 317. [DOI: https://dx.doi.org/10.3390/md18060317]

17. Cox, R.J.; Skellam, E.; Williams, K. Biosynthesis of Fungal Polyketides. Physiology and Genetics (A Comprehensive Treatise on Fungi as Experimental Systems for Basic and Applied Research); Anke, T.; Schüffler, A. Springer: Cham, Switzerland, 2018; pp. 385-412. [DOI: https://dx.doi.org/10.1007/978-3-319-71740-1_13]

18. Wong, S.-M.; Musza, L.L.; Kydd, G.C.; Kullnig, R.; Gillum, A.M.; Cooper, R. Fiscalins. New substance p inhibitors produced by the fungus Neosartorya fischeri. Taxonomy, fermentation, structures, and biological properties. J. Antibiot.; 1993; 46, pp. 545-553. [DOI: https://dx.doi.org/10.7164/antibiotics.46.545]

19. Wu, B.; Chen, G.; Liu, Z.G.; Pei, Y. Two new alkaloids from a marine-derived fungus Neosartorya fischeri. Rec. Nat. Prod.; 2015; 9, pp. 271-275.

20. Lin, S.; He, Y.; Li, F.; Yang, B.; Liu, M.; Zhang, S.; Liu, J.; Li, H.; Qi, C.; Wang, J. et al. Structurally diverse and bioactive alkaloids from an insect-derived fungus Neosartorya fischeri. Phytochemistry; 2020; 175, 112374. [DOI: https://dx.doi.org/10.1016/j.phytochem.2020.112374]

21. Lan, W.-J.; Fu, S.-J.; Xu, M.-Y.; Liang, W.-L.; Lam, C.-K.; Zhong, G.-H.; Xu, J.; Yang, D.-P.; Li, H.-J. Five New Cytotoxic Metabolites from the Marine Fungus Neosartorya pseudofischeri. Mar. Drugs; 2016; 14, 18. [DOI: https://dx.doi.org/10.3390/md14010018]

22. Liang, W.-L.; Le, X.; Taglialatela-Scafati, O.; Yang, X.; Chen, J.-X.; Xu, J.; Liu, H.-L.; Wang, L.-Y.; Wang, K.-T.; Hu, K.-C. et al. Exploring the Chemodiversity and Biological Activities of the Secondary Metabolites from the Marine Fungus Neosartorya pseudofischeri. Mar. Drugs; 2014; 12, pp. 5657-5676. [DOI: https://dx.doi.org/10.3390/md12115657] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/25421322]

23. Zin, W.W.M.; Buttachon, S.; Dethoup, T.; Fernandes, C.; Cravo, S.; Pinto, M.M.M.; Gales, L.; Pereira, J.A.; Silva, A.M.S.; Sekeroglu, N. et al. New Cyclotetrapeptides and a New Diketopiperzine Derivative from the Marine Sponge-Associated Fungus Neosartorya glabra KUFA 0702. Mar. Drugs; 2016; 14, 136. [DOI: https://dx.doi.org/10.3390/md14070136] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/27447650]

24. Wakana, D.; Hosoe, T.; Itabashi, T.; Nozawa, K.; Kawai, K.-I.; Okada, K.; Takaki, G.M.D.C.; Yaguchi, T.; Fukushima, K. Isolation of Isoterrein from Neosartorya fischeri. Mycotoxins; 2006; 56, pp. 3-6. [DOI: https://dx.doi.org/10.2520/myco.56.3]

25. Eamvijarn, A.; Gomes, N.; Dethoup, T.; Buaruang, J.; Manoch, L.; Silva, A.; Pedro, M.; Marini, I.; Roussis, V.; Kijjoa, A. Bioactive meroditerpenes and indole alkaloids from the soil fungus Neosartorya fischeri (KUFC 6344), and the marine-derived fungi Neosartorya laciniosa (KUFC 7896) and Neosartorya tsunodae (KUFC 9213). Tetrahedron; 2013; 69, pp. 8583-8591. [DOI: https://dx.doi.org/10.1016/j.tet.2013.07.078]

26. Shan, W.; Wang, S.; Ying, Y.; Ma, L.; Zhan, Z. Indole-benzodiazepine-2,5-dione Derivatives from Neosartorya fischeri. J. Chem. Res.; 2014; 38, pp. 692-694. [DOI: https://dx.doi.org/10.3184/174751914X14140034695581]

27. Bang, S.; Song, J.H.; Lee, D.; Lee, C.; Kim, S.; Kang, K.S.; Lee, J.H.; Shim, S.H. Neuroprotective Secondary Metabolite Produced by an Endophytic Fungus, Neosartorya fischeri JS0553, Isolated from Glehnia littoralis. J. Agric. Food Chem.; 2019; 67, pp. 1831-1838. [DOI: https://dx.doi.org/10.1021/acs.jafc.8b05481]

28. Yim, T.; Kanokmedhakul, K.; Kanokmedhakul, S.; Sanmanoch, W.; Boonlue, S. A new meroterpenoid tatenoic acid from the fungus Neosartorya tatenoi KKU-2NK23. Nat. Prod. Res.; 2014; 28, pp. 1847-1852. [DOI: https://dx.doi.org/10.1080/14786419.2014.951353]

29. Zin, W.W.M.; Buttachon, S.; Buaruang, J.; Gales, L.; Pereira, J.A.; Pinto, M.M.M.; Silva, A.M.S.; Kijjoa, A. A New Meroditerpene and a New Tryptoquivaline Analog from the Algicolous Fungus Neosartorya takakii KUFC 7898. Mar. Drugs; 2015; 13, pp. 3776-3790. [DOI: https://dx.doi.org/10.3390/md13063776]

30. Kumla, D.; Aung, T.S.; Buttachon, S.; Dethoup, T.; Gales, L.; Pereira, J.A.; Inácio, Â.; Costa, P.M.; Lee, M.; Sekeroglu, N. et al. A New Dihydrochromone Dimer and Other Secondary Metabolites from Cultures of the Marine Sponge-Associated Fungi Neosartorya fennelliae KUFA 0811 and Neosartorya tsunodae KUFC 9213. Mar. Drugs; 2017; 15, 375. [DOI: https://dx.doi.org/10.3390/md15120375]

31. Chen, B.-Y.; Wang, Z.; Ying, Y.-M.; Jiang, L.-X.; Zhan, Z.-J.; Wang, J.-L.; Zhang, W. Neofipiperzine D, A New Prenylated Indole Alkaloid metabolite of the Fungus Neosartorya fischeri. J. Chem. Res.; 2014; 38, pp. 539-541. [DOI: https://dx.doi.org/10.3184/174751914X14097355956467]

32. Zheng, Z.-Z.; Shan, W.-G.; Wang, S.-L.; Ying, Y.-M.; Ma, L.-F.; Zhan, Z.-J. Three New Prenylated Diketopiperazines from Neosartorya fischeri. Helv. Chim. Acta; 2014; 97, pp. 1020-1026. [DOI: https://dx.doi.org/10.1002/hlca.201300416]

33. Ying, Y.-M.; Huang, L.; Tian, T.; Li, C.-Y.; Wang, S.-L.; Ma, L.-F.; Shan, W.-G.; Wang, J.-W.; Zhan, Z.-J. Studies on the Chemical Diversities of Secondary Metabolites Produced by Neosartorya fischeri via the OSMAC Method. Molecules; 2018; 23, 2772. [DOI: https://dx.doi.org/10.3390/molecules23112772] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/30366473]

34. Fujimoto, H.; Ikeda, M.; Yamamoto, K.; Yamazaki, M. Structure of Fischerin, a New Toxic Metabolite from an Ascomycete, Neosartorya fischeri var. fischeri. J. Nat. Prod.; 1993; 56, pp. 1268-1275. [DOI: https://dx.doi.org/10.1021/np50098a010] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/8229011]

35. Eamvijarn, A.; Kijjoa, A.; Bruyère, C.; Mathieu, V.; Manoch, L.; Lefranc, F.; Silva, A.; Kiss, R.; Herz, W. Secondary Metabolites from a Culture of the Fungus Neosartorya pseudofischeri and Their In Vitro Cytostatic Activity in Human Cancer Cells. Planta Med.; 2012; 78, pp. 1767-1776. [DOI: https://dx.doi.org/10.1055/s-0032-1315301] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/22976482]

36. Jiao, R.H.; Xu, S.; Liu, J.Y.; Ge, H.M.; Ding, H.; Xu, C.; Zhu, A.H.L.; Tan, R.X. Chaetominine, a Cytotoxic Alkaloid Produced by Endophytic Chaetomium sp. IFB-E015. Org. Lett.; 2006; 8, pp. 5709-5712. [DOI: https://dx.doi.org/10.1021/ol062257t] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/17134253]

37. Liao, L.; You, M.; Chung, B.K.; Oh, D.-C.; Oh, K.-B.; Shin, J. Alkaloidal Metabolites from a Marine-Derived Aspergillus sp. Fungus. J. Nat. Prod.; 2015; 78, pp. 349-354. [DOI: https://dx.doi.org/10.1021/np500683u]

38. Paluka, J.; Kanokmedhakul, K.; Soytong, M.; Soytong, K.; Kanokmedhakul, S. Meroditerpene pyrone, tryptoquivaline and brasiliamide derivatives from the fungus Neosartorya pseudofischeri. Fitoterapia; 2019; 137, 104257. [DOI: https://dx.doi.org/10.1016/j.fitote.2019.104257]

39. Paluka, J.; Kanokmedhakul, K.; Soytong, M.; Soytong, K.; Yahuafai, J.; Siripong, P.; Kanokmedhakul, S. Meroterpenoid pyrones, alkaloid and bicyclic brasiliamide from the fungus Neosartorya hiratsukae. Fitoterapia; 2020; 142, 104485. [DOI: https://dx.doi.org/10.1016/j.fitote.2020.104485]

40. Kijjoa, A.; Santos, S.; Dethoup, T.; Manoch, L.; Almeida, A.P.; Vasconcelos, M.H.; Silva, A.; Gales, L.; Herz, W. Sartoryglabrins, Analogs of Ardeemins, from Neosartorya glabra. Nat. Prod. Commun.; 2011; 6, pp. 807-812. [DOI: https://dx.doi.org/10.1177/1934578X1100600615]

41. Masi, M.; Andolfi, A.; Mathieu, V.; Boari, A.; Cimmino, A.; Banuls, L.M.Y.; Vurro, M.; Kornienko, A.; Kiss, R.; Evidente, A. Fischerindoline, a pyrroloindole sesquiterpenoid isolated from Neosartorya pseudofischeri, with in vitro growth inhibitory activity in human cancer cell lines. Tetrahedron; 2013; 69, pp. 7466-7470. [DOI: https://dx.doi.org/10.1016/j.tet.2013.06.031]

42. Buttachon, S.; Chandrapatya, A.; Manoch, L.; Silva, A.; Gales, L.; Bruyère, C.; Kiss, R.; Kijjoa, A. Sartorymensin, a new indole alkaloid, and new analogues of tryptoquivaline and fiscalins produced by Neosartorya siamensis (KUFC 6349). Tetrahedron; 2012; 68, pp. 3253-3262. [DOI: https://dx.doi.org/10.1016/j.tet.2012.02.024]

43. Prata-Sena, M.; Ramos, A.; Buttachon, S.; Castro-Carvalho, B.; Marques, P.; Dethoup, T.; Kijjoa, A.; Rocha, E. Cytotoxic activity of Secondary Metabolites from Marine-derived Fungus Neosartorya siamensisin Human Cancer Cells. Phytotherapy Res.; 2016; 30, pp. 1862-1871. [DOI: https://dx.doi.org/10.1002/ptr.5696] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/27530464]

44. Rajachan, O.-A.; Kanokmedhakul, K.; Sanmanoch, W.; Boonlue, S.; Hannongbua, S.; Saparpakorn, P.; Kanokmedhakul, S. Chevalone C analogues and globoscinic acid derivatives from the fungus Neosartorya spinosa KKU-1NK1. Phytochemistry; 2016; 132, pp. 68-75. [DOI: https://dx.doi.org/10.1016/j.phytochem.2016.09.008] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/27680770]

45. Yamazaki, M.; Fujimoto, H.; Okuyama, E. Structure determination of six fungal metabolites, tryptoquivaline E,F,G,H,I and J from Aspergillus fumigatus. Chem. Pharm. Bull.; 1978; 26, pp. 111-117. [DOI: https://dx.doi.org/10.1248/cpb.26.111]

46. Gomes, N.M.; Bessa, L.J.; Buttachon, S.; Costa, P.M.; Buaruang, J.; Dethoup, T.; Silva, A.M.S.; Kijjoa, A. Antibacterial and Antibiofilm Activities of Tryptoquivalines and Meroditerpenes Isolated from the Marine-Derived Fungi Neosartorya paulistensis, N. laciniosa, N. tsunodae, and the Soil Fungi N. fischeri and N. siamensis. Mar. Drugs; 2014; 12, pp. 822-839. [DOI: https://dx.doi.org/10.3390/md12020822]

47. Sun, F.-Y.; Chen, G.; Bai, J.; Li, W.; Pei, Y.-H. Two new alkaloids from a marine-derived fungus Neosartorya sp.HN-M-3. J. Asian Nat. Prod. Res.; 2012; 14, pp. 1109-1115. [DOI: https://dx.doi.org/10.1080/10286020.2012.725393]

48. Yu, G.; Zhou, G.; Zhu, M.; Wang, W.; Zhu, T.; Gu, Q.; Li, D. Neosartoryadins A and B, Fumiquinazoline Alkaloids from a Mangrove-Derived Fungus Neosartorya udagawae HDN13-313. Org. Lett.; 2015; 18, pp. 244-247. [DOI: https://dx.doi.org/10.1021/acs.orglett.5b02964]

49. Shan, W.-G.; Wang, S.-L.; Lang, H.-Y.; Chen, S.-M.; Ying, Y.-M.; Zhan, Z.-J. Cottoquinazolines E and F from Neosartorya fischeri NRRL 181. Helv. Chim. Acta; 2015; 98, pp. 552-556. [DOI: https://dx.doi.org/10.1002/hlca.201400270]

50. Lin, S.; Yu, H.; Yang, B.; Li, F.; Chen, X.; Li, H.; Zhang, S.; Wang, J.; Hu, Y.; Hu, Z. et al. Reisolation and Configurational Reinvestigation of Cottoquinazolines E–G from an Arthropod-Derived Strain of the Fungus Neosartorya fischeri. J. Nat. Prod.; 2020; 83, pp. 169-173. [DOI: https://dx.doi.org/10.1021/acs.jnatprod.9b01000]

51. Fujita, T.; Makishima, D.; Akiyama, K.; Hayashi, H. New Convulsive Compounds, Brasiliamides A and B, from Penicillium brasilianum Batista JV-379. Biosci. Biotechnol. Biochem.; 2002; 66, pp. 1697-1705. [DOI: https://dx.doi.org/10.1271/bbb.66.1697]

52. Didier, C.; Critcher, D.J.; Walshe, N.D.; Kojima, Y.; Yamauchi, Y.; Barrett, A.G.M. Full Stereochemical Assignment and Synthesis of the Potent Anthelmintic Pyrrolobenzoxazine Natural Product CJ-12662. J. Org. Chem.; 2004; 69, pp. 7875-7879. [DOI: https://dx.doi.org/10.1021/jo048711t] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/15527264]

53. Liu, W.-H.; Zhao, H.; Li, R.-Q.; Zheng, H.-B.; Yu, Q. Polyketides and Meroterpenoids from Neosartorya glabra. Helv. Chim. Acta; 2015; 98, pp. 515-519. [DOI: https://dx.doi.org/10.1002/hlca.201400231]

54. Kaifuchi, S.; Mori, M.; Nonaka, K.; Masuma, R.; Ōmura, S.; Shiomi, K. Sartorypyrone D: A new NADH-fumarate reductase inhibitor produced by Neosartorya fischeri FO-5897. J. Antibiot.; 2015; 68, pp. 403-405. [DOI: https://dx.doi.org/10.1038/ja.2014.167] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/25586023]

55. Tan, Q.-W.; Ouyang, M.-A.; Shen, S.; Li, W. Bioactive metabolites from a marine-derived strain of the fungus Neosartorya fischeri. Nat. Prod. Res.; 2011; 26, pp. 1402-1407. [DOI: https://dx.doi.org/10.1080/14786419.2011.592834]

56. Li, G.; Kusari, S.; Spiteller, M. Natural products containing ‘decalin’ motif in microorganisms. Nat. Prod. Rep.; 2014; 31, pp. 1175-1201. [DOI: https://dx.doi.org/10.1039/C4NP00031E]

57. Prompanya, C.; Dethoup, T.; Gales, L.; Lee, M.; Pereira, J.A.C.; Silva, A.M.S.; Pinto, M.M.M.; Kijjoa, A. New Polyketides and New Benzoic Acid Derivatives from the Marine Sponge-Associated Fungus Neosartorya quadricincta KUFA 0081. Mar. Drugs; 2016; 14, 134. [DOI: https://dx.doi.org/10.3390/md14070134]

58. de Sá, J.D.M.; Pereira, J.A.; Dethoup, T.; Cidade, H.; Sousa, M.E.; Rodrigues, I.C.; Costa, P.M.; Mistry, S.; Silva, A.M.S.; Kijjoa, A. Anthraquinones, Diphenyl Ethers, and Their Derivatives from the Culture of the Marine Sponge-Associated Fungus Neosartorya spinosa KUFA 1047. Mar. Drugs; 2021; 19, 457. [DOI: https://dx.doi.org/10.3390/md19080457]

59. Ozoe, Y.; Kuriyama, T.; Tachibana, Y.; Harimaya, K.; Takahashi, N.; Yaguchi, T.; Suzuki, E.; Imamura, K.-I.; Oyama, K. Isocoumarin Derivative as a Novel GABA Receptor Ligand from Neosartorya quadricincta. J. Pestic. Sci.; 2004; 29, pp. 328-331. [DOI: https://dx.doi.org/10.1584/jpestics.29.328]

60. Proksa, B.; Uhrin, D.; Liptaj, T.; Sturdikova, M. ChemInform Abstract: Neosartorin, an Ergochrome Biosynthesized by Neosartorya fischeri. ChemInform; 2010; 29, pp. 116-1164. [DOI: https://dx.doi.org/10.1002/chin.199844247]

61. Yu, G.; Wang, Q.; Liu, S.; Zhang, X.; Che, Q.; Zhang, G.; Zhu, T.; Gu, Q.; Li, D. Methylsulfonylated Polyketides Produced by Neosartorya udagawae HDN13-313 via Exogenous Addition of Small Molecules. J. Nat. Prod.; 2019; 82, pp. 998-1001. [DOI: https://dx.doi.org/10.1021/acs.jnatprod.9b00035]

62. Jayasuriya, H.; Zink, D.; Basilio, A.; Vicente, F.; Collado, J.; Bills, G.; Goldman, M.L.; Motyl, M.; Huber, J.; Dezeny, G. et al. Discovery and antibacterial activity of glabramycin A–C from Neosartorya glabra by an antisense strategy. J. Antibiot.; 2009; 62, pp. 265-269. [DOI: https://dx.doi.org/10.1038/ja.2009.26] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/19343064]

63. Hansson, D.; Menkis, A.; Olson, Å.; Stenlid, J.; Broberg, A.; Karlsson, M. Biosynthesis of fomannoxin in the root rotting pathogen Heterobasidion occidentale. Phytochemistry; 2012; 84, pp. 31-39. [DOI: https://dx.doi.org/10.1016/j.phytochem.2012.08.008] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/22981000]

64. Rajamani, S.; Bauer, W.D.; Robinson, J.B.; Farrow, J.; Pesci, E.; Teplitski, M.; Gao, M.; Sayre, R.; Phillips, D.A. The Vitamin Riboflavin and Its Derivative Lumichrome Activate the LasR Bacterial Quorum-Sensing Receptor. Mol. Plant-Microbe Interact.; 2008; 21, pp. 1184-1192. [DOI: https://dx.doi.org/10.1094/MPMI-21-9-1184] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/18700823]

65. Voser, T.M.; Campbell, M.D.; Carroll, A.R. How different are marine microbial natural products compared to their terrestrial counterparts?. Nat. Prod. Rep.; 2021; 39, pp. 7-19. [DOI: https://dx.doi.org/10.1039/D1NP00051A] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/34651634]