3.1. Bicyclogermacrane Sesquiterpenes
Chemical investigation of the soft coral
L. arboreum, which was collected near Bali, Indonesia, yielded the sesquiterpene (−)-bicyclogermacrene (
1) [
32] (
Figure 2). This compound exhibited low antiproliferative activities against the cell lines L-929 and K-562 with GI
50 values of 186 and 200 μM, respectively, and low cytotoxic effect against the HeLa cell line with CC
50 of 182 μM.
Figure 2. Chemical structure of the bicyclogermacrane sesquiterpene isolated from soft corals of the genus Litophyton.
3.2. Sec-Germacrane Sesquiterpenes
Very recently, Ahmed et al. [
33] carried out chemical investigation of the Red Sea specimen
L. arboreum, which was collected at Neweba, Egypt. The acyclic sesquiterpene (2
E,6
E)-3-isopropyl-6-methyl-10-oxoundeca-2,6-dienal (
2) was found from this sample, which possessed a
sec-germacrane nucleus (
Figure 3). Anti-malarial bioassays disclosed the isolate
2 was active against chloroquine-sensitive (D6) and chloroquine-resistant (W2) strains of
Plasmodium falciparum with IC
50 values of 3.7 and 2.2 mg/mL, respectively. In addition, the metabolite
2 was non-toxic to the Vero cell line at the concentration of 4.76 mg/mL. These findings demonstrated that sesquiterpene
2 could be developed as an anti-malarial lead compound that is highly safe in the range of tested concentrations.
Figure 3. Chemical structure of the sec-germacrane sesquiterpene from soft corals of the genus Litophyton.
3.3. Guaiane Sesquiterpenes
Interestingly, the guaiane sesquiterpenes were frequently encountered in the Red Sea soft coral L. arboreum.
Bioassay-guided fractionation of the Red Sea alcyonarian
L. arboreum by Ellithey et al., which was collected at Sharm El-Sheikh, Egypt, yielded three guaiane sesquiterpenes alismol (
3), 10-
O-methyl alismoxide (
4), and alismoxide (
5) [
34] (
Figure 4). Compound
3 showed potent inhibitory activity against HIV-1 protease receptor with IC
50 of 7.2 µM, compared to the positive control, which had IC
50 of 8.5 μM. A molecular docking study disclosed the hydrogen bond between
3 and the amino acid residue Asp 25 in the hydrophobic receptor pocket with a score of −11.14. Meanwhile, sesquiterpenes
3 and
4 showed moderate cytotoxic activities against the cell lines HeLa (IC
50 30 and 38 μM, respectively) and Vero (IC
50 49 and 49.8 μM, respectively). Moreover,
4 exhibited moderate cytotoxicity against the U937 cell line with IC
50 of 50 µM. However,
5 was judged as inactive against the above-mentioned cell lines (all IC
50 > 100 µM). In a further study, compounds
2 and
5 demonstrated cytostatic action in HeLa cells, revealing potential use in virostatic cocktails. In Ellithey’s continual study [
35], alismol (
3) showed promising cytotoxic effects against the cancer cell lines HepG2, MDA and A549 (IC
50 4.52, 7.02, and 9.23 μg/mL, respectively).
Figure 4. Chemical structures of the guaiane sesquiterpenes from soft corals of the genus Litophyton.
Hawas’s group reported the presence of alismol (
3) in a Red Sea specimen of
L. arboreum collected off the coast of Jeddah, Saudi Arabia, together with another guaiane sesquiterpene alismorientol B (
6) [
36] (
Figure 4). These two secondary metabolites were subjected to antimicrobial and cytotoxic bioassays. As a result, metabolites
3 and
6 showed weak to strong antibacterial activities against
Escherichia coli ATCC 10536,
Pseudomonas aeruginosa NTCC 6750,
Bacillus cereus ATCC 9634,
Bacillus subtilis ATCC6633, and
Staphylococcus aureus ATCC5141 with MIC values ranging from 10.4 to 1.3 μg/mL. Here, compound
6 had significant activity against
B. cereus ATCC 9634 with MIC of 1.3 μg/mL. Compounds
3 and
6 exhibited weak to moderate antifungal activities against
Candida albicans and
Aspergillus niger with MIC values ranging from 10.1 to 6.0 μg/mL. Moreover, they displayed cytotoxic effects against the cell lines MCF-7, HCT-116, and HepG2, with IC
50 ranging from 4.32 to 44.52 μM. Here, compound
6 showed the most potent cytotoxic effect against MCF-7 cells with IC
50 of 4.32 μM. Additionally, Hawas’s group evaluated the methanolic extract of the above-mentioned soft coral for its in vivo genotoxicity and antigenotoxicity against the mutagenicity induced by the anticancer drug cyclophosphamide [
20]. The extract was found to be safe and nongenotoxic at 100 mg/kg b. wt. Moreover, the mice group of cyclophosphamide pretreated with the extract (100 mg/kg b. wt.) showed significant reduction in the percentage of chromosomal aberrations induced in bone marrow and mouse spermatocytes.
The existence of alismoxide (
5) was shown in the Egyptian Red Sea
L. arboreum collection from Hurghada by Mahmoud et al. [
37]. In the anticancer bioassays, sesquiterpene
5 displayed no cytotoxic activities against the cell lines A549, MCF-7, and HepG2 (all IC
50 > 100 µmol/mL). The co-existence of alismol (
3) and alismoxide (
5) as well as an undescribed sesquiterpene, litoarbolide A (
7), and three known analogues 4
α,7
β,10
α-trihydroxyguai-5-ene (
8), leptocladol B (
9), and nephthetetraol (
10) (
Figure 4) in another Egyptian Red Sea
L. arboreum specimen from Neweba, was revealed by Ahmed et al.’s work [
33]. Viewing from the perspective of their structures, litoarbolide A (
7) was supposed to be the biosynthetic precursor to other sesquiterpenes, which could be generated via further post-translational modifications. The anti-malarial properties of substances
7–
10 were evaluated. However, only compounds
9 and
10 exhibited anti-malarial activities against chloroquine-resistant
P. falciparum W2 with IC
50 values of 4.3 and 3.2 mg/mL, respectively.
Guaiane sesquiterpenes 10-
O-methyl alismoxide (
4) and alismoxide (
5) were also obtained from the octocoral
Nephthea sp. by Hegazy et al., which was collected from the Egyptian Red Sea off the coast of Hurghada [
38]. These two metabolites showed cytotoxicity against the cell line MCF-7 (IC
50 85.5 and 151.9 μg/mL, respectively).
3.4. Pseudoguaiane Sesquiterpenes
A new pseudoguaiane-type sesquiterpene named litopharbol (
11) (
Figure 5) was isolated from the methanolic extract of the Saudi Arabian Red Sea soft coral
L. arboreum by Hawas’s group [
36]. Its structure was determined through the elucidation of NMR data. Compound
11 exhibited a wide spectrum of antibacterial activities against Gram-negative bacteria
E. coli ATCC 10536 and
P. aeruginosa NTCC 6750, as well as Gram-positive bacteria
B. cereus ATCC 9634,
B. subtilis ATCC6633, and
S. aureus ATCC5141 with MIC values ranging from 1.8 to 9.6 μg/mL. Among these bacteria,
11 showed significant activity against
B. cereus ATCC 9634 with an MIC of 1.8 μg/mL. In addition, this sesquiterpene exhibited weak antifungal activities against
C. albicans and
A. niger with MIC values of 12.5 and 12.9 μg/mL, respectively. Moreover, it displayed cytotoxic effects against cell lines MCF-7, HCT-116, and HepG2 with IC
50 values of 9.42, 26.21, and 38.92 μM, respectively. In Hawas’s continual study, litopharbdiol (
12) was identified, which shared the same carbon framework with
11 [
20] (
Figure 5). However, no bioassay for this compound was reported in the article.
Figure 5. Chemical structures of the pseudoguaiane sesquiterpenes from soft corals of the genus Litophyton.
3.5. Himachalene Sesquiterpenes
Purification of the CH
2Cl
2/MeOH extract of Saudi Arabian Red Sea alcyonarian
L. arboreum yielded a new himachalene-type sesquiterpene 3
α,6
α-epidioxyhimachal-1-ene (
13) (
Figure 6), which showed antiproliferative effects toward three different cancer cell lines MCF-7, HCT116, and HepG-2 [
39]. (It might be worth pointing out that no specific data of the bioassay results were provided in this article).
Figure 6. Chemical structure of the himachalene sesquiterpene from soft corals of the genus Litophyton.
3.6. Eudesmane Sesquiterpenes
The
n-hexane-chloroform (1:1) fraction of the Egyptian Red Sea
L. arboreum sample exhibited cytotoxicity towards the A549 cell line (IC
50 22.6 mg/mL) [
37]. The subsequent bioassay-guided isolation yielded a eudesmane sesquiterpene 5
β,8
β-epidioxy-11-hydroxy-6-eudesmene (
14) (
Figure 7). Compound
14 exerted noticeable activity against the A549 cell line (IC
50 67.3 µmol/mL) compared to etoposide as standard cytotoxic agent (IC
50 48.3 µmol/mL). However, this compound did not show cytotoxic effects against cell lines MCF-7 and HepG2 (both IC
50 > 100 µmol/mL).
Figure 7. Chemical structure of the eudesmane sesquiterpene from soft corals of the genus Litophyton.
3.7. Seco-Eudesmane Sesquiterpenes
In the above-mentioned study [
37], a
seco-eudesmane sesquiterpene chabrolidione B (
15) (
Figure 8) was co-isolated. However, compound
15 was judged as inactive against the cell lines A549, MCF-7, and HepG2 (all IC
50 > 100 µmol/mL).
Figure 8. Chemical structure of the seco-eudesmane sesquiterpene from soft corals of the genus Litophyton.
3.8. Tri-Nor-Eudesmane Sesquiterpenes
The methanolic extract of the Saudi Arabia Red Sea
L. arboreum collection harbored two tri-nor-eudesmane sesquiterpenes teuhetenone A (
16) and calamusin I (
17) [
36] (
Figure 9). Interestingly, these two nor-sesquiterpenes
16 and
17 displayed a wide spectrum of bioactivities. In the antibacterial bioassays, they showed moderate to strong activities against
E. coli ATCC 10536,
P. aeruginosa NTCC 6750,
B. cereus ATCC 9634,
B. subtilis ATCC6633, and
S. aureus ATCC5141 with MIC values ranging from 10.9 to 1.2 μg/mL. Here,
16 exhibited the most potent activity against
E. coli ATCC 10536 with an MIC of 1.9 μg/mL, and
17 displayed the most potent activity against
P. aeruginosa NTCC 6750 with an MIC of 1.2 μg/mL. In the antifungal biotests, they exhibited weak to moderate activities against
C. albicans and
A. niger with MIC values ranging from 7.4 to 3.2 μg/mL. In the cytotoxic experiments, they displayed cytotoxic effects against cell lines MCF-7 and HepG2 with IC
50 ranging from 6.43 to 39.23 μM. In addition, the methanolic extract of the Egyptian Red Sea
L. arboreum sample yielded another tri-nor-eudesmane sesquiterpene 7-oxo-tri-nor-eudesm-5-en-4
β-ol (
18) [
37] (
Figure 9). However, this nor-sesquiterpene
18 did not show cytotoxic activities against the cell lines A549, MCF-7, and HepG2 (all IC
50 > 100 µmol/mL).
Figure 9. Chemical structures of the tri-nor-eudesmane sesquiterpenes from soft corals of the genus Litophyton.
3.9. Eremophilane Sesquiterpenes
11,12-Dihydroxy-6,10-eremophiladiene (
19) (
Figure 10) was obtained from the soft coral
L. nigrum, using a structure-oriented HR-MS/MS approach [
31]. This alcyonarian specimen was collected at Xisha Islands, Hainan, China. However, no bioassays were performed due to its scarcity.
Figure 10. Chemical structure of the eremophilane sesquiterpene from soft corals of the genus Litophyton.
3.10. Nardosinane Sesquiterpenes
Interestingly, the South China Sea soft coral L. nigrum is a rich source of nardosinane sesquiterpenes.
The chemical investigation of the Xisha collection by Yang et al. afforded two new terpenes linardosinenes B (
20) and C (
21) [
14] (
Figure 11). These two compounds were evaluated for cytotoxities against different cell lines. Sesquiterpene
20 exhibited cytotoxic effect against the THP-1 cell line with IC
50 of 59.49 μM, while compound
21 displayed cytotoxicities against the cell lines SNU-398 and HT-29 with IC
50 of 24.3 and 44.7 μM, respectively. In their continual study on the Xisha sample, four additional new secondary metabolites linardosinenes D–G (
22–
25) (
Figure 11) were obtained [
40]. All metabolites exhibited weak inhibitory effect against bromodomain-containing protein 4 (BRD4), a promising therapeutic target in various human diseases, at a concentration of 10 μM with inhibitory rates ranging from 15.8% to 18.1%.
Figure 11. Chemical structures of the nardosinane sesquiterpenes from soft corals of the genus Litophyton.
Using a structure-oriented HR-MS/MS approach, an undescribed sesquiterpene linardosinene I (
26), along with its known 7
β,12
α-epimer lemnal-l(l0)-ene-7
β,12
α-diol (
27) (
Figure 11) were isolated from Xisha alcyonarian
L. nigrum [
31]. The absolute configuration of terpene
27 was determined to be 4
S,5
S,6
R,7
S,11
S,12
S by single crystal X-ray diffraction analysis with Cu K
α radiation [Flack parameter: 0.13(14)]. Sesquiterpene
26 exhibited a potent PTP1B inhibitory activity (IC
50 10.67 μg/mL). It also showed moderate cytotoxic activities against the human tumor cell lines HT-29, Capan-1, and SNU-398 with IC
50 values of 35.48, 42.55, and 25.17 μM, respectively. However, co-isolated metabolite
27 was inactive against PTP1B (IC
50 > 20 μg/mL) or cell lines HT-29, Capan-1, and SNU-398 (all IC
50 > 50 μM).
Recently, two members of this cluster, paralemnolin J (
28) and (l
S,8
S,8a
S)-
l-[(
E)-2′-acetoxy-l′-methylethenyl]-8,8
a-dimethyl-3,4,6,7,8,8
a-hexahydronaphthalen-2(1
H)-one (
29) (
Figure 11), were isolated in the chemical investigation of a Balinese soft coral
L. setoensis [
16]. In terms of biological activity, cytotoxic effects against several solid tumor and leukemia cell lines HT-29, Capan-1, A549, and SNU-398 were assessed for compounds
28 and
29. As a result, both compounds showed weak cytotoxic activities against the test cell lines (all IC
50 > 20 μM).
3.11. Nornardosinane Sesquiterpenes
Chemical study of Xisha alcyonarian
L. nigrum afforded an uncommon nornardosinane sesquiterpene linardosinene A (
30) [
14] (
Figure 12). The absolute configuration of
30 was determined by a modified Mosher’s method and TDDFT ECD approach. This isolate was evaluated for cytotoxicity against the THP-1 cell line and inhibitory activities against the PTP1B, BRD4, HDAC1, and HDAC6 protein kinases. However, it was inactive against the above-mentioned cell line and protein kinases.
Figure 12. Chemical structure of the nornardosinane sesquiterpene from soft corals of the genus Litophyton.
3.12. Neolemnane Sesquiterpenes
A study on the chemical constituents of the Chinese soft coral
L. nigrum yielded three new sesquiterpenes lineolemnenes A–C (
31–
33), which possessed the neolemnane carbon framework, together with the related known compound 4-acetoxy-2,8-neolemnadien-5-one (
34) [
14] (
Figure 13). It might be worth pointing out that the absolute configuration of
34 was unambiguously determined to be 1
S,4
S,12
S by X-ray diffraction analysis for the first time. The cytotoxicities of substances
31 and
32 against SNU-398, HT-29, Capan-1, and A549 were evaluated. This revealed that
31 and
32 only exhibited cytotoxic activity against SNU-398 with IC
50 values of 44.4 and 27.6 μM, respectively, and none of them showed potent inhibitory activities against the PTP1B, BRD4, HDAC1, and HDAC6 protein kinases. Compound
34 was also found in the Indonesian soft coral
L. setoensis, together with another sesquiterpene paralemnolin E (
35) [
16] (
Figure 13). They were subjected to cytotoxic bioassays against several solid tumor and leukemia cell lines HT-29, Capan-1, A549, and SNU-398. The results revealed both two compounds had weak cytotoxic activities against the test cell lines (all IC
50 > 20 μM). Parathyrsoidin E (
36) (
Figure 13) was reported in the soft coral
Nephthea sp., which was collected from the Egyptian coasts of the Red Sea at Sharm El-Sheikh [
41]. In silica study indicated this compound was a potential SARS-CoV-2 main protease inhibitor.
Figure 13. Chemical structures of the neolemnane sesquiterpenes from soft corals of the genus Litophyton.
3.13. Seconeolemnane Sesquiterpenes
A new sesquiterpene lineolemnene D (
37) (
Figure 14) was isolated and characterized from the Xisha soft coral
L. nigrum [
14]. Structurally, this compound possessed an unusual seconeolemnane skeleton. The absolute configuration of
37 was determined to be 1
S,4
R,12
S by TDDFT ECD approach. Bioassays including cytotoxicity against the THP-1 cell line and inhibitory activities against the PTP1B, BRD4, HDAC1, and HDAC6 protein kinases were performed for this isolate. However, it was judged as inactive in these biotests.
Figure 14. Chemical structure of the seconeolemnane sesquiterpene from soft corals of the genus Litophyton.
3.14. Kelsoane Sesquiterpenes
Interestingly, a new kelsoane-type sesquiterpene, namely kelsoenethiol (
38) (
Figure 15), was obtained from the Formosan soft coral
N. erecta [
30]. Its structure was elucidated with the assistance of quantum chemical calculations. The cytotoxicities of
38 against A-459, P-388, and HT-29 cancer cell lines were evaluated in vitro. The results revealed compound
38 exhibited cytotoxic activities against P-388 and HT-29 cells with ED
50s of 1.3 and 1.8 μg/mL, respectively.
Figure 15. Chemical structure of the kelsoane sesquiterpene from soft corals of the genus Litophyton.