Flavonoids and Stilbenoids of the Genera Dracaena and Sansevieria: Structures and Bioactivities.

The genera Dracaena and Sansevieria (Asparagaceae, Nolinoideae) are still poorly resolved phylogenetically. Plants of these genera are commonly distributed in Africa, China, Southeast Asia, and America. Most of them are cultivated for ornamental and medicinal purposes and are used in various traditional medicines due to the wide range of ethnopharmacological properties. Extensive in vivo and in vitro tests have been carried out to prove the ethnopharmacological claims and other bioactivities. These investigations have been accompanied by the isolation and identification of hundreds of phytochemical constituents. The most characteristic metabolites are steroids, flavonoids, stilbenes, and saponins; many of them exhibit potent analgesic, anti-inflammatory, antimicrobial, antioxidant, antiproliferative, and cytotoxic activities. This review highlights the structures and bioactivities of flavonoids and stilbenoids isolated from Dracaena and Sansevieria.

1. Introduction

The taxonomic boundaries of the dracaenoid genera Dracaena and Sansevieria have long been debated. In the APG IV system of flowering plant classification, the two genera are still differentiated; both have been placed in the subfamily Nolinoideae of the family Asparagaceae, in the order Asparagales [1]. However, recent molecular phylogenetic studies showed that Sansevieria was nested within Dracaena, rendering the latter paraphyletic unless Dracaena was expanded to include species formerly placed in Sansevieria [2,3,4]. In this paper we have maintained the historical division in the two genera because the chemical literature is mainly based on the former botanical classification. However, known Dracaena synonyms for Sansevieria species are also reported.

The genus Dracaena consists of more than 100 accepted species which are mainly distributed in the tropics and subtropics, especially in Africa, Australia, and Southern Asia [5]. They are mainly succulent shrubs and trees, and a few are commonly grown as shrubby houseplants, especially the variegated forms. The complete chloroplast (CP) genomes of six species have recently been reported, showing that can be used as a super-barcode for Dracaena spp. identification [6].

“Dragon’s blood” is a non-specific name for deep red resinous exudates that are obtained from cut stems of different plant taxa endemic to various regions around the globe and belonging to the families of Asparagaceae, Arecaceae, Chamaesyce (Euphorbiaceae), and Fabaceae [7,8]. About six Dracaena plants, growing in China, Southeast Asia, West Africa, Arabian Peninsula, Yemen, India, and Macaronesia are the main sources of this resin [6,8]. The drug (Figure 1a) was a commercially important export, notably from the island of Socotra (Yemen) (Figure 1b) and it has widely been used in traditional medicines through the world for thousands of years as an efficacious remedy for the treatment of hemorrhage, dysentery, diarrhea, stomach and external ulcers, wounds, leucorrhea, fractures, piles, diabetes, and even tumors [6,8,9,10,11]. In fact, the resin is known to have remarkable anti-inflammatory and antioxidant effects and to enhance immune function, promote skin repair, stop bleeding, and enhance blood circulation [8,9,10,12,13]. Dragon’s blood is included in the Pharmacopoeia of the People’s Republic of China, where it was first imported through the silk road during the Sui and Tang dynasties. Until the 1970s, the red resin of Dracaena cochinchinensis S. C. Chen, used originally by the Dai people, living in the south part of Chinese Yunnan province, for treating pain and stopping hemorrhages, was found and used as the substitute of the traditionally imported dragon’s blood, called Long-Xue-Jie (Chinese dragon’s blood) [9,10].

Figure 1

(a) Dragon’s blood; (b) Dracaena cinnabari Balf. f. (Socotra, Yemen); and (c) Sansevieria cylindrica Bojer ex Hook. The images have been downloaded from the Internet.

Besides medicinal uses, the resin has also been employed as a pigment in works of art since ancient times by many cultures. In addition to flavonoids and stilbenoids (vide infra), chemical and pharmacological studies have indicated that other phenolic compounds, saponins, and terpenes are the main effective compounds occurring in dragon’s blood [8,9,10,11].

The genus Sansevieria includes species (Figure 1c) with a distribution ranging from Africa, Madagascar through Asia to Myanmar and the islands of the Indian Ocean [14,15]. The genus comprises perennial herbs with erect, stiff leaves and short, thick, and stoloniferous rhizomes. Common names for the about 70 or more known species include mother-in-law’s tongue, devil’s tongue, cow tongue, bow-string hemp, snake plant, and zebra lily [14,15]. The genus was originally named Sanseverinia by Vincenzo Petagna in 1787, to honor his patron Pietro Antonio Sanseverino, Count of Chiaromonte (1724–1771), in whose garden Petagna saw the plant. In 1794 Thunberg used the name Sansevieria that, since that time, has been conserved in the botanical literature [16]. The name honors Italian scientist and inventor Raimondo di Sangro (1710–1771), Prince of Sanseviero. The spellings “Sanseveria” and “Sanseviera” are commonly used as well, the confusion deriving from alternate spellings of the Italian place name. The leaves and rhizomes of Sansevieria genus are used in folk medicine for treating asthma, cough, sexual weakness, hypertension, abdominal pains, colic, eczema, piles, edema, jaundice, anuria, palpitations, viral hepatitis, malaria, snake- and insect bites, etc. [15,17,18,19,20].

Besides the medicinal aspects, several Dracaena and Sansevieria species have great horticultural importance and are commercialized for use in landscaping and as indoor ornamental plants [21]. Moreover, it has been reported that Dracaena spp. can be used as bioindicators for the control of increasing air pollution in urban cities [22].

This review describes the most characteristic flavonoids and stilbenes isolated from Dracaena and Sansevieria species that have been investigated so far; the main biological activities are also reported. Compounds found in each species have been divided according to the plant organ from which they have been isolated. The literature has been retrieved from the databases Reaxys and Google Scholar until February 2020. A few papers written in Chinese (see reference [8]) could not be reviewed.

2. Bioactive Flavonoids and Stilbenoids from the Genera Dracaena and Sansevieria

2.1. Dracaena Species

2.1.1. Dracaena angustifolia Medik, (Roxb.)

The native range of this shrub is from Bangladesh, through Indochina and Malaysia to Northern Australia. Tazettone H (structure 1 in Figure 2), (2R)-7,3′-dihydroxy-5′,5-dimethoxy-8-methylflavan (2), (2R)-7,4′-dihydroxy-5,3′-dimethoxy-8-methylflavone, (2R)-7,4′-dihydroxy-5-methoxy-8- methylflavanone, 5,4′-dihydroxy-7-methoxy-8-methylflavan, 4′-hydroxy-5,7-dimethoxy-8-methylflavan, (3S)-3,5,7-trihydroxy-4′-methoxyhomoisoflavanone, 5,7,4′-trihydroxy-6-methyl- homoisoflavanone, desmethylisoophiopogonone B (3), and 5,7,4′-trihydroxyhomoisoflavone (4) were isolated from the stems [23].

Figure 2

Chemical structures of compounds 1–4 isolated from D. angustifolia.

Compounds 2–4 displayed weak anti-inflammatory activity with IC50 values of 45, 33 and 61 μM, respectively [23].

2.1.2. Dracaena cambodiana Pierre ex Gagnep

The plant grows in China and Southeast Asia. Intense investigations of dragon’s blood led to the isolation of cambodianins A (5) and B (6), 4,4′-dihydroxy-2,3′-dimethoxydihydrochalcone (7), 4,4′-dihydroxy-2-methoxydihydrochalcone (loureirin C) (8), 4,4′-dihydroxy-2,6-dimethoxy- dihydrochalcone, 4,2′,4′-trihydroxychalcone (10), 4,4′-dihydroxy-2′-methoxychalcone (11), (2S)-7,3′-dihydroxy-4′-methoxy-8-methylflavan (9), (2S)-7,4′-dihydroxyflavanone (12), (3R)-7,4′-dihydroxyhomoisoflavanone (13) (Figure 3), together with cambodianins D (14) and E (15), (2S)-7,4′-dihydroxy-6,8-dimethylflavan (16), cambodianins G (18) and H (19) (Figure 4) [24,25,26].

Figure 3

Chemical structures of compounds 5–13 isolated from D. cambodiana.

Figure 4

Chemical structures of compounds 14–19 isolated from D. cambodiana.

In an MTT assay, 4,4′-dihydroxy-2,6-dimethoxydihydrochalcone and compounds 5, 6, 11, and 13 exhibited moderate cytotoxic effects against human myelogenous leukemia (K-562), human hepatocarcinoma (SMMC-7721), and human gastric tumor (SGC-7901) cell lines [24]. Compound 18 was moderately cytotoxic against K562 and SGC-7901 cell lines with IC50 values of 9.5 and 16.2 μg/mL, respectively [26]. Compounds 5–16, 18, and 19 showed antibacterial activities against Staphylococcus aureus and compounds 5, 6, 7, 8, 10, 12, and 13–16 also exhibited antibacterial effects against methicillin-resistant S. aureus (MRSA) [24,25,26]. The dragon’s blood of D. cambodiana also produced 5,7-dihydroxy-4′-methoxy-8-methylflavan, 7,4′-dihydroxy-8-methoxyhomoisoflavan, (2R)-7,4′-dihydroxy-8-methylflavan, and (2S)-7,3′-dihydroxy-4′-methoxyflavan [27]. The Dai and Mei research group isolated the biflavonoids 8-methyl-3′-methoxysocotrin-4′-ol (cochinchinenin D) (structure 17 in Figure 4), 8-methyl-4′-methoxysocotrin-3′-ol, and 8-methylsocotrin-4′-ol, together with (2S)-7,4′-dihydroxy-6,8-dimethylflavan, (2S)-5,7-dihydroxy-4′-methoxy-8-methylflavan, (2S)-7,3′-dihydroxy-4′-methoxy-8-methylflavan (9), (2R)-7,4′-dihydroxy-8-methylflavan, (±)-7,3′-dihydroxy-4′-methoxyflavan, (±)-7,4′-dihydroxy-3′-methoxyflavan, and (2S)-7,4′-dihydroxyflavan from the stems of D. cambodiana [28,29,30]. The antimicrobial activities of these compounds were reported. In addition, a new homoisoflavonoid, named cambodianol (structure 20 in Figure 5), was isolated from the same sample.

Figure 5

Chemical structures of compounds 20–22 isolated from D. cambodiana.

Cambodianol exhibited high cytotoxic activity against chronic myelogenous leukemia (K562), human hepatoma (SMMC-7721), and human gastric cancer (SGC-7901) cells in an MTT assay with IC50 values of 1.4, 2.9, and 5.0 µg/mL, respectively, that were comparable with those of paclitaxel [30,31]. 7,4′-Dihydroxy-8-methoxyhomoisoflavan, 7,4′-dihydroxyhomoisoflavan, 4,4′-dihydroxy-2-methoxydihydrochalcone, 4,4′-dihydroxy-3,2′-dimethoxychalcone, 4,2′,4′-trihydroxychalcone, 4,4′-dihydroxy-2′-methoxychalcone were also isolated from D. cambodiana stems [32,33]. 4,4′-Dihydroxy-3,2′-dimethoxychalcone showed significant activity against chronic myelogenous leukemia (K562), human hepatoma (SMMC-7721), and human gastric cancer (SGC-7901) cells in an MTT assay, with IC50 values of 2.5, 4.3, and 4.4 mg/mL, respectively. These values were comparable with those of mitomycin C [32]. The antioxidant and radical scavenging activities of compounds 20, (2S)-7,3′-dihydroxy-4′-methoxy-8-methylflavan (9), (2R)-7,4′-dihydroxy-8-methyl flavan, (±)-7,4′-dihydroxy-3′-methoxyflavan, (2S)-7,4′-dihydroxyflavan, 7,4′-dihydroxyhomoisoflavan, and 4,4′-dihydroxy-2′-methoxychalcone were from weak to moderate [33].

Dragon’s blood of D. cambodiana, artificially induced by mineral salt and acid injection into trunk of the plant by transfusion [31,34], produced a wide range of phenolic compounds, some of which were the same as those isolated from the natural red resin. They include (2R)-7,4′-dihydroxy-8-methylflavan, (2R)-7,4′-dihydroxy-6-methylflavan (21), (2S)-7,4′-dihydroxyflavan, (2S)-5,4′-dihydroxy-7-methoxy-6,8-dimethylflavan, (2S)-7,3′,4′-trihydroxy-8-methylflavan, (2S)-7,4′-dihydroxy-3′-methoxyflavan, (±)-7,4′-dihydroxy-3′-methoxyflavan, (2S)-5,7-dihydroxy-4′-methoxy-8-methylflavan, (2S)-7,3′-dihydroxy-4′-methoxy-8-methylflavan, (3R)-7,4′-dihydroxyhomoisoflavan, (3R)-7,4′-dihydroxy-8-methoxyhomoisoflavan, (3R)-7,3′,4′-trihydroxyhomoisoflavan (22) (Figure 5), 2,4,4′-trihydroxy-3′-methoxy-3-methydihydrochalcone, 2,4,4′-trihydroxy-3-methydihydrochalcone, 4,2′,4′-trihydroxy-3-methoxychalcone, (±)-5,7,4′-trihydroxy-6-methylhomoisoflavanone, (±)-7,4′-dihydroxyhomoisoflavanone, (3S)-7,3′-dihydroxy-4′-methoxyhomoisoflavanone, (3R)-cambodianol (20), (2S)-7,4′-dihydroxyflavanone, pterostilbene, 10-hydroxy-11-methoxydracaenone C, 10,11-dihydroxydracaenone C, (3E)-7-hydroxy-3-[(3-hydroxy-4-methoxybenzylidene)chroman-4-one, (3E)-7-hydroxy-3-(4-hydroxybenzylidene)chroman-4-one, 3′-methoxy-8-methylsocotrin-4′-ol, 4′-methoxy-8-methylsocotrin-3′-ol, and 8-methylsocotrin-4′-ol [31,34]. (±)-7,4′-Dihydroxyhomo- isoflavanone and 8-methylsocotrin-4′-ol exhibited moderate cytotoxic effects against human myeloid leukemia (K562) and human gastric tumor (SGC-7901) cell lines (IC50 = 16–29 μg/mL) [30], whereas compound 21 was weakly cytotoxic against human hepatoma (BEL-7402) cells (IC50 = 39.2 μM) [34]. Compound 22 showed significant acetylcholinesterase (AChE) inhibitory activity [34]. Most isolated compounds demonstrated antibacterial activity against S. aureus; instead, they were only weakly active against MRSA [31].

2.1.3. Dracaena cinnabari Balf. f.

The plant grows in Arabian Peninsula and Yemen, especially in the island of Socotra (Figure 1b) where it has become a touristic attraction. From the red resin of the plant collected at Socotra, known in Arabic as Dammalakhawin or Cinnabar, Masaoud et al. isolated 7,3′-dihydroxy-4′-methoxyhomoisoflavan, 7,4′-dihydroxy-8-methoxyhomoisoflavan, 4′-hydroxy-7,8-methylendioxy- homoisoflavan (structure 23 in Figure 6), 7,4′-dihydroxyhomoisoflavan, (±)-7,4′-dihydroxy-3′-methoxyflavan, (2S)-7,3′-dihydroxy-4′-methoxyflavan, (2S)-7-hydroxyflavan, 4,4′-dihydroxy-2′-methoxychalcone, 4-hydroxy-2-methoxydihydrochalcone, 4,4′-dihydroxy-2-methoxydihydro- chalcone, (2S)-7-hydroxyflavanone, and 7,4′-dihydroxyflavone [35].

Figure 6

Chemical structures of compounds 23–25 isolated from D. cinnabari.

Compound 23 inhibited nitric oxide (NO), TNF-α, and IL-6 production in lipopolysaccharide- stimulated mouse macrophage RAW 264.7 cells [36], thus having potential anti-inflammatory activity.

Unprecedented phenols isolated from the resin were the C-linked chalcone-dihydrochalcone dimer dracidione (structure 24 in Figure 6) [37], the triflavonoid damalachawin (structure 25 in Figure 6) [38], the biflavonoids cinnabarone (26) [39], 2′-methoxysocotrin-5′-ol (27), socotrin-4′-ol (28), and homoisosocotrin-4′-ol (29) [40], and the metacyclophane dracophane (structure 30 in Figure 7) [41]. Dracidione (24) showed moderate α-glucosidase inhibitory activity (IC50 = 40.27 µg/mL) [37].

Figure 7

Chemical structures of compounds 26–30 isolated from D. cinnabari.

2.1.4. Dracaena cochinchinensis (Lour.) S.C. Chen

The plant grows in China and Southeast Asia. Phytochemical and pharmacological investigations performed on D. cochinchinensis extracts are innumerable, given the wide use of the drug in the traditional Chinese medicine. Several extracts of the plant, especially of the red resin, known as Chinese dragon’s blood or Yunnan dragon’s blood, have been true mines of a great number of novel compounds with intriguing structures (Figure 8, Figure 9, Figure 10, Figure 11, Figure 12, Figure 13, Figure 14, Figure 15 and Figure 16). The immunomodulatory, antibacterial, antiviral, antidiarrheal, antioxidant, antiatherosclerosis, antiulcer, antiseptic, mutagenic and antimutagenic, antitumor, anticancer, and cytotoxic effects of Chinese dragon’s blood have been proved by pharmacological investigations [42]. The drug is commonly prescribed to improve blood circulation, to stop hemorrhages, and to heal wound cuts and pains [42]. It has also been used to treat a diverse range of peripheral inflammation and central inflammation-associated diseases such as diabetes, arthritis, colitis, gynecopathy, and allergic dermatitis [42]. A Chinese pharmaceutical formulation, named Longxuetongluo Capsule (LTC), which is derived from the total phenolic extract of Chinese dragon’s blood, has been proved to be safe as well as effective against ischemic stroke. At least ten different research groups, mainly from China, have isolated and determined the structures of a great number of flavonoids and stilbenoids from the red resin. To avoid repetitions, compounds have been grouped according to their biosynthetic families. Flavones (Figure 8): 7-hydroxy-6-methoxyflavone [43], 7,3′-dihydroxy-4′-methoxyflavone (31) [44], 7,4′-dihydroxyflavone (32) [44,45,46], 7-hydroxyflavone (33) [42], 5,7,4′-trihydroxy-8-methylflavone [42], 5,7,4′-trihydroxyflavone (apigenin) [42]. Flavanones: 7,4′-dihydroxyflavanone (liquiritigenin) [42,44], (2S)-5,7-dihydroxyflavanone (pinocembrin) [42]. Chalcones: 4,4′-dihydroxy-2-methoxychalcone (echinatin) [42,46], 4,4′-dihydroxy-3′-methoxychalcone [44], 4,4′-dihydroxy-2′-methoxychalcone (11) [44,47]. Dihydrochalcones derivatives (Figure 8): 6-methoxy-3-methyl-(1-hydroxy-3-(4-hydroxyphenyl)propyl)-bicyclo[3.1.0]hex-6-ene-2,4-dione (“cochinchinenene H”) (34) [42], 4-hydroxy-2,4′-dimethoxy- dihydrochalcone [48], 3,4′-dihydroxy-2,4,6-trimethoxydihydrochalcone [48], 2,4,4′-trihydroxy- dihydrochalcone [47,48], cochinchinenone (35) [47], 4′-hydroxy-2,4-dimethoxydihydrochalcone (loureirin A) (36) [43,45,46,47,48], 4′-hydroxy-2,4,6-trimethoxydihydrochalcone (loureirin B) [43,45,46,48], 2,4′-dihydroxy-4,6-dimethoxydihydrochalcone (37) [48], loureirin C (8) [42,44,46,47,48], 4,4′-dihydroxy-2,6-dimethoxydihydrochalcone [42,44,46,47,49], 4,6,4′-trihydroxy-2-methoxydihydrochalcone [47], 4′-hydroxy-4,2′-dimethoxydihydrochalcone (38) [50], and 4-hydroxy-2′,6′- dimethoxydihydro-chalcone (39) [51].

Figure 8

Selected flavones and dihydrochalcone derivatives from D. cochinchinensis red resin.

Figure 9

Selected homoisoflavanones and stilbenoids from D. cochinchinensis red resin.

Figure 10

Selected flavans from D. cochinchinensis red resin.

Figure 11

Selected homoisoflavans and meta-homoisoflavans from D. cochinchinensis red resin.

Figure 12

Selected flavonoid dimers from D. cochinchinensis red resin.

Figure 13

Selected flavonoid dimers (cont.) and trimers from D. cochinchinensis red resin.

Figure 14

Chemical structure of dracol isolated from D. draco.

Figure 15

Chemical structures of compounds 93–103 isolated from D. loureiri.

Figure 16

Chemical structure of compound 104 isolated from D. usambarensis.

Homoisoflavones: 5,4′-dihydroxy-7-methoxyhomoisoflavone [52], 7,4′-dihydroxyhomoisoflavone [46], 7-hydroxy-3-(4-hydroxy-benzylidene)chroman-4-one [42]. Homoisoflavanones (Figure 9): (3S)-3,7-dihydroxy-4′-methoxyhomoisoflavanone [(3S)-dracaeconolide A] (40) [49], (3S)-3,7,4′-trihydroxy-5-methoxyhomoisoflavanone (41), (3S)-7,4′-dihydroxy-5-methoxyhomoisoflavanone [42,52], 7,4′-dihydroxyhomoisoflavanone (42) [42,43,52], (3S)-7,4′-dihydroxyhomoisoflavanone [44], 3,5,7,4′-tetrahydroxyhomoisoflavanone (loureiriol) [52], and 7,4′-dihydroxy-8-methoxyhomoisoflavanone [47]. Stilbenoids (Figure 9): trans-resveratrol [42,44], 3,4′-dihydroxy-5-methoxystilbene [42], cis-resveratrol [42], trans-3,5-dihydroxy-4′-methoxystilbene [47], trans-3,5,4′-trihydroxystilbene [47], pterostilbene (4′-hydroxy-3,5-dimethoxystilbene) (43) [43], 3-methylresveratrol [44], and cochinchin (structure 44 in Figure 9) [45].

Flavans (Figure 10): 7,4′-dihydroxy-8-methylflavan (45) [43,44,49], 4,4′-dihydroxy-2,6-dimethoxydihydrochalcone [47,48], (2R)-7,4′-dihydroxy-5-methoxy-8-methylflavan [49], 5,4′-dihydroxy-7-methoxy-6-methylflavan (46) [44,46,49], 7,4′-dihydroxy-3′-methoxyflavan [49], 7,4′-dihydroxyflavan (47) [46,49], (–)-7-hydroxy-4′-methoxyflavan [43,45,46,47], (2S)-7,4′-dihydroxy-8-methylflavan (48) [46,47], (2S)-5,4′-dihydroxy-7-methoxy-8-methylflavan [47], (2R)-4′-hydroxy-7-methoxy-8-methylflavan [47], and 6,4′-dihydroxy-7-methoxy-8-methylflavan [46].

Homoisoflavans and meta-homoisoflavans (Figure 11): (3R)-7,4′-dihydroxy-5,8-dimethoxy- homoisoflavan [(3R)-dracaeconolide B] (49) [49] (Figure 11) (3R)-7,4′-dihydroxy-8-methoxy- homoisoflavan (50) [48,49,53], (3R)-7,4′-dihydroxyhomoisoflavan (51) [45,46,48,49], (3R)-7,4′-dihydroxy-5-methoxyhomoisoflavan (52) [42,46,48,49], 7,4′-dihydroxyhomoisoflavan (53) [43,44], (3R)-7,4′-dihydroxy-6-methoxyhomoisoflavan [52], 6,4′-dihydroxy-7-methoxyhomoisoflavan (54) [43,46], (3R)-6,4′-dihydroxy-8-methoxyhomoisoflavan [49], 7,3′-dihydroxy-8,4′-dimethoxyhomo- isoflavan [48], 4′-hydroxy-7,8-dimethoxyhomoisoflavan [48], 4′-hydroxy-5,7-dimethoxyhomo- isoflavan [48], (7R,12bR)-7,10-dihydroxy-4,11-dimethoxydracaenone (55) [52], (7S,12bS)-11-hydroxy-1,10-dimethoxydracaenone (56) [52], (7S,12bS)-10,11-dihydroxy-1-methoxydracaenone (57) [52], 10-hydroxy-11-methoxydracaenone (58) [52], 10,11-dihydroxydracaenone C (59) [44], and 4′-hydroxy-7,8-methylenedioxyhomoisoflavan (23) [46,48].

Flavonoid dimers and trimers (Figure 12 and Figure 13): cochinchinenenes A–D (structures 60,63–65 in Figure 11) [44,47,53], cochinchinenenes E (66) and F (61) [43], cochinchinenenes G (67) and H (62) [44], “cochinchinenene G” (68) [42], (2R)-8-methylsocotrin-4′-ol (69) [47], cochinchinenin [44], cochinchinenin B (75) [47], (γS)-1-[5-(4,4′-dihydroxy-2-methoxydihydrochalconyl)]-1-(4-hydroxyphenyl)-3-(2-methoxy-4-hydroxy-phenyl)propane (cochinchinenin C) (76) [42,47], 1-[5-(2-methoxy-4,4′-dihydroxydihydrochalconyl)]-1-(4-hydroxyphenyl)-3-(2-methoxy-4-hydroxy-phenyl)- propane [44,47], cochinchinenins D-H (structures 70,80,77,90,89 in Figure 12 and Figure 13), cinnabarone (26) [39], dracaenin A (79) [42,54], socotrin-4′-ol (28) and homoisosocotrin-4′-ol (29)[40], cochinchinenins I-M (structures 78,81,71,72,73 in Figure 12), (2RγS)-3′-methoxy-8-methylsocotrin-4′-ol, (2SγR)-3′-methoxy-8-methylsocotrin-4′-ol, (2RγR)-8-methylsocotrin-4′-ol, (2RγS)-8-methyl- socotrin-4′-ol [55,56,57], compound 74 [53], and biflavocochins A-G (structures 82–88 in Figure 13) [53].

It is worth noting that the names cochinchinenenes G and H, at first attributed to compounds 67 and 62, respectively [44], were later also used for naming “compounds” 68 and 34, respectively [42].

(7E)-1,5-Dihydroxy-11,12,13-trimethoxystilbene, (7E)-1,5-dihydroxy-11,13-dimethoxystilbene, (7E)-2,4-dihydroxy-1-methylstilbene (structure 91 in Figure 13), 1,3-dihydroxy-2,4-dimethyl-5-methoxychalcone, (2S)-7,4′-dimethoxy-5-hydroxy-6-methylflavan, and (3S)-3,7-dihydroxy-4-methoxyhomoisoflavanone were identified by Niu and his co-workers in dragon’s blood of D. cochinchinensis elicited by Fusarium graminearum [58]. Flavonoids and stilbenoids contained in other parts of the plant have been less investigated than the flavonoids isolated from the resin. (2S)-4′,7-dihydroxy-3′-methoxy-8-methylflavan, (2S)-7,3′-dihydroxy-4′-methoxy-8-methylflavan (9), 7-hydroxy-4′-methoxyhomoisoflavanone, (3R)-3,7-dihydroxy-8,4′-dimethoxyhomoisoflavanone, and 4,2′,4′-trihydroxychalcone were isolated from D. cochinchinensis leaves [59]. 7,4′-Dihydroxy- homoisoflavanone (42), 10,11-dihydroxydracaenone C (59), 7,4′-dihydroxyflavone, 7,4′-dihydroxy- flavan, 4,4′-dihydroxy-2-methoxychalcone (echinatin), 4,4′-dihydroxy-2-methoxydihydrochalcone, and 7,4′-homoisoflavan, together with sterols and phenolic glycosides, were isolated from fresh stems [60].

Compounds 49–51 and 45–47 did not show cytotoxic effects at a concentration of 10 µM, whereas they significantly promoted osteogenic differentiation of mesenchymal stem cells (MSCs) by increasing the levels of alkaline phosphatase (ALP) activity to 159.6 ± 5.9%, 167.6 ± 10.9%, 162.0 ± 1.4%, 151.3 ± 4.0%, 171.0 ± 8.2%, and 169.9 ± 7.3%, respectively, relative to the control [49]. Compounds 72 and 73 showed significant inhibitory activities against NO production in lipopolysaccharide-stimulated BV-2 microglial cells with IC50 values of 4.9 ± 0.4 and 5.4 ± 0.6 μM, respectively [56], whereas IC50 values of compounds 41, 42, and 58 were in the range of 60.4–75.6 μM [52]. Apigenin, 7-hydroxy-3-(4-hydroxybenzylidene)chroman-4-one, compounds 8, 31–33, 52, and 68 exhibited significant anti-neuroinflammatory properties without showing cytotoxic effects at the tested concentrations. A primary mechanistic study revealed that these effective compounds could inhibit neuroinflammation by inhibiting NO production and reducing the expressions of iNOS, IL-6, and TNF-α in LPS-activated BV2 microglial cells [42]. Compounds 60, 63–65, 69, 75, 76, and 1-[5-(2-methoxy-4,4′-dihydroxydihydrochalconyl)]-1-(4-hydroxyphenyl)-3-(2-methoxy-4-hydroxyphenyl)- propane showed moderate thrombin inhibitory activity, whereas compounds 48, 75, and 76 were active against Helicobacter pylori (ATCC43504) with MIC values of 29.5, 29.5, and 31.3 μM, respectively [47]. Compounds 43, 58, 61, and 66 showed good NAD(P)H Quinone Dehydrogenase 1 (NQO1) inducing activities, whereas compounds 36, 37, 43, 46, 53, and 54 exhibited anti-inflammatory activities [43]. Compound 82 showed neuroprotective effect on serum deficiency-induced cellular damage in neuroendocrine PC12 cells (pheochromocytoma cells derived from the adrenal gland of Rattus norvegicus), whereas compounds 83, 87, and 88 exhibited moderate protein tyrosine phosphatase 1B (PTP1B) inhibitory activities [53]. Compound 91 exhibited potent antioxidant activity and a broad-spectrum of inhibitory activity against fungal strains, including Exserohilum turcicum, Bipolaris maydis, Curvularia lunata, and F. graminearum [58].

2.1.5. Dracaena draco L.

D. draco L. is native to India, the Canary Islands, Cape Verde, Madeira, and locally in Western Morocco. It is the natural symbol of Tenerife island. Independently, an Italian research group [61] and Gonzàlez and collaborators [62] isolated from the red resin of D. draco the following group of compounds: (2S)-7,4′-dihydroxy-3′-methoxy-8-methylflavan, (2S)-5,4′-dihydroxy-7-methoxy-8-methylflavan, (2S)-7,4′-dihydroxy-3′-methoxyflavan, (2S)-7,4′-dihydroxy-8-methylflavan, (2S)-7,3′-dihydroxy-4′-methoxy-8-methylflavan (9), 7,4′-dihydroxyhomoisoflavan, 7,4′-dihydroxy-8-methoxyhomoisoflavan, 4′-hydroxy-5,7-dimethoxyhomoisoflavan, 4′-hydroxy-7,8-methylendioxy- homoisoflavan, 5,7,4′-trihydroxyhomoisoflavan, 10-hydroxy-11-methoxydracaenone (42), 3,4′-dihydroxy-7-methoxyflavone, liquiritigenin (7,4′-dihydroxyflavanone), 7,4′-dihydroxyhomoiso- flavanone, 5,7,4′-trihydroxy-6-methylhomoisoflavanone, 5,7,4′-trihydroxyhomoisoflavanone, 4,4′-dihydroxy-2′-methoxychalcone, isoliquiritigenin (4,2′,4′-trihydroxychalcone), 2,4,4′-trihydroxy- dihydrochalcone, and loureirin C (4,4′-dihydroxy-2-methoxydihydrochalcone) (8). Flavans of dragon’s blood from D. draco L. subsp. draco (Tenerife and Cape Verde) and D. draco L. subsp. ajgal (Morocco) were identified as (2S)-7,3′-dihydroxy-4′-methoxy-8-methylflavan (9), (2S)-7,4′-dihydroxy-3′-methoxy-8-methylflavan, (2S)-7,4′-dihydroxy-3′-methoxyflavan, (2S)-7,4′-dihydroxy-8-methylflavan, and (2S)-5,4′-dihydroxy-7-methoxy-8-methylflavan [63]. From samples of dragon’s blood collected from ancients specimens of D. draco L. subsp. draco growing in Palermo, Di Stefano reported the isolation and structural characterization of 7,4′-dihydroxyflavan, 7,3′-dihydroxy- 4′-methoxy-8-methylflavan, 7,4′-dihydroxy-3′-methoxy-8-methylflavan, 7,4′-dihydroxy-3′-methoxy- flavan, 7,4′-dihydroxy-8-methylflavan, 5,4′-dihydroxy-7-methoxy-8-methylflavan, 7,4′-dihydroxy- homoisoflavan, 7,4′-dihydroxy-8-methylhomoisoflavan, 7,4′-dihydroxy-8-methoxyhomoisoflavan, 7,4′-dihydroxy-5-methoxyhomoisoflavan, 7,4′-dihydroxyhomoisoflavanone, 5,7,4′-trihydroxyhomo- isoflavanone, 5,8,4′-trihydroxy-7-methoxyhomoisoflavanone, 5,7,4′-trihydroxy-6-methoxyhomo- isoflavanone, 5,7,4′-trihydroxy-6-methylhomoisoflavanone, and 5,7,4′-trihydroxy-6,8-dimethyl- homoisoflavanone [64]. Dracol (structure 92 in Figure 14), 5,7,4′-trihydroxyhomoisoflavanone, and helichrysetin were isolated from an EtOH extract of D. draco leaves [65]. Compound 92 was completely ineffective against HL-60 (leukemia), A431 (epidermoid), HeLa (cervix), and SK-OV-3 (ovarian) tumor cells (IC50 values > 100 µM) [65]. Quercetin-3-O-rutinoside was identified in aqueous extract of D. draco fruits [13]. 4′-Hydroxy-7,8-methylendioxyhomoisoflavan, (2S)-7,4′-dihydroxy-8-methylflavan, 7,4′-dihydroxy-8-methoxyhomoisoflavan, loureirins A and C, (-)-7,3′-dihydroxy-4′-methoxy-8-methylflavan, 7,4′-dihydroxyhomoisoflavan, isoliquiritigenin. (2S)-7,4′-dihydroxy-3′-methoxyflavan, and (2S)-5,4′-dihydroxy-7-methoxy-8-methylflavan were isolated from D. draco roots [65]. Loureirin C (8), (2S)-7,4′-dihydroxy-3′-methoxyflavan, and isoliquiritigenin [66,67] were isolated from D. draco stem bark [67].

2.1.6. Dracaena loureiri Gagnep

D. loureiri Gagnep is a misspelled name for D. loureiroi Gagnep, which is considered illegitimate and synonym for Dracaena cochinchinensis (Lour.) S.C. Chen [68]. The plant is known by Thai’s as ‘Jun-Par’ and is commonly referred to as “Thai Dracaena”. This herb has positive activities of promoting blood circulation for removing blood stasis, regenerating tissue to heal wound, relieving pain, and eliminating swelling. It has been commonly used for the treatment of coronary heart diseases, angina, and acute myocardial infarction. Moreover, the EtOAc extract of D. loureiri can promote inflammatory response induced by LPS through inhibiting ROS production in vascular smooth muscle cells and macrophages. Meksuriyen and Cordell isolated loureirins A–D (structures 93–96 in Figure 15) from the leaves of the plant collected in Thailand [69]. Loureirin D (96) exhibited mild inhibition of LPS-stimulated NO production in RAW 264.7 macrophages, with an IC50 value of 50.3 μM, whereas it inhibited the activation of the IL-6/STAT3/NF-κB signaling pathway [48,70]. Ichikawa et al. isolated loureirins B (94) and D (96), 4,4′-dihydroxy-2,6-dimethoxydihydrochalcone (97), 2,4′-dihydroxy-4,6-dimethoxydihydrochalcone (98), 3,5,7-trihydroxy-4′-methoxyhomoisoflavanone (eucomol), 5,7,4′-trihydroxyhomoisoflavanone, and 7,4′-dihydroxy-5-methoxyhomoisoflavanone from the stem wood of the plant, a Thai folkloric medicine called “Chan-daeng” [71]. Likhitwitayawuid also isolated loureiriol (99), 4,6,4′-trihydroxy-2-methoxydihydrochalcone, 4,3′,5′-trihydroxystilbene (100), 4,3′-dihydroxy-5′-methoxystilbene (101), and 4-hydroxy-3′,5′-dimethoxy- stilbene (102) [72]. Compounds 97 and 98 were estrogen agonist and stimulated the estrogen-dependent human breast adenocarcinoma MCF-7 cell proliferation in a concentration-dependent manner between 10−8 and 10−5 M. 5,7,4′-Trihydroxyhomoisoflavanone showed appreciable estrogenic activity, competing with [3H]-estradiol for binding to the bovine uterine estrogen receptor. The apparent IC50 value was 375 nM, compared to the value of 225 nM for genistein [71]. Compounds 100–102 showed potent inhibitory activity of COX-1 and COX-2 with IC50 values in the range between 1.29 and 4.92 µM [72].

The bioactivities of loureirin B (94) are worthy of note. The compound can modulate the TTX-R sodium channel in DRG neurons via an AC/cAMP/PKA pathway that involves the activation of AC and PKA [73]. Another study confirmed that compound 94 promotes insulin secretion and lowers blood glucose level mainly through increasing mRNA level of Pdx-1, MafA, and intracellular ATP level, and inhibiting KATP current and influx of intracellular Ca2+ [74]. Experiments on Crohn’s disease (CD) rat model induced by 2,4,6-trinitrobenzenesulfonic acid (TNBS) indicated that loureirin B (94) can be beneficial for ameliorating the damage to colon length in a dose dependent manner. Moreover, loureirin B remarkably ameliorated TNBS-induced inflammatory response via regulation of cytokines in the colonic tissues, and inhibited apoptosis through regulation of IL-6/STAT3/NF-κB signaling pathway. This finding may represent a novel approach to treat CD and provides an alternative choice for disorders associated with CD [70]. Homoisoflavans 69 and 7,10-dihydroxy-11-methoxydracaenone (structure 103 in Figure 15) were isolated from a CHCl3 extract of the plant. They were inactive against S. aureus, Bacillus subtilis, and Escherichia coli (MIC > 250 µg/mL) [75].

2.1.7. Dracaena usambarensis Engl. (synonym for Dracaena mannii Baker)

The plant is distributed from Senegal to Angola along the African west coast; it is widespread in tropical Africa and grows along the African east coast from Kenya to Kosi Bay in northern KwaZulu-Natal. Separation of a root extract afforded 4,4′-dihydroxy-2,3-dimethoxydihydrochalcone, the homoisoflavonoid 7-O-methyl-8-demethoxy-3-hydroxy-3,9-dihydropunctatin, and the homoisoflavanones 99 and (3S)-3,5,6,4′-tetrahydroxy-7-methoxyhomoisoflavanone (structure 104 in Figure 16) [76]. Compound 104 showed moderate cytotoxic effects against drug sensitive human lymphoblastic leukemia CCRF-CEM T cells; instead, it was inactive against all the other tested cell lines, including leukemia (CEM/ADR5000), human breast adenocarcinoma (MDA-MB-231-pcDNA3 and MDA-MB-231-BCRP clone 23), human glioblastoma (U87.MG and the resistant subline U87.MGΔEGFR), human hepatocyte carcinoma (Hep G2), and healthy hepatocyte (AML12) cell lines [76].

2.1.8. Other Dracaena spp.

(2S)-7,4′-Dihydroxy-8-methylflavan and (2S)-5,4′-dihydroxy-7-methoxy-8-methylflavan were isolated from the dragon’s blood of Dracaena tamaranae Marrero Rodr., R. S. Almeira, and M. Gonzales-Martin (Gran Canaria) [63]. The common flavonoids rutin, kaempferol, and quercetin were isolated from a methanolic extract of the leaves of Dracaena ombet Heuglin ex Kotschy and Peyr. [77]. Kaempferol 3-O-α-l-rhamnopyranosyl-(1→2)-O-[α-l-rhamnopyranosyl-(1→6)]-β-d-galacto- pyranoside and kaempferol 3-O-α-l-rhamnopyranosyl-(1→2)-O-[α-l-rhamnopyranosyl-(1→6)]-β-d-glucopyranoside were isolated from the leaves of Dracaena thalioides Makoy ex E. Morris, a perennial plant native to tropical regions of Africa [78].

2.1.9. Colorants of Dragon’s Blood Resins

Different red colorants, namely, dracaenin A (79) [42,54] (Figure 12), nordrachorhodin (105), dracorhodin (106), dracoflavilium (107/108), and dracorubin (109) (Figure 17), have been isolated from dragon’s blood resins obtained from different Dracaena trees [79]. The compounds share a common chromophore constituted by three conjugated rings forming a 2-phenyl-1-benzopyran moiety.

Figure 17

Chemical structures of compounds 105–109 responsible for the red color of dragon’s blood resin from Dracaena species.

These compounds undergo multiple structural transformations in aqueous acidic and basic solution, following the same basic mechanisms, that were completely characterized in the case of 7,4′-dihydroxy-5-methoxyflavilium, called dracoflavilium (107/108) [79]. This colorant was isolated from a resin extracted from D. draco centenary trees existing in the region of Lisbon and Madeira island; the structure was confirmed by total synthesis [79]. Dragon’s blood is yellow in strongly acidic aqueous solutions, because the species present is the flavylium cation 108. At moderately acidic pH values, the red quinoid base 107 is formed which absorbs at about 550 nm. This base is the major species (63%) at biological pH (ca. 6) and gives the resin the characteristic red color (Figure 1a). The remaining species (37%) in the equilibrium is the pale-yellow (E)-chalcone 110. Ionized (E)-chalcone 111 and the predominant pink deprotonated quinoid base 112 are present at pH = 8–9, whereas the double deprotonated base 113 is the only species occurring at pH = 12 (Figure 18) [79].

Figure 18

Species 110–113 in equilibrium with dracoflavilium (107/108) in aqueous solution at different pH.

2.2. Sansevieria Species

2.2.1. Sansevieria cylindrica Bojer ex Hook. (Dracaena angolensis (Welw. ex Carrière) Byng & Christenh)

Sansevieria cylindrica (Figure 1c), known with the indigenous names of cylindrical snake plant, African spear, spear sansevieria, and Saint Bárbara sword in Brazil, is a succulent plant native to Angola. In addition to ornamental uses, the whole plant is used in Myanmar traditional medicine for treating cuts, sprains, and broken bones, whereas the roots are used to cure snakebites. The hydroxymethyldihydrochalcone (1,2-seco-homoisoflavanone) (+)-2′,4′-dihydroxy-3′-methoxy-3,4-methylenedioxy-8-hydroxymethyldihydrochalcone, named (+)-(8S)-trifasciatine C (114), was isolated from the aerial parts of S. cylindrica [80]. It showed moderate cytotoxic effects against human breast adenocarcinoma (MCF7) cells. From the aerial parts of S. cylindrica Said et al. also isolated 3,7-dihydroxy-8-methoxy-3-(3′,4′-methylenedioxybenzyl) chroman-4-one, named (+)-(3S)-trifasciatine B (116 ≡ ent-127). This compound exhibited significant DPPH radical scavenging activity (IC50 35.2 µg/mL), that was comparable with that of ascorbic acid (IC50 33.3 µg/mL) [81]. Phytochemical investigations of S. cylindrica rhizomes, collected in Myanmar, revealed the presence of (-)-(8R)-trifasciatine C (115 ≡ ent-114), homoisoflavanones (-)-(3R)-trifasciatine A (126), (+)-trifasciatine B (116), compounds 117–120 (Figure 19), and (-)-cambodianol (20) [30], along with the furanoflavones lanceolatin B (121) and pongaglabol methyl ether (122), the flavone de(s)methoxy-kanugin (123), and the pterocarpan (-)-(6aR, 11aR)-homopterocarpin (124) [82,83].

Figure 19

Chemical structures of compounds 114–124 isolated from S. cylindrica.

Compounds 115, 116–120 displayed weak radical scavenging activity in the DPPH test (EC50 values > 100 mM) [82]. Lanceolatin B (121) showed high cancer chemopreventive potential [84], and anti-neuroinflammatory and analgesic properties [85].

2.2.2. Sansevieria roxburghiana Schult. & Schult. f.

The homoisoflavanone (-)-(3R)-cambodianol (20) was claimed to have been isolated from a MeOH extract of S. roxburghiana [86]. However, recent careful examination of the NMR spectra of the compound led to a revision of the structure. In fact, the correct structure corresponds to that of compound 125 (Figure 20), that is the enantiomer of homoisoflavanone 119 isolated from S. cylindrica [82,83].

Figure 20

Chemical structure of compound 125 isolated from S. roxburghiana.

2.2.3. Sansevieria trifasciata Prain (Dracaena trifasciata (Prain) Mabb)

Tchegnitegni and collaborators isolated two sappanin-type homoisoflavonoids, named trifasciatine A (126) and (-)-(3R)-trifasciatine B (127 ≡ ent-116) (Figure 21), from the EtOAc soluble fraction of a methanol extract of S. trifasciata [87]. Dihydrochalcone (+)-(8S)-trifasciatine C (114) was isolated from the aerial parts [88].

Figure 21

Chemical structures of compounds 126 and 127 isolated from S. trifasciata.

3. Chemical Structures and Chemotaxonomic Considerations

A wide variety of flavonoids and stilbenoids have been isolated from Dracaena species. They cover the families of flavones (e.g., 31), flavans (e.g., 2), flavanones (e.g., 12), homoisoflavans (e.g., 22), meta-homoisoflavans (e.g., 55), homoisoflavones (e.g., 3), homoisoflavanones (e.g., 13), chalcones (e.g., 10), dihydrochalcones (e.g., 7), chalcanes (e.g., 34), stilbenes (e.g., 43), and flavonoid dimers and trimers. Dimeric structures include flavan-flavan (e.g., 15), chalcane-flavan (e.g., 17), chalcone-dihydrochalcone (e.g., 24), chalcane-dihydro chalcone (e.g., 26), chalcane-homoisoflavan (e.g., 29), chalcane-stilbene (e.g., 60), chalcane-flavilium (e.g., 79), homoisoflavan-stilbene (e.g., 82), dihydrochalcone-stilbene (e.g., 84), and dihydrochalcone-homoisoflavan dimers (e.g., 86). Other dimers include a stilbene-phenylpropanoid dimer (44) and flavan-phenylpropanoid dimers (e.g., 5). Trimeric structures include chalcane-chalcane-flavan (e.g., 25), chalcane-chalcane-chalcane (e.g., 30), and dihydrochalcone-chalcane-chalcane trimers (e.g., 89). Interestingly, in contrast to these flavonoids, Dracaena anthocyanidins and anthocyanidin have poorly been characterized. Moreover, it is worth noting that the absolute configurations of several flavans, homoisoflavans, homoisoflavanones, and flavonoid dimers and trimers have not been determined. Nonetheless, the stereochemistry should be assigned, both for completing the structural determination of isolated compounds and for a better understanding of compound bioactivities.

Among flavonoid families, dihydrochalcones, flavans, homoisoflavans, meta-homoisoflavans, and oligomers appear to be diagnostic chemical clusters in Dracaena species. Loureins A (36) and B (37) are often used as the chemical markers for the quality control of dragon’s blood.

In contrast to the wide variety of Dracaena flavonoids, the chemical families mostly occurring in Sansevieria species are only flavones (e.g., 121) and homoisoflavanones (e.g., 116). This finding may depend on the fact that, compared with Dracaena species, less phytochemical studies have been devoted to Sansevieria spp. Moreover, Dracaena flavonoids have mostly been isolated from red resins, while those identified in Sansevieria have been found in extracts of aerial parts and rhizomes. Interestingly, the pterocarpan 124 and the 8-hydroxymethyldihydrochalcones (1,2-seco-homoisoflavanones) 114 and 115, isolated from two Sansevieria spp., are the only examples of such structures occurring in the two groups of plants. In addition to flavones, homoisoflavanones are the only flavonoids isolated from both Sansevieria and Dracaena species, although they display different substitution patterns. In fact, compared with Dracaena homoisoflavanones, the structures of the corresponding derivatives from Sansevieria spp. usually contain more O- and C-alkyl substituents; moreover, a hydroxy group is often bonded to C3. Enantiomeric trifasciatines B (116 and 127) and C (114 and 115), and homoisoflavanones 119 and 125 are examples of antipodal congeners occurring in different species of the same genus. More interesting is the isolation of enantiomeric compounds from different parts of the same plant. Thus, (+)-(8S)-trifasciatine C (114) was isolated from aerial parts of S. cylindrica [80], while the (8R)-enantiomer (115) was isolated from rhizomes [82]. Two different biosynthetic routes have been proposed to explain the formation of such antipodal flavonoids. Enantiodivergent biosynthetic reactions are involved that stem from achiral intermediates [82,87]. The isolation of homoisoflavonoids appears to have chemotaxonomic significance, because the largest number have been associated with Asparagaceae, Fabaceae and, to a minor extent, Liliaceae and Orchidaceae families [89].

4. Biological and Pharmacological Properties

The biological and pharmacological activities determined for dragon’s blood, crude and enriched extracts from Dracaena spp. are described in detail in reference [8]. These properties include analgesic, anti-inflammatory, antibacterial, hypolipidemic, hypoglycemic, and cytotoxic activities, as well as bidirectional regulation of hemorheology and cardiovascular and cerebrovascular effects. Pharmacological activities determined for individual flavonoids and stilbenoids isolated from Dracaena and Sansevieria species are summarized in Table 1. Standard in vitro biological assays have usually been carried out to measure the effects reported in the Table.

Table 1

Biological/pharmacological activities of characteristic flavonoids and stilbenoids isolated from Dracaena and Sansevieria species.

Source(s) and Compound(s)	Biological/pharmacological Activities	References
Dracaena angustifolia
(2R)-3′,7-dihydroxy-5′,5-dimethoxy-8-methylflavone (2)	Anti-inflammatory activity: 2 (IC50 = 45 µM); 3 (IC50 = 33 µM); 4 (IC50 = 61 µM)	[23]
desmethylisoophiopogonone B (3)
5,7,4′-trihydroxyhomoisoflavanone (4)
Dracaena cambodiana
cambodianins A (5) and B (6);4,4′-dihydroxy-2′-methoxychalcone (11)(3R)-7,4′-dihydrohomoisoflavanone (13)	Cytotoxic effects against chronic myelogenous leukemia K-562 (5, IC50 = 13.300 ± 0.064 µg/mL; 6, IC50 = 14.100 ± 0.042 µg/mL; 11, IC50 = 32.500 ± 0.082 µg/mL; 13, IC50 = 15.600 ± 0.040 µg/mL), human hepatocarcinoma SMMC-7721 (6, IC50 = 25.000 ± 0.025 µg/mL; 11, IC50 = 12.500 ± 0.025 µg/mL; 13, IC50 = 30.200 ± 0.022 µg/mL), and human gastric tumor SGC-7901 (6, IC50 = 68.000 ± 0.226 µg/mL; 11, IC50 = 11.000 ± 0.018 µg/mL; 13, IC50 = 20.500 ± 0.082 µg/mL) cell lines.Antibacterial activity against Staphylococcus aureus and methicillin-resistant S. aureus (MRSA)	[24]
(±)-7,4′-dihydroxyhomoisoflavanone	Moderate cytotoxic effects against human myeloid leukemia (K562) and human gastric tumor (SGC-7901) cell lines (IC50 = 16–29 μg/mL)	[31]
4,4′-dihydroxy-2,3′-dimethoxydihydrochalcone (7)	Antibacterial activity against S. aureus and MRSA	[24,25]
4,4′-dihydroxy-2-methoxydihydrochalcone (8)
cambodianins D (14) and E (15)
(2S)-7,4′-dihydroxy-6,8-dimethylflavan (16)
cambodianin G (18)	Cytotoxic effects against K-562 (IC50 = 9.5 µg/mL) and SGC-7901 (IC50 = 16.2 µg/mL) cell lines; antibacterial activity against S. aureus	[26]
cambodianin H (19)	Antibacterial activity against S. aureus
cambodianol (20)	Cytotoxic effects against K562 (IC50 = 1.4 µg/mL), SGC-7901 (IC50 = 2.9 µg/mL) and SMMC-7721 (IC50 = 5.0 µg/mL) cell lines, comparable with the values of paclitaxel	[30,31]
8-methylsocotrin-4′-ol	Moderate cytotoxic effects against K562 and SGC-7901 cell lines	[31]
4,4′-dihydroxy-3,2′-dimethoxychalcone	Cytotoxic effects against K562, SMMC-7721, and SGC-7901 cell lines, with IC50 values of 2.5, 4.3, and 4.4 mg/mL, respectively, comparable with the values of mitomycin C	[32]
(2R)-7,4′-dihydroxy-6-methylflavan (21)	Weak cytotoxic effects (IC50 = 39.22 μM) against human hepatocellular carcinoma BEL-7402 cell line	[34]
(3R)-7,3′,4′-trihydroxyhomoisoflavan (22)	Acetylcholinesterase (AChE) inhibitory activity	[34]
Dracaena cinnabari
4′-hydroxy-7,8-methylenedioxyhomoisoflavan (23)	Inhibition of NO (nitric oxide), TNF-α, and IL-6 production in lipopolysaccharide stimulated mouse macrophage RAW 264.7 cells	[36]
dracidione (24)	α-Glucosidase inhibitory activity (IC50 = 40.27 µg/mL)	[37]
Dracaena cochinchinensis
4,4′-dihydroxy-2-methoxydihydrochalcone (8)	Anti-neuroinflammatory effects (IC50 = 10.29 ± 1.05 µM)	[42]
apigenin	Remarkable anti-neuroinflammatory activity (inhibition of NO production): apigenin (IC50 = 3.12 ± 1.27 µM); 7-hydroxy-3-(4-hydroxybenzylidene) chroman-4-one (IC50 = 4.46 ± 0.95 μM); 31 (IC50 = 4.31 ± 1.79 µM); 32 (IC50 = 8.00 ± 2.04 µM); 33 (IC50 = 3.36 ± 1.67 µM)	[42]
7-hydroxy-3-(4-hydroxybenzylidene)chroman-4-one
7,3′-dihydroxy-4′-methoxyflavone (31)
7,4′-dihydroxyflavone (32)
7-hydroxyflavone (33)
4′-hydroxy-2,4-dimethoxydihydrochalcone (36)	Anti-inflammatory activity	[43]
4′-hydroxy-2,4,6-trimethoxydihydrochalcone (37)
(3S)-3,7,4′-trihydroxy-5-methoxyhomoisoflavanone (41)	Inhibitory activity against nitric oxide (NO) production: 41 (IC50 = 75.6 ± 1.2 µM); 42 (IC50 = 60.4 µM)	[52]
7,4′-dihydroxyhomoisoflavanone (42)
pterostilbene (43)	NQO1 [NAD(P)H Quinone Dehydrogenase 1] inducing activity and anti-inflammatory effects	[43]
7,4′-dihydroxy-8-methylflavan (45)	Osteogenic effects on mesenchymal stem cells (MSCs)	[49]
5,4′-dihydroxy-7-methoxy-6-methylflavan (46)	Osteogenic effects on mesenchymal stem cells (MSCs) and anti-inflammatory activity	[43,49]
7,4′-dihydroxyflavan (47)	Osteogenic effects on mesenchymal stem cells (MSCs)	[49]
(2S)-7,4′-dihydroxy-8-methylflavan (48)	Antibacterial activities against Helicobacter pylori (MIC = 31.3 µM)	[47]
dracaeconolide B (49)	Osteogenic effects on mesenchymal stem cells (MSCs)	[49]
(3R)-7,4′-dihydroxy-8-methoxyhomoisoflavan (50)
(3R)-7,4′-dihydroxyhomoisoflavan (51)
(3R)-7,4′-dihydroxy-5-methoxyhomoisoflavan (52)	Anti-neuroinflammatory activity (IC50 = 8.50 ± 1.28 µM)	[42]
7,4′-dihydroxyhomoisoflavan (53)	Anti-inflammatory activity	[43]
6,4′-dihydroxy-7-methoxyhomoisoflavan (54)
10-hydroxy-11-methoxydracaenone (58)	Inhibitory activity against NO production (IC50 = 62.4 ± 3.5 µM) and NQO1 inducing activity	[43,52]
cochinchinenene F (61)	NQO1 inducing activity	[43]
cochinchinenenes A (60), B (63), C (64), and D (65)	Thrombin inhibitory activity: 60 (IC50 > 9.5 µM); 63 (IC50 = 17.8 µM); 64 (IC50 = 26.7 µM); 65 (IC50 > 41.3 µM)	[47]
cochinchinenene E (66)	NQO1 inducing activity	[43]
“cochinchinenene G” (68)	Inhibitory activity against NO production (IC50 = 2.18 ± 1.43 µM)	[52]
(2R)-8-methylsocotrin-4′-ol (69)	Thrombin inhibitory activity (IC50 = 21.5 µM)	[47]
cochinchinenins L (72) and M (73)	Inhibitory effects on NO production in lipopolysaccharide (LPS)-stimulated BV-2 microglial cells: 72 (IC50 = 4.9 ± 0.4 µM); 73 (IC50 = 5.4 ± 0.6 µM)	[56]
cochinchinenin C (76)	Thrombin inhibitory activity (IC50 > 9.2 µM); antibacterial activity against Helicobacter pylori (MIC = 29.5 µM)	[47]
1-[5-(2-methoxy-4,4′- dihydroxydihydrochalconyl)]-1-(4-hydroxyphenyl)-3-(2-methoxy-4-hydroxyphenyl)propane	Thrombin inhibitory activity (IC50 = 26.3 µM)	[47]
biflavocochin A (82)	Neuroprotective effect on serum deficiency-induced cellular damage in neuroendocrine PC12 cells (pheochromocytoma cells derived from the adrenal gland of Rattus norvegicus)	[53]
biflavocochins B (83), F (87), and G (88)	Protein-tyrosine phosphatase 1B (PTP1B) inhibitory activity	[53]
(7E)-2,4-dihydroxy-1-methylstilbene (91)	Antioxidant activity and antifungal activity against Exserohilum turcicum, Bipolaris maydis, Curvularia lunata, and Fusarium graminearum	[58]
Dracaena loureiri
loureirin B (94)	Modulatory activity on the TTX-R sodium channel in dorsal root ganglion (DRG) neurons; effect on insulin secretion of pancreatic β-cells, increase of the mRNA level of Pdx-1, MafA, and intracellular ATP level; suppression of inflammatory cytokines and inhibition of apoptosis through regulation of IL-6/STAT3/NF-κB signalling pathway	[70,73,74]
loureirin D (96)	Inhibition of NO production stimulated byLPS-activated RAW 264.7 murine macrophages (IC50 = 50.3 µM)	[48,70]
4,4′-dihydroxy-2,6-dimethoxydihydrochalcone (97)(also isolated from D. cambodiana)	Cytotoxic effects against K-562 (IC50 = 12.800 ± 0.015 µg/mL), SMMC-7721 (IC50 = 16.200 ± 0.040 µg/mL), and SGC-7901 (IC50 = 10.000 ± 0.060 µg/mL) cell lines; antibacterial activities against S. aureus;stimulation of the hormone-dependent MCF-7 cell growth in a concentration dependent manner between 10−8 and 10−5 M	[24,71]
4′,2-dihydroxy-4,6-dimethoxydihydrochalcone (98)	Stimulation of the MCF-7 cell proliferation in a concentration dependent manner between 10−8 and 10−5 M	[71]
4,3′,5′-trihydroxystilbene (100)	Inhibitory activities of the enzymes COX-1 and COX-2: 100 (IC50 = 2.61 and 2.16 µM, respectively); 101 (IC50 = 4.92 and 2.21 µM, respectively); 102 (IC50 = 4.84 and 1.29 µM, respectively)	[72]
4,3′-dihydroxy-5′-methoxystilbene (101)
4-hydroxy-3′,5′-dimethoxystilbene (102)
5,7,4′-trihydroxyhomoisoflavanone (4)	Binding affinity for the bovine uterine estrogen receptor (IC50 = 375 nM)	[71]
Dracaena usambarensis
(3S)-3,4ʹ,5,6-tetrahydroxy-7-methoxyhomoisoflavanone (104)	Moderate cytotoxicity against drug sensitive human lymphoblastic leukemia CCRF-CEM cells	[76]
Sansevieria cylindrica
(+)-trifasciatine C (114)	Moderate cytotoxicity against MCF7 cells (IC50 = 34.1 µg/mL)	[80]
(+)-trifasciatine B (116)	Weak DPPH radical scavenging activity (IC50 = 35.2 µg/mL)	[81]
lanceolatin B (121)	High cancer chemopreventive potential, anti-neuroinflammatory and analgesic properties	[84,85]

Especially remarkable are the anti-inflammatory activities of cochinchinenins L (72) and M (73) [56], and pterostilbene (43) [43], and the anti-neuroinflammatory properties of 4,4′-dihydroxy-2-methoxydihydrochalcone (8), flavones 31–33, and homoisoflavan 59 [42]. The high cytotoxic effects exhibited by cambodianol (20) [30,31] and 4,4′-dihydroxy-3,2′-dimethoxychalcone [32] against different cell lines in an MTT assay are comparable with those the very well-known anti-cancer chemotherapy drugs paclitaxel and mitomycin C. The osteogenic effects of compounds 45–47, 49–51 [49] and the thrombin-inhibiting activities of cochinchinenene A (60) and cochinchinenin C (76) [47] are highly interesting. The inhibitory activities of the pro-inflammatory enzymes COX-1 and COX-2 by compounds 100–102 [72], as well as the PTP1B inhibitory activities of biflavocochins B (83), F (87), and G (88) [53], the multifaceted activities of loureirin B (94) [69,72,73], and the high cancer chemopreventive potential, anti-neuroinflammatory, and analgesic properties of lanceolatin B (121) are also worthy of note [84,85].

It must be stressed that in vivo pharmacological studies of the activities and underlying mechanisms of dragon’s blood and extracts from Dracaena and Sansevieria species are still incomplete or had an inappropriate scientific approach. The results are thus scientifically invalid [8]. Therefore, although these natural remedies have attractive potential therapeutic effects on different diseases, especially for the treatment of cardiovascular and cerebrovascular diseases, there is an urgent need to conduct experiments on appropriate cell lines and animal models under scientifically correct protocols, before they can enter into clinical trials [8]. The same conclusion holds for individual flavonoids and stilbenes; namely, more scientific experiments, especially in vivo, must be performed before promising bioactive compounds can be promoted as approved effective drugs.

5. Conclusions

The field of natural product chemistry has greatly contributed to the progress of pharmacology and medicine. The wide range of bioactive compounds isolated from different plants still motivate many research groups worldwide to find new bioactive constituents and to determine their structures and biological activities. In this review we have reported the most characteristic structures and bioactivities of flavonoids and stilbenes isolated from Dracaena and Sansevieria species. These plants have revealed to be rich sources of compounds having unprecedented structures and exhibiting a wide range of biological and pharmacological properties. More attention has been devoted to Dracaena than Sansevieria flavonoids, possibly due to the very well-known effects of the red resin dragon’s blood, that is collected from some Dracaena species and is widely used in several Asian traditional medicines. Indeed, the number and diversity of flavonoids isolated from Dracaena dragon’s blood are impressive, encompassing a great number of chemical families. In addition, the potential therapeutic effects of the drug and individual constituents on different diseases are attractive, such as the remarkable activities on cardiovascular, inflammatory, and cerebrovascular diseases. However, more in vitro and in vivo scientific experiments must be programmed and carried out before the effective material may be qualified as a suitable candidate for clinical trials.

Compared to the phytochemical investigations conducted on Dracaena spp., those concerning Sansevieria species are less numerous and isolated flavonoids are chemically less diverse. However, the structural similarities of flavonoids isolated from Sansevieria and Dracaena plants seem to justify, on a chemotaxonomic basis, the recent inclusion of Sansevieria species inside the genus Dracaena.