May 11, 2015 - from Ganoderma (Boh et al., 2007; Kim and Kim, 1999; Paterson, ...... Cheng, C.R., Yue, Q.X., Wu, Z.Y., Song, X.Y., Tao, S.J., Wu, X.H., Xu, P.P., ...
Phytochemistry 114 (2015) 66–101
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Secondary metabolites from Ganoderma Sabulal Baby ⇑, Anil John Johnson, Balaji Govindan Phytochemistry and Phytopharmacology Division, Jawaharlal Nehru Tropical Botanic Garden and Research Institute, Pacha-Palode, Thiruvananthapuram 695 562, Kerala, India
a r t i c l e
i n f o
Article history: Available online 11 May 2015 Keywords: Ganoderma Ganodermataceae Lanostane type triterpenoids Ganoderic acids Lucidenic acids Meroterpenoids Steroids Volatiles Biological activities
a b s t r a c t Ganoderma is a genus of medicinal mushrooms. This review deals with secondary metabolites isolated from Ganoderma and their biological significance. Phytochemical studies over the last 40 years led to the isolation of 431 secondary metabolites from various Ganoderma species. The major secondary compounds isolated are (a) C30 lanostanes (ganoderic acids), (b) C30 lanostanes (aldehydes, alcohols, esters, glycosides, lactones, ketones), (c) C27 lanostanes (lucidenic acids), (d) C27 lanostanes (alcohols, lactones, esters), (e) C24, C25 lanostanes (f) C30 pentacyclic triterpenes, (g) meroterpenoids, (h) farnesyl hydroquinones (meroterpenoids), (i) C15 sesquiterpenoids, (j) steroids, (k) alkaloids, (l) prenyl hydroquinone (m) benzofurans, (n) benzopyran-4-one derivatives and (o) benzenoid derivatives. Ganoderma lucidum is the species extensively studied for its secondary metabolites and biological activities. Ganoderma applanatum, Ganoderma colossum, Ganoderma sinense, Ganoderma cochlear, Ganoderma tsugae, Ganoderma amboinense, Ganoderma orbiforme, Ganoderma resinaceum, Ganoderma hainanense, Ganoderma concinna, Ganoderma pfeifferi, Ganoderma neo-japonicum, Ganoderma tropicum, Ganoderma australe, Ganoderma carnosum, Ganoderma fornicatum, Ganoderma lipsiense (synonym G. applanatum), Ganoderma mastoporum, Ganoderma theaecolum, Ganoderma boninense, Ganoderma capense and Ganoderma annulare are the other Ganoderma species subjected to phytochemical studies. Further phytochemical studies on Ganoderma could lead to the discovery of hitherto unknown biologically active secondary metabolites. Ó 2015 Elsevier Ltd. All rights reserved.
1. Genus Ganoderma Ganoderma is a group of wood degrading mushrooms with hard fruiting bodies. They belong to the kingdom of Fungi, division of Basidiomycota, class of Homobasidiomycetes, order of Aphyllophorales, family of Polyporaceae (Ganodermataceae) and genus of Ganoderma. A search for ‘Ganoderma’ in the database Index Fungorum displayed 428 species records, including synonyms. Taxonomic studies reported more than 300 species in genus Ganoderma, and most of them are distributed in the tropical regions (Richter et al., 2015; Seo and Kirk, 2000). Phytochemical and other studies reported varying species numbers in the genus (Li et al., 2013a; Peng et al., 2014b; Yan et al., 2013). Ganoderma species are generally not listed among edible mushrooms because their fruiting bodies are thick, corky and tough and do not have the fleshy texture characteristics (Jonathan et al., 2008; Jong and Birmingham, 1992). It is a genus of traditionally used medicinal mushrooms. Crude extracts of Ganoderma species are used as remedies for the treatment of a number of ailments including
⇑ Corresponding author. Tel.: +91 472 2869226x214; fax: +91 472 2869646. E-mail address: sabulal@gmail.com (S. Baby). http://dx.doi.org/10.1016/j.phytochem.2015.03.010 0031-9422/Ó 2015 Elsevier Ltd. All rights reserved.
cancer. A recent search for ‘Ganoderma’ in SciFinder Scholar gave more than 6500 publications of which nearly half were written in the Chinese language (Adams et al., 2010). Ganoderma lucidum is the best known medicinal mushroom (Leung et al., 2002; Paterson, 2006; Ríos et al., 2012; Sanodiya et al., 2009; Ziegenbein et al., 2006). It is known as ‘Lingzhi’ in Chinese, ‘Reishi’ in Japanese and ‘Yeongji’ in Korean. It occurs in different colors and shapes. In the Chinese medical texts, six strains of G. lucidum are described. Their names are derived from the colors of their fruit bodies: Sekishi (red), Shishi (violet), Kokushi (black), Oushi (yellow), Hakushi (white) and Seishi (blue) (Hirotani et al., 1993; Wang et al., 1993). G. lucidum, highly ranked in oriental traditional medicine, has been used as a panacea for chronic diseases such as hepatopathy, nephritis, hypertension, arthritis, insomnia, bronchitis, asthma, diabetes and cancer (Fatmawati et al., 2010; Mizushina et al., 1998a; Nishitoba et al., 1988b; Wasser, 2005; Wasser and Weis, 1999). It is a well known crude drug which has long been used in Traditional Chinese Medicine for the promotion of longevity and maintenance of vitality (Adams et al., 2010; Liew et al., 1992; Wang et al., 2006). Owing to its ‘‘magical’’ medicinal properties, G. lucidum was considered as an ‘elixir that could revive the dead’ (Cheng et al., 2010; Leung et al., 2002).
S. Baby et al. / Phytochemistry 114 (2015) 66–101
The use of G. lucidum even to cure major disease conditions prompted extensive phytochemical and biological studies (Ríos et al., 2012). So far, over 240 secondary compounds have been isolated from G. lucidum (Chen et al., 2012; Paterson, 2006; Qiao et al., 2007; Shiao, 2003) (Table 1, Fig. 1). Triterpenoids are the major constituents in G. lucidum and they play a critical role in its biological effects. G. lucidum has a strong bitterness which originates from its triterpenes and it depends on the strain, cultivation conditions and manufacturing processes (Seo et al., 2009). Several recent systematic studies have established the therapeutic potential of this mushroom as an anticancer agent (Gao et al., 2002; Joseph et al., 2011b; Kimura et al., 2002; Liu et al., 2009a; Muller et al., 2006; Ríos et al., 2012; Yuen and Gohel, 2005). G. lucidum was also found to possess antiviral especially anti-HIV (El-Mekkawy et al., 1998; Eo et al., 1999a,b; Min et al., 1998), immunomodulating (Chen et al., 2006), antiinflammatory (Joseph et al., 2009, 2011b; Ko et al., 2008), antiandrogenic (Fujita et al., 2005; Liu et al., 2007), cholesterol synthesis inhibitory (Hajjaj et al., 2005; Komoda et al., 1985), hypoglycemic (Hikino et al., 1989), hepatoprotective (Kim et al., 1999), inhibition of lipid peroxidation/oxidative DNA damage (Joseph et al., 2009; Lee et al., 2001), antimicrobial (Yoon et al., 1994) and anti-aging (Shie et al., 2001) activities. G. lucidum is also safe because oral administration of its extracts did not show any toxicity (Kim et al., 1986). Dried powder of G. lucidum is currently used worldwide as a dietary supplement. The annual sale of products derived from G. lucidum was estimated to be more than 2.5 billion U.S. dollars (Cao et al., 2012; Li et al., 2013a). The genome sequence of G. lucidum has been recently elucidated by next generation sequencing and optical mapping approaches (Chen et al., 2012). The 43.3 Mb G. lucidum genome sequence revealed an array of genes encoding cytochrome P450s (CYPs), transporters and regulatory proteins that cooperate in secondary metabolism. The genome encoded one of the richest sets of wood degradation enzymes among the sequenced basidiomycetes. G. lucidum genome analysis led to the identification of 24 CYP gene clusters. Totally 78 CYP genes were found to be co-expressed with lanosterol synthase and 16 of them showed high similarity with fungal CYPs that specifically catalyze the hydroxylation of testosterone, suggesting their possible roles in triterpenoid biosynthesis (Chen et al., 2012). Recent molecular studies found the commercially cultivated ‘G. lucidum’ (‘Lingzhi’) in East Asia as a different species from the G. lucidum originally described from Europe. Cao et al. proposed a new species Ganoderma lingzhi Sheng H. Wu, Y. Cao & Y. C. Dai for ‘Lingzhi’ which has an East Asia distribution (Cao et al., 2012; Liu et al., 2012a). Medicinal properties of Ganoderma applanatum are antitumor (Boh et al., 2000), aldose reductase inhibition (Lee et al., 2006), inhibition of Epstein–Barr virus activation (Chairul et al., 1994) and antibacterial activities (Smania et al., 1999). Ganoderma australe and Ganoderma capense showed antimicrobial (Smania et al., 2007) and mitogenic (Ngai and Ng, 2004) activities, respectively. Ganoderma colossum was reported to possess anti-HIV-1 protease activity (El Dine et al., 2008a). Ganoderma neo-japonicum showed radical scavenging and antihepatotoxic activities (Lin et al., 1995). Ganoderma pfeifferi possessed antimicrobial (Mothana et al., 2000) and antiviral (Mothana et al., 2003) activities. An Indonesian unidentified Ganoderma species was reported to have antitumor promoting activity (Chairul et al., 1990). Ganoderma tsugae showed cytotoxicity (Gan et al., 1998a; Su et al., 2000), anti-inflammatory (Ko et al., 2008), antitumor (Wang et al., 1993) and antioxidant activities (Mau et al., 2005). Recent reviews on the chemical constituents and biological activities of Ganoderma described the genus as a therapeutic biofactory (Paterson, 2006). This review is a compilation of secondary metabolites isolated from various Ganoderma species. Biological activities of secondary
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compounds, chemotaxonomical and biosynthetic aspects are also described briefly.
2. Secondary metabolites of Ganoderma G. lucidum, G. applanatum, G. colossum, Ganoderma sinense, Ganoderma cochlear, G. tsugae, Ganoderma amboinense, Ganoderma orbiforme, Ganoderma resinaceum, Ganoderma hainanense, Ganoderma concinna, G. pfeifferi, G. neo-japonicum, Ganoderma tropicum, G. australe, Ganoderma carnosum, Ganoderma fornicatum, Ganoderma lipsiense (synonym G. applanatum), Ganoderma mastoporum, Ganoderma theaecolum, Ganoderma boninense, G. capense and Ganoderma annulare are the Ganoderma species subjected to phytochemical studies so far (Table 1, Fig. 1). Most studies for biologically active molecules in Ganoderma species were carried out on the extracts of their fruiting bodies, spores and cultured mycelia. Triterpenes, steroids and polysaccharides are the major constituents in Ganoderma species (Boh et al., 2007). Proteins, peptides, amino acids, nucleosides, fatty acids, alkaloids and inorganic elements are also biologically significant constituents in Ganoderma (Li et al., 2013b). Secondary metabolites are a diverse group of organic molecules biosynthesized by plants, fungi, bacteria and algae. They are not involved in the normal growth, development and reproduction of an organism, but they contribute to its survival through signaling and defense. Triterpenoids are a major group of secondary metabolites found in terrestrial and marine flora and fauna (Hill and Connolly, 2012, 2013). They are composed of six isoprene units (C30) and they exist as acyclic, mono-, di-, tri-, tetra- or pentacyclic carbon skeletons. Among these pentacyclic triterpenoids are the widely distributed and most studied group (Mahato and Kundu, 1994). Triterpenoids occur in free form or as either their ether, ester, or glycoside derivatives. Many studies established the potential pharmacological effects of triterpenoids (Hill and Connolly, 2012, 2013). Triterpene structures in Ganoderma evolved from the intermediate lanosterol skeleton. Cyclization of squalene-2,3-epoxide leads to a protosterol, which on subsequent backbone rearrangement gives rise to lanosterol. Lanostane skeleton (C30H54) is tetracyclic (Hill and Connolly, 2013). It acts as the intermediate molecule in the biosynthesis of various lanostane type triterpenoids (Ríos et al., 2012). Squalene and lanosterol synthases are the two major enzymes controlling the formation of squalene and lanosterol, respectively (Shi et al., 2010; You et al., 2013). Lanostane type triterpenoids are characteristic of the trans junction of rings A/B, B/C and C/D, b-oriented methyls at C10, C13, a-oriented methyl at C14, b-oriented sidechain at C17 and R configuration for C20. Most lanostanes isolated from Ganoderma species show a high degree of oxidation (Fig. 1). Secondary metabolites isolated from various Ganoderma species belong to the following groups, (a) C30 lanostanes (ganoderic acids) (1–171), (b) C30 lanostanes (aldehydes, alcohols, esters, glycosides, lactones, ketones) (172–284), (c) C27 lanostanes (lucidenic acids) (285–319), (d) C27 lanostanes (alcohols, lactones, esters) (320–343), (e) C24, C25 lanostanes (344–353), (f) C30 pentacyclic triterpenes (354–357), (g) meroterpenoids (358–365), (h) farnesyl hydroquinones (meroterpenoids) (366–370), (i) C15 sesquiterpenoids (371–379), (j) steroids (380–413), (k) alkaloids (414– 420), (l) prenyl hydroquinone (421), (m) benzofurans (422–423), (n) benzopyran-4-one derivatives (424–428) and (o) benzenoid derivatives (429–431). Several compounds were reported from more than one Ganoderma species (Table 1, Fig. 1). Previous studies reported inconsistent numbers of secondary metabolites isolated from Ganoderma (Boh et al., 2007; Kim and Kim, 1999; Paterson, 2006; Ríos et al., 2012; Shiao, 2003). Of the 431 secondary compounds reported from various Ganoderma species (Table 1, Fig. 1), 240 were isolated from
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S. Baby et al. / Phytochemistry 114 (2015) 66–101
Table 1 Compound names, species (source) and literature listings of secondary metabolites isolated from genus Ganoderma. Compound number
Compound name
(a) C30 lanostanes, ganoderic acids 1 Ganoderic acid A
2
Ganoderic acid B
3
Ganoderic acid C1
4
Ganoderic acid C2
5
Ganoderic acid D1
6
Ganoderic acid E
7
Ganoderic acid F
8
Ganoderic acid G
9
Ganoderic acid H
10
Ganoderic acid I
11 12 13
Ganoderic acid J Ganoderic acid K Ganoderic acid K
14 15 16
Ganoderic acid L Ganoderic acid M Ganoderic acid N
17 18
Ganoderic acid O Ganoderic acid AM1
19 20 21
Ganoderic acid AP Ganoderic acid AP3 Ganoderic acid B8
22
Ganoderic acid C6
23 24 25 26 27 28 29 30 31 32
Ganoderic acid Df Ganoderic acid a 12-Hydroxy ganoderic acid C2 20-Hydroxy ganoderic acid G 20-Hydroxy ganoderic acid AM1 3-O-Acetyl ganoderic acid B 3-O-Acetyl ganoderic acid H 3-O-Acetyl ganoderic acid K 12-Acetoxy ganoderic acid D Ganolucidic acid A
33
Ganolucidic acid B
34 35
Compound B9 12b-Hydroxy-3,7,11,15,23-pentaoxo-5a-lanosta-8-en-26-oic acid
36 37
12,15-Bis(acetyloxy)-3-hydroxy-7,11,23-trioxo-lanost-8-en-26-oic acid Ganoderic acid O
Ganoderma species
References
Ganoderma lucidum, G. lucidum, G. sinense G. lucidum, G. lucidum, G. lucidum, G. lucidum G. lucidum, G. lucidum, G. lucidum, G. lucidum, G. lucidum G. lucidum, G. lucidum G. lucidum, G. lucidum, G. sinense G. lucidum, G. lucidum, G. lucidum, G. sinense G. lucidum, G. lucidum, G. amboinense G. lucidum, G. lucidum, G. lucidum G. lucidum, G. lucidum, G. lucidum, G. lucidum, G. lucidum, G. amboinense G. lucidum, G. lucidum G. lucidum G. lucidum G. lucidum, G. lucidum G. lucidum G. lucidum G. lucidum, G. lipsiense G. lucidum G. amboinense, G. lucidum G. applanatum G. applanatum G. lucidum, G. applanatum, G. lucidum G. lucidum, G. lucidum G. lucidum G. lucidum G. lucidum G. lucidum G. theaecolum G. lucidum G. lucidum G. lucidum G. lucidum G. lucidum, G. lucidum G. lucidum, G. lucidum, G. sinense G. lucidum G. lucidum, G. lucidum G. lucidum G. lucidum
Kubota et al. (1982); El-Mekkawy et al. (1998); Liu et al. (2012b) Kubota et al. (1982); Nishitoba et al. (1985c); Morigiwa et al. (1986); El-Mekkawy et al. (1998) Nishitoba et al. (1984); Nishitoba et al. (1985a); Nishitoba et al. (1985c); El-Mekkawy et al. (1998); Seo et al. (2009) Kikuchi et al. (1986a); Min et al. (2000) Nishitoba et al. (1985a); Nishitoba et al. (1985b); Qiao et al. (2007) Kikuchi et al. (1985a); Komoda et al. (1985); Kikuchi et al. (1986a); Liu et al. (2012b) Kikuchi et al. (1985a); Komoda et al. (1985); Yang et al. (2012) Komoda et al. (1985); Kikuchi et al. (1985b); Kikuchi et al. (1986b) Kikuchi et al. (1985a); Kikuchi et al. (1986b); Morigiwa et al. (1986); Nishitoba et al. (1987c); El-Mekkawy et al. (1998); Yang et al. (2012) Kikuchi et al. (1985b); Kikuchi et al. (1986a) Nishitoba et al. (1985b) Morigiwa et al. (1986) Kikuchi et al. (1986a); Nishitoba et al. (1987c) Nishitoba et al. (1986a) Nishitoba et al. (1987c) Nishitoba et al. (1987c); Rosecke and Konig (2000) Nishitoba et al. (1987c) Lin et al. (1993); Cheng et al. (2010) Nishitoba et al. (1989) Wang and Liu, (2008) Kikuchi et al. (1986a); Nishitoba et al. (1989); Gao et al. (2002) Kikuchi et al. (1986b); Min et al. (2001) Fatmawati et al. (2010) El-Mekkawy et al. (1998) Yang et al. (2007) Ma et al. (2002) Liu et al. (2014b) Li et al. (2009) Yang et al. (2007) Li et al. (2009) Yang et al. (2007) Kikuchi et al. (1985b); Kikuchi et al. (1986c) Kikuchi et al. (1985b); Kikuchi et al. (1986c); Liu et al. (2012b) Kikuchi et al. (1986a) Komoda et al. (1985); Cheng et al. (2010) Yang et al. (2007) Hirotani et al. (1987)
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S. Baby et al. / Phytochemistry 114 (2015) 66–101 Table 1 (continued) Compound number
Compound name
Ganoderma species
References
38 39
Ganoderic acid U Ganoderic acid V
40
Ganoderic acid W
41 42 43 44 45 46 47 48 49 50 51
Ganoderic Ganoderic Ganoderic Ganoderic Ganoderic Ganoderic Ganoderic Ganoderic Ganoderic Ganoderic Ganoderic
52
7-O-Methyl ganoderic acid O
53 54
7-O-Ethyl ganoderic acid O 7-Oxo-ganoderic acid Z
55 56 57 58 59 60 61 62 63 64 65 66
7-Oxo-ganoderic acid Z2 7-Oxo-ganoderic acid Z3 Ganorbiformin B Ganorbiformin C Ganorbiformin D Ganorbiformin E Ganorbiformin F 3a,22b-Diacetoxy-7a-hydroxyl-5a-lanost-8,24E-dien-26-oic acid 3b,15a-Diacetoxy lanosta-8,24-dien-26-oic acid 11a-Hydroxy-3,7-dioxo-5a-lanosta-8,24(E)-dien-26-oic acid 11b-Hydroxy-3,7-dioxo-5a-lanosta-8,24(E)-dien-26-oic acid Ganoderic acid P
67 68
Ganoderic acid Q Ganoderic acid R
69
Ganoderic acid S
70
Ganoderic acid S
71
Ganoderic acid T
72
Ganoderic acid X
73
Ganoderic acid Y
74 75 76 77
Ganoderic acid Me Ganoderic acid Mf Ganoderic acid TR1 15-Hydroxy ganoderic acid S
78 79 80 81 82 83 84
Ganodermic Ganodermic Ganodermic Ganodermic Ganodermic Ganodermic Ganodermic
85 86 87
Ganorbiformin G Lanosta-7,9(11),24-trien-3a-acetoxy-15a,22b-dihydroxy-26-oic acid Lanosta-7,9(11),24-trien-3b,15a,22b-triacetoxy-26-oic acid
88
3a,15a,22a-Trihydroxylanosta-7,9(11),24-trien-26-oic acid
G. lucidum G. lucidum, G. orbiforme G. lucidum, G. lucidum G. lucidum G. sinense G. sinense G. lucidum G. lucidum G. lucidum G. lucidum G. lucidum G. lucidum G. lucidum G. lucidum, G. sinense G. lucidum, G. orbiforme G. lucidum G. lucidum, G. resinaceum G. resinaceum G. resinaceum G. orbiforme G. orbiforme G. orbiforme G. orbiforme G. orbiforme G. lucidum G. lucidum G. lucidum G. lucidum G. lucidum, G. orbiforme, G. amboinense G. lucidum G. lucidum, G. orbiforme G. lucidum, G. orbiforme G. lucidum, G. lucidum G. lucidum, G. lucidum, G. lucidum, G. lucidum, G. orbiforme G. lucidum, G. lucidum, G. amboinense, G. orbiforme G. lucidum, G. lucidum, G. concinna, G. resinaceum, G. hainanense G. lucidum G. lucidum G. lucidum G. lucidum, G. amboinense G. lucidum G. lucidum G. lucidum G. lucidum G. lucidum G. lucidum G. lucidum, G. hainanense G. orbiforme G. lucidum G. lucidum, G. amboinense G. lucidum
Toth et al. (1983b) Toth et al. (1983b); Isaka et al. (2013) Toth et al. (1983b); Nishitoba et al. (1987a) Toth et al. (1983b) Sato et al. (2009b) Sato et al. (2009b) Nishitoba et al. (1987a) Nishitoba et al. (1987a) Nishitoba et al. (1987a) Nishitoba et al. (1987b) Nishitoba et al. (1987b) Nishitoba et al. (1987b) Nishitoba et al. (1987b) Min et al. (1998); Sato et al. (2009b) Hirotani et al. (1987); Isaka et al. (2013) Wang et al. (2010b) Li et al. (2006); Peng et al. (2013) Peng et al. (2013) Peng et al. (2013) Isaka et al. (2013) Isaka et al. (2013) Isaka et al. (2013) Isaka et al. (2013) Isaka et al. (2013) Li et al. (2013c) Lin et al. (1988a) Cheng et al. (2010) Cheng et al. (2010) Hirotani et al. (1987); Isaka et al. (2013); Yang et al. (2012) Hirotani et al. (1987) Hirotani et al. (1987); Isaka et al. (2013) Hirotani et al. (1987); Isaka et al. (2013) Morigiwa et al. (1986); Adams et al. (2010) Toth et al. (1983b); Hirotani et al. (1987); Nishitoba et al. (1987a); Shiao et al. (1988b); Isaka et al. (2013) Toth et al. (1983b); Shiao et al. (1988a); Li et al. (2005b); Isaka et al. (2013) Toth et al. (1983b); Morigiwa et al. (1986); Gonzalez et al. (2002); Peng et al. (2013); Ma et al. (2013) Nishitoba et al. (1987a) Nishitoba et al. (1987a) Adams et al. (2010) Li et al. (2006); Yang et al. (2012) Shiao et al. (1987) Shiao et al. (1988a) Shiao et al. (1988a) Shiao et al. (1988a) Lin et al. (1988b) Lin et al. (1988b) Lin et al. (1988b); Ma et al. (2013) Isaka et al. (2013) Shiao et al. (1988b) Shiao et al. (1988b); Yang et al. (2012) Lin et al. (1988a)
acid acid acid acid acid acid acid acid acid acid acid
Z GS-1 GS-2 Ma Mc Md Mg Mh Mi Mj b
acid acid acid acid acid acid acid
S Ja Jb P2 T-N T-O T–Q
(continued on next page)
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S. Baby et al. / Phytochemistry 114 (2015) 66–101
Table 1 (continued) Compound number
Compound name
Ganoderma species
References
89
3b,15a,22b-Trihydroxylanosta-7,9(11),24-trien-26-oic acid
90 91 92 93 94 95 96 97 98
3a,15a-Diacetoxy-22a-hydroxylanosta-7,9(11),24-trien-26-oic acid 3b,15a-Diacetoxy-22a-hydroxylanosta-7,9(11),24-trien-26-oic acid 22b-Acetoxy-3a,15a-dihydroxylanosta-7,9(11),24-trien-26-oic acid 22b-Acetoxy-3b,15a-dihydroxylanosta-7,9(11),24-trien-26-oic acid Ganoderic acid AP2 Ganoderic acid LM2 Ganoderic acid c Ganoderic acid d Ganoderic acid e
99 100 101 102
Ganoderic acid n Ganoderic acid g Ganoderic acid h Ganolucidic acid D
103 104 105 106
Ganolucidic acid E Ganolucidic acid ca Ganolucidate F Ganoderic acid DM
107 108 109 110 111 112 113 114 115
Ganoderic acid GS-3 Ganoderic acid V1 Ganoderic acid XL1 Ganoderic acid XL2 Ganoderic acid Jc Lanosta-7,9(11),24-trien-3a-acetoxy-15a-hydroxy-23-oxo-26-oic acid Lanosta-7,9(11),24-trien-15a-acetoxy-3a-hydroxy-23-oxo-26-oic acid Lanosta-7,9(11),24-trien-3a,l5a-diacetoxy-23-oxo-26-oic acid Ganoderic acid Sz
116
Ganoderic acid TR
117 118 119 120 121
23-Hydroxy ganoderic acid S 8b,9a-Dihydroganoderic acid C 8b,9a-Dihydroganoderic acid J Ganosporeric acid A Ganolucidic acid C
122 123 124 125
Ganorbiformin A 3b,7b,20,23n-Tetrahydroxy-11,15-dioxolanosta-8-en-26-oic acid 7b,20,23n-Trihydroxy-3,11,15-trioxolanosta-8-en-26-oic acid Ganoderenic acid A
126 127 128
Ganoderenic acid B Ganoderenic acid C Ganoderenic acid D
G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G.
lucidum, amboinense lucidum lucidum lucidum lucidum applanatum lucidum lucidum lucidum lucidum, lucidum lucidum lucidum lucidum lucidum, lucidum lucidum sinense sinense lucidum, lucidum, amboinense sinense lucidum theaecolum theaecolum sinense lucidum lucidum lucidum lucidum, hainanense lucidum, lucidum lucidum lucidum lucidum lucidum lucidum, sinense orbiforme applanatum applanatum lucidum, applanatum, lipsiense lucidum lucidum lucidum, lipsiense,
129 130 131 132 133 134 135 136 137 138 139
Ganoderenic acid E Ganoderenic acid F Ganoderenic acid G Ganoderenic acid H Ganoderenic acid I Ganoderenic acid K Elfvingic acid A 12b-Acetoxy-7b-hydroxy-3,11,15,23-tetraoxo-5a-lanosta-8,20-dien-26-oic acid Ganoderenic acid AM1 7b,23n-Dihydroxy-3,11,15-trioxolanosta-8,20E(22)-dien-26-oic acid Applanoxidic acid A
140 141 142
Applanoxidic acid B Applanoxidic acid E Applanoxidic acid F
G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G.
applanatum lucidum applanatum applanatum applanatum applanatum lucidum lucidum lucidum theaecolum applanatum applanatum, annulare, pfeifferi, australe applanatum applanatum applanatum, australe, annulare
Lin et al. (1988a); Yang et al. (2012) Lin et al. (1988a) Lin et al. (1988a) Lin et al. (1988a) Lin et al. (1988a) Wang and Liu, (2008) Luo et al. (2002) Min et al. (2000) Min et al. (2000) Min et al. (2000); Chen et al. (2009a) Min et al. (2000) Min et al. (2000) Min et al. (2000) Nishitoba et al. (1986a); Min et al. (2000) Nishitoba et al. (1988a) Liu et al. (2012b) Liu et al. (2012b) Wang et al. (1997a); Adams et al. (2010); Yang et al. (2012) Sato et al. (2009b) Hirotani et al. (1993) Liu et al. (2014b) Liu et al. (2014b) Liu et al. (2012b) Shiao et al. (1988b) Shiao et al. (1988b) Shiao et al. (1988b) Li et al. (2005a); Ma et al. (2013) Liu et al. (2006); Adams et al. (2010) Adams et al. (2010) Li et al. (2009) Ma et al. (2002) Chen and Yu, (1993) Nishitoba et al. (1985b); Liu et al. (2012b) Isaka et al. (2013) Shim et al. (2004) Shim et al. (2004) Komoda et al. (1985); Ming et al. (2002); Rosecke and Konig (2000) Komoda et al. (1985) Komoda et al. (1985) Komoda et al. (1985); Rosecke and Konig (2000); Ming et al. (2002) Nishitoba et al. (1987c) Nishitoba et al. (1989) Nishitoba et al. (1989) Nishitoba et al. (1989) Nishitoba et al. (1989) Yang et al. (2007) Yang et al. (2007) Cheng et al. (2010) Liu et al. (2014b) Shim et al. (2004) Chairul et al. (1991); Smania et al. (2003); Niedermeyer et al. (2005); León et al. (2003) Chairul et al. (1991) Chairul et al. (1994) Chairul et al. (1994); León et al. (2003); Smania et al. (2003)
71
S. Baby et al. / Phytochemistry 114 (2015) 66–101 Table 1 (continued) Compound number
Compound name
Ganoderma species
References
143
Applanoxidic acid C
144 145
Applanoxidic acid D Applanoxidic acid G
146
Applanoxidic acid H
147 148 149 150 151 152 153 154 155 156
3b,7b-Dihydroxy-11,15,23-trioxo-lanost-8,16-dien-26-oic acid 3b,7b,15b-Trihydroxy-11,23-dioxo-lanost-8,16-dien-26-oic acid 12b-Acetoxy-3b,7b-dihydroxy-11,15,23-trioxo-lanost-8,16-dien-26-oic acid Ganoderesin C Ganodermacetal Ganosinensic acid B Colossolactone V Colossolactone VI Furanoganoderic acid 3a-Carboxyacetoxy-24-methyl-23-oxolanost-8-en-26-oic acid (carboxyacetylquercinic acid)
157 158 159 160
3a-Carboxyacetoxy-24-methylene-23-oxolanost-8-en-26-oic acid (carboxyacetylquercinic acid derivative 01) Carboxyacetylquercinic acid derivative 02 8a,9a-Epoxy-3,7,11,15,23-pentaoxo-5a-lanosta-26-oic acid Tsugaric acid A
161 162 163
Tsugaric acid D 3b-Hydroxy-5a-lanosta-8,24-dien-21-oic acid 3-Oxo-5a-lanosta-8,24-dien-21-oic acid
164 165 166 167 168
Tsugaric acid B Tsugaric acid C Tsugaric acid E 3a-Acetoxy-16a-hydroxy-24-methylene-5a-lanost-8-en-21-oic acid (3-epipachymic acid) 3a-(3-Hydroxy-5-methoxy-3-methyl-1,5-dioxopentyloxy)-24-methylene-5a-lanost-8-en-21-oic acid 3a,16a-Dihydroxylanosta-7,9(11),24-trien-21-oic acid 3a,16a,26-Trihydroxylanosta-7,9(11),24-trien-21-oic acid 16a-Hydroxy-3-oxolanosta-7,9(11),24-trien-21-oic acid
G. applanatum, G. australe, G. annulare, G. pfeifferi G. applanatum G. applanatum, G. pfeifferi, G. australe, G. annulare G. applanatum, G. annulare G. lucidum G. tropicum G. lucidum G. theaecolum G. amboinense G. sinense G. colossum G. colossum G. applanatum Ganoderma spp., G. applanatum Ganoderma spp., G. applanatum Ganoderma spp. G. lucidum G. tsugae, G. fornicatum G. tsugae G. tsugae G. tsugae, G. resinaceum G. tsugae G. tsugae G. tsugae G. resinaceum G. resinaceum
Chairul et al. (1991); León et al. (2003); Smania et al. (2003); Niedermeyer et al. (2005) Chairul et al. (1991) Chairul et al. (1994); Mothana et al. (2003); León et al. (2003); Smania et al. (2003) Chairul et al. (1994); Smania et al. (2003) Guan et al. (2007) Hu et al. (2013) Guan et al. (2007) Liu et al. (2014b) Yang et al. (2012) Wang et al. (2010a) El Dine et al. (2008a) El Dine et al. (2008a) Nishitoba et al. (1989) Chairul et al. (1990); de Silva et al. (2006) Chairul et al. (1990); de Silva et al. (2006) Chairul et al. (1990) Joseph et al. (2011a) Lin et al. (1997); Qiao et al. (2006) Lin et al. (2013) Lin et al. (1997) Lin et al. (1997); Niu et al. (2007) Lin et al. (1997) Su et al. (2000) Lin et al. (2013) Niu et al. (2007) Niu et al. (2007)
G. applanatum G. applanatum G. applanatum
de Silva et al. (2006) de Silva et al. (2006) de Silva et al. (2006)
G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G.
Morigiwa et al. (1986); Gan et al. (1998b); Gonzalez et al. (2002); Niedermeyer et al. (2005) Gao et al. (2002); Gonzalez et al. (2002) Adams et al. (2010) Arisawa et al. (1986); Morigiwa et al. (1986); Gao et al. (2002); Gonzalez et al. (2002); Niedermeyer et al. (2005) Morigiwa et al. (1986); Niedermeyer et al. (2005); Peng et al. (2013) Arisawa et al. (1986); Gonzalez et al. (2002); Liu et al. (2012b); Yang et al. (2012) Liu et al. (2012b) Sato et al. (1986); Gonzalez et al. (2002) Nishitoba et al. (1988a); Gonzalez et al. (2002); Sato et al. (2009b); Ma et al. (2013); Yang et al. (2012) Gonzalez et al. (2002); Cheng et al. (2010) Qiao et al. (2006) Ma et al. (2013)
169 170 171
(b) C30 lanostanes (aldehydes, alcohols, esters, glycosides, lactones, ketones) 172 Ganoderal A
173
Lucialdehyde A (5a-Lanosta-7,9(11),24-triene-3b-hydroxy-26-al)
174 175
Ganoderic aldehyde TR Ganoderol A (ganodermenonol)
176
Ganoderol B
177
Ganodermatriol
178 179
Ganodermatetraol Ganoderiol B
180
Ganoderiol F
181
5a-Lanosta-7,9(11),24-triene-15a-26-dihydroxy-3-one
182 183
Polycarpol Agnosterol (lanosta-7,9(11),24-trien-3b-ol)
lucidum, neo-japonicum, concinna, pfeifferi lucidum, concinna lucidum lucidum, lucidum, lucidum, concinna, pfeifferi lucidum, pfeifferi, resinaceum lucidum, concinna, sinense, amboinense sinense lucidum, concinna lucidum, concinna, sinense, hainanense, amboinense concinna, lucidum fornicatum hainanense
(continued on next page)
72
S. Baby et al. / Phytochemistry 114 (2015) 66–101
Table 1 (continued) Compound number
Compound name
Ganoderma species
References
184 185 186
Ganoderal B Lucidal Lucialdehyde B
187
Lucialdehyde D
188 189 190 191 192
Lucialdehyde E Ganoderic aldehyde A Ganoderone A 16a,26-Dihydroxy lanosta-8,24-dien-3-one Ganodermanondiol
193
Lucidumol B
194 195 196
Ganoderitriol M Lucidumol A Ganodermanontriol
197
Ganoderiol A
198 199
Ganoderiol C Ganoderiol D
200 201 202
Ganoderiol G Ganoderiol H Ganoderiol E
203 204 205 206 207 208 209 210 211 212 213
Ganoderiol I Ganoderiol J Ganoderiol A triacetate 26-Nor-11,23-dioxo-5a-lanost-8-en-3b,7b,15a,25-tetrol Lanosta-7,9(11),24-trien-3b,21-diol 3b,22S-Dihydroxylanosta-7,9(11),24-triene 26-Hydroxy-5a-lanosta-7,9(11),24-triene-3,22-dione 26,27-Dihydroxy-5a-lanosta-7,9(11),24-triene-3,22-dione 26,27-Dihydroxylanosta-7,9(11),24-trien-3,16-dione Colossolactone A Lucidadiol
214 215 216 217 218 219 220 221 222 223 224 225
Fornicatin C Epoxyganoderiol A Ganoderone C Epoxyganoderiol B Epoxyganoderiol C Ganodercochlearin A Ganodercochlearin B Ganodercochlearin C Ganosinensin A Ganosinensin B Ganosinensin C Methyl ganoderate A
226
Methyl ganoderate B
227 228 229
Methyl ganoderate C Methyl ganoderate D Methyl ganoderate E
230 231 232 233 234 235 236 237 238 239 240 241
Methyl ganoderate F Methyl ganoderate H Methyl ganoderate J Methyl-O-acetyl ganoderate C 3b,7b-Dihydroxy-12b-acetoxy-11,15,23-trioxo-5a-lanosta-8-en-26-oic acid methyl ester Ethyl ganoderate J Ethyl 3-O-acetyl ganoderate B 12b-Acetoxy-3,7,11,15,23-pentaoxo-5a-lanosta-8-en-26-oic acid ethyl ester Butyl ganoderate A Butyl ganoderate B Butyl ganoderate H 12b-Acetoxy-3b,7b-dihydroxy-11,15,23-trioxolanost-8-en-26-oic acid butyl ester
G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G.
Nishitoba et al. (1988b) González et al. (1999) Gao et al. (2002); Niedermeyer et al. (2005) Niedermeyer et al. (2005); Ma et al. (2012) Ma et al. (2012) Lin et al. (1990) Niedermeyer et al. (2005) Ma et al. (2013) Fujita et al. (1986); Adams et al. (2010); Ma et al. (2013) Min et al. (1998); Liu et al. (2012b) Chen et al. (2009a) Min et al. (1998) Fujita et al. (1986); Gonzalez et al. (2002); Sato et al. (2009b); Yang et al. (2012) Sato et al. (1986); Gonzalez et al. (2002); Sato et al. (2009a) Nishitoba et al. (1988a) Nishitoba et al. (1988a); Sato et al. (2009a) Nishitoba et al. (1988a) Nishitoba et al. (1988a) Nishitoba et al. (1988a); Liu et al. (2012b) Nishitoba et al. (1988b) Liu et al. (2012b) Qiao et al. (2007) Hu et al. (2014) Jain and Gupta (1984) Peng et al. (2014b) Ha et al. (2000) Ha et al. (2000) Keller et al. (1997) Kleinwächter et al. (2001) González et al. (1999); Mothana et al. (2003); Liu et al. (2012b) Qiao et al. (2006) Nishitoba et al. (1988b) Niedermeyer et al. (2005) Nishitoba et al. (1988b) Nishitoba et al. (1988b) Peng et al. (2014b) Peng et al. (2014b) Peng et al. (2014b) Sato et al. (2009a) Sato et al. (2009a) Sato et al. (2009a) Seo et al. (2009); Lee et al. (2011a) Lee et al. (2010b); Yang et al. (2012) Yang et al. (2012) Lee et al. (2010b) Lee et al. (2010b); Yang et al. (2012) Iwatsuki et al. (2003) Lee et al. (2010b) Tung et al. (2013) Li et al. (2009) Cheng et al. (2010) Li et al. (2009) Li et al. (2009) Cheng et al. (2010) Lee et al. (2010b) Lee et al. (2010b) Lee et al. (2011a) Liu et al. (2014a)
lucidum lucidum lucidum, pfeifferi pfeifferi, lucidum lucidum lucidum pfeifferi hainanense lucidum, lucidum, hainanense lucidum, sinense lucidum lucidum lucidum, concinna, sinense, amboinense lucidum, concinna, sinense lucidum lucidum, sinense lucidum lucidum lucidum, sinense lucidum sinense sinense tropicum australe cochlear lucidum lucidum carnosum colossum lucidum, pfeifferi, sinense fornicatum lucidum pfeifferi lucidum lucidum cochlear cochlear cochlear sinense sinense sinense lucidum, lucidum lucidum, amboinense amboinense lucidum lucidum, amboinense lucidum lucidum lucidum lucidum lucidum lucidum lucidum lucidum lucidum lucidum lucidum lucidum
73
S. Baby et al. / Phytochemistry 114 (2015) 66–101 Table 1 (continued) Compound number
Compound name
Ganoderma species
References
242 243 244 245 246 247 248 249 250 251 252
12b-Acetoxy-3,7,11,15,23-pentaoxolanost-8-en-26-oic acid butyl ester Methyl 8b,9a-dihydroganoderate J Ganoderesin B Methyl ganoderate A acetonide Ganoderesin A 3b,7b,15b-Trihydroxy-11,23-dioxo-lanost-8,16-dien-26-oic acid methyl ester 3b,15b-Dihydroxy-7,11,23-trioxo-lanost-8,16-dien-26-oic acid methyl ester 3b,7b-Dihydroxy-11,15,23-trioxo-lanost-8,16-dien-26-oic acid methyl ester 7b-Hydroxy-3,11,15,23-tetraoxolanosta-8,20E(22)-dien-26-oic acid methyl ester Ganosinoside A Tsugarioside A (3a-acetoxy-5a-lanosta-8,24-dien-21-oic acid ester b-D-glucoside)
253 254 255
Tsugarioside B Tsugarioside C Ganosporelactone A
256
Ganosporelactone B
257
Colossolactone I
Liu et al. (2014a) Ma et al. (2002) Peng et al. (2013) Lee et al. (2011a) Peng et al. (2013) Hu et al. (2013) Hu et al. (2013) Guan et al. (2007) Shim et al. (2004) Liu et al. (2012b) Gan et al. (1998a); Su et al. (2000); Liu et al. (2012b) Su et al. (2000) Su et al. (2000) Chen and Yu (1991); Jin-Ming (2006) Chen and Yu (1991); Jin-Ming (2006) El Dine et al. (2008b); Lakornwong et al. (2014)
258 259
Colossolactone II Colossolactone B
G. lucidum G. lucidum G. resinaceum G. lucidum G. resinaceum G. tropicum G. tropicum G. lucidum G. applanatum G. sinense G. tsugae, G. tsugae, G. sinense G. tsugae G. tsugae G. lucidum, G. lucidum G. lucidum, G. lucidum G. colossum, Ganoderma sp. KM01 G. colossum G. colossum,
260
Ganoderma lactone E
261 262
Colossolactone III Colossolactone IV
263
Ganoderma lactone C
264 265
Colossolactone VII Colossolactone VIII (23-hydroxycolossolactone E)
266 267
Colossolactone D Colossolactone E
Ganoderma sp. KM01 Ganoderma sp. KM01 G. colossum G. colossum, Ganoderma sp. KM01 Ganoderma sp. KM01 G. colossum G. colossum, G. colossum G. colossum G. colossum,
268 269 270a
Colossolactone F Schisanlactone A Colossolactone G
G. colossum, Ganoderma sp. KM01 G. colossum G. colossum G. colossum,
270b
Colossolactone G (revised structure)
271
Colossolactone C (ganoderma lactone B)
272
Ganoderma lactone A
273
Ganoderma lactone D
274
Ganoderma lactone F
275
Ganoderma lactone G
276 277 278 279 280 281 282 283
Ganoboninketal A Ganoboninketal B Ganoboninketal C Inonotsuoxide B Australic acid Methyl australate Austrolactone Schisanlactone B
284
24n-Methyl-5a-lanosta-25-one
G. colossum Ganoderma sp. KM01 G. colossum, Ganoderma sp. KM01 Ganoderma sp. KM01 Ganoderma sp. KM01 Ganoderma sp. KM01 Ganoderma sp. KM01 G. boninense G. boninense G. boninense G. cochlear G. australe G. australe G. australe Ganoderma sp. KM01 G. applanatum
El Dine et al. (2008b) Kleinwächter et al. (2001); Lakornwong et al. (2014) Lakornwong et al. (2014) El Dine et al. (2008b) El Dine et al. (2008b); Lakornwong et al. (2014) Lakornwong et al. (2014) El Dine et al. (2008a) El Dine et al. (2008a); Ofodile et al. (2012) Kleinwächter et al. (2001) Kleinwächter et al. (2001); El Dine et al. (2008a); Lakornwong et al. (2014) Kleinwächter et al. (2001) El Dine et al. (2008a) Kleinwächter et al. (2001); El Dine et al. (2008a) Lakornwong et al. (2014) Kleinwächter et al. (2001); Lakornwong et al. (2014) Lakornwong et al. (2014) Lakornwong et al. (2014) Lakornwong et al. (2014) Lakornwong et al. (2014) Ma et al. (2014) Ma et al. (2014) Ma et al. (2014) Peng et al. (2014b) León et al. (2003) Smania et al. (2007) León et al. (2003) Lakornwong et al. (2014) Gan et al. (1998b) (continued on next page)
74
S. Baby et al. / Phytochemistry 114 (2015) 66–101
Table 1 (continued) Compound number
Compound name
(c) C27 lanostanes, lucidenic acids 285 Lucidenic acid A (lucidenate A) 286 287 288 289
Lucidenic Lucidenic Lucidenic Lucidenic
acid acid acid acid
B C D1 D2
290 291 292
Lucidenic acid E1 Lucidenic acid E2 Lucidenic acid F
293
Lucidenic acid N
294 295 296 297 298 299
Lucidenic acid P 20-Hydroxy lucidenic 20-Hydroxy lucidenic 20-Hydroxy lucidenic 20-Hydroxy lucidenic 20-Hydroxy lucidenic
300 301 302 303 304 305 306 307 308 309 310
20-Hydroxy lucidenic acid P 3b-Hydroxy-4,4,14-trimethyl-7,11,15-trioxochol-8-en-24-oic acid Lucidenic acid G Lucidenic acid H Lucidenic acid I Lucidenic acid J Lucidenic acid K Lucidenic acid L Lucidenic acid M Lucidenic acid O 20(21)-Dehydrolucidenic acid A
311 312 313 314 315 316
20(21)-Dehydrolucidenic acid N Ganoderic acid Jd 4,4,14a-Trimethyl-5a-chol-7,9(11)-dien-3-oxo-24-oic acid 4,4,14a-Trimethyl-3,7-dioxo-5a-chol-8-en-24-oic acid Fornicatin A Fornicatin B
317 318 319
Fornicatin D Cochlate B Ganosinensic acid A
acid acid acid acid acid
A D2 E2 F N
(d) C27 lanostanes (alcohols, lactones, esters) 320 Lucidenic lactone 321 Lucidenolactone (ganolactone) 322 323 324 325 326
Ganolactone B Fornicatin E Fornicatin F Cochlate A Methyl lucidenate A
327 328
Methyl lucidenate C Methyl lucidenate F
329
Methyl lucidenate N
330 331 332 333 334 335 336 337 338 339 340 341 342 343
Methyl lucidenate P Methyl lucidenate Q Methyl lucidenate D2 Ethyl lucidenate A Butyl lucidenate A Butyl lucidenate N t-Butyl lucidenate B Butyl lucidenate P Butyl lucidenate Q Butyl lucidenate D2 Butyl lucidenate E2 Methyl lucidenate Ha Methyl 20(21)-dehydrolucidenate A Methyl ganosinensate A
Ganoderma species
References
G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G.
lucidum, hainanense lucidum lucidum lucidum lucidum, lucidum, sinense lucidum lucidum lucidum, lucidum lucidum, lucidum, hainanense lucidum sinense lucidum lucidum lucidum lucidum, sinense lucidum lucidum lucidum lucidum lucidum lucidum lucidum lucidum lucidum lucidum lucidum, sinense sinense sinense lucidum lucidum fornicatum fornicatum, cochlear cochlear cochlear sinense
Nishitoba et al. (1985c); Ma et al. (2013) Nishitoba et al. (1985c) Nishitoba et al. (1985c) Nishitoba et al. (1985a) Kikuchi et al. (1985a); Komoda et al. (1985); Sato et al. (2009b) Nishitoba et al. (1985a) Kikuchi et al. (1985a) Kikuchi et al. (1985a); Kikuchi et al. (1986a) Wu et al. (2001); Min et al. (2001); Ma et al. (2013) Iwatsuki et al. (2003) Sato et al. (2009b) Akihisa et al. (2005) Akihisa et al. (2005) Akihisa et al. (2005) Akihisa et al. (2005); Sato et al. (2009b) Akihisa et al. (2005) Yang et al. (2007) Nishitoba et al. (1986a) Nishitoba et al. (1987c) Nishitoba et al. (1987c) Nishitoba et al. (1987c) Nishitoba et al. (1987c) Nishitoba et al. (1987c) Nishitoba et al. (1987c) Mizushina et al. (1999) Akihisa et al. (2005); Sato et al. (2009b) Sato et al. (2009b) Liu et al. (2012b) Zhang et al. (2011b) Cheng et al. (2010) Niu et al. (2004) Niu et al. (2004); Peng et al. (2014b) Peng et al. (2014b) Peng et al. (2014b) Wang et al. (2010a)
G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G. G.
lucidum lucidum, lucidum sinense cochlear cochlear cochlear lucidum, hainanense lucidum lucidum, lucidum lucidum, hainanense lucidum lucidum lucidum lucidum lucidum lucidum lucidum lucidum lucidum lucidum lucidum sinense lucidum sinense
Mizushina et al. (1999) Wang et al. (1997b); Wu et al. (1997) Qiao et al. (2007) Peng et al. (2014b) Peng et al. (2014b) Peng et al. (2014b) Iwatsuki et al. (2003); Ma et al. (2013) Cheng et al. (2010) Wu et al. (2001); Zhang et al. (2011a) Lee et al. (2010a); Ma et al. (2013) Iwatsuki et al. (2003) Iwatsuki et al. (2003) Iwatsuki et al. (2003) Li et al. (2013b) Lee et al. (2010b) Lee et al. (2010b) Lee et al. (2010a) Tung et al. (2013) Tung et al. (2013) Tung et al. (2013) Tung et al. (2013) Liu et al. (2012b) Akihisa et al. (2005) Wang et al. (2010a)
75
S. Baby et al. / Phytochemistry 114 (2015) 66–101 Table 1 (continued) Compound number
Compound name
(e) C24, C25 lanostanes 344 Lucidone A
345 346 347
Lucidone B Lucidone C Lucidone D
348 349 350 351 352 353
Lucidone E Lucidone F Lucidone G Lucidone H 8a,9a-Epoxy-4,4,14a-trimethyl-3,7,11,15,20-pentaoxo-5a-pregnane Ganosineniol A
(f) C30 pentacyclic triterpenes 354 Friedelin 355 356 357
Alnusenone b-Amyrenone b-Amyrin acetate
(g) Meroterpenoids 358 Fornicin A 359 Fornicin B 360 Fornicin C 361 Ganocin A 362 Ganocin B 363 Ganocin C 364 Ganocin D 365 Lingzhiol (h) Farnesyl hydroquinones (meroterpenoids) 366 Farnesyl hydroquinone 367 Ganomycin A 368 Ganomycin B 369 370
Ganomycin I Ganomycin K
(i) C15 sesquiterpenoids 371 Ganosinensine 372 Ganomastenol A 373 Ganomastenol B 374 Ganomastenol C 375 Ganomastenol D 376 Echinolactone D 377 Ganodermycin 378 Cryptoporic acid H 379 Cryptoporic acid I (j) Steroids 380
Ergosterol
381
Ergosta-7,22-dien-3b-ol (stellasterol; 5,6-dihydroergosterol)
382 383
22,23-Dihydroergosterol Ergosterol peroxide (5,8-epidioxy-5a-8a-ergosta-6,22E-dien-3-bol)
Ganoderma species
References
G. G. G. G. G. G. G. G. G. G. G. G. G. G.
lucidum, amboinense, applanatum, resinaceum lucidum lucidum resinaceum, tropicum resinaceum resinaceum resinaceum resinaceum concinna sinense
Nishitoba et al. (1985a); Lin et al. (1993); Gan et al. (1998b); Peng et al. (2013) Nishitoba et al. (1985a) Nishitoba et al. (1986a) Peng et al. (2013); Hu et al. (2014) Peng et al. (2013) Peng et al. (2013) Peng et al. (2013) Peng et al. (2013) Gonzalez et al. (2002) Liu et al. (2012b)
G. G. G. G. G.
applanatum, cochlear applanatum applanatum applanatum
Nishitoba et al. (1989); Peng et al. (2014b) Nishitoba et al. (1989) Ming et al. (2002) Ming et al. (2002)
G. G. G. G. G. G. G. G.
fornicatum fornicatum fornicatum cochlear cochlear cochlear cochlear lucidum
Niu et al. (2006) Niu et al. (2006) Niu et al. (2006) Peng et al. (2014a) Peng et al. (2014a) Peng et al. (2014a) Peng et al. (2014a) Yan et al. (2013)
G. G. G. G. G. G.
pfeifferi pfeifferi pfeifferi, colossum colossum pfeifferi
Niedermeyer et al. (2013) Mothana et al. (2000) Mothana et al. (2000); El Dine et al. (2009) El Dine et al. (2009) Niedermeyer et al. (2013)
G. G. G. G. G. G. G. G. G.
sinense mastoporum mastoporum mastoporum mastoporum applanatum applanatum neo-japonicum neo-japonicum
Liu et al. (2012b) Hirotani et al. (1995) Hirotani et al. (1995) Hirotani et al. (1995) Hirotani et al. (1995) Fushimi et al. (2010) Jung et al. (2011) Hirotani et al. (1991) Hirotani et al. (1991)
G. lipsiense, G. applanatum, G. australe, G. fornicatum, G. colossum, G. lucidum, Ganoderma sp. KM01 G. lucidum, G. amboinense, G. carnosum, G. tsugae, G. applanatum, G. neo-japonicum, G. lipsiense, G. australe, G. annulare, G. pfeifferi, G. lucidum, G. sinense G. lucidum G. amboinense, G. carnosum, G. lucidum, G. concinna,
Rosecke and Konig (2000); Ming et al. (2002); León et al. (2003); Qiao et al. (2006); El Dine et al. (2008b); Seo et al. (2009); Lakornwong et al. (2014) Lin et al. (1990); Lin et al. (1993); Keller et al. (1997); Lin et al. (1997); Gan et al. (1998b); Gan et al. (1998b); Rosecke and Konig (2000); León et al. (2003); Smania et al. (2003); Niedermeyer et al. (2005); Seo et al. (2009); Sato et al. (2009b) González et al. (1999) Lin et al. (1993); Keller et al. (1997); Mizushina et al. (1998b); Gonzalez et al. (2002); (continued on next page)
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S. Baby et al. / Phytochemistry 114 (2015) 66–101
Table 1 (continued) Compound number
Compound name
Ganoderma species
References
G. australe, G. annulare, G. pfeifferi, G. applanatum, G. fornicatum, G. sinense, G. lucidum, G. tsugae G. amboinense, G. applanatum, G. lucidum, G. tsugae G. lucidum G. lucidum, G. applanatum G. lucidum, G. applanatum G. lucidum, G. tsugae, G. neo-japonicum G. applanatum G. lucidum, G. applanatum, G. sinense G. lucidum G. lucidum G. amboinense G. lucidum G. lucidum G. lucidum G. lucidum G. lucidum G. lucidum G. lucidum G. applanatum, G. neo-japonicum, G. lucidum, G. pfeifferi G. australe, G. lucidum, G. applanatum, G. neo-japonicum, G. lipsiense, G. concinna G. lucidum G. lucidum, G. applanatum, G. neo-japonicum G. lucidum, G. amboinense, G. lipsiense G. lipsiense G. lucidum G. lipsiense,
(24S)-24-Methyl-5a-cholest-7-ene-3b-ol (24S)-24-Methyl-5a-cholest-7,l6-diene-3b-ol b-Sitosterol Daucosterol
G. G. G. G. G. G. G. G. G.
lucidum lucidum, concinna, annulare, australe applanatum applanatum lucidum applanatum
León et al. (2003); Smania et al. (2003); Niedermeyer et al. (2005); Lee et al. (2006); Qiao et al. (2006); Sato et al. (2009b); Wu et al. (2012); Lin et al. (2013) Lin et al. (1993); Gan et al. (1998b); Chen et al. (2009b); Lin et al. (2013) El-Mekkawy et al. (1998) Zhang et al. (2008); Lee et al. (2011b) Zhang et al. (2008); Lee et al. (2011b) Lin et al. (1991); Gan et al. (1998a); Gan et al. (1998b) Lee et al. (2011b) El-Mekkawy et al. (1998); Lee et al. (2006); Sato et al. (2009b) Zhang et al. (2008) Zhang et al. (2008) Lin et al. (1993) Nishitoba et al. (1988b) Nishitoba et al. (1988b) Hirotani et al. (1987) Weng et al. (2010) Weng et al. (2010) Weng et al. (2011) Weng et al. (2011) Gan et al. (1998b); Gan et al. (1998b); González et al. (1999); Niedermeyer et al. (2005) Jain and Gupta (1984); Lin et al. (1990); Gan et al. (1998b); Gan et al. (1998b); Rosecke and Konig (2000); Gonzalez et al. (2002) Ziegenbein et al. (2006) Lin et al. (1990); Gan et al. (1998b); Gan et al. (1998b) Lin et al. (1991); Lin et al. (1993); Rosecke and Konig (2000) Rosecke and Konig (2000) Lin et al. (1991) Rosecke and Konig (2000); Ziegenbein et al. (2006) González et al. (1999); Gonzalez et al. (2002); Smania et al. (2003); Smania et al. (2007) Strigina et al. (1971) Strigina et al. (1971) Joseph et al. (2011a) Lee et al. (2005)
Ganoderma alkaloid A Ganoderma alkaloid B Sinensine Sinensine B Sinensine C Sinensine D Sinensine E
G. G. G. G. G. G. G.
capense capense sinense sinense sinense sinense sinense
Yang and Yu (1990) Yang and Yu (1990) Liu et al. (2010) Liu et al. (2011) Liu et al. (2011) Liu et al. (2011) Liu et al. (2011)
384
5a,8a-Epidioxyergosta-6,9(11),22-trien-3b-ol (9,11-Dehydroergosterol peroxide)
385 386
3b,5a-Dihydroxy-6b-methoxy ergosta-7,22-diene 3b,5a-Dihydroxy-(22E,24R)-ergosta-7,22-dien-6-one (6-dehydrocerevisterol)
387
3b,5a,9a-Trihydroxy-(22E,24R)-ergosta-7,22-dien-6-one
388
Ergosta-7,22-diene-2b,3a,9a-triol
389 390
3b,5a,6b,8b,14a-Pentahydroxy-(22E,24R)-ergost-22-en-7-one 22E,24R-Ergosta-7,22-diene-3b,5a,6b-triol (cerevisterol)
391 392 393 394 395 396 397 398 399 400 401
22E,24R-Ergosta-7,22-diene-3b,5a,6b,9a-tetraol 22E,24R-Ergosta-7,22-diene-3b,5a,6b,9a,14a-pentol 2b-Methoxyl-3a,9a-dihydroxyergosta-7,22-diene 6a-Hydroxy-ergosta-4,7,22-trien-3-one 6b-Hydroxy-ergosta-4,7,22-trien-3-one Ergosta-4,7,22-triene-3,6-dione Ganodermaside A Ganodermaside B Ganodermaside C Ganodermaside D Ergosta-4,6,8(14),22-tetraen-3-one
402
Ergosta-7,22-dien-3-one
403 404
Ergosta-7,22-diene-3b-yl pentadecanoate Ergosta-7,22-dien-3b-yl palmitate
405
Ergosta-7,22-dien-3b-yl linoleate
406 407 408
3b-Linoleyloxyergosta-7,24(28)-diene 5a,8a-Epidioxy ergosta-6,22-dien-3b-yl linoleate Ergosta-7-ene-3b-yl linoleate
409
Fungisterol (5a-ergost-7-en-3b-ol)
410 411 412 413 (k) Alkaloids 414 415 416 417 418 419 420
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S. Baby et al. / Phytochemistry 114 (2015) 66–101 Table 1 (continued) Compound number
Compound name
Ganoderma species
References
(l) Prenyl hydroquinone 421 Ganoderma aldehyde
G. applanatum
Ming et al. (2002)
(m) Benzofurans 422 423
G. tsugae G. lucidum
La Clair et al. (2011) Adams et al. (2010)
(n) Benzopyran-4-one derivatives 424 Applanatine A 425 Applanatine B 426 Applanatine C 427 Applanatine D 428 Applanatine E
G. G. G. G. G.
Fushimi Fushimi Fushimi Fushimi Fushimi
(o) Benzenoid derivatives 429 2,5-Dihydroxy benzoic acid 430 2,5-Dihydroxyacetophenone 431 Protocatechualdehyde
G. applanatum G. applanatum G. applanatum
Ganodone Ganofuran B
applanatum applanatum applanatum applanatum applanatum
et et et et et
al. al. al. al. al.
(2010) (2010) (2010) (2010) (2010)
Ming et al. (2002) Lee et al. (2005) Lee et al. (2005)
Naming issues and other related facts on secondary metabolites from Ganoderma are listed in Table S1. In Table S1, compounds are listed in the order of their trivial names, keeping the compound numbers same as in this Table. Author citations in bold indicate references with NMR data, and the citations which are not in bold indicate repeated reports of compounds, and they do not list NMR data. G. applanatum and G. lipsiense are synonyms.
G. lucidum (C30 ganoderic acids 112, other C30 lanostanes 55, C27 lucidenic acids 27, other C27 lanostanes 18, C24 lanostanes 3, meroterpenoid 1, steroids 23, benzofuran 1). Only 63, 49, 22, 19, 18, 16, 16, 15, 14, 13, 10 and 2 secondary metabolites were reported from G. applanatum/G. lipsiense (C30 ganoderic acids 28, other C30 lanostanes 2, C24 lanostane 1, C30 pentacyclic triterpenes 4, C15 sesquiterpenoids 2, steroids 17, prenyl hydroquinone 1, benzopyran-4-one derivatives 5, benzenoid derivatives 3), G. sinense, G. amboinense, G. colossum, G. pfeifferi, G. resinaceum, G. cochlear, G. concinna, G. australe, G. orbiforme, G. fornicatum and G. capense, respectively (Table 1, Fig. 1). C30 lanostanes, ganoderic acid A (1) and B (2) were first isolated by Kubota and co-workers from G. lucidum fruiting bodies in 1982 (Kubota et al., 1982). The second major group of triterpenoid constituents isolated from Ganoderma was lucidenic acids with the C27 skeleton. Nishitoba and co-workers isolated bitter C27 lucidenic acids for the first time from the mycelial part of G. lucidum in 1984 (Nishitoba et al., 1984). Their structures were elucidated as lucidenic acid A (285), B (286) and C (287) (Nishitoba et al., 1985a,c). Further, highly oxygenated lanostane type triterpenoids ganoderic acids C1 (3) to O (17), O (37), P (66) to T (71), U (38) to W (40), X (72), Y (73), Z (41) and lucidenic acids D1 (288), D2 (289), E1 (290), E2 (291), F (292), G (302) to M (308), N (293), O (309), P (294) were isolated from the fruiting bodies and cultured mycelia of various Ganoderma species (Table 1, Fig. 1). Another group of structurally very similar ganoderenic acids A (125), B (126), C (127) and D (128) were isolated from the dried fruiting bodies of G. lucidum by Komoda and co-workers in 1985 along with ganoderic acid E (6), F (7), G (8) and lucidenic acid D (lucidenic acid D2, 289) (Table 1, Fig. 1) (Komoda et al., 1985). Several other lanostane type terpenoids were also isolated from various Ganoderma species (Table 1, references therein). Ganoderic alcohols named ganoderiol A (197), B (179), C (198), D (199), E (202), F (180), G (200), H (201), I (203), J (204) were isolated from G. lucidum, G. concinna, G. sinense, G. hainanense and G. amboinense (Table 1, Fig. 1). Epoxyganoderiol A (215), B (217), C (218) having epoxy functionalities at the side-chain of ganoderiols were reported by Nishitoba et al. (1988b). C30 lanostanes with aldehydic functionality at the side-chain, ganoderal A (172), B (184), ganoderic aldehyde A (189) and TR (174), were also reported (Adams et al., 2010; Lin et al., 1990; Morigiwa et al., 1986; Nishitoba et al., 1988b). Similarly, lucidal (185) and lucialdehydes A (173), B (186), C (lucidal, 185), D (187), E (188) with an aldehydic group in the side-chain were reported from G. lucidum, G. pfeifferi and
G. concinna (Gao et al., 2002; González et al., 1999; Ma et al., 2012; Niedermeyer et al., 2005). So far, 284 C30 lanostane compounds (1–284) were identified from genus Ganoderma (Table 1, Fig. 1). Most C30 lanostanes (1–284) have a C8–C9 double bond, and a second group has two double bonds at C7–C8 and C9–C11 in their tetracyclic skeleton (Table 1, Fig. 1). 8b,9a-Dihydroganoderic acid C (118), 8b,9a-dihydroganoderic acid J (119), ganosporeric acid A (120), methyl 8b,9a-dihydroganoderate J (243), ganoderesin B (244) and 24n-methyl-5a-lanosta-25-one (284) have no double bonds in their four skeletal rings (Fig. 1). 8a,9a-Epoxy3,7,11,15,23-pentaoxo-5a-lanosta-26-oic acid (159), instead of a double bond, has an epoxy group between C8 and C9. Ganorbiformin A (122), tsugaric acid E (166), fornicatin C (214) and ganoderesin A (246) have unusual double bonds at C8–C14, C6–C7, C13–C17 and C16–C17, respectively. Applanoxidic acid A (139), B (140), C (143), D (144), E (141), F (142), G (145), H (146), australic acid (280) and methyl australate (281) have epoxy groups between C7 and C8 along with C9–C11 double bonds (Table 1, Fig. 1). In most cases, the acid groups in ganoderic acids are found at the end of the side-chain (C26). In some cases, however, acid groups are found at C21 (tsugaric acid A (160), B (164), C (165), D (161), E (166), 3b-hydroxy-5a-lanosta-8,24-dien-21oic acid (162), 3-oxo-5a-lanosta-8,24-dien-21-oic acid (163), 3aacetoxy-16a-hydroxy-24-methylene-5a-lanost-8-en-21-oic acid or 3-epipachymic acid (167), 3a-(3-hydroxy-5-methoxy-3methyl-1,5-dioxopentyloxy)-24-methylene-5a-lanost-8-en-21-oic acid (168), 3a,16a-dihydroxylanosta-7,9(11),24-trien-21-oic acid (169), 3a,16a,26-trihydroxylanosta-7,9(11),24-trien-21-oic acid (170), 16a-hydroxy-3-oxolanosta-7,9(11),24-trien-21-oic acid (171)). Double bonds in ganoderic acid side-chains are found at C24–C25, and at C20–C22 in relatively few cases. Ganoderic acid I (10), L (14), N (16), O (17), AP (19), AP3 (20), V1 (108), XL1 (109), XL2 (110), 20-hydroxy ganoderic acid G (26), 20-hydroxy ganoderic acid AM1 (27), 3b,7b,20,23n-tetrahydroxy11,15-dioxolanosta-8-en-26-oic acid (123), 7b,20,23n-trihydroxy3,11,15-trioxolanosta-8-en-26-oic acid (124), applanoxidic acid C (143), D (144), G (145) and H (146) have hydroxyl substitutions at C20 along with carboxyl groups in their side-chains. Similarly, ganoderic acid LM2 (95), c (96), d (97), e (98), n (99), g (100), h (101), Jc (111), ganolucidic acid D (102), ca (104), ganolucidate F (105), 23-hydroxy ganoderic acid S (117), 3b,7b,20,23n-tetrahydroxy-11,15-dioxolanosta-8-en-26-oic acid (123), 7b,20,23n-trihydroxy-3,11,15-trioxolanosta-8-en-26-oic acid (124) and 7b, 23n-dihydroxy-3,11,15-trioxolanosta-8,20E(22)-dien-26-oic acid (138)
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S. Baby et al. / Phytochemistry 114 (2015) 66–101
(a) C30 lanostanes, ganoderic acids R4 R3
12
19
1
R1
9
3
5
29
28
21 18
R6 20
23 25
O
17
COOH
27 8
30
R2
R5
32
R1 = O, R2 = H, R3 = O, R4 = H, R5 = α-OH, R6 = H
33
R1 = β-OH, R2 = H, R3 = O, R4 = H, R5 = α-OH, R6 = H
34
R1 = β-OH, R2 = α-OH, R3 = O, R4 = H, R5 = α-OH, R6 = H
35
R1 = O, R2 = O, R3 = O, R4 = β-OH, R5 = O, R6 = H
36
R1 = OH, R2 = O, R3 = O, R4 = OAc, R5 = OAc, R6 = H R5
1
R1 = O, R2 = β-OH, R3 = O, R4 = H, R5 = α-OH, R6 = H
2
R1 = β-OH, R2 = β-OH, R3 = O, R4 = H, R5 = O, R6 = H
3
R1 = O, R2 = β-OH, R3 = O, R4 = H, R5 = O, R6 = H
COOH
R3
R1
R2
R4
4
R1 = β-OH, R2 = β-OH, R3 = O, R4 = H, R5 = α-OH, R6 = H
5
R1 = O, R2 = β-OH, R3 = O, R4 = β-OH, R5 = O, R6 = H
37
R1 = α-OAc, R2 = α-OH, R3 = H, R4 = α-OAc, R5 = β-OAc
6
R1 = O, R2 = O, R3 = O, R4 = H, R5 = O, R6 = H
38
R1 = α-OH, R2 = α-OH, R3 = H, R4 = H, R5 = H
7
R1 = O, R2 = O, R3 = O, R4 = β-OAc, R5 = O, R6 = H
39
R1 = O, R2 = α-OH, R3 = H, R4 = α-OAc, R5 = H
8
R1 = β-OH, R2 = β-OH, R3 = O, R4 = β-OH, R5 = O, R6 = H
40
R1 = α-OAc, R2 = α-OH, R3 = H, R4 = α-OAc, R5 = H
9
R1 = β-OH, R2 = O, R3 = O, R4 = β-OAc, R5 = O, R6 = H
41
R1 = β-OH, R2 = H, R3 = H, R4 = H, R5 = H
10
R1 = β-OH, R2 = β-OH, R3 = O, R4 = H,R5 = O, R6 = ξ-OH
42
R1 = O, R2 = β-OH, R3 = O, R4 = O, R5 = H
11
R1 = O, R2 = O, R3 = O, R4 = H, R5 = α-OH, R6 = H
43
R1 = O, R2 = β-OH, R3 = O, R4 =α-OH, R5 = H
12
R1 = β-OH, R2 = β-OH, R3 = O, R4 = β-OAc,R5 = O, R6 = H
44
R1 = α-OAc, R2 = α-OAc, R3 = H, R4 = α-OH, R5 = H
13
R1 = β-OH, R2 = O, R3 = O, R4 = H, R5 = α-OH, R6 = H
45
R1 = α-OAc, R2 = α-OAc, R3 = H, R4 = α-OH, R5 = ξ-OAc
14
R1 = β-OH, R2 = β-OH, R3 = O, R4 = H,R5 = α-OH, R6 = ξ-OH
46
R1 = α-OAc, R2 = α- OMe, R3 = H, R4 = H, R5 = ξ-OAc
15
R1 = O, R2 = β-OH, R3 = O, R4 = α-OH, R5 = O, R6 = H
47
R1 = α-OAc, R2 = α- OMe, R3 = H, R4 = α-OH, R5 = ξ-OAc
16
R1 = O, R2 = β-OH, R3 = O, R4 = H, R5 = O, R6 = ξ-OH
48
R1 = α-OAc, R2 = α-OH, R3 = H, R4 = α-OH, R5 = ξ-OAc
17
R1 = O, R2 = O, R3 = O, R4 = H, R5 = O, R6 = ξ-OH
49
R1 = α-OAc, R2 = α-OMe, R3 = H, R4 = α-OH, R5 = H
18
R1 = β-OH, R2 = O, R3 = O, R4 = H, R5 = O, R6 = H
50
R1 = α-OH, R2 = α-OMe, R3 = H, R4 = H, R5 = ξ-OAc
19
R1 = O, R2 = O, R3 = O, R4 = β-OH, R5 = α-OH, R6 = ξ-OH
51
R1 = β-OH, R2 = β-OH, R3 = O, R4 = O, R5 = H
20
R1 = O, R2 = O, R3 = O, R4 =H, R5 = α-OH, R6 = ξ-OH
52
R1 = α-OAc, R2 = α-OMe, R3 = H, R4 = α-OAc, R5 = β-OAc
21
R1 = O, R2 = α-OH, R3 = O, R4 = H, R5 = α-OH, R6 = H
53
R1 = α-OAc, R2 = α-OEt, R3 = H, R4 = α-OAc, R5 = ξ-OAc
22
R1 = β-OH, R2 = O, R3 = O, R4 = β-OH, R5 = O, R6 = H
54
R1 = β-OH, R2 = O, R3 = H, R4 = H, R5 = H
23
R1 = O, R2 = β-OH, R3 = β-OH, R4 = H, R5 = O, R6 = H
55
R1 = β-OH, R2 = O, R3 = O, R4 = H, R5 = H
24
R1 = β-OH, R2 = O, R3 = O, R4 = β-OAc, R5 = β-OH, R6 = H
56
R1 = β-OH, R2 = O, R3 = H, R4 = α-OH, R5 = H
25
R1 = β-OH, R2 = β-OH, R3 = O, R4 = OH, R5 = α-OH, R6 = H
57
R1 = β-OAc, R2 = O, R3 = H, R4 = H, R5 = β-OAc
26
R1 = β-OH, R2 = β-OH, R3 = O, R4 = β-OH, R5 = O, R6 = OH
58
R1 = β-OH, R2 = O, R3 = H, R4 = H, R5 = β-OAc
27
R1 = β-OH, R2 = O, R3 = O, R4 = H, R5 = O, R6 = ξ-OH
59
R1 = O, R2 = α-OH, R3 = H, R4 = α-OAc, R5 = β-OAc
28
R1 = β-OAc, R2 = β-OH, R3 = O, R4 = H, R5 = O, R6 = H
60
R1 = O, R2 = α-OH, R3 = H, R4 = H, R5 = β-OAc
29
R1 = β-OAc, R2 = O, R3 = O, R4 = β-OAc, R5 = O, R6 = H
61
R1 = O, R2 = α-OMe, R3 = H, R4 = H, R5 = β-OAc
30
R1 = β-OAc, R2 = O, R3 = O, R4 = H, R5 = α-OH, R6 = H
62
R1 = α-OAc, R2 = α-OH, R3 = H, R4 = H, R5 = β-OAc
31
R1 = O, R2 = β-OH, R3 = O, R4 = OAc, R5 = O, R6 = H
63
R1 = β-OAc, R2 = H, R3 = H, R4 = α-OAc, R5 = H
Fig. 1. Secondary metabolites isolated from various Ganoderma species.
79
S. Baby et al. / Phytochemistry 114 (2015) 66–101
64
R1 = O, R2 = O, R3 = α-OH, R4 = H, R5 = H
65
R1 = O, R2 = O, R3 = β-OH, R4 = H, R5 = H
R1 = β-OH, R2 = α-OH, R3 = β-OAc
93
R3 COOH
O
R3
R5
COOH R2
R1
R1
R2
R4
94
R1 = β-OH, R2 = H, R3 = β-OAc, R4 = α-OAc, R5 = H
95
R1 = O, R2 = β-OH, R3 = H, R4 = O, R5 = OH
66
R1 = α-OH, R2 = α-OAc, R3 = β-OAc
96
R1 = O, R2 = β-OH, R3 = H, R4 = α-OH, R 5 = β-OH
67
R1 = α-OAc, R2 = α-OH, R3 = β-OAc
97
R1 = O, R2 = α-OH, R3 = H, R4 = α-OH, R 5 = β-OH
68
R1 = α-OAc, R2 = H, R3 = β-OAc
98
R1 = β-OH, R2 = β-OH, R3 = H, R4 = O, R 5 = β-OH
69
R1 = α-OH, R2 = H, R3 = β-OAc
99
R1 = β-OH, R2 = O, R3 = H, R4 = O, R 5 = β-OH
70
R1 = O, R2 = H, R3 = H
100
R1 = β-OH, R2 = β-OH, R3 = β-OH, R4 = O, R 5 = β-OH
71
R1 = α-OAc, R2 = α-OAc, R3 = β-OAc
101
R1 = β-OH, R2 = O, R3 = β-OH, R4 = O, R5 = β-OH
72
R1 = α-OH, R2 = α-OAc, R3 = H
102
R1 = O, R2 = H, R3 = H, R4 = α-OH, R 5 = β-OH
73
R1 = β-OH, R2 = H, R3 = H
103
R1 = O, R2 = H, R3 = H, R4 = α-OH, R 5 = H
74
R1 = α-OAc, R2 = α-OAc, R3 = H
104
R1 = β-OH, R2 = β-OH, R3 = H, R4 = α-OH, R 5 = OH
75
R1 = α-OAc, R2 = α-OH, R3 = H
105
R1 = β-OH, R2 = H, R3 = H, R4 = α-OH, R5 = OH
76
R1 = O, R 2 = β-OH, R3 = H
77
R1 = O, R 2 = α-OH, R3 = H
78
R1 = β-OAc, R2 = α-OAc, R3 = H
79
R1 = α-OH, R2 = α-OH, R3 = H
80
R1 = β-OH, R2 = α-OH, R3 = H
81
R1 = β-OH, R2 = α-OAc, R3 = β-OAc
82
R1 = β-OH, R2 = α-OAc, R3 = H
83
R1 = β-OAc, R2 = α-OH, R3 = H
84
R1 = O, R2 = α-OAc, R3 = H
85
R1 = O, R2 = H, R3 = β-OAc
86
R1 = α-OAc, R2 = α-OH, R3 = β-OH
87
R1 = β-OAc, R2 = α-OAc, R3 = β-OAc
88
R1 = α-OH, R2 = α-OH, R3 = α-OH
89
R1 = β-OH, R2 = α-OH, R3 = β-OH
90
R1 = α-OAc, R2 = α-OAc, R3 = α-OH
91
R1 = β-OAc, R2 = α-OAc, R3 = α-OH
R1
92
R1 = α-OH, R2 = α-OH, R3 = β-OAc
111
COOH
O
O
106
R4
R2
COOH
O
HO
R1
R3
107
R1 = β-OH, R2 = β-OAc, R3 = O, R4 = H
108
R1 = O, R2 = H, R3 = O, R4 = OH
109
R1 = β-OH, R2 = H, R3 = α-OH, R4 = OH
110
R1 = α-OH, R2 = H, R3 = α-OH, R4 = OH
COOH R3 R2
R1 = O, R2 = OH, R3 = OH
Fig. 1 (continued)
have hydroxyl group substitutions at C23 along with carboxyl groups in their side-chains. Lanosta-7,9(11),24-trien-3a-acetoxy15a,22b-dihydroxy-26-oic acid (86), 3a,15a,22a-trihydroxylanosta-7,9(11),24-trien-26-oic acid (88), 3b,15a,22b-trihydrox
ylanosta-7,9(11),24-trien-26-oic acid (89), 3a,15a-diacetoxy22a-hydroxylanosta-7,9(11),24-trien-26-oic acid (90), 3b,15a-diacetoxy-22a-hydroxylanosta-7,9(11),24-trien-26-oic acid (91), 3b,22S-dihydroxylanosta-7,9(11),24-triene (208), colossolactone
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S. Baby et al. / Phytochemistry 114 (2015) 66–101
124
R=O
R1 = α-OAc, R2 = OH, R3 = O
112
R3 O
113
R1 = α-OH, R2 = OAc, R3 = O
114
R1 = α-OAc, R2 = OAc, R3 = O R2
R1
R3
115
R1 = O, R2 = H, R3 =H
116
R1 = O, R2 = α-OH, R3 =H
117
R1 = OH, R2 = H, R3 =OH R1 O H H
O
COOH
O
O
R2
118
R1 = H, R2 = O
119
R1 = H, R2 = α-OH
120
R1 = O, R2 = O
R4
125
R1 = O, R2 = β-OH, R3 = H, R4 = α-OH
126
R1 = β-OH, R2 = β-OH, R3 = H, R4 = O
127
R1 = β-OH, R2 = β-OH, R3 = H, R4 = α-OH
128
R1 = O, R2 = β-OH, R3 = H, R4 = O
129
R1 = O, R2 = β-OH, R3 = β-OH, R4 = O
130
R1 = O, R2 = O, R3 = H, R4 = O
131
R1 = O, R2 = O, R3 = H, R4 = α-OH
132
R1 = β-OH, R2 = O, R3 = H, R4 = O
133
R1 = β-OH, R2 = O, R3 = H, R4 = α-OH
134
R1 = β-OH, R2 = β-OH, R3 = β-OAc, R4 = O
135
R1 = O, R2 = O, R3 = α-OH, R4 = β-OH
136
R1 = O, R2 = β-OH, R3 = β-OAc, R4 = O
COOH
R2
R1
O O
COOH
O
HO
O
O
COOH
O
137
OH
HO
COOH
O
O
OH
COOH HO
121
O
COOH
138
HO
O
OH O
OH
O
OAc
OH
O O
122
R1
COOH
R2
OH COOH
O OH
R
123
OH
O
139
R1 = O, R2 = α-OH
140
R1 = β-OH, R2 = O
141
R1 = O,R2 = β-OH
R = β-OH Fig. 1 (continued)
A (212) and ganodercochlearin C (221) have hydroxyls at C22 and tsugaric acid C (165), ganodermanondiol (192), ganoderitriol M (194), ganodermanontriol (196), ganoderiol A (197), C (198), D (199), G (200), H (201), lucidumol A (195), B (193) and ganoderesin
B (244) have hydroxyls at C24. Ganoderic acid (C30 lanostane) side-chains also have keto, acetyl, furano (furanoganoderic acid (155)) and ethylenic (3a-carboxyacetoxy-24-methylene-23oxolanost-8-en-26-oic acid (157)) substitutions along with
81
S. Baby et al. / Phytochemistry 114 (2015) 66–101
142
R1 = O,R2 = O R2
153 OH
OAc
COOH
O O R1
AcO HOOC
R3
MeOOC
143
R1 = O, R2 = O, R3 = O
144
R1 = β-OH, R2 = O, R3 = O
145
R1 = O, R2 = O, R3 = β-OH
146
R1 = β-OH, R2 = α-OH, R3 = O
HO
154 COOH O
O
R1 COOH
O
O
O HO
OH
O
OH
R2
155 147
R1 = H, R2 = O
148
R1 = H, R2 = β-OH
149
R1 = β-OAc, R2 = O
R
O O O
O
COOH
156
H O
HO
COOH
O
H
OH
R=
O
O COOH
157
150
R=
O
OH COOH
O
COOH
O
158
R=
O
O
HO
O
O O
O
151 O O
H OH
152
O
COOH
O
OH
O
159
HOOC
O
OAc
R1
AcO HOOC MeOOC
HO
Fig. 1 (continued)
160
R1 = α-OAc, R2 = H
161
R1 = α-OAc, R2 = O
R2
COOH
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S. Baby et al. / Phytochemistry 114 (2015) 66–101
162
R1 = β-OH, R2 = H
172
R1 = O, R2 = H, R3 = Me, R4 = CHO
163
R1 = O, R2 = H
173
R1 = β-OH, R2 = H, R3 = Me, R4 = CHO
174
R1 = O, R2 = α-OH, R3 = CHO, R4 = Me
175
R1 = O, R2 = H, R3 = Me, R4 = CH2OH
176
R1 = β-OH, R2 = H, R3 = Me, R4 = CH2OH
177
R1 = β-OH, R2 = H, R3 = CH2OH, R4 = CH2OH
178
R1 = β-OH, R2 = α-OH, R3 = CH2OH, R4 = CH2OH
179
R1 = O, R2 = α-OH, R3 = CH2OH, R4 = CH2OH
180
R1 = O, R2 = H, R3 = CH2OH, R4 = CH2OH
181
R1 = O, R2 = α-OH, R3 = Me, R4 = CH2OH
182
R1 = β-OH, R2 = α-OH, R3 = Me, R4 = Me
183
R1 = β-OH, R2 = H, R3 = Me, R4 = Me
R2
HOOC
R1
AcO
164
R1 = α-OH, R2 = Me
165
R1 = H, R2 = OH HOOC
OH
O
R3
166
CHO
HOOC
R1
R2
R4
R2
R1
167
R1 = α-OAc, R2 = α-OH O HO
168
R1 = α-
O OMe ,
O
R2 = H
184
R1 = O, R2 = α-OH, R3 = H, R4 = H
185
R1 = β-OH, R2 = O, R3 = H, R4 = H
186
R1 = O, R2 = O, R3 = H, R4 = H
187
R1 = O, R2 = O, R3 = O, R4 = H
188
R1 = O, R2 = β-OH, R3 = O, R4 = α-OH
HOOC
O CHO
R2
OH
HO
R1
189 169
R1 = α-OH, R2 = H
170
R1 = α-OH, R2 = OH
171
R1 = O, R2 = H
R2
O
(b) C30 lanostanes, others (aldehydes, alcohols, esters, glycosides, lactones, ketones)
OH
R1
190
R1 = O, R2 = H
191
R1 = H, R2 = α-OH OH
R4 R3 R1
OH
R2
R
Fig. 1 (continued)
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S. Baby et al. / Phytochemistry 114 (2015) 66–101
205 192
R=O
193
R = β-OH
OH
O O
OH OH
HO
OH
OH
206 R
O
194
R = β-OH
195
R=O
R2
R1
R2 HO
OH OH
207
R1 = CH2OH, R2 = H
208
R1 = Me, R2 = α-OH
R1
196
R1 = O, R2 = α-OH
197
R = β-OH, R2 = OH
O
OH
O
OH R1
R2
198
R1 = O, R2 = α-OEt
199
R1 = O, R2 = O
200
R1 = O, R2 = α-OMe
201
R1 = β-OH, R2 = O
OH
R
OH
209
R = Me
210
R = CH2OH
OH
O OH O
211
OH
OH
OH R3
R1
R2
202
R1 = β-OH, R2 = O, R3 = H
203
R1 = O, R2 = α-OMe, R3 = α-OH
204
R1 = O, R2 = O, R3 = H
AcO OH HO
212 OAc
OH
OH
OAc HO
O
AcO
Fig. 1 (continued)
carboxylic (acid) groups. Other C30 lanostanes (other than ganoderic acids) such alcohols, esters, aldehydes, epoxy-alcohols, ketones (24n-methyl-5a-lanosta-25-one (284)), glycosides (ganosinoside A (251), tsugarioside A (252), B (253), C (254)),
lactones and farnesylhydroquinone adducts (ganosinensin A (222), B (223), C (224)) were also isolated from various Ganoderma species (Table 1, Fig. 1). These C30 lanostanes also show variations in double bond positions and substitutions in their
84
S. Baby et al. / Phytochemistry 114 (2015) 66–101
213
OH
221
COOH
OH
HO O HO
O
O OH
214
OH
H
O
O CH2OH
222 R
O
OH HO
215
R = α-OH
216
R=O
O
O
O OH
H
O
OH
CH2OH
OH
O
R
223 217 218
OH
R=O HO
R = β-OH
O
O
O
OH
OH
OH
HO
O
219
224 O
OH
R3 O
OH
R1
HO
O
R2
COOR 5
R4
225
R1 = O, R2 = β-OH, R3 = H, R4 = α-OH, R5 = Me
226
R1 = β-OH, R2 = β-OH, R3 = H, R4 = O, R5 = Me
227
R1 = β-OH, R2 = β-OH, R3 = H, R4 = α-OH, R5 = Me
228
R1 = O, R2 = β-OH, R3 = H, R4 = O, R5 = Me
229
R1 = O, R2 = O, R3 = H, R4 = O, R5 = Me
230
R1 = O, R2 = O, R3 = β-OAc, R4 = O, R5 = Me
231
R1 = β-OH, R2 = O, R3 = β-OAc, R4 = O, R5 = Me
220 OH
OMe
HO
Fig. 1 (continued)
85
S. Baby et al. / Phytochemistry 114 (2015) 66–101
249 232
R1 = O, R2 = O, R3 = H, R4 = α-OH, R5 = Me
233
R1 = β-OAc, R2 = O, R3 = β-OAc, R4 = O, R5 = Me
234
R1 = β-OH, R2 = β-OH, R3 = β-OAc, R4 = O, R5 = Me
R1 = β-OH, R2 = O O
O
235
R1 = Ο, R2 = O, R3 = H, R4 = α-OH, R5 = Et
236
R1 = β-OAc, R2 = β-OH, R3 = H, R4 = O, R5 = Et
237
R1 = O, R2 = O, R3 = β-OAc, R4 = O, R5 = Et
238
R1 = O, R2 = β-OH, R3 = H, R4 = α-OH, R5 = Bu
239
R1 = β-OH, R2 = β-OH, R3 = H, R4 = O, R5 = Bu
240
R1 = β-OH, R2 = O, R3 = β-OAc, R4 = O, R5 = Bu
241
R1 = β-OH, R2 = β-OH, R3 = β-OAc, R4 = O, R5 = Bu
242
R1 = O, R2 = O, R3 = β-OAc, R4 = O, R5 = Bu
O
H H R1
O
O
OH
250 R2OOC
R1
251
R1 = O, R2 = β-D-glucopyranosyl
252
R1 = α-OAc, R2 = β-D-glucosyl ROH2C
R2 O
COOM e
O
COOM e
OH
AcO
253
243
R1 = O, R2 = H
244
R1 = β-OH, R2 = β-OH
R = β-D-xylosyl ROOC
COOM e
O
AcO
O O
O
254
O
R = β-D-xylosyl OH O
245
O
O
O
H H HO
O
R
COOM e
OH
OH
255
R=O
256
R = OH
O
O
O O
246 R2
O
O
COOM e R1 HO
HO
R1
R2
247
R1 = β-OH, R2 = β-OH
248
R1 = O, R2 = β-OH Fig. 1 (continued)
257
R1 = H, R2 = H
258
R1 = β-OH, R2 = H
259
R1 = H, R2 = OAc
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S. Baby et al. / Phytochemistry 114 (2015) 66–101
R1 = H, R2 = OH
260
270b O O
O
AcO
H
MeO
O
O
O
O
261
271 R
O
O
O
O
HO
O
O
O
262
R=H
263
R = β-OH
272 HO
O O
O
AcO
AcO
MeOOC HO
Ac O HO
264
273 R4 R2
O
O
O
O
O
R3 O
R1
265
R1 = H, R2 = H, R3 = OAc, R4 = β-OH
266
R1 = H, R2 = H, R3 = OH, R4 = H
267
R1 = H, R2 = H, R3 = OAc, R4 = H
268
R1 = H, R2 = β-OH, R3 = OAc, R4 = H
269
R1 = H, R2 = H, R3 = H, R4 = H
270a
R1 = OH, R2 = H, R3 = OAc, R4 = H
O
O
274
O H O O
O O
O
OAc O
O
O OH
Fig. 1 (continued)
O
O
O
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S. Baby et al. / Phytochemistry 114 (2015) 66–101
275
282
O MeOOC
O
O
O
O
H O R
276
R = β-OAc
277
R=O
O
283
O
O
O
O
O
MeOOC
284
H OAc
(c) C27 lanostanes, lucidenic acids 278 R3 12
O
O 1
R1
HO
O O
ROOC O
280
R=H
281
R = Me
OAc
OH
O
O
OH
Fig. 1 (continued)
25
27
R2
COOH
O
286
R1 = O, R2 = β-OH, R3 = β-OH, R4 = H
287
R1 = β-OH, R2 = β-OH, R3 = β-OH, R4 = H
288
R1 = O, R2 = O, R3 = O, R4 = H
289
R1 = O, R2 = O, R3 = β-OAc, R4 = H
290
R1 = O, R2 = β-OH, R3 = α-OH, R4 = H
291
R1 = β-OH, R2 = O, R3 = β-OAc, R4 = H
292
R1 = O, R2 = O, R3 = H, R4 = H
293
R1 = β-OH, R2 = β-OH, R3 = H, R4 = H
294
R1 = β-OH, R2 = β-OH, R3 = β-OAc, R4 = H
295
R1 = O, R2 = β-OH, R3 = H, R4 = ξ-OH
296
R1 = O, R2 = O, R3 = β-OAc, R4 = ξ-OH
297
R1 = β-OH, R2 = O, R3 = β-OAc, R4 = ξ-OH
298
R1 = O, R2 = O, R3 = H, R4 = ξ-OH
299
R1 = β-OH, R2 = β-OH, R3 = H, R4 = ξ-OH
300
R1 = β-OH, R2 = β-OH, R3 = β-OAc, R4 = ξ-OH
O
HO
26
8
23
R1 = O, R2 = β-OH, R3 = H, R4 = H
O O
5
22
285
279 O
9
3
20 17
19
OH
R4
21 18
88
S. Baby et al. / Phytochemistry 114 (2015) 66–101
301
314
R1 = β-OH, R2 = O, R3 = H, R4 = H
O
COOH
O
COOH
HOOC
OH
O
HO
OH
O
315
OH
302
COOH
O R4
ROOC
COOH
O
OH R3
R1
R5
316
R=H
317
R = Me
R2
303
R1 = β-OH, R2 = OH, R3 = β-OH, R4 = H, R5 = O
COOH O
304
R1 = β-OH, R2 = OH, R3 = O, R4 = H, R5 = O
305
R1 = β-OH, R2 = OH, R3 = O, R4 = β-OH, R5 = O
306
R1 = O, R2 = H, R3 = O, R4 = α-OH, R5 = O
307
R1 = β-OH, R2 = H, R3 = O, R4 = β-OH, R5 = O
308
R1 = β-OH, R2 = H, R3 = α-OH, R4 = H, R5 = α-OH
O
318
O
COOH
O
H OH COOH
OH
R1
MeOOC
R3
O
OH
319
R2
309
R1 = β-OH, R2 = OH, R3 = α-OH
310
R1 = O, R2 = H, R3 = O
311
R1 = β-OH, R2 = H, R3 = O
(d) C27 lanostanes (alcohols, lactones, esters) O O O
COOH
HO
R
O
CH2OH
OH
320 312
R = α-OH
313
R=H
O O O COOH
O O
O
Fig. 1 (continued)
OH
O
OH
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S. Baby et al. / Phytochemistry 114 (2015) 66–101
R1 = β-OH, R2 = O, R3 = β-OAc, R4 = O, R5 = Bu
340 O
321
COOMe
O
O O
HO
OH
O
OH
HO O
OH
322
341
COOMe
O
COOMe
O
ROOC
O
OH
O
OH
342 323
R=H
324
R = Me COOMe
H OH
O
COOMe
O HOOC
O
OH
O
343 325 (e) C24, C25 lanostanes R3
21
COOR5
O
18
O
12
19
R1
R2
1
R4
3
9 5
24
R2 23
O
17
8
R1
20
R3
22
326
R1 = Ο, R2 = β-OH, R3 = H, R4 = O, R5 = Me
327
R1 = β-OH, R2 = β-OH, R3 = β-OH, R4 = O, R5 = Me
344
R1 = β-OH, R2 = β-OH, R3 = O
328
R1 = O, R2 = O, R3 = H, R4 = O, R5 = Me
345
R1 = O, R2 = β-OH, R3 = O
329
R1 = β-OH, R2 = β-OH, R3 = H, R4 = O, R5 = Me
346
R1 = β-OH, R2 = β-OH, R3 = α-OH
330
R1 = β-OH, R2 = β-OH, R3 = β-OAc, R4 = O, R5 = Me
347
R1 = β-OH, R2 = O, R3 = O
331
R1 = O, R2 = β-OH, R3 = H, R4 = α-OH, R5 = Me
348
R1 = β-OH, R2 = O, R3 = α-OH
332
R1 = O, R2 = O, R3 = β-OAc, R4 = O, R5 = Me
349
R1 = O, R2 = β-OH, R3 = α-OH
333
R1 = Ο, R2 = β-OH, R3 = H, R4 = O, R5 = Et
350
R1 = O, R2 = H, R3 = α-OH
334
R1 = O, R2 = β-OH, R3 = H, R4 = O, R5 = Bu
351
R1 = O, R2 = O, R3 = O
335
R1 = β-OH, R2 = β-OH, R3 = H, R4 = O, R5 = Bu
336
R1 = O, R2 = β-OH, R3 = β-OH, R4 = O, R5 = Bu
337
R1 = β-OH, R2 = β-OH, R3 = β-OAc, R4 = O, R5 = Bu
338
R1 = O, R2 = β-OH, R3 = H, R4 = α-OH, R5 = Bu
339
R1 = O, R2 = O, R3 = β-OAc, R4 = O, R5 = Bu
O O O
O
Fig. 1 (continued)
O
O
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S. Baby et al. / Phytochemistry 114 (2015) 66–101
359 352
OH
OH
O
HO
OH
OH
OH
O
COOH
360 353 O
(f) C30 pentacyclic triterpenes HO
O CHO
361 O
O
HO
354 O
362 O HO
O O
355
363 O HO
O
R
364
356
R=O
357
R = β-OAc
OH
OH
O OH
O
O
(g) Meroterpenoids 365
OH
OH
(h) Farnesyl hydroquinones (meroterpenoids)
O
O
OH
358 OH OH
OCH3 OH
O
O
Fig. 1 (continued)
91
S. Baby et al. / Phytochemistry 114 (2015) 66–101
375
366
OH
O
OH
O
R
HO COOH
367
R = OH
368
R=H
376 O
OH
O
HO O
HOOC
O
O H
369 OH
377 OH
OH
OH
O
H
H O
R2 R2 R2
O R1
370
(i) C15 sesquiterpenoids
378
R1 = H, R2 = COOH
379
R1 = β-OH, R2 = COOH
H
HO
(j) Steroids
OH
28
21
O
18 12
19
371
R
1
H
HO
OH
3
8
9 5
380 OH
H
372
R = α-OH
373
R = β-OH
HO
381 HO
H
OH OH
H
HO
374 382 H
HOH2C
H
OH OH
HO
Fig. 1 (continued)
O
O
20 17
26
23 27
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S. Baby et al. / Phytochemistry 114 (2015) 66–101
393
383
O
HO
O
O
R
394
R = α-OH
395
R = β-OH
396
R=O
384
HO
R1 OH R2
385
R1 = H, R2 = β-OMe
386
R1 = H, R2 = O
387
R1 = α-OH, R2 = O
R1 O
HO OH HO
R2
397
R1 = H, R2 = α-OH
398
R1 = H, R2 = β-OH
399
R1 = α-OH, R2 = O
400
R1 = α-OH, R2 = H
401
R1 = H, R2 = H
388
OH OH HO
OH OH
R
O
389
R1 HO
402
R=O
403
R = β-O-pentadecanoyl
404
R = β-O-palmitoyl
405
R = β-O-linoleoyl
R2
OH OH
390
R1 = H, R2 = H
391
R1 = α-OH, R2 = H
R
392
R1 = α-OH, R2 = α-OH
406
R = β-O-linoleoyl
H3CO OH
R
HO
O
O
Fig. 1 (continued)
skeletons and side-chains (as in C30 ganoderic acids) (Table 1, Fig. 1). In most C27 lanostanes (lucidenic acids), a single double bond in the tetracyclic ring was found at C8–C9 (Fig. 1). Only ganoderic
acid Jd (312) and 4,4,14a-trimethyl-5a-chol-7,9(11)-dien-3-oxo24-oic acid (313) showed two double bonds at C7–C8 and C9–C11 in their tetracyclic skeleton. Lucidenic acid O (309), 20(21)-dehydrolucidenic acid A (310) and 20(21)-
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407
415
R = β-O-linoleoyl
HO
HO
N HO
416
R
408
R = β-O-linoleoyl
409
R = β-OH
HO R
N HO
417
R=H
418
R = OH
HO
O
410
OH
N HO
419 O HO
OH
N HO
411
420
(l) Prenyl hydroquinone RO O
412
R=Η
413
R = β-D-glucopyranosyl
HO O
O OH
CHO
H
421 (k) Alkaloids
OHC
(m) Benzofurans
O
N
HO
O
OH O
OH
O
414 422 OHC
N
O
OH
HO
COOH
Fig. 1 (continued)
dehydrolucidenic acid N (311) showed ethylenic groups at C20. Hydroxyl substitutions at C20 were observed in 20-hydroxy lucidenic acid A (295), D2 (296), E2 (297), F (298), N (299) and P (300). Other side-chain substitutions are relatively few,
because the side-chains in C27 lanostanes are shorter compared to the C30s. Double bonds in the ring systems of C27 lanostanes (esters, alcohols, lactones) are also found at C8–C9 (Table 1, Fig. 1).
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423
428
(n) Benzopyran-4-one derivatives
(o) Benzenoid derivatives
O
R
OH
OH
O
HO
424
429
R = COOH
430
R = COCH3
O OH O
CHO
425 O HO
OH OH
O
431
426 O
H
O
O
(Structures of isolated secondary metabolites are drawn in O
varying stereochemical patterns by authors. In lanostanes and steroids, the following stereochemical patterns are followed for uniformity, (i) α-H at C5, C17 or equivalent positions is
427 O O
suppressed, (ii) C17 side-chain β, (iii) C10, C13 methyls β, (vi) C21 H
OH
α, (iv) C14 methyl α (lanostanes) and (v) C29/C28 β/α (C30
OH
lanostanes), C26/C25 β/α (C27 lanostanes), C24/C23 β/α (C25 lanostanes), C23/C22 β/α (C24 lanostanes)). Fig. 1
C30 and C27 lanostanes show more unique types of double bonds and substitutions in their four ring skeletons and side-chains. Ganoderic acid Df (23) has a rare hydroxyl substituent at C11 in the C30 lanostane skeleton (Fatmawati et al., 2010). Ganoderic acid L (14) has a hydroxyl group at C20 and it can be a possible precursor of lucidone C (346) (Nishitoba et al., 1986a). Ganoderic acid T (71) and lanosta-7,9(11),24-trien-3b,15a,22b-triacetoxy-26-oic acid (87) are lanostane type triterpenoids having heteroannular diene moieties and three acetoxyl groups each (Hirotani et al., 1986). 7O-Ethyl ganoderic acid O (53) isolated from G. lucidum has a rare ethoxy group at C7 (Wang et al., 2010b). Most lanostanoids have a keto group at C23, but Ha et al. isolated two lanostanoids (26-hydroxy-5a-lanosta-7,9(11),24-triene-3,22-dione (209), 26,27-dihydroxy-5a-lanosta-7,9(11),24-triene-3,22-dione (210)) with ketonic groups at C22 (Ha et al., 2000). Lee et al. recently reported a lanostane analog, methyl ganoderate A acetonide (245), with an acetal carbon connected to C7 and C15 through oxygen atoms, forming a seven-membered 1,3-dioxepane moiety (Lee et al., 2011a). This compound isolated from the fruiting bodies of G. lucidum is most likely not of natural origin but an artifact (Yang et al., 2012). Ganodermacetal (151) isolated from G. amboinense fruiting bodies with a similar acetonide group is a natural product resulting from the acetalization of ganoderic acid C (ganoderic acid C2, 4), as acetone was not used during the isolation procedure (Yang et al., 2012). Triterpene–farnesyl hydroquinone conjugates, ganosinensin A (222), B (223), C (224), isolated under mild conditions from the methanol extract of G. sinense, are natural products only and not artifacts formed through extraction processes (Sato et al., 2009a). Niu
et al. reported a C30 lanostane triterpenoid (168) with a 3-hydroxy-5-methoxy-3-methyl-1,5-dioxopentyloxy group at C3 from G. resinaceum fruiting bodies (Niu et al., 2007). Ganolucidic acid D (102) has an allylic alcohol group in the side-chain and it can be a possible biogenetic intermediate between the mycelial components and terpenoids of the fruiting body of G. lucidum (Min et al., 2000; Nishitoba et al., 1986a). Ganosporeric acid A (120) has five keto groups in the lanostane skeleton and a sixth group in the side-chain (Chen and Yu, 1993). Ganoderic acid E (6), F (7), 12b-hydroxy3,7,11,15,23-pentaoxo-5a-lanosta-8-en-26-oic acid (35), 8b,9a-dihydroganoderic acid C (118), methyl ganoderate E (229), F (230) and 12b-acetoxy-3,7,11,15,23-pentaoxo-5a-lanosta-8-en-26-oic acid ethyl ester (237) have four keto groups in their lanostane skeletons and a fifth in their side-chains (Table 1, Fig. 1). 8a,9a-Epoxy3,7,11,15,23-pentaoxo-5a-lanosta-26-oic acid (159) has four keto groups in the lanostane skeleton, a fifth group in the side-chain and an epoxy group between C8 and C9 (Joseph et al., 2011a). Ganoderenic acids A (125) to I (133), K (134), elfvingic acid A (135), 12b-acetoxy-7b-hydroxy-3,11,15,23-tetraoxo-5a-lanosta8,20-dien-26-oic acid (136), 7b,23n-dihydroxy-3,11,15-trioxolanosta-8,20E(22)-dien-26-oic acid (138), applanoxidic acid A (139), B (140), E (141), F (142), 7b-hydroxy-3,11,15,23-tetraoxolanosta-8,20E(22)-dien-26-oic acid methyl ester (250), australic acid (280) and methyl australate (281) have 20E-double bonds on their ganoderic acid side-chains (Komoda et al., 1985). Lakornwong et al. recently revised the structure of colossolactone G (270a) to (270b) (El Dine et al., 2008a; Kleinwächter et al., 2001; Lakornwong et al., 2014) (Table 1, Fig. 1). Colossolactone I (257), II
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(258), III (261), IV (262), VII (264), VIII (265), colossolactone B (259), C (271), D (266), E (267), F (268), G (270a, b), ganoderma lactone A (272), C (263), D (273), E (260), F (274), G (275) and schisanlactone A (269), B (283) are characterized by the presence of a six membered a,b-unsaturated d-lactone group in their side-chain with or without a seven membered lactone ring A. Colossolactone VIII (265), colossolactone D (266), E (267), F (268), G (270a, b), ganoderma lactone A (272), F (274), G (275) and schisanlactone A (269) have three double bonds in their first two seven/six membered rings. Ganolucidic acid C (121) isolated from G. lucidum and G. sinense possesses an unusual b-hydroxymethyl group at C4 (Liu et al., 2012b; Nishitoba et al., 1985b, 1987c). Applanoxidic acid A (139), E (141) and G (145) have hydroxyl substitutions at C15 whereas applanoxidic acid B (140), C (143), D (144), F (142) and H (146) are 15-keto analogs (Chairul et al., 1994). Several other C30 lanostanes also have hydroxyl or keto substitutions at C15 (Table 1, Fig. 1). Among the C27 lucidenic acids, lucidenic acid G (302) has a hydroxyl group at C26, not found in other isolates (Nishitoba et al., 1986a). Lucidenic acid O (309) isolated from G. lucidum has an exo-methylene group at C20, an acid group at C24 and a hydroxyl group at C25 (Mizushina et al., 1999). Lucidenic acid D1 (288) has five keto groups in its tetracyclic lanostane skeleton (Table 1, Fig. 1). Akihisa et al. and Sato et al. isolated C20 hydroxylated analogs of lucidenic acid A (G. sinense) (295), lucidenic acid D2 (G. lucidum) (296), E2 (G. lucidum) (297), F (G. lucidum) (298), N (G. lucidum/ G. sinense) (299) and P (G. lucidum) (300) (Akihisa et al., 2005; Sato et al., 2009b). Ganosinensic acid B (152), ganosinensic acid A (319) and methyl ganosinensate A (343) isolated from G. sinense have triterpenoid skeletons with a unique four membered ring (Wang et al., 2010a). Fornicatin A (G. fornicatum) (315), B (G. fornicatum, G. cochlear) (316) and D (G. cochlear) (317) are naturally occurring unique 25,26,27-trinorlanostane triterpenoids with the cleavage of the bond between C3 and C4 in ring A (Niu et al., 2004; Peng et al., 2014b). Two novel trinorlanostanes, cochlate A (325) and B (318), with 3,4-seco-9,10-seco-9,19-cyclo skeletons, were isolated from the fruiting bodies of G. cochlear (Peng et al., 2014b). Cochlate A (325) and B (318) could be derived by enzymatic modification of fornicatin B (316) (Peng et al., 2014b) (Table 1, Fig. 1). A series of C24 lanostanes, lucidone A (344), B (345), C (346), D (347), E (348), F (349), G (350), H (351), were isolated from G. lucidum, G. amboinense, G. applanatum, G. resinaceum and G. tropicum (Gan et al., 1998b; Hu et al., 2014; Lin et al., 1993; Nishitoba et al., 1985a, 1986a; Peng et al., 2013) (Table 1, Fig. 1). Nishitoba et al. first isolated lucidone A (344) from G. lucidum (Nishitoba et al., 1985a). Thereafter, similar C24 terpenoids (lucidone B (345) to H (351)) and their lactones (lucidenic lactone (320), lucidenolactone (321), ganolactone B (322)) were isolated by various groups (Table 1, Fig. 1). Substitutions in lanostanes (C30, C27, C24/C25) particularly at C3, double bonds, type of the side-chain and the number of hydroxyl groups play important roles in their structure–activity relationships (Cheng et al., 2010). Lanostanes and other secondary metabolites could provide chemotaxonomic clues in the genus Ganoderma (Cheng et al., 2010). Chemotaxonomy of genus Ganoderma has been recently reviewed (Richter et al., 2015). As in Table 1 and Fig. 1, most phytochemical studies in the genus are on G. lucidum, and relatively less chemical data are available on G. applanatum/G. lipsiense and G. sinense. Very limited studies are available on a few other Ganoderma species (Table 1, Fig. 1) and the remaining species are chemically not studied so far. Chemical profiling of standardized extracts using advanced liquid chromatography–mass spectrometry-based techniques or isolation of chemotaxonomically relevant compounds (ganoderic acids, lucidenic acids, triterpenes, applanatines, ganomastenols, steroids) could help in resolving the existing taxonomic issues in genus Ganoderma (Chen et al., 1999; Cheng et al., 2010; Paterson, 2006; Richter et al., 2015).
95
C30 pentacyclic triterpenoids (friedelin (354), alnusenone (355), b-amyrenone (356), b-amyrin acetate (357)) were isolated from G. applanatum and G. cochlear (Ming et al., 2002; Nishitoba et al., 1989; Peng et al., 2014b). Meroterpenoids fornicin A (358), B (359), C (360), ganocin A (361), B (362), C (363), D (364) and lingzhiol (365) were isolated from G. fornicatum, G. lucidum and G. cochlear (Niu et al., 2006; Peng et al., 2014a; Yan et al., 2013). Meroterpenoids are natural products biosynthesized from polyketide and terpenoid precursors. Peng and co-workers recently isolated ganocins A (361), B (362), C (363) possessing a spiro[4,5]decane substructure and ganocin D (364) with an eightmembered carbon ring from the fruiting bodies of G. cochlear (Peng et al., 2014b). Lingzhiol (365) isolated from G. lucidum has a novel 5/5/6/6 ring system and its three rings sharing a C-3–C-7 axis gives it a rotary door like structure (Yan et al., 2013). Niedermeyer et al. first reported the isolation of farnesyl hydroquinone (366) from G. pfeifferi (Niedermeyer et al., 2013). Farnesyl hydroquinone (366) could be the biosynthetic precursor of ganomycin A (G. pfeifferi) (367), B (G. pfeifferi; G. colossum) (368), I (G. colossum) (369) and K (G. pfeifferi) (370) (El Dine et al., 2009; Mothana et al., 2000; Niedermeyer et al., 2013). Farnesyl hydroquinone (366) and ganomycin A (367), B (368), I (369) and K (370) also fall into the group of meroterpenoids (Table 1, Fig. 1). Sesquiterpenoids such as ganosinensine (G. sinense) (371), ganomastenol A (372), B (373), C (374), D (375) (G. mastoporum), echinolactone D (G. applanatum) (376), ganodermycin (G. applanatum) (377), cryptoporic acid H (G. neo-japonicum) (378) and cryptoporic acid I (G. neo-japonicum) (379) were isolated from various Ganoderma species (Fushimi et al., 2010; Hirotani et al., 1991, 1995; Jung et al., 2011; Liu et al., 2012b). Several steroids and steroidal esters were isolated from G. lucidum and other Ganoderma species. Major steroidal metabolites isolated from Ganoderma include ergosterol (380), ergosta-7,22-dien3b-ol (381), ergosterol peroxide (383), ergosta-7,22-diene-3-one (402), ergosta-7,22-diene-3b-yl pentadecanoate (403), ergosta7,22-dien-3b-yl palmitate (404) and ergosta-7,22-dien-3b-yl linoleate (405) (Gan et al., 1998a,b; Ko et al., 2008; Lin et al., 1993, 1997; Nishitoba et al., 1988b; Rosecke and Konig, 2000; Seo et al., 2009; Smania et al., 1999; Strigina et al., 1971; Ziegenbein et al., 2006) (Table 1, Fig. 1). Steroid isolates showed one, two or three double bonds at C5–C6, C6–C7, C7–C8 (most common), C5–C6/C7–C8, C4–C5/C7–C8, C6–C7/C9–C11, C7–C8/ C16–C17 and C4–C5/C6–C7/C8–C14 in their ring systems. Ergosterol peroxide (383), 5a,8a-epidioxyergosta-6,9(11),22trien-3b-ol (384) and 5a,8a-epidioxy ergosta-6,22-dien-3b-yl linoleate (407) have C6-C7 double bonds and an epidoxy group linked to C5 and C8 (Fig. 1). 5a,8a-Epidioxyergosta-6,9(11),22trien-3b-ol (384) also has a C9–C11 double bond (Table 1, Fig. 1). Ganodermasides A (397), B (398), C (399), D (400) isolated from G. lucidum have four double bonds, three within three six membered rings (C4–C5, C6–C7, C8–C14) of their steroid skeletons and a fourth at C22 in side-chains (Weng et al., 2010, 2011). Most steroids (Table 1, Fig. 1) have C22–C23 double bonds in their side-chains, but some of them have no side-chain double bonds. 3b-Linoleyloxyergosta-7,24(28)-diene (406) isolated from G. lipsiense has an ethylene linkage at C24 (Rosecke and Konig, 2000). Ganoderma alkaloids A (414) and B (415) were isolated from the fruiting bodies of G. capense in 1990 (Liu et al., 2011; Yang and Yu, 1990). More alkaloids, sinensine (416), sinensine B (417), C (418), D (419), E (420) were isolated recently from G. sinense (Liu et al., 2010, 2011). Prenyl hydroquinone (ganoderma aldehyde (421)), benzofurans (ganodone (422), ganofuran B (423)), benzopyran-4-one derivatives (applanatine A (424), B (425), C (426), D (427), E (428)) and benzenoid derivatives (429–431) were also isolated from various Ganoderma species (Table 1, Fig. 1). Flavonoids, a widely distributed group of secondary metabolites, are not reported from genus Ganoderma so far.
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In most cases, the genus name (Ganoderma) or source species names were used to coin trivial names of isolated secondary metabolites (ganoderic acid (Ganoderma), lucidenic acid (lucidum), cochlate (cochlear), fornicatin (fornicatum), australic acid (australe)) (Table 1, Fig. 1, Table S1). In some cases, compounds with sequential trivial names do not show structural similarities (ganoderic acid Jd (312) isolated from G. sinense is not a C30 lanostane, but a C27 lucidenic acid type molecule) (Liu et al., 2012b). Moreover, trivial names of ganoderic acids and lucidenic acids are confusing because identical compounds were given different names or different compounds were named identically. These naming issues are mostly in papers published by four research groups in the 1980s (Hirotani et al., 1985, 1986, 1987; Hirotani and Furuya, 1986; Kikuchi et al., 1985a,b, 1986a,b,c; Kohda et al., 1985; Nishitoba et al., 1984, 1985a,b,c, 1986a,b, 1987a,b,c, 1988a,b, 1989) (Table 1, Fig. 1, Table S1). For example, Nishitoba et al. (1984, 1985a,c) reported (3) as ganoderic acid C. Kohda et al., 1985 reported (3) as ganoderic acid D, but later (3) was renamed as ganoderic acid C1 by Kikuchi et al. (1986a). Kohda et al. (1985) named (4) as ganoderic acid C and Kikuchi et al. (1985a) named (4) as ganoderic acid D. It (4) was later renamed as ganoderic acid D2 by Nishitoba et al. (1985b) and as ganoderic acid C2 by Kikuchi et al. (1986a). Hirotani and Furuya (1986) reported (4) as ganoderic acid E. Hirotani et al., 1985 reported (9) as ganoderic acid C. Nishitoba et al. (1985a) reported (5) as ganoderic acid D and Nishitoba et al. (1985b) renamed it as ganoderic acid D1. Kikuchi et al. (1986b) reported (5) as compound C50 . Some attempts were made to rectify these naming issues (see Kikuchi et al., 1986a; Nishitoba et al., 1985a, 1986a), but these problems are not fully resolved (see Table S1 ganoderic acid C1 (3), ganoderic acid C2 (4), ganoderic acid D1 (5), ganoderic acid K (12, 13), ganoderic acid O (17, 37), ganoderic acid Q (67), ganoderic acid S (69, 70), ganoderic acid B8 (21), ganoderic acid C6 (22), ganoderol B (176), lucidenic acid D1 (288), lucidenic acid D2 (289), lucidenic acid E1 (290), lucidenic acid E2 (291), lucidenic acid N (293), etc.). Another observation is, in several papers published in the 1980s, G. lucidum extracts were methylated (with diazomethane) during isolation, and ganoderic acids and lucidenic acids were obtained as their methyl derivatives (see Hirotani and Furuya, 1986; Kikuchi et al., 1985a,b, 1986a,b,c; Nishitoba et al., 1987c). In Table 1, Fig. 1, these methyl derivatives are compiled as their free acids. Most phytochemical studies on genus Ganoderma reported isolation, structure elucidation and biological activities of secondary metabolites. Similar studies are still being continued in genus Ganoderma, and new isolates in various systematic and trivial names are periodically added to the Ganoderma literature (Hu et al., 2013, 2014; Isaka et al., 2013; Lakornwong et al., 2014; Li et al., 2013b,c; Lin et al., 2013; Liu et al., 2014a; Ma et al., 2013, 2014; Niedermeyer et al., 2013; Peng et al., 2013, 2014a,b; Tung et al., 2013; Yan et al., 2013). Secondary metabolites isolated from various Ganoderma species (mostly first reports) and the literature describing their isolation and structure elucidation are given emphasis in this compilation (Table 1, Fig. 1). Most triterpenoids isolated from Ganoderma showed significant biological activities. Ganoderic acids from G. lucidum showed anticancer, antiviral, hepatoprotective, antiplatelet aggregation, antioxidant, hypocholesterolemic and inhibition of histamine release activities (Chairul et al., 1991; Gonzalez et al., 2002; Komoda et al., 1989; Lin et al., 2003; Min et al., 2000; Ríos et al., 2012; Sonoda et al., 1988; You et al., 2013). Ganoderic acid A (1) and methyl ganoderate A (225) were reported to have an inhibitory effect against farnesyl protein transferase (Lee et al., 1998). Inhibitors of farnesyl protein transferase have been shown to inhibit Ras (oncoprotein)-dependent cell transformation and thus lead to a potential therapeutic strategy for the treatment of human cancers (Lee et al., 1998). Ganoderic acid B (2), C2 (4) and their derivatives
were reported to have anticholesterol activity (Komoda et al., 1989; Sonoda et al., 1988). Ganoderic acid C1 (3) showed inhibition of the glycosyl transferase from the cariogenic bacterium Streptococcus mutans (Gao et al., 2004). Kohda et al. showed histamine releasing inhibitory activity for ganoderic acid C2 (4) and D1 (5) (Kohda et al., 1985). Yue and co-workers recently showed inhibition of the proliferation of HeLa human cervical carcinoma cells by ganoderic acid B (2), D (ganoderic acid C1, 3), F (7), K (12) and AM1 (18) (Yue et al., 2010). Ganoderic acids A (1), B (2), G (8) and H (9) isolated from G. lucidum exhibited antinociceptive activity (Koyama et al., 1997). Morigiwa et al. showed inhibitory effect on angiotensin converting enzyme for ganoderic acid F (7) isolated from G. lucidum (Morigiwa et al., 1986). Ganoderic acid Df (23) showed aldose reductase inhibitory activity (Fatmawati et al., 2010). Ganoderic acids U (38), V (39), W (40), X (72), Y (73), Z (41) were found to have cytotoxicity against hepatoma cells in vitro (Hirotani et al., 1987; Toth et al., 1983a,b,c). Six ganoderic acids c (96), d (97), e (98), n (99), g (100) and h (101) isolated from G. lucidum spores showed cytotoxic effects against Meth-A (sarcoma) and LLC (lung) tumor cell lines (Camargo and Kaneno, 2011; Min et al., 2000). Iwatsuki et al. reported inhibitory effect on Epstein–Barr virus activation for ganoderic acids E (6), F (7), ganodermic acid T–Q (84), lucidenic acid A (285), C (287), D2 (289), E2 (291), F (292) and their ester derivatives (Iwatsuki et al., 2003). Recently, ganoderic acid T (71) has been demonstrated to inhibit tumor metastasis by suppression of NF-kB activation (You et al., 2013). G. lucidum isolates ganolucidic acid A (32), ganoderic acid b (51), ganodermanondiol (192), lucidumol B (193) and ganodermanontriol (196) showed anti-HIV-1 protease activity (Min et al., 1998). Ganoderiol F (180), ganodermanondiol (192) and ganodermanontriol (196) showed anti-HIV and anticomplement activities (ElMekkawy et al., 1998; Min et al., 1998, 2001). Lucidenic acid O (309) and lucidenic lactone (320) showed inhibitory effect on eukaryotic DNA polymerase (Mizushina et al., 1999). Lin and coworkers reported cytotoxicity against hepatoma PLC/PRF/5 and KB cells for ganoderic aldehyde A (189) (Lin et al., 1990, 1991). Kim et al. reported b-glucosidase inhibitory and hepatoprotective activities for ganoderenic acid A (125) (Kim et al., 1999). Ganoderiol A (197)-enriched G. lucidum extract was found to suppress cell migration and cell adhesion by inactivation of focal adhesion kinase and disrupting of focal adhesion kinase/SRC complex formation, which subsequently inhibited paxillin activation. Moreover, ganoderiol A (197)-enriched extract downregulated the expression of Rho GTPases and influenced actin polymerization. Thus ganoderiol A (197)-enriched extract showed the potential for treatment of breast cancer metastasis (Wu et al., 2013). Lucidal (lucialdehyde C, 185), lucialdehyde B (186), ganodermanonol (ganoderol A or ganodermenonol, 175) and ganodermanondiol (192) showed cytotoxicity against Lewis lung carcinoma, T-47D, Sarcoma 180 and Meth-A tumor cell lines. Lucidal (185) exhibited the most potent cytotoxicity against these tumor cells (Gao et al., 2002). Butyl ganoderate A (238), B (239), butyl lucidenate A (334) and N (335) showed antiobesity effects through inhibition of adipocyte differentiation in 3T3-L1 cells in vitro (Lee et al., 2010b). Adams et al. reported in vitro antiplasmodial activity for ganoderic acid S (70), 23-hydroxy ganoderic acid S (117) and ganoderic aldehyde TR (174) (Adams et al., 2010). These reports revealed the pharmacological potentials of various lanostanes isolated from Ganoderma. Similarly, other secondary metabolites (steroids, alkaloids, ganomycins, fornicins, ganocins) isolated from Ganoderma are biologically active molecules. Ganoderic acids, highly oxygenated C30 lanostane-type triterpenoids, are the prominent bioactive constituents in genus Ganoderma. Ganoderic acid skeleton shows oxidative modifications with hydroxyl, oxo, acetoxyl and other functional groups especially at C3, C7, C15 and C22 positions (Fig. 1). Table 1, Fig. 1 lists 171
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ganoderic acids isolated from various Ganoderma species. Regulation of ganoderic acid biosynthesis and enhancing ganoderic acid production are critical in utilizing Ganoderma species for medicinal applications. G. lucidum is the key species used for medicinal purposes. However, so far the pathways of ganoderic acid biosynthesis are not fully understood. Biogenetic investigation of triterpenoids demonstrated that ganoderic acids are biosynthesized via the mevalonate–isoprenoid pathway (Chen et al., 2012; Xu et al., 2010). Ganoderic acids and their derivatives are synthesized from lanosterol by a series of oxidation, reduction, hydroxylation and acetylation steps (Liang et al., 2010; Ríos et al., 2012; Xu et al., 2010; You et al., 2013). Ganoderic acids are extracted mainly from the cultivated fruiting bodies of Ganoderma species. Cultivation of Ganoderma fruiting bodies is time consuming and ganoderic acid production fluctuates depending on various factors (Seo et al., 2009). Xu and co-workers recently reviewed the biotechnological interventions made in enhancing the production of ganoderic acids (Xu et al., 2010). New strategies for accelerated mycelia growth, enhancing ganoderic acid production by mycelia fermentation and varying fermentation conditions were studied by various groups (Wagner et al., 2003; Xu et al., 2010). Submerged fermentation is a promising technology for the enhanced production of ganoderic acids from Ganoderma (Wagner et al., 2003). The application of various inducers such as methyl jasmonate and phenobarbital has been used to enhance ganoderic acid production in submerged cultures (You et al., 2013). Zhu and co-workers reported the enhanced production of ganoderic acids under induction by a microbial polysaccharide in the submerged culture of G. lucidum (Zhu et al., 2008; Liang et al., 2010). More recently, enhanced production of individual ganoderic acids was demonstrated in a two stage culture of G. lucidum (Xu et al., 2010). Metabolic engineering of Ganoderma species is a very promising approach to enhance ganoderic acid production. In the postgenomic era (Chen et al., 2012), the integration of transcriptomic, proteomic and metabolomic tools could be utilized to elucidate the regulatory mechanism of ganoderic acid biosynthesis. The regulation of metabolic pathways along with the optimization of fermentation processes could lead to enhanced production of ganoderic acids from Ganoderma species (Xu et al., 2010). 3. Volatiles from Ganoderma Volatile oils were also reported in Ganoderma species. Ziegenbein et al. isolated volatile oil from the fruit bodies of G. lucidum by hydrodistillation and characterized it by GC-FID and GC– MS. Of the 65 constituents identified in G. lucidum essential oil, major ones were trans-anethole (9.1%), R-(�)-linalool (4.4%), S(+)-carvone (4.4%), 2-pentylfuran (2.8%), a-terpineol (2.7%) and n-nonanal (2.3%) (Ziegenbein et al., 2006). Volatile oil was isolated from the mycelia of G. japonicum by hydrodistillation and characterized by GC–MS. The main components of the oil were (E)-nerolidol (17.6%), (2E,4E)-decadienal (6.2%) and linalool (4.5%) (Liu et al., 2009b). 4. Conclusions Phytochemical studies led to the isolation of 431 secondary metabolites from genus Ganoderma. The major isolates are lanostane type triterpenoids (ganoderic acids, lucidenic acids), meroterpenoids, steroids and their various derivatives. More and more new molecules are being added periodically to the Ganoderma literature by various research groups. Most secondary metabolites isolated from Ganoderma showed biological potentials. However, the majority of the fungi in genus Ganoderma are not subjected to systematic studies so far. These factors reflect the need for more
phytochemical and biological activity studies on Ganoderma, particularly on the least investigated species.
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Dr. Sabulal Baby is Senior Scientist and Head at the Phytochemistry and Phytopharmacology Division of Jawaharlal Nehru Tropical Botanic Garden and Research Institute at Palode, Thiruvananthapuram in India. Dr. Sabulal received his doctorate in Chemistry from the Indian Institute of Technology Bombay in 1997. He did postdoctoral research at the University of Pennsylvania, USA and the University of Toronto, Canada. His research areas are phytochemistry and biochemistry. He published over forty five peer reviewed publications in these research areas.
101 Dr. Anil John Johnson obtained his Ph. D. in Chemistry from Gandhigram Rural University, Tamil Nadu, India in 2009. He is currently working as Technical Officer at the Phytochemistry and Phytopharmacology Division of Jawaharlal Nehru Tropical Botanic Garden and Research Institute at Palode, Thiruvananthapuram in India. His research work is focused on chemistry of medicinal and aromatic plants. He has published over twenty five peer reviewed research papers.
Mr. Balaji Govindan is a postgraduate in Biotechnology from Kalasalingam University, Tamil Nadu, India. Presently he is doing doctoral research in phytochemistry at the Jawaharlal Nehru Tropical Botanic Garden and Research Institute at Palode, Thiruvananthapuram in India. His research interests are in secondary metabolites, their nutritional and biological aspects.
