Secondary Metabolites from Marine-Derived Fungi and Actinobacteria as Potential Sources of Novel Colorectal Cancer Drugs
Abstract
:1. Introduction
2. Potential Cytotoxic Metabolites from Various Marine Microorganisms against CRC
2.1. Marine Fungi
2.1.1. Aspergillus sp.
2.1.2. Penicillium sp.
2.1.3. Westerdykella sp.
2.1.4. Paradendryphiella sp.
2.1.5. Dichotomomyces sp.
2.1.6. Neosartorya sp.
2.2. Actinobacteria
2.2.1. Nocardiopsis sp.
2.2.2. Streptomyces sp.
3. Cytotoxicity Assays
4. Perspectives
5. Conclusions
Author Contributions
Funding
Institutional Review Board Statement
Informed Consent Statement
Acknowledgments
Conflicts of Interest
References
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Compound | Chemical Class | Producing Strain | Method, Cell Lines | Anticancer Potential * | Ref |
Marine fungi | |||||
Rosellichalasin (1) | Alkaloid, Cytochalasins | Aspergillus sp. nov. F1 | MTT assay, RKO | Moderate with IC50 = 37.3 µM | [16] |
Cytochalasin E (2) | Alkaloid, Cytochalasins | Aspergillus sp. nov. F1 | MTT assay, RKO | Weak with IC50 = 62.3 µM | [16] |
Allianthrone A (3) | Bianthrone | A. alliaceus (new strain, G4) | MTT assay, HCT116 | Very strong with IC50 = 9 µM | [18] |
Allianthrone B (4) | Bianthrone | A. alliaceus (new strain, G4) | MTT assay, HCT117 | Very strong with IC50 = 10.5 µM | [18] |
Allianthrone C (5) | Bianthrone | A. alliaceus (new strain, G4) | MTT assay, HCT118 | Strong with IC50 = 13.7 µM | [18] |
Fellutamide F (6) | Peptide, Lipopeptide | A. versicolor PF10M | SRB assay, HCT15 | Strong with IC50 = 0.13 µg/mL | [19] |
Fellutamide C (7) | Peptide, Lipopeptide | A. versicolor PF10M | SRB assay, HCT15 | Strong with IC50 = 1.74 µg/mL | [19] |
Asperphenin A (8) | Peptide, Lipopeptidyl Benzophenones | A. versicolor Ppf48 | SRB assay, RKO | Very strong with IC50 = 0.84 µM | [22] |
Asperphenin B (9) | Peptide, Lipopeptidyl Benzophenones | A. versicolor Ppf48 | SRB assay, RKO | Very strong with IC50 = 1.26 µM | [22] |
Penipacid A (10) | Anthranilic acid derivatives | P. paneum SD-44 | MTT assay, RKO | Very strong with IC50 = 8.4 µM | [23] |
Penipacid B (11) | Anthranilic acid derivatives | P. paneum SD-44 | MTT assay, RKO | Non-cytotoxic | [23] |
Penipacid C (12) | Anthranilic acid derivatives | P. paneum SD-44 | MTT assay, RKO | Non-cytotoxic | [23] |
Penipacid D (13) | Anthranilic acid derivatives | P. paneum SD-44 | MTT assay, RKO | Non-cytotoxic | [23] |
Penipacid E (14) | Anthranilic acid derivatives | P. paneum SD-44 | MTT assay, RKO | Very strong with IC50 = 9.7 µM | [23] |
Compound (15) | Anthranilic acid derivatives | P. paneum SD-44 | MTT assay, RKO | Non-cytotoxic | |
Brocazine A (16) | Peptide, Diketopiperazines with disulfide-bridged | P. brocae MA-231 | MTT assay, SW480 | Very strong with IC50 = 2.0 nM | [25] |
Brocazine B (17) | Peptide, Diketopiperazines with disulfide-bridged | P. brocae MA-231 | MTT assay, SW480 | Very strong with IC50 = 1.2 nM | [25] |
Brocazine C (18) | Peptide, Diketopiperazines with disulfide-bridged | P. brocae MA-231 | MTT assay, SW480 | Non-cytotoxic | [25] |
Brocazine D (19) | Peptide, Diketopiperazines with disulfide-bridged | P. brocae MA-231 | MTT assay, SW480 | Non-cytotoxic | [25] |
Brocazine E (20) | Peptide, Diketopiperazines with disulfide-bridged | P. brocae MA-231 | - | Not tested but showed activity against Du145, Hela, HepG2, MCF-7, NCI-H460, SGC-7901, SW1990, and U251 | [25] |
Brocazine F (21) | Peptide, Diketopiperazines with disulfide-bridged | P. brocae MA-231 | - | Not tested but showed activity against Du145, Hela, HepG2, MCF-7, NCI-H460, SGC-7901, SW1990, and U251 | [25] |
18-oxo-19,20-dihydrophomacin C (22) | Alkaloid, Cytochalasans | W. dispersa XL602 | MTT assay, HT29 | Non-cytotoxic | [27] |
18-oxo-19-methoxy-19,20- dihydrophomacin C C (23) | Alkaloid Cytochalasans | W. dispersa XL602 | MTT assay, HT29 | Non-cytotoxic | [27] |
18-oxo-19-hydroxyl-19,20-dihydrophomacin C (24) | Alkaloid, Cytochalasans | W. dispersa XL602 | MTT assay, HT29 | Non-cytotoxic | [27] |
19,20-dihydrophomacin C (25) | Alkaloid, Cytochalasans | W. dispersa XL602 | MTT assay, HT29 | Weak with IC50 = 49.09 µM | [27] |
19-methoxy-19,20-dihydrophomacin C (26) | Alkaloid, Cytochalasans | W. dispersa XL602 | MTT assay, HT29 | Weak with IC50 = 55.31 µM | [27] |
19-hydroxyl-19,20-dihydrophomacin C (27) | Alkaloid, Cytochalasans | W. dispersa XL602 | MTT assay, HT29 | Weak with IC50 = 55.48 µM | [27] |
Gymnastatin Z (28) | Alkaloid, Tyrosine-derivative | W. dispersa XL602 | MTT assay, HT29 | Weak with IC50 = 49.31 µM | [27] |
(3R, 6R) Hyalodendrin (29) | Heterocyclic aromatics, Piperazine | P. salina PC 362H | MTT assay, HCT116oxa | Very Strong with IC50 = 25.7 nM | [28] |
Dichotomocej A (30) | Amides | D. cejpii F31-1 | SRB assay, HCT116 | Non-cytotoxic | [30] |
Diorcinol (31) | Polyphenols | D. cejpii F31-1 | SRB assay, HCT116 | Non-cytotoxic | [30] |
3-O-methyldiorcinol (32) | Polyphonols | D. cejpii F31-1 | SRB assay, HCT116 | Non-cytotoxic | [30] |
Butyl (2-ethylhexyl) phthalate (33) | Phthalic Acid Esters | D. cejpii F31-1 | SRB assay, HCT116 | Non-cytotoxic | [30] |
Dichocerazine A (34) | Diketopiperazines | D. cejpii F31-1 | SRB assay, HCT116 | Non-cytotoxic | [30] |
Pityriacitrin (35) | Alkaloid, Indoles | D. cejpii F31-1 | SRB assay, HCT116 | Moderate with IC50 = 35.1 µM | [30] |
Stellarine A (36) | Alkaloid, Indoles | D. cejpii F31-1 | SRB assay, HCT116 | Non-cytotoxic | [30] |
Indolyl-3-acetic acid methyl ester (37) | Alkaloid, Indoles | D. cejpii F31-1 | SRB assay, HCT116 | Non-cytotoxic | [30] |
Chevalone C (38) | Meroterpenoids | N. siamensis KUFA 0017 | MTT assay, HCT116 | Non-cytotoxic with IC50 = 153 µM | [31] |
Nortryptoquivaline (39) | α-amino acid ester derivatives | N. siamensis KUFA 0017 | MTT assay, HCT116 | Non-cytotoxic with IC50 = 114 µM | [31] |
Tryptoquivaline H (40) | α-amino acid ester derivatives | N. siamensis KUFA 0017 | MTT assay, HCT116 | Non-cytotoxic with IC50 = 202 µM | [31] |
Fiscalin A (41) | Alkaloid, Indoles | N. siamensis KUFA 0017 | MTT assay, HCT116 | Non-cytotoxic with IC50 = 123 µM | [31] |
epi-Fiscalin A (42) | Alkaloid, Indoles | N. siamensis KUFA 0017 | MTT assay, HCT116 | Non-cytotoxic with IC50 = 277 µM | [31] |
epi-Neofiscalin A (43) | Alkaloid, Indoles | N. siamensis KUFA 0017 | MTT assay, HCT116 | Non-cytotoxic with IC50 = 203 µM | [31] |
epi-Fiscalin C (44) | Alkaloid, Indoles | N. siamensis KUFA 0017 | MTT assay, HCT116 | Weak with IC50 = 86 µM | [31] |
Actinobacteria | |||||
Androsamide (45) | Peptide, Cyclic Tetrapeptide | Nocardiopsis sp. CNT-189 | MTT assay, Caco-2 and HCT116 | Strong (for both cell lines tested) with IC50 = 13 µM againts Caco-2 cells and IC50 = 21 µM againts HCT116 cells | [32] |
Cyclo(Pro-Ala) (46) | Peptide, Diketopiperazines | S. nigra sp. nov. 452 | MTT assay, HCT116 | Moderate with IC50 = 47.6 µg/mL | [33] |
Cyclo(Pro-Val) (47) | Peptide, Diketopiperazines | S. nigra sp. nov. 452 | MTT assay, HCT116 | Moderate with IC50 = 67.2 µg/mL | [33] |
Cyclo(Pro-Leu) (48) | Peptide, Diketopiperazines | S. nigra sp. nov. 452 | MTT assay, HCT116 | Moderate with IC50 = 92.6 µg/mL | [33] |
Cyclo(Pro-Phe) (49) | Peptide, Diketopiperazines | S. nigra sp. nov. 452 | MTT assay, HCT116 | Moderate with IC50 = 32.3 µg/mL | [33] |
Furan-type Compound (50) | Heterocyclic aromatics, Furan | Streptomyces sp. VN1 | MTT assay, HCT116 | Non-cytotoxic with IC50 = 123.7 µM | [34] |
Petrocidin A (51) | Peptide, Cyclic Dipeptide | Streptomyces sp. SBT348 | MTT assay, HT29 | Strong with IC50 = 5.3 µg/mL | [35] |
2,3-dihydroxybenzoic acid (52) | Benzene | Streptomyces sp. SBT348 | MTT assay, HT29 | Non-cytotoxic | |
2,3-Dihydroxybenzamide (53) | Benzene | Streptomyces sp. SBT348 | MTT assay, HT29 | Strong with IC50 = 3.8 µg/mL | [35] |
Maltol (54) | 4H-pyran | Streptomyces sp. SBT348 | MTT assay, HT29 | Non-cytotoxic | |
Napyradiomycin CNQ525.510B (55) | Terpene, Meroterpenoids | Streptomyces sp. CNQ525 | MTS assay, HCT116 | Strong with IC50 = 17 µM | [37] |
Napyradiomycin CNQ525.538 (56) | Terpene, Meroterpenoids | Streptomyces sp. CNQ525 | MTS assay, HCT116 | Very strong with IC50 = 6 µM | [37] |
Napyradiomycin CNQ525.554 (57) | Terpene, Meroterpenoids | Streptomyces sp. CNQ525 | MTS assay, HCT116 | Non-cytotoxic | |
Napyradiomycin CNQ525.600 (58) | Terpene, Meroterpenoids | Streptomyces sp. CNQ525 | MTS assay, HCT116 | Moderate with IC50 = 49 µM | [37] |
Dionemycin (59) | Alkaloid, Indoles | Streptomyces strain SCSIO 11791 | MTT assay, HCT116 | Very strong with IC50 = 4.3 µM | [38] |
6-OMe-7′,7″-dichorochromopyrrolic acid (60) | Alkaloid, Indoles | Streptomyces strain SCSIO 11791 | MTT assay, HCT116 | Strong againts with IC50 = 13.1 µM | [38] |
Lynamicin B (61) | Alkaloid, Indoles | Streptomyces strain SCSIO 11791 | MTT assay, HCT116 | Very strong with IC50 = 8.7 µM | [38] |
Spiroindimicin B (62) | Alkaloid, Indoles | Streptomyces strain SCSIO 11791 | MTT assay, HCT116 | Very strong with IC50 = 2.2 µM | [38] |
K41 A (63) | Polyether | S. cacaoi 14CM034 | WST-1 assay, Caco-2 | Very Strong with IC50 = 7.4 µM | [39] |
Compound (64) | Polyether | S. cacaoi 14CM034 | WST-1 assay, Caco-2 | Strong with IC50 = 7.4 µM | |
PM100117 (65) | Macrolide, Polyhydroxyl | S. caniferus GUA-06-05-006A | SRB assay, HT29 | Very Strong with LC50 = 3.8 µM | [40] |
PM100118 (66) | Macrolide, Polyhydroxyl | S. caniferus GUA-06-05-006A | SRB assay, HT29 | Very Strong with IC50 = 4.1 µM | [40] |
Neo-actinomycin A (67) | Peptide, Cyclic Dipeptide | Streptomyces sp. IMB094 | SRB assay, HCT116 | Very Strong with IC50 = 38.7 nM | [41] |
Neo-actinomycin B (68) | Peptide, Cyclic Dipeptide | Streptomyces sp. IMB094 | SRB assay, HCT116 | Very Strong with IC50 = 339.1 nM | [41] |
Actinomycin D (69) | Peptide, Cyclic Dipeptide | Streptomyces sp. IMB094 | SRB assay, HCT116 | Very Strong with IC50 = 0.045 nM | [41] |
Actinomycin X2 (70) | Peptide, Cyclic Dipeptide | Streptomyces sp. IMB094 | SRB assay, HCT116 | Very Strong with IC50 = 0.0075 nM | [41] |
Ohmyungsamycin A (71) | Peptide, Cyclic Dipeptide | Streptomyces strain SNJ042 | SRB assay, HCT116 | Very Strong with IC50 = 7.61 µM | [42] |
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Julianti, E.; Abrian, I.A.; Wibowo, M.S.; Azhari, M.; Tsurayya, N.; Izzati, F.; Juanssilfero, A.B.; Bayu, A.; Rahmawati, S.I.; Putra, M.Y. Secondary Metabolites from Marine-Derived Fungi and Actinobacteria as Potential Sources of Novel Colorectal Cancer Drugs. Mar. Drugs 2022, 20, 67. https://doi.org/10.3390/md20010067
Julianti E, Abrian IA, Wibowo MS, Azhari M, Tsurayya N, Izzati F, Juanssilfero AB, Bayu A, Rahmawati SI, Putra MY. Secondary Metabolites from Marine-Derived Fungi and Actinobacteria as Potential Sources of Novel Colorectal Cancer Drugs. Marine Drugs. 2022; 20(1):67. https://doi.org/10.3390/md20010067
Chicago/Turabian StyleJulianti, Elin, Ikram Ammar Abrian, Marlia Singgih Wibowo, Muhammad Azhari, Nadya Tsurayya, Fauzia Izzati, Ario Betha Juanssilfero, Asep Bayu, Siti Irma Rahmawati, and Masteria Yunovilsa Putra. 2022. "Secondary Metabolites from Marine-Derived Fungi and Actinobacteria as Potential Sources of Novel Colorectal Cancer Drugs" Marine Drugs 20, no. 1: 67. https://doi.org/10.3390/md20010067
APA StyleJulianti, E., Abrian, I. A., Wibowo, M. S., Azhari, M., Tsurayya, N., Izzati, F., Juanssilfero, A. B., Bayu, A., Rahmawati, S. I., & Putra, M. Y. (2022). Secondary Metabolites from Marine-Derived Fungi and Actinobacteria as Potential Sources of Novel Colorectal Cancer Drugs. Marine Drugs, 20(1), 67. https://doi.org/10.3390/md20010067