Pharmacy and Drug Development

Abstract

Lichens are found on every landform and have a history of use as food, medicine, dyes, livestock feed and other fields. The pharmaceutical potential of lichens is high and several companies are now attempting to commercialise these unique agents. The secondary metabolites that lichen produces have a wide range of biological functions, including antibacterial, antiviral, antitumor, antioxidant, antiherpes, allelochemical, insecticidal, and allergenic effect. The purpose of this review was to systematically evaluate the literature on the biologically active secondary metabolites of lichen.

Introduction

Lichens are composite organisms containing algae and fungi. Lichens are a stable and self-supporting symbiosis between fungi (Mycobionts) and algal partners. Lichens are used in traditional medicine, food and various other ethnic uses by cultures across different countries in Asia. Moreover, some lichens are popularly used for lichen produce in ethnic and modern life. Many lichens are very sensitive to environmental disturbances and they can be used to assess air pollution. Lichens distribute on different types of the planet’s surface (About 7%); additionally, they are important components of primary producers in a wide range of substrates and habitats, including some of the most extreme conditions on earth [1-11]. Ethnolichenology is a branch of ethnobotany that studies the uses that man makes of lichens traditionally. Lichens are used for many different medicinal purposes, but there are some general categories of use that reoccur across the world. Lichens are often drunk as a decoction to treat ailments relating to either the lungs or the digestive system [12]. About 20,000 species of lichens growing on wide variety of substrates like rocks, walls, exposed soil surfaces and as epiphytes on the bark of trees and leaves have been recorded worldwide [13]. Secondary metabolites of lichen have long been used by Mankind, about 17000 species and more than 800 lichen metabolites are known to be utilized by human for several purposes. Lichen metabolites show great varieties of biological activities like antimycobacterial, antiviral, anti-inflammatory, antipyretic, analgesic, antiproliferative and cytotoxic properties [14]. 

Some lichens have been used in tribal medicine for treatment of different types of diseases and the secondary metabolites present in lichens have antibiotic, antimycobacterial, antiviral, antitumour, analgesic and antipyretic properties [15] and also have antiproliferative and antioxidant [16], and anti-HIV properties [17]. Lichens and their secondary metabolites have reported to possess great potential as antifungal source [18].  Lichen metabolites showed antihervivore activity [19]. Metabolites produced from lichens are poisonous to insects, snails, and nematodes [20]. In folk medicine lichens has been widely used for treatment of various diseases, such as eczema, respiratory diseases, pulmonary diseases and arthritis. They have been used cosmetics as well as food [21]. Lichen produces aromatic substances which strongly absorb UV light and protect the photobiont from dangerous irradiation [22]. Lichen secondary metabolites are sensitive to heavy metal accumulation and play a general role in metal homeostasis and pollution tolerance [19].

Secondary metabolites

The simplest definition of secondary metabolites is that they are not generally included in the standard metabolic charts [23]. Secondary metabolites are customarily distinguished from primary metabolites, which are the almost universally distributed compounds of intermediary metabolism. Secondary metabolites are often bioactive, usually of low molecular weight, and are produced as families of related compounds at restricted parts of the life cycle, with production often correlated with a specific stage of morphological differentiation. Secondary metabolites share the enigmatic properties of cellular dispensability - producer organisms can grow without synthesising these metabolites and restricted taxonomic distribution [24].

The Lichens

Lichens are symbiotic organisms composed of a fungal partner (mycobiont) in association with one or more photosynthetic partners (photobiont). The photobiont can be green algae, cyanobacteria, or both [25]. The fungus most often represents the Ascomycota division, less frequently the Basidiomycota one [26], while the photobiont belongs to the Chlorophyta or Cyanobacteria division [27]. Recent studies show lichens comprise about 18500 species [28]. In lichen (98%) of the fungal partners are Ascomycota [29], and the others are Basidiomycota and Anamorphic fungi. It has been estimated that 21% of all fungi are able to act as a mycobiont [29]. About 40 genera, 25 algae and 15 cyanobacteria, as photosynthetic partners are involved in the formation of lichens [19]. Lichen can be found in a wide range of habitat: from arctic to tropical regions, from plains to highest mountains [30], and from aquatic to xeric conditions. Also, Molnar and Farkas, [19], reported that most of the lichens are terrestrial, but a few species occur in freshwater streams and others in marine intertidal zones. According to Jayanthi et al., [31], lichens basically show three types of growth forms i. e. crustose, foliose and fruticose. Crustose lichens are encrusting forms which spread over and into the surface of their habitat and cannot be removed from the surface without crumbling away. Foliose lichens are lichens with leafy lobes, which spread out in a horizontal layer over the surface. On the other hand, Fruticose lichens are shrubby forms with many branches and they can be removed from the surface by hand.

To withstand extreme conditions, lichens synthesized metabolites which are valuable sources to develop new biotechnologies [32]. Ability to produce wide range of unique chemical compounds approves usage of lichens from ancient times as sources of colorants, cosmetics and remedies [33]. For example, Parmelia sulcata have been used to treat diseases of respiratory system, while Xanthoria parietina and Letharia vulpine were used against to cure jaundice and gastrointestinal disorders, respectively [34].

Lichen secondary metabolites

A great variety of secondary metabolites are synthesized by lichens with distinct biological properties [19]. These metabolites are complex, but predominantly small molecules, which comprise up to 20 % of lichen’s dry weight [35]. The content of secondary metabolites in the lichen thallus varies from 0.1 to 10%, but sometimes can even reach 30% of the dry weight of the thallus [36].

The secondary metabolites in lichens are produced through three major pathways: (1) acetylpolymalonyl, (2) mevalonic acid, and (3) shikimic acid [14]. To date more than 800 secondary metabolites have been identified for lichens. The continuing trends in compounds isolated from lichens approved their importance as a source of new natural products [33]. Long-time lichens were out of attention by pharmaceutical industry reasons of which were their slow-growing nature and difficulties to cultivate in laboratory conditions [33]. For the same reason it is difficult to obtain pure lichen metabolites in needful quantity for checking out their biological activities [33]. 

Lichen primary metabolism pathways produce basic substances constituting the structure of bionts, such as proteins, pigments, and vitamins [37]. Lichen secondary metabolites comprise many classes of compounds including amino acid derivatives, sugar alcohols, aliphatic acids, macrolytic lactones, monocyclic aromatic compounds, quinines, chromones, xanthones, dibenzofurans, depsides, depsidones, depsones, terpenoids, steroids, carotenoids, and diphenyl ethers [38]. 

Lichens promising antimicrobial agents

Ahmed et al., [39], studied different (Successive extraction by acetone, methanol, petroleum ether, and diethyl ether) extracts of Dirinaria picta, Dirinaria papillulifera, and Dirinaria applanata against Gram-positive and Gram-negative bacteria show solvent dependent inhibition activity. Most of the crude extracts showed far better inhibition activity than commercial streptomycin. As a result, it can be concluded that lichen extracts can be used as an alternative to commercially available antibacterial drugs. Thus, further investigations on purification, characterization, and identification of antimicrobial compound from lichen is needed [39].

Numerous lichen substances inhibit or slow down the growth of many microbial pathogens including bacteria, fungi [40] and viruses [41], as well as cancer cells [42]. Their analgesic, antipyretic [43] and antioxidant [44] properties have also been confirmed. On the other hand, the unusual properties of lichen compounds can be used for pharmacological purposes; hence, the wide interest of modern researchers in this field [45]. Among the widely investigated studies, those on the inhibition of dermatophytes, fungi that degrade keratin and therefore cause fungal infections of skin, hair and nails, are included [46]. 

Lichens as antifungal agent

The antifungal activity of extracts and secondary metabolites derived from lichen thalli against several species of dermatophytes was reviewed by a lot of scientists such as Epidermophyton floccosum (Harz) responsible for smooth skin mycosis, Microsporum canis, M. audouinii, M. nanum, M. gypseum causing mycosis of the scalp and hairy skin, Trichophyton rubrum (mycosis of the feet, groin, skin, hands, nails), T. mentagrophytes (foot fungus, smoother skin, hair), T. tonsurans and T. violaceum (hairy and smooth skin mycoses) [47, 48]. Also, the standard methods of culturing and testing the activity of lichen substances against dermatophytes have been provided by the Clinical and Laboratory Standards Institute.

Lichen extracts (Secondary metabolites) used against Fusarium sp. moulds by Furmanek et al., [49]. Lichen extracts were obtained from 51 corticolous, 17 terricolous and 18 saxicolous lichen species and 37 secondary compounds were tested against eight fungal species, i.e., Fusarium acuminatum, F. avenaceum, F. culmorum, F. fujikuroi, F. oxysporum, F. roseum, F. solani and F. udum. Lichen extracts were obtained by several solvents types. Lichen substances (Single secondary metabolites) were from Alectoria sarmentosa, Cladonia mitis, C. rangiferina, Flavoparmelia caperata, Hypotrachyna cirrhata, Leucodermia leucomelos, Parmotrema austrosinense, P. reticulatum, Physcia aipolia, Pseudevernia furfuracea, Roccella montagnei and Umbilicaria nylanderiana. Secondary metabolites such as 2-hydroxy-4-methoxy-3,6-dimethylbenzoic acid, atranorin, lecanoric and (+)-usnic acids showed the highest antifungal potential. These activities could compete with the potential of fungicides, such as fucytosine and fuconazole.  Different researches data showed that lichen extracts exert significant fungistatic potential [49]. 

The antifungal activity of secondary lichen metabolites extracted by means of acetone and ethanol from Cetraria islandica, Cladonia mitis, C. rangiferina, Pseudevernia furfuracea and Usnea dasopoga on the pathogenic fungi Fusarium oxysporum and F. avenacuem was studied by Tekiela et al., [50]. The most active extracts inhibiting the growth of fungal mycelia contained fumarprotocetraric, salazinic and usnic acids, and atranorin. The growth rate of the two Fusarium (Fusarium oxysporum and F. avenacuem) representatives was strongly inhibited by both alcoholic extracts from Cladonia mitis and from Cetraria rangiferina, more strongly than by the extracts from the mixed thalli of the two terricolous taxa [50]. 

Anti- dermatophytes fungi (Epidermophyton floccosum, Microsporum audouinii, M. canis, M. gypseum, M. nanum, Trichophyton longifusus, T. mentagrophytes, T. rubrum, T. tonsurans and T. violaceum) inhibition by compounds extracted by acetone, ethanol, methanol and water derived from several lichen genera (Caloplaca, Everniastrum, Heterodermia, Hypotrachyna, Platismatia and Ramalina) were represented by [51]. Lichen secondary compounds, like usnic acid, on the growth rates of these dermatophytes was also represented by Furmanek et al., [51]. The fungicidal activity of water-extracted compounds from Heterodermia leucomela and Hypotrachyna cirrhata and of methanol-extracted compounds from Evernia divaricata and Ramalina pollinaria, as well as protolichesterinic and 2-hydroxy-4-methoxy-3,6-dimethylbenzoic acids, are significant [51].

Antifungal potential of extracted lichen compounds and individual secondary metabolites against mold species of the genus Aspergillus is reported by Furmanek et al., [52]. Crude extracts from 49 epiphytic, 16 epigeic and 22 epilithic species of lichens and 44 secondary metabolites against 10 species, Aspergillus candidus, A. favus, A. fumigatus, A. nidulans, A. niger, A. ochraceus, A. parasiticus, A. restrictus, A. stellatus and A. ustus, were analysed by Furmanek et al., [52]. Lichen substances were extracted with different solvents (Alcoholic and other organic solvents). Crude extracts from the thalli of the lichens Cladonia foliacea, Hypotrachyna cirrhata, Leucodermia leucomelos, Platismatia glauca and Pseudevernia furfuracea against Aspergillus favus, from Cladonia foliacea, Nephroma arcticum and Parmelia sulcata against Aspergillus fumigatus and from Evernia prunastri, Hypogymnia physodes, Umbilicaria cylindrica and Variospora dolomiticola against Aspergillus niger have the greatest antifungal potential. The lichen secondary metabolites showed a higher inhibitory potential and their secondary metabolites shows that they can compete with commonly used antifungal substances, such as ketoconazole and clotrimazole [52].

Conclusion

Lichens are complex symbiotic associations between fungi and algae which are important constituents of many ecosystems. Lichens are a significant source of secondary metabolites with a wide range of biological functions. The considerable chemical diversity of lichen secondary metabolites makes them a powerful natural source of nutritional, medicinal, and antimicrobial compounds. The commercialisation of lichens is growing but, in the future, metabolic and biotechnological approaches can be used as an alternative production to overcome the limited availability of biologically active, commercially valuable and medicinally important secondary metabolite components. Further research is required in order to isolate and identify more bioactive compounds responsible for such biological activities.

References

1. Ahmed E, Elkhateeb W, Taie H, Rateb M, Fayad W. (2017). Biological capacity and chemical composition of secondary metabolites from representatives Japanese lichens. Journal of Applied Pharmaceutical Science, 7(01): 098-103.‏
   View at Publisher | View at Google Scholar
2. El-Garawani IM, Elkhateeb WA, Zaghlol GM, Almeer RS, Ahmed EF, Rateb ME, Moneim A. (2019). Candelariella vitellina extract triggers in vitro and in vivo cell death through induction of apoptosis: A novel anticancer agent. Food and Chemical Toxicology, 127: 110-119.‏
   View at Publisher | View at Google Scholar
3. Elkhateeb WA, Daba, G. M. (2019). Lichens, an alternative drug for modern diseases. International Journal of Research in Pharmacy and Biosciences, 6(10): 5-9.‏
   View at Publisher | View at Google Scholar
4. El-Garawani I, Emam M, Elkhateeb W, El-Seedi H, Khalifa S, Oshiba S, Daba G. (2020). In vitro antigenotoxic, antihelminthic and antioxidant potentials based on the extracted metabolites from lichen, Candelariella vitellina. Pharmaceutics, 12(5), 477.‏
   View at Publisher | View at Google Scholar
5. Elkhateeb WA, Daba, GM, El-Dein AN, Sheir DH, Fayad W, Shaheen MN, Wen TC. (2020). Insights into the in-vitro hypocholesterolemic, antioxidant, antirotavirus, and anticolon cancer activities of the methanolic extracts of a Japanese lichen, Candelariella vitellina, and a Japanese mushroom, Ganoderma applanatum. Egyptian Pharmaceutical Journal, 19(1), 67.‏
   View at Publisher | View at Google Scholar
6. Elkhateeb WA, Daba, GM. (2020). Occurrence of terpenes, polyketides, and tannins in some Japanese lichens and green mosses. Egyptian Pharmaceutical Journal, 19(3), 216.‏
   View at Publisher | View at Google Scholar
7. Elkhateeb WA, Elnahas MO, Daba GM. (2021). Lichentherapy: Highlights on the Pharmaceutical Potentials of Lichens. Open Access Journal of Microbiology & Biotechnology. 6(1): 1-10.
   View at Publisher | View at Google Scholar
8. Elkhateeb WA, Daba GM, Sheir D, Hapuarachchi KK, Thomas PW. (2021). Mysterious World of Lichens: Highlights on Their History, Applications, and Pharmaceutical Potentials. The Natural Products Journal, 11(3): 275-287.‏
   View at Publisher | View at Google Scholar
9. Elkhateeb WA, Daba GM. (2021). Fungi over fungi, endophytic fungi associated with mushroom fruiting bodies and lichens.‏ Journal of Pharmaceutics and Pharmacology Research. 4(2): 1-4.
   View at Publisher | View at Google Scholar
10. Elkhateeb W, Somasekhar T, Thomas P, Wen TC, Daba G. (2021). Mycorrhiza and Lichens as Two Models of Fungal Symbiosis. Journal of microbiology, biotechnology and food sciences, 11(3): e4644-e4644.‏
    View at Publisher | View at Google Scholar
11. Elkhateeb WA, El-Ghwas DE, Daba GM. (2022). Lichens Uses: Surprising Uses of Lichens that Improve Human Life. Journal ISSN, 2766, 2276.‏
    View at Publisher | View at Google Scholar
12. Yang MX, Devkota S, Wang LS, Scheidegger C. (2021). Ethnolichenology—the use of lichens in the Himalayas and southwestern parts of china. Diversity, 13(7): 330.‏
    View at Publisher | View at Google Scholar
13. Ellis CJ. (2012). Lichen epiphyte diversity: a species, community and trait-based review. Perspect Plant Ecol Evol Syst., 14(2): 131–152.
    View at Publisher | View at Google Scholar
14. Boustie J, Grube M. (2005). Lichens-a promising source of bioactive secondary metabolites. Plant Genet Resour., 3 (2): 273-287.
    View at Publisher | View at Google Scholar
15. Ingolfsdottir K, Hjalmarsdottir MA, Guojonsdottir GA, Brynjolfsdottir A, Sigurdsson A, Steingrimsson O. (1997). In vitro susceptibility of Helicobacter pylori to protolichesterinic acid from Cetraria islandica. Antimicrob Agents Chemotherapy. 41: 215- 217.
    View at Publisher | View at Google Scholar
16. Hidalgo ME, Fernandez E, Quilhot W, Lissi E. (1994). Antioxidant capacity of depsides and depsidones. Phytochem. 37: 1585–1587.
    View at Publisher | View at Google Scholar
17. Neamati N, Hong H, Mazumder A, Wang S, Sunder S, Nicklaus MC, Milne GW, Proksa B, Pommier Y. (1997). Depsides and depsidones as inhibitors of HIV-1 integrase: discovery of novel inhibitors through 3D database searching. J Med Chem. 40: 942–951.
    View at Publisher | View at Google Scholar
18. Muller K. (2002). Pharmaceutically relevant metabolites from lichens. Applied Microbiology and Biotechnology. 56: 9-16.
    View at Publisher | View at Google Scholar
19. Molnar K, Farkas E (2010). Current Results on Biological Activities of Lichen Secondary Metabolites. z Naturforsch. 65 c: 157 – 173.
    View at Publisher | View at Google Scholar
20. Ahad AM, Goto Y, Kiuchi F, Tsuda Y, Kondo K, Sato T. (1991). Nematocidal principles in “oakmoss absolute” and nematocidal activity of 2,4-dihydroxybenzoates. Chem Pharm Bull. 39: 1043-1046.
    View at Publisher | View at Google Scholar
21. Zeybek U, John V. (1992). Likenler (Lichenes), Kimyasal Bilesikleri ve Tibbi. Kullammlari. Pharmacia JTPA. 32(1): 37-48.
    View at Publisher | View at Google Scholar
22. Rundel PW. (1978). The ecological role of secondary lichen substances. Biochem Systemat Ecol. 6: 157-170.
    View at Publisher | View at Google Scholar
23. Davies J. (1985). Recombinant DNA and the production of small molecules. Washington: American Society for Microbiology Press.
    View at Publisher | View at Google Scholar
24. Keller NP, Turner G, Bennett JW. (2005). Fungal secondary metabolism‑from biochemistry to genomics. Nat Rev Microbiol, 3, 937‑47.
    View at Publisher | View at Google Scholar
25. Ertz D, Guzow-Krzemi_nska B, Thor G, Łubek A, Kukwa M. (2018). Photobiont switching causes changes in the reproduction strategy and phenotypic dimorphism in the Arthoniomycetes. Sci Rep 8, 4952–4966.
    View at Publisher | View at Google Scholar
26. Lücking R, Hodkinson BP, Leavitt SD. (2017). The 2016 classifcation of lichenized fungi in the Ascomycota and Basidiomycota— approaching one thousand genera. Bryologist 119: 361–416.
    View at Publisher | View at Google Scholar
27. 27. Bates ST, Cropsey GWG, Caporaso JG, Knight R, Fierer N. (2011). Bacterial community associated with the lichen symbiosis. Appl Environ Microbiol 77(4): 1309–1314.
    View at Publisher | View at Google Scholar
28. Feuerer T, Hawksworth DL. (2007). Biodiversity of lichens, including a world-wide analysis of checklist data based on Takhtajan’s floristic regions. Biodivers Conserv. 16: 85- 98.
    View at Publisher | View at Google Scholar
29. Honegger R. (1991). Functional aspects of the lichen symbioses. Annu Rev Plant Physiol Plant Mol Bio. 42: 553 – 578.
    View at Publisher | View at Google Scholar
30. Muller K (2001). Pharmaceutically relevant metabolites from lichens. Appl Microbiol Biotechnol. 56: 9 – 16.30. Muller K (2001). Pharmaceutically relevant metabolites from lichens. Appl Microbiol Biotechnol. 56: 9 – 16.30. Muller K (2001). Pharmaceutically relevant metabolites from lichens. Appl Microbiol Biotechnol. 56: 9 – 16.30. Muller K (2001). Pharmaceutically relevant metabolites from lichens. Appl Microbiol Biotechnol. 56: 9 – 16.30. Muller K (2001). Pharmaceutically relevant metabolites from lichens. Appl Microbiol Biotechnol. 56: 9 – 16.
    View at Publisher | View at Google Scholar
31. Jayanthi S, Priya P, Monica Devi D, Benila Smily JM. (2012). Lichens: Origin, types, secondary metabolites and applications. J Acad Indus Res. 1(1): 45-49.
    View at Publisher | View at Google Scholar
32. Suzuki MT, Parrot D, Berg G, Grube M, Tomasi S. (2016). Lichens as natural sources of biotechnologically relevant bacteria. Appl Microbiol Biotechnol. 100 (2): 583–595.
    View at Publisher | View at Google Scholar
33. Calcott MJ, Ackerley DF, Knight A, Keyzers RA, Owen JG. (2018). Secondary metabolism in the lichen symbiosis. Chem Soc Rev., 47(5): 1730–1760.
    View at Publisher | View at Google Scholar
34. Crawford SD. (2015). Lichens used in traditional medicine. In: Ranković B (ed) Lichen secondary metabolites: bioactive properties and pharmaceutical potential. Springer, Heidelberg, 27–80.
    View at Publisher | View at Google Scholar
35. Muggia L, Schmitt I, Grube M (2009). Lichens as treasure chests of natural products. SIM News. 59: 85-97.
    View at Publisher | View at Google Scholar
36. Ranković, B. and Kosanić, M. (2015). Lichens as a potential lichen source of bioactive secondary metabolites. In Lichen Secondary Metabolites. Bioactive Properties and Pharmaceutical Potential ed. Rankovic, B. pp. 1–26. Cham, Switzerland: Springer International Publishing.
    View at Publisher | View at Google Scholar
37. Shukla I, Azmi L, Gautam A, Shukla SK, Rao ChV. (2018). Lichens are the next promising candidates for medicinally active compounds. Int J Phytopharm 8(4):31–38.
    View at Publisher | View at Google Scholar
38. Huneck S. (1999). The significance of lichens and their metabolites. Naturwissenschaften. 86: 559–570.
    View at Publisher | View at Google Scholar
39. Ahmed S, Roy S, Tayung K, Yasmin F. (2020). Assessment of antibacterial potential of different solvent extract of foliose lichens against human pathogenic bacteria. Journal of Applied Pharmaceutical Science, 10(10): 072-076.‏
    View at Publisher | View at Google Scholar
40. Ranković B, Miśić M, Sukdolak S. (2008). The antimicrobial activity of substances derived from the lichens Physcia aipolia, Umbilicaria polyphylla, Parmelia caperata and Hypogymnia physodes. World J Microbiol Biotechnol 24, 1239–1242.
    View at Publisher | View at Google Scholar
41. Lai, D., Odimegwu, D.C., Esimone, C., Grunwald, T, Proksch, P. (2013) Phenolic compounds with in vitro activity against respiratory syncytial virus from the Nigerian lichen Ramalina farinacea. Planta Med 79, 1440–1446.
    View at Publisher | View at Google Scholar
42. Brisdelli F, Perilli M, Sellitri D, Piovano M, Garbarino JA, Nicoletti M, Bozzi A, Amicosante G. et al. (2013). Cytotoxic activity and antioxidant capacity of purified lichen metabolites: an in vitro study. Phytother Res 27: 431–437.
    View at Publisher | View at Google Scholar
43. Okuyama, E., Umeyama, K., Yamazaki, M., Kinoshita, Y, Yamamoto, Y. (1995). Usnic acid and diffractaic acid as analgesic and antipyretic components of Usnea diffracta. Planta Med 61, 113–115.
    View at Publisher | View at Google Scholar
44. Sisodia, R., Geol, M., Verma, S., Rani A, Dureja, P. (2013). Antibacterial and antioxidant activity of lichen species Ramalina roesleri. Nat Prod Res., 27: 2235–2239.
    View at Publisher | View at Google Scholar
45. Bellio, P., Segatore, B., Mancini, A., Di Pietro, L., Bottoni, C., Sabatini, A., Brisdelli, F., Piovano, M. et al. (2015). Interaction between lichen secondary metabolites and antibiotics against clinical isolates methicillin-resistant Staphylococcus aureus strains. Phytomedicine 22: 223–230.
    View at Publisher | View at Google Scholar
46. Pathak, A., Mishra, R.K., Shukla, S.K., Kumar, R., Pandey, M., Pandey, M., Qidwai, A. and Dikshit, A. (2016). In vitro evaluation of antidermatophytic activity of five lichens. Cogent Biol 2, 1–7.
    View at Publisher | View at Google Scholar
47. Kalinowska, K., Hryncewicz-Gwōźdź, A. and Plomer-Niezgoda, E. (2009). Rōznicowanie dermatofitōw z rodzaju Trichophyton. Micol Lek 16: 171–177.
    View at Publisher | View at Google Scholar
48. Kalinowska, K., Hryncewicz-Gwōźdź, A. and Plomer-Niezgoda, E. (2010). Rōznicowanie dermatofitōw z rodzaju Microsporum oraz Epidermophyton. Mikol Lek 17: 47–52.
    View at Publisher | View at Google Scholar
49. Furmanek Ł, Czarnota P, Seaward MR. (2022). A review of the potential of Fusarium lichen substances as antifungal agents: the effects of extracts and lichen secondary metabolites on fungi. Archives of Microbiology, 204(8): 1-31.‏
    View at Publisher | View at Google Scholar
50. Tekiela A, Furmanek Ł, Andrusiewicz M, Bara G, Seaward MR, Kapusta I, Czarnota P. (2021). Can lichen secondary compounds impact upon the pathogenic soil fungi Fusarium oxysporum and F. avenaceum?. Folia Cryptogamica Estonica, 58: 165-181.‏
    View at Publisher | View at Google Scholar
51. Furmanek Ł, Czarnota P, Seaward M. (2019). Antifungal activity of lichen compounds against dermatophytes: a review. Journal of Applied Microbiology, 127(2): 308-325.
    View at Publisher | View at Google Scholar
52. Furmanek Ł, Czarnota P, Seaward M. (2022). The effect of lichen secondary metabolites on Aspergillus fungi. Archives of microbiology, 204(1): 1-34.‏
    View at Publisher | View at Google Scholar