Antibacterial potencial of 12 Lichen species

MICHELETTI, ANA C.; HONDA, NELI K.; RAVAGLIA, LUCIANA M.; MATAYOSHI, TATIANA; SPIELMANN, ADRIANO A.

doi:10.1590/0001-3765202120191194

Abstract

Resistant bacterial infections are a major public health problem worldwide, which entails the need to search for new therapeutic agents. In this context, lichens stand out, provided that they are producers of structurally diverse compounds that have attractive biological properties, including antimicrobial activity. Thus, extracts of 12 lichen species were prepared and their potential to inhibit the growth of 5 bacterial strains was evaluated in this work. The chemical compositions of these extracts were examined using TLC and microcrystallization, being the identity of the active compounds in each extract attributed based on the bioautography technique. The most active extracts (and their identified active compounds) were from Cladonia borealis (usnic, barbatic and 4-O-demethylbarbatic acids), Cladina confusa (usnic and perlatolic acids), Stereocaulom ramulosum (atranorin, perlatolic and anziaic acids) and Canoparmelia cryptochlorophaea (cryptochlorophaeic and caperatic acids), with MICs ranging from 7.8 to 31.25 μg/mL, including for resistant clinical strains. MIC values were also obtained for substances isolated from lichens for comparison purposes. A group of four extracts containing usnic acid was analyzed by ¹H NMR in order to correlate relative proportion of major metabolites and extracts activity. The less active extracts in this group, in fact, presented low proportion of usnic acid.

Key words
Antimicrobial; bioautography; lichen; microdilution

INTRODUCTION

Antibiotic resistance has drawn the attention of public agencies all over the world. The cost of treatment for patients infected with resistant microorganisms is high, as well as the risks in surgical procedures and infections (Picconi et al. 2017PICCONI P, HIND C, JAMSHIDI S, NAHAR K, CLIFFORD M, WAND ME, SUTTON JM & RAHMAN KM. 2017. Triaryl Benzimidazoles as a New Class of Antibacterial Agents against Resistant Pathogenic Microorganisms. J Med Chem 60: 6045-6059., WHO 2018WHO – WORLD HEALTH ORGANIZATION. 2018. Available at: http://www.who.int/mediacentre/factsheets/fs194/en/.
http://www.who.int/mediacentre/factsheet... ). According to Rai et al. (2017)RAI M, INGLE AP, RANDIT R, PARALIKAR P, GUPTA I, CHAUD MV & DOS SANTOS CA. 2017. Synergistic antimicrobial potential of essential oils in combination with nanoparticles: Emerging trends and future perspectives. Int J Pharm 532: 67-78. there are about 2 million cases of resistant infections per year in the United States, with 23,000 deaths, and in Europe, the death toll reaches 25,000 per annum. The situation in Asia and developing countries is even more worrying and considering the increase in antibiotic resistance to several pathogens, infections with multi-resistant microorganisms are estimated to account for 10 million deaths per year by 2050, surpassing other diseases such as cancer (Rai et al. 2017RAI M, INGLE AP, RANDIT R, PARALIKAR P, GUPTA I, CHAUD MV & DOS SANTOS CA. 2017. Synergistic antimicrobial potential of essential oils in combination with nanoparticles: Emerging trends and future perspectives. Int J Pharm 532: 67-78.).

Taking this into account, the search for new active compounds should be frequent to keep up with the adaptability of bacteria. Consequently, processes in drug discovery, activity optimization and characterization of selectivity and toxicity of compounds are of utmost importance.

Nature is an important source of chemical compounds for the search for unknown therapeutic agents (Owen & Laird 2018OWEN L & LAIRD K. 2018. Synchronous application of antibiotics and essential oils: dual mechanisms of action as a potential solution to antibiotic resistance. Crit Rev Microbiol 44: 414-435., Rondevaldova et al. 2018RONDEVALDOVA J, HUMMELOVA J, TAUCHEN J & KOKOSKA L. 2018. In vitro antistaphylococcal synergistic effect of isoflavone metabolite demethyltexasin with amoxicillin and oxacillin. Microb Drug Resist 24: 24-29.), and is a great ally in the urgent search for new antimicrobial agents. In this context, lichens have a vital role because they produce a number of unique compounds (e.g., depsides, depsidones, dapsones, dibenzofurans, anthraquinones, xanthones), with a wide range of biological activities (Calcott et al. 2018CALCOTT MJ, ACKERLEY DF, KNIGHT A, KEYZERS RA & OWEN JG. 2018. Secondary metabolism in the lichen symbiosis. Chem Soc Rev 47: 1730-1760., Galanty et al. 2019GALANTY A, PAŚKO P & PODOLAK I. 2019. Enantioselective activity of usnic acid: a comprehensive review and future perspectives. Phytochem Rev 18: 527-548., Reddy et al. 2019REDDY SD ET AL. 2019. Comprehensive analysis of secondary metabolites in Usnea longissima (lichenized ascomycetes, Parmeliaceae) using UPLC-ESI-QTOF-MS/MS and pro-apoptotic activity of barbatic acid. Molecules 24: 2270-2288.), among them, antibiotic activity. According to Kosanić & Ranković (2015)KOSANIĆ M & RANKOVIĆ B. 2015. Lichen secondary metabolites as potential antibiotic agents. In: Ranković B (Eds), Lichen secondary metabolites bioactive properties and pharmaceutical potential, Springer, Cham, p. 81-104., more than 50% of the lichens studied for their antibiotic potential were active. A recent review by Basnet et al. (2018)BASNET BB, LIU H, LIU L & SULEIMEN YM. 2018. Diversity of anticancer and antimicrobial compounds from lichens and lichen-derived fungi: a systematic review (1985-2017). Cur Org Chem 22: 2487-2500. compiles the antimicrobial activity information of lichen compounds described in the literature between 1985 and 2017, showing the wide structural variety and biological potential, with quantitative and qualitative data. Among the compounds described, some prominent examples are physodic, lobaric and rhizocarpic acids, active on multiresistant strains of S. aureus; gyrophoric acid, with MICs up to 0.125 μg/mL for various bacterial strains; the sulfur compounds coniothiepinol A and coniothienol A, active on Enterococcus strains.

Given the importance of lichen as a source of biologically active substances and in order to contribute to the search for strategies to constrain bacterial infections, 12 species of lichen were selected to evaluate their antibacterial potential, together with the analysis of their chemical composition as well as to investigate the substances responsible for the activity presented by the extracts.

MATERIALS AND METHODS

Lichens and isolated compounds

The species selected for the study were: Cladonia borealis Stenroos, Cladonia confusa, R. Santesson, Cladonia crispatula (Nyl.) Ahti, Cladonia furcata (Hudson) Schrader, Punctelia canaliculata (Lynge) Krog, Parmotrema lichexanthonicum Eliasaro & Adler, Pseudoparmelia sphaerospora (Nyl.) Hale, Ramalina anceps Nyl., Stereocaulon ramulosum (Sw.) Räusch, Usnea jamaicensis Ach., Canoparmelia cryptochlorophaea (Hale) Elix and Concamerella pachyderma (Hue) W.L. Culb. & C.F. Culb. Exsiccates are deposited in the herbarium of the Federal University of Mato Grosso do Sul, in Campo Grande/ MS (CGMS 52970, CGMS 40953, CGMS 39230, CGMS 39229, CGMS 40952, CGMS 52969, CGMS 49837, CGMS 49839, CGMS 40957, CGMS 49838, CGMS 37949 and CGMS 52968, respectively). All species studied are registered at SisGen platform (entry ABAE41C).

Some isolated compounds were selected for evaluation of their antimicrobial activity. Usnic (from Usnea subcavata), perlatolic (from C. confusa), psoromic (from U. jamaicensis), hypostictic, secalonic (both from P. sphaerospora), salazinic (from P. lichexanthonicum), norstictic (from Ramalina sp.), barbatic (from C. borealis) and protocetraric acids and atranorin (both from Parmotrema dilatatum) were isolated according to the procedure described in the literature (Honda et al. 2010HONDA NK, PAVAN FR, COELHO RG, LEITE SRA, MICHELETTI AC, LOPES TIB, MISUTSU MY, BEATRIZ A, BRUM RL & LEITE CQF. 2010. Antimycobacterial activity of lichen substances. Prytomedicine 17: 328-332., Brandão et al. 2013BRANDÃO LFG, ALCANTARA GB, MATOS MFC, BOGO D, FREITAS DS, OYAMA N & HONDA NK. 2013. Cytotoxic evaluation of phenolic compounds from lichens against melanoma cells. Chem Pharm Bull 61: 176-183., Guterres et al. 2017GUTERRES ZR, HONDA NK, COELHO RG, ALCANTARA GB & MICHELETTI AC. 2017. Antigenotoxicity of depsidones isolated from brazilian lichens. Orbital: Electron J Chem 9: 50-54.).

Chemical composition of the extracts

The composition analysis of each extract was performed by thin layer chromatography (TLC) and also by making use of the microcrystallization (MC) technique. Portions of the thalli were cleaned, fragmented and extracted twice with acetone at room temperature. Silica gel 60 GF₂₅₄ precoated TLC plates (Merck) were used for TLC by applying the following eluents: toluene: ethyl acetate: formic acid (139: 83: 8, v/ v/ v); toluene: acetic acid (85: 15, v/ v). The spots were visualized under UV light (254 nm) and then chemically revealed by nebulization with methanol / H₂SO₄ solution (10%) followed by heating, and after that, with p-anisaldehyde / H₂SO₄ solution, which was also followed by heating.

For MC technique, the following solutions were used: glycerin: acetic acid (GE 1: 3 and 3: 1 v/ v), glycerin: ethanol: water (GAW 1: 1: 1 v/ v/ v) and glycerin: ethanol: O-toluidine (GAoT 2: 2: 1 v/ v/ v). The produced crystalline forms were observed under a microscope (Nikkon Eclipse E 220) with 10x magnification. Purity grade P.A solvents were employed at all stages of the work.

NMR spectroscopy was used for composition analysis of some extracts of interest in order to obtain the relative proportion of their major constituents (C. confusa, U. jamaicensis, C. borealis and R. anceps). The dried extracts were resuspended using DMSO-d₆ (Sigma-Aldrich), at a concentration of 15 mg/mL. ¹H NMR spectra were acquired on a Bruker DPX-300 spectrometer (operating at 300.13 MHz for ¹H) using one single pulse sequence (90°x) with 8 transient scans. The spectra were acquired and processed with 64k points. Manual phase, baseline corrections and exponential multiplication of 0.3 Hz were applied. The chemical shifts were calibrated using the residual solvent signal as a reference. Signals unambiguously attributed to the analyzed substances were used to assess the relative proportion. In C. confusa extract, the signals at 2.0 ppm (methyl-16 of usnic acid) and 3.74 ppm (methoxyl group of perlatolic acid) were analyzed and in U. jamaicensis, the signals in ppm 6.26 (H-4 of usnic acid) and 3.83 ppm (psoromic acid methoxyl) were used. For C. borealis extract, the signals analyzed were that at 6.18 ppm (H-4 of usnic acid) and 3.82 ppm (barbatic acid methoxyl). R. anceps extract showed ¹H NMR signals for only one major component.

Antibacterial assays

Sigma-Aldrich culture media and reagents were used for the evaluation of the biological activity. Commercial Newprov bacterial strains Staphylococcus aureus (NEWP0023), Enterococcus faecalis (NEWP0012), Escherichia coli (NEWP0022), and clinical strains which were provided by UFMS University Hospital were used (S. aureus resistant to clindamycin, erythromycin and penicillin G, and Enterococcus faecium resistant to vancomycin, SisGen entries ACF89BA and A38E2AF).

Microdilution and bioautography assays were conducted as described by Honda et al. 2016aHONDA NK, FREITAS DS, MICHELETTI AC, CARVALHO NCP, SPIELMANN AA & CANÊZ LS. 2016a. Parmotrema screminiae (Parmeliaceae), a novel lichen species from Brazil with potent antimicrobial activity. Orbital: Electron J Chem 8: 334-340.. Briefly, for microdilution test, the samples were serially diluted in 96-well plates prepared with Mueller Hinton broth, with final concentrations ranging from 1000 to 0.98 μg/mL. For positive control (gentamicin), the final concentrations ranged from 60 to 0.5 μg/mL. A 5 μL aliquot of the bacterial inoculum was added to each well (24h culture in Mueller-Hinton agar suspended in 0.45% sterile saline solution at 10⁸ CFU/mL, diluted 1:10 in saline solution). Assays were performed in triplicate and the microdilution plates were incubated at 36°C for 18 h. After this time, 20 μL triphenyltetrazolium chloride aqueous solution (0.5%) (TTC) was added to each well and the plates were re-incubated at 36°C for 2 h. In wells where microbial metabolism remained active, it went from colorless to red. The minimum inhibitory concentration (MIC), was defined as the lowest concentration of each sample in which no color change occurred.

For bioautography assays chromatograms of each extract were placed on a Petri dish containing Mueller-Hinton agar and covered with an approximately 2 mm thick agar layer. The plates were then seeded with bacterial inocula and incubated at 36°C for 24 h. An aqueous solution (0.5%) of TTC was nebulized over the plates and the absence of color change indicated regions of the chromatograms containing active substances.

RESULTS AND DISCUSSION

After TLC and MC analyses (figure S1 – see Supplementary Material), with support from the literature (Culberson 1972CULBERSON CF. 1972. Improved conditions and new data for identification of lichen products by standardized thin-layer chromatographic method. J Chromatogr A 72: 113-125., Culberson et al. 1981CULBERSON C, CULBERSON W & JOHNSON A. 1981. A standardized TLC analysis of β-orcinol depsidones. Bryologist 84: 16-29., Huneck & Yoshimura 1996HUNECK S & YOSHIMURA I. 1996. Identification of Lichen Substances, Berlin, Heidelberg: Springer, 493 p.) and using some isolated substances as standards, it was possible to access the main chemical constituents of each extract, as shown in Table I.

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Table I
Studied species and their chemical composition.

The extracts and some isolated compounds were evaluated for their antibiotic activity against Gram-positive bacteria S. aureus (NEWP0023 and clinical strain resistant to clindamycin, erythromycin and penicillin G), E. faecalis (NEWP0012) and E. faecium (clinical strain resistant to vancomycin) and Gram-negative Escherichia coli (NEWP0022) by the broth microdilution assay (Honda et al. 2016aHONDA NK, FREITAS DS, MICHELETTI AC, CARVALHO NCP, SPIELMANN AA & CANÊZ LS. 2016a. Parmotrema screminiae (Parmeliaceae), a novel lichen species from Brazil with potent antimicrobial activity. Orbital: Electron J Chem 8: 334-340.). The results, expressed as the minimum inhibitory concentration (MIC) in µg/mL, are shown in Table II. Gentamicin was used as a positive control.

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Table II
MIC values (µg/mL) for lichen extracts or isolated compounds against five bacterial strains.

Among the 12 assessed extracts, the antimicrobial activity of 9 of them is being described for the first time. For C. furcata, S. ramulosum and C. confusa extracts, antibacterial activity data are described in the literature, however, the evaluations were not performed with the same bacteria and, for the last two, the assay method was also different (Perry et al. 1999PERRY NB, BENN MH, BRENNAN NJ, BURGESS EJ, ELIS G, GALLOWAY DJ, LORIMER SD & TANGNEY S. 1999. Antimicrobial, antiviral and cytotoxic activity of New Zeland lichens. Lichenologist 31: 627-633., Ranković et al. 2011RANKOVIĆ BR, KOSANIĆ MM & STANOJKOVIĆ TP. 2011. Antioxidant, antimicrobial and anticâncer octivity of the lichens Cladonia furcata, Lecanora atra and Lecanora muralis. BMC Complementary Altern Med 11: 97-104., Kosanić et al. 2014KOSANIĆ M, RANKOVIĆ B, STANOJKOVIĆ T, RANČIĆ A & MANOJLOVIĆ N. 2014. Cladonia lichens and their major metabolites as possible natural antioxidante, antimicrobial and anticâncer agentes. LWT-Food Sci Technol 59: 518-525.).

Some extracts showed significant activity on the evaluated bacteria, with MIC values up to 7.8 μg/mL. According to Kuete, MICs up to 10 μg/mL are considered as expressive activity for pure compounds, and for the extracts, this limit would be up to 100 μg/mL (Kuete 2010KUETE V. 2010. Potential of Cameroonian plants and derived products against microbial infections: a review. Planta Med 76: 1479-1491.). Also noteworthy is the fact that several extracts showed good activity on multi-resistant clinical strains. It can be highlighted the activity of C. borealis, C. confusa, S. ramulosum and C. cryptochlorophaea extracts, which presented the lowest values of MIC. C. crispatula, C. furcata and S. sphaerospora extracts were moderately active (100 <CMI ≤ 625 μg/mL) for both S. aureus strains, while extracts from P. canaliculata, R. anceps and U. jamaicensis showed good to moderate activity for the 4 strains tested. None of the extracts were active on E. coli.

The literature provides some recent studies showing the antibacterial activity of lichen extracts (Shrestha et al. 2014SHRESTHA G, RAPHAEL J, LEAVITT SD & ST. CLAIR L. 2014. In vitro evaluation of the antibacterial activity of extracts from 34 species of North American lichens. Pharm Biol 52: 1262-1266., 2016, Jha et al. 2017JHA BN, SHRESTHA M, PANDEY DP, BHATTARAI T, BHATTARAI HD & PAUDEL B. 2017. Investigation of antioxidant, antimicrobial and toxicity activities of lichens from high altitude regions of Nepal. BMC Complementary Altern Med 17: 282-289., Moura et al. 2017MOURA JB, VARGAS AC, GOUVEIA GV, GOUVEIA JJS, RAMOS-JÚNIOR JC, BOTTON SA, PEREIRA EC & COSTA MM. 2017. In vitro antimicrobial activity of the organic extract of Cladonia substellata Vainio and usnic acid against Staphylococcus spp. obtained from cats and dogs. Pesq Vet Bras 37: 368-378., Brakni et al. 2018BRAKNI R ET AL. 2018. UHPLC-HRMS/MS based profiling of algerian lichens and their antimicrobial activities. Chem Biodiversity 15: e1800031., Maurya et al. 2018MAURYA IK, SINGH S, TEWARI R, TRIPATHI M, UPADHYAY S & JOSHI Y. 2018. Antimicrobial activity of Bulbothrix setschwanensis (Zahlbr.) Hale lichen by cell wall disruption of Staphylococcus aureus and Cryptococcus neoformans. Microb Pathog 115: 12-18.). The work from Moura et al. describes the good activity of Cladonia substelatta extract on 136 Staphylococcus spp. strains isolated from cats and dogs, with different resistance profiles, showing that lichens can be an interesting source of antimicrobials either for veterinary purpose (Moura et al. 2017MOURA JB, VARGAS AC, GOUVEIA GV, GOUVEIA JJS, RAMOS-JÚNIOR JC, BOTTON SA, PEREIRA EC & COSTA MM. 2017. In vitro antimicrobial activity of the organic extract of Cladonia substellata Vainio and usnic acid against Staphylococcus spp. obtained from cats and dogs. Pesq Vet Bras 37: 368-378.). They report meaningful results for a strategic area, as zoonotic antibiotic resistance can be transmitted to human pathogens through direct contact between animal and humans (Wegener 2012WEGENER HC. 2012. Antibiotic resistance—linking human and animal health. In: IMPROVING FOOD SAFETY THROUGH A ONE HEALTH APPROACH: Workshop Summary. Washington, DC: The National Academies Press, p. 331-349.).

Shrestha et al. draws attention to a study of 34 lichen species from North America, and highlight that extracts with MICs <16 μg/mL over methicillin-resistant S. aureus (MRSA) were considered very active (Shrestha et al. 2014SHRESTHA G, RAPHAEL J, LEAVITT SD & ST. CLAIR L. 2014. In vitro evaluation of the antibacterial activity of extracts from 34 species of North American lichens. Pharm Biol 52: 1262-1266.). Based on this parameter, extracts from C. borealis, C. confusa, S. ramulosum and C. cryptochlorophaea have a great antibacterial potential, since they presented MIC values <16 μg/mL for the two multi-resistant clinical strains evaluated. In addition, in a further work the author selected one of these 34 extracts (Letharia vulpina) and studied its mode of antimicrobial action, proven it to interfere in membrane stability and to disrupt cell division processes (Shrestha et al. 2016SHRESTHA G, THOMPSON A, ROBISON R & ST. CLAIR L. 2016. Letharia vulpina, a vulpinic acid containing lichen, targets cell membrane and cell division processes in methicillin-resistant Staphylococcus aureus. Pharm Biol 54: 413-418.).

The active extracts were selected for the antibiotic activity assay using the bioautography technique (Honda et al. 2016aHONDA NK, FREITAS DS, MICHELETTI AC, CARVALHO NCP, SPIELMANN AA & CANÊZ LS. 2016a. Parmotrema screminiae (Parmeliaceae), a novel lichen species from Brazil with potent antimicrobial activity. Orbital: Electron J Chem 8: 334-340.), in order to have qualitative indications of which would be the active components of each extract. The assignment of the constituents, which are likely to be responsible for inhibiting microbial growth, was based on chromatograms of the same extracts which were chemically revealed (Table III, Figures S6 to S9). It´s interesting to highlight that cryptochlorophaeic and caperatic acids were found to be the active compounds on C. cryptochlorophaea extract. This is the first report of antimicrobial activity for these substances.

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Table III
Active components in bioautography assay of selected extracts.

Figure 1 shows the structures of the compounds identified as active in the evaluated extracts.

Figure 1
Chemical structures of compounds with antimicrobial activity according to bioautography test.

Some isolated compounds were also evaluated for their antimicrobial potential by broth microdilution method. Usnic, perlatolic and barbatic acids and atranorin were selected for assessment because they are present in active extracts and have been identified as responsible for antimicrobial activity, according to the bioautography assay. The other active compounds, according to bioautography, could not be isolated due to small amount of lichen available. Psoromic acid as well as hypostictic, secalonic, norstictic, salazinic, and protocetraric acids, were present in extracts with moderate or no activity, but were also selected to be evaluated separately.

Table II presents the MIC data for these compounds and shows the great antibacterial potential of usnic and perlatolic acids, which presented low MIC values for the 4 strains tested. Barbatic acid showed good to moderate activity, especially against E. faecalis strain for which it was more active. E. faecalis was also more susceptible to depsidones norstictic acid, hypostictic acid and salazinic acid, with moderate MIC values.

There have been reports for promising antibiotic activity of usnic and perlatolic acids, the most active compounds found in this work. The recent review published by Galanty et al. presented antimicrobial activity of usnic acid for a large set of bacterial strains, showing MIC values from 2 to 16 μg/mL for E. faecalis, E. faecium, MSSA (methicillin-susceptible S. aureus) and MRSA (methicillin-resistant S. aureus) (Galanty et al. 2019GALANTY A, PAŚKO P & PODOLAK I. 2019. Enantioselective activity of usnic acid: a comprehensive review and future perspectives. Phytochem Rev 18: 527-548.). Antonenko et al. (2019)ANTONENKO YN, KHAILOVA LS, ROKITSKAYA TI, NOSIKOVA ES, NAZAROV PA, LUZINA OA, SALAKHUTDINOV NF & KOTOVA EA. 2019. Mechanism of action of an old antibiotic revisited: Role of calcium ions in protonophoric activity of usnic acid. Biochim Biophys Acta Bioenerg 1860: 310-316. discussed the mechanism of action of this compound, pointing out that it is related to its ability to cause dissipation of membrane potential in bacterial cells (Antonenko et al. 2019ANTONENKO YN, KHAILOVA LS, ROKITSKAYA TI, NOSIKOVA ES, NAZAROV PA, LUZINA OA, SALAKHUTDINOV NF & KOTOVA EA. 2019. Mechanism of action of an old antibiotic revisited: Role of calcium ions in protonophoric activity of usnic acid. Biochim Biophys Acta Bioenerg 1860: 310-316.). For perlatolic acid, Bellio et al. (2015)BELLIO P ET AL. 2015. Interaction between lichen secondary metabolites and antibiotics against clinical isolates methicillin-resistant Staphylococcus aureus strains. Phytomedicine 22: 223-230. showed their relevant antimicrobial activity against 20 strains of MRSA, with MICs ranging from 4 to 64 μg/mL. In addition, they revealed a synergistic relationship between perlatolic acid and some commercial antibiotics, such as clindamycin and gentamicin (Bellio et al. 2015BELLIO P ET AL. 2015. Interaction between lichen secondary metabolites and antibiotics against clinical isolates methicillin-resistant Staphylococcus aureus strains. Phytomedicine 22: 223-230.), which has been described as an interesting approach to overcome antimicrobial resistance.

There are also data for anziaic acid (Lin et al. 2013LIN H, ANNAMALAI T, BANSOD P, TSE-DINH Y & SUN D. 2013. Synthesis and antibacterial evaluation of anziaic acid and its analogues as topoisomerase I inhibitors. Med Chem Com 4: 1613-1618.), barbatic acid (Martins et al. 2010MARTINS MCB, DE LIMA MJG, SILVA FP, AZEVEDO-XIMENES E, DA SILVA NH & PEREIRA EC. 2010. Cladia aggregata (lichen) from Brazilian Northeast: Chemical characterization and antimicrobial activity. Braz Arch Biol Technol 53: 115-122.) and atranorin (Studzińska-Sroka et al. 2017STUDZIŃSKA-SROKA E, GALANTY A & BYLKA W. 2017. Atranorin - an interesting lichen secondary metabolite. Mini-Rev Med Chem 17: 1633-1645.) against various bacterial strains. The MIC values found throughout this work are comparable to those found in the literature, but for some compounds, such as perlatolic and barbatic acids and atranorin, the activity on Enterococcus is being described for the first time.

The extracts of C. confusa, U. jamaicensis, C. borealis and R. anceps present usnic acid as one of their chemical components, and this substance was strongly active against the evaluated bacteria, however, the antimicrobial profile of the extracts did not show the same behavior. For this reason, ¹H NMR spectra were obtained from the extracts to compare the relative proportion of the major metabolites enabling to understand how the variation of the concentration of the substances may be influencing the evaluated biological activity (Table IV, Figures S2 to S5).

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Table IV
Porportion of main compounds found in selected lichen extracts by NMR analisys.

With this analysis, it was possible to observe that activity was directly linked to proportion of active compounds. R. anceps and U. jamaicensis extracts contain no or few usnic acid, and it correlates with their poor antibiotic activity. For the first one, it can be observed that the MIC values of the extract and isolated norstictic acid are the same for 3 of the 4 strains evaluated. The behavior observed for the U. jamaicensis extract follows the same trend, as psoromic acid, the major component, was not active when evaluated alone and the low activity of the extract reflects the low proportion of usnic acid in the mixture.

The relative proportion observed between usnic acid and barbatic acid was approximately 1:1 in C. borealis extract. It was not found in the ¹H NMR spectrum of the extract signals that could be assigned only to 4-O-demethylbarbatic acid, so it was not possible to establish its relative proportion in the mixture. The antibacterial activity of the extract generally seems to assume a median behavior between the activity of the two compounds alone, being more active than barbatic acid and less active than usnic acid.

The C. confusa extract presented a relative proportion between usnic and perlatolic acids of approximately 1:1.5, being the perlatolic acid the major component. Both compounds have outstanding antibacterial activity (Table II); however, the extract shows a higher MIC than the isolated components for the two standard strains. Nevertheless, the reduction in activity does not appear to be significant enough to state that the effect between the compounds is antagonistic (Owen & Laird 2018OWEN L & LAIRD K. 2018. Synchronous application of antibiotics and essential oils: dual mechanisms of action as a potential solution to antibiotic resistance. Crit Rev Microbiol 44: 414-435.).

CONCLUSION

Extracts from 12 lichen species had their chemical profile evaluated, in order to attribute their major chemical components. These extracts presented a wide variety of compounds, from the classes of usnic acids, depsides, depsidones, xanthones and fatty acids. The extracts were also tested for their antibacterial potential by broth microdilution assay against 5 bacterial strains, and among the active ones, there was selectivity for Gram-positive bacteria, which included 2 standard strains and 2 multi-resistant clinical strains. C. borealis, C. confusa, S. ramulosum and C. cryptochlorophaea extracts were the most active, with MIC values between 7.8 and 31.25 µg/ mL. It was possible to assign the active components of each extract through the bioautography technique: usnic acid, barbatic and 4-O-demethylbarbatic acids, perlatolic and anziaic acids, atranorin, cryptochlorophaeic and caperatic acids. For these last two acids, it is the first report of antibiotic activity. Other compounds found in the extracts were also evaluated by microdilution and proved active, like usnic, perlatolic, barbatic, salazinic, hypostictic and norstictic acids.

As usnic acid was strongly active and some extracts containing this component were inactive, an NMR analysis was performed to assign the relative proportion between the major components of 4 extracts containing this substance (C. borealis, C. confusa, R. anceps. and U. jamaicensis) making it clear that the proportion in which this active component is found in the extract is directly related to the potency of the activity. When correlating the MIC values found for the isolated compounds and extracts, no evidence of synergistic or antagonistic effect was found between the components.

ACKNOWLEDGMENTS

The authors would like to thank Conselho Nacional de Desenvolvimento Científico e Tecnológico (CNPq) and Fundação de Apoio ao Desenvolvimento do Ensino, Ciência e Tecnologia do Estado de Mato Grosso do Sul (FUNDECT-MS) for the financial support and to Pró-Reitoria de Pesquisa e Pós-Graduação/ Universidade Feral de Mato Grosso do Sul (PROPP- UFMS). This study was financed in part by the Coordenação de Aperfeiçoamento de Pessoal de Nível Superior Brazil (CAPES) – Finance Code 001.

REFERENCES

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BRAKNI R ET AL. 2018. UHPLC-HRMS/MS based profiling of algerian lichens and their antimicrobial activities. Chem Biodiversity 15: e1800031.
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CALCOTT MJ, ACKERLEY DF, KNIGHT A, KEYZERS RA & OWEN JG. 2018. Secondary metabolism in the lichen symbiosis. Chem Soc Rev 47: 1730-1760.
CULBERSON C, CULBERSON W & JOHNSON A. 1981. A standardized TLC analysis of β-orcinol depsidones. Bryologist 84: 16-29.
CULBERSON CF. 1972. Improved conditions and new data for identification of lichen products by standardized thin-layer chromatographic method. J Chromatogr A 72: 113-125.
FLEIG M, GRÜNINGER W, MAYER WE & HAMPP R. 2008. Lichens of the Araucaria Forest of Rio Grande do Sul. Pró-Mata: Field Guide Nr. 3, Tübingen: University of Tübingen, 219 p.
GALANTY A, PAŚKO P & PODOLAK I. 2019. Enantioselective activity of usnic acid: a comprehensive review and future perspectives. Phytochem Rev 18: 527-548.
GUTERRES ZR, HONDA NK, COELHO RG, ALCANTARA GB & MICHELETTI AC. 2017. Antigenotoxicity of depsidones isolated from brazilian lichens. Orbital: Electron J Chem 9: 50-54.
HONDA NK, FREITAS DS, MICHELETTI AC, CARVALHO NCP, SPIELMANN AA & CANÊZ LS. 2016a. Parmotrema screminiae (Parmeliaceae), a novel lichen species from Brazil with potent antimicrobial activity. Orbital: Electron J Chem 8: 334-340.
HONDA NK, GONÇALVES K, BRANDÃO LFG, COELHO RG, MICHELETTI AC, SPIELMAN AA & CANÊZ LS. 2016b. Screening of lichen extracts using tyrosinase inhibition and toxicity against Artemia salina. Orbital: Electron J Chem 8: 181-188.
HONDA NK, LOPES TIB, COSTA RCS, COELHO RG, YOSHIDA NC, RIVAROLA CRV, MARCELLI MP & SPIELMANN AA. 2015. Radical-scavenging Potential of Phenolic Compounds from Brazilian Lichens. Orbital: Electron J Chem 7: 99-107.
HONDA NK, PAVAN FR, COELHO RG, LEITE SRA, MICHELETTI AC, LOPES TIB, MISUTSU MY, BEATRIZ A, BRUM RL & LEITE CQF. 2010. Antimycobacterial activity of lichen substances. Prytomedicine 17: 328-332.
HUNECK S & YOSHIMURA I. 1996. Identification of Lichen Substances, Berlin, Heidelberg: Springer, 493 p.
JHA BN, SHRESTHA M, PANDEY DP, BHATTARAI T, BHATTARAI HD & PAUDEL B. 2017. Investigation of antioxidant, antimicrobial and toxicity activities of lichens from high altitude regions of Nepal. BMC Complementary Altern Med 17: 282-289.
KOSANIĆ M & RANKOVIĆ B. 2015. Lichen secondary metabolites as potential antibiotic agents. In: Ranković B (Eds), Lichen secondary metabolites bioactive properties and pharmaceutical potential, Springer, Cham, p. 81-104.
KOSANIĆ M, RANKOVIĆ B, STANOJKOVIĆ T, RANČIĆ A & MANOJLOVIĆ N. 2014. Cladonia lichens and their major metabolites as possible natural antioxidante, antimicrobial and anticâncer agentes. LWT-Food Sci Technol 59: 518-525.
KUETE V. 2010. Potential of Cameroonian plants and derived products against microbial infections: a review. Planta Med 76: 1479-1491.
LIN H, ANNAMALAI T, BANSOD P, TSE-DINH Y & SUN D. 2013. Synthesis and antibacterial evaluation of anziaic acid and its analogues as topoisomerase I inhibitors. Med Chem Com 4: 1613-1618.
MARTINS MCB, DE LIMA MJG, SILVA FP, AZEVEDO-XIMENES E, DA SILVA NH & PEREIRA EC. 2010. Cladia aggregata (lichen) from Brazilian Northeast: Chemical characterization and antimicrobial activity. Braz Arch Biol Technol 53: 115-122.
MAURYA IK, SINGH S, TEWARI R, TRIPATHI M, UPADHYAY S & JOSHI Y. 2018. Antimicrobial activity of Bulbothrix setschwanensis (Zahlbr.) Hale lichen by cell wall disruption of Staphylococcus aureus and Cryptococcus neoformans. Microb Pathog 115: 12-18.
MICHELETTI AC, BEATRIZ A, DE LIMA DP, HONDA NK, PESSOA CO, DE MORAES MO, LOTUFO LV, MAGALHÃES EYF & CARVALHO NCP. 2009. Constituintes químicos de Parmotrema lichexanthonicum Eliasaro & Adler: isolamento, modificações estruturais e avaliação das atividades antibiótica e citotóxica. Quim Nova 32: 12-20.
MOURA JB, VARGAS AC, GOUVEIA GV, GOUVEIA JJS, RAMOS-JÚNIOR JC, BOTTON SA, PEREIRA EC & COSTA MM. 2017. In vitro antimicrobial activity of the organic extract of Cladonia substellata Vainio and usnic acid against Staphylococcus spp. obtained from cats and dogs. Pesq Vet Bras 37: 368-378.
OSYCZKA P. 2006. The lichen genus Cladonia (Cladoniaceae, lichenized Ascomycota) from Spitsbergen. Pol Polar Res 27: 207-242.
OWEN L & LAIRD K. 2018. Synchronous application of antibiotics and essential oils: dual mechanisms of action as a potential solution to antibiotic resistance. Crit Rev Microbiol 44: 414-435.
PERRY NB, BENN MH, BRENNAN NJ, BURGESS EJ, ELIS G, GALLOWAY DJ, LORIMER SD & TANGNEY S. 1999. Antimicrobial, antiviral and cytotoxic activity of New Zeland lichens. Lichenologist 31: 627-633.
PICCONI P, HIND C, JAMSHIDI S, NAHAR K, CLIFFORD M, WAND ME, SUTTON JM & RAHMAN KM. 2017. Triaryl Benzimidazoles as a New Class of Antibacterial Agents against Resistant Pathogenic Microorganisms. J Med Chem 60: 6045-6059.
RAI M, INGLE AP, RANDIT R, PARALIKAR P, GUPTA I, CHAUD MV & DOS SANTOS CA. 2017. Synergistic antimicrobial potential of essential oils in combination with nanoparticles: Emerging trends and future perspectives. Int J Pharm 532: 67-78.
RANKOVIĆ BR, KOSANIĆ MM & STANOJKOVIĆ TP. 2011. Antioxidant, antimicrobial and anticâncer octivity of the lichens Cladonia furcata, Lecanora atra and Lecanora muralis. BMC Complementary Altern Med 11: 97-104.
RAVAGLIA LM, GONÇALVES K, OYAMA NM, COELHO RG, SPIELMANN AA & HONDA NK. 2014. Radical-scavenging activity, toxicity against A. salina, and NMR profiles of extracts of lichens collected from Brazil and Antarctica. Quim Nova 37: 1015-1021.
REDDY SD ET AL. 2019. Comprehensive analysis of secondary metabolites in Usnea longissima (lichenized ascomycetes, Parmeliaceae) using UPLC-ESI-QTOF-MS/MS and pro-apoptotic activity of barbatic acid. Molecules 24: 2270-2288.
RONDEVALDOVA J, HUMMELOVA J, TAUCHEN J & KOKOSKA L. 2018. In vitro antistaphylococcal synergistic effect of isoflavone metabolite demethyltexasin with amoxicillin and oxacillin. Microb Drug Resist 24: 24-29.
SHRESTHA G, RAPHAEL J, LEAVITT SD & ST. CLAIR L. 2014. In vitro evaluation of the antibacterial activity of extracts from 34 species of North American lichens. Pharm Biol 52: 1262-1266.
SHRESTHA G, THOMPSON A, ROBISON R & ST. CLAIR L. 2016. Letharia vulpina, a vulpinic acid containing lichen, targets cell membrane and cell division processes in methicillin-resistant Staphylococcus aureus. Pharm Biol 54: 413-418.
STUDZIŃSKA-SROKA E, GALANTY A & BYLKA W. 2017. Atranorin - an interesting lichen secondary metabolite. Mini-Rev Med Chem 17: 1633-1645.
WEGENER HC. 2012. Antibiotic resistance—linking human and animal health. In: IMPROVING FOOD SAFETY THROUGH A ONE HEALTH APPROACH: Workshop Summary. Washington, DC: The National Academies Press, p. 331-349.
WHO – WORLD HEALTH ORGANIZATION. 2018. Available at: http://www.who.int/mediacentre/factsheets/fs194/en/
» http://www.who.int/mediacentre/factsheets/fs194/en/

SUPPLEMENTARY MATERIAL

Figures S1-S9

Publication Dates

Publication in this collection
22 Oct 2021
Date of issue
2021

History

Received
2 Oct 2019
Accepted
30 Dec 2019

This is an open-access article distributed under the terms of the Creative Commons Attribution License

[1] ANTONENKO YN, KHAILOVA LS, ROKITSKAYA TI, NOSIKOVA ES, NAZAROV PA, LUZINA OA, SALAKHUTDINOV NF & KOTOVA EA. 2019. Mechanism of action of an old antibiotic revisited: Role of calcium ions in protonophoric activity of usnic acid. Biochim Biophys Acta Bioenerg 1860: 310-316.

[2] BASNET BB, LIU H, LIU L & SULEIMEN YM. 2018. Diversity of anticancer and antimicrobial compounds from lichens and lichen-derived fungi: a systematic review (1985-2017). Cur Org Chem 22: 2487-2500.

[3] BELLIO P ET AL. 2015. Interaction between lichen secondary metabolites and antibiotics against clinical isolates methicillin-resistant Staphylococcus aureus strains. Phytomedicine 22: 223-230.

[4] BRAKNI R ET AL. 2018. UHPLC-HRMS/MS based profiling of algerian lichens and their antimicrobial activities. Chem Biodiversity 15: e1800031.

[5] BRANDÃO LFG, ALCANTARA GB, MATOS MFC, BOGO D, FREITAS DS, OYAMA N & HONDA NK. 2013. Cytotoxic evaluation of phenolic compounds from lichens against melanoma cells. Chem Pharm Bull 61: 176-183.

[6] CALCOTT MJ, ACKERLEY DF, KNIGHT A, KEYZERS RA & OWEN JG. 2018. Secondary metabolism in the lichen symbiosis. Chem Soc Rev 47: 1730-1760.

[7] CULBERSON C, CULBERSON W & JOHNSON A. 1981. A standardized TLC analysis of β-orcinol depsidones. Bryologist 84: 16-29.

[8] CULBERSON CF. 1972. Improved conditions and new data for identification of lichen products by standardized thin-layer chromatographic method. J Chromatogr A 72: 113-125.

[9] FLEIG M, GRÜNINGER W, MAYER WE & HAMPP R. 2008. Lichens of the Araucaria Forest of Rio Grande do Sul. Pró-Mata: Field Guide Nr. 3, Tübingen: University of Tübingen, 219 p.

[10] GALANTY A, PAŚKO P & PODOLAK I. 2019. Enantioselective activity of usnic acid: a comprehensive review and future perspectives. Phytochem Rev 18: 527-548.

[11] GUTERRES ZR, HONDA NK, COELHO RG, ALCANTARA GB & MICHELETTI AC. 2017. Antigenotoxicity of depsidones isolated from brazilian lichens. Orbital: Electron J Chem 9: 50-54.

[12] HONDA NK, FREITAS DS, MICHELETTI AC, CARVALHO NCP, SPIELMANN AA & CANÊZ LS. 2016a. Parmotrema screminiae (Parmeliaceae), a novel lichen species from Brazil with potent antimicrobial activity. Orbital: Electron J Chem 8: 334-340.

[13] HONDA NK, GONÇALVES K, BRANDÃO LFG, COELHO RG, MICHELETTI AC, SPIELMAN AA & CANÊZ LS. 2016b. Screening of lichen extracts using tyrosinase inhibition and toxicity against Artemia salina. Orbital: Electron J Chem 8: 181-188.

[14] HONDA NK, LOPES TIB, COSTA RCS, COELHO RG, YOSHIDA NC, RIVAROLA CRV, MARCELLI MP & SPIELMANN AA. 2015. Radical-scavenging Potential of Phenolic Compounds from Brazilian Lichens. Orbital: Electron J Chem 7: 99-107.

[15] HONDA NK, PAVAN FR, COELHO RG, LEITE SRA, MICHELETTI AC, LOPES TIB, MISUTSU MY, BEATRIZ A, BRUM RL & LEITE CQF. 2010. Antimycobacterial activity of lichen substances. Prytomedicine 17: 328-332.

[16] HUNECK S & YOSHIMURA I. 1996. Identification of Lichen Substances, Berlin, Heidelberg: Springer, 493 p.

[17] JHA BN, SHRESTHA M, PANDEY DP, BHATTARAI T, BHATTARAI HD & PAUDEL B. 2017. Investigation of antioxidant, antimicrobial and toxicity activities of lichens from high altitude regions of Nepal. BMC Complementary Altern Med 17: 282-289.

[18] KOSANIĆ M & RANKOVIĆ B. 2015. Lichen secondary metabolites as potential antibiotic agents. In: Ranković B (Eds), Lichen secondary metabolites bioactive properties and pharmaceutical potential, Springer, Cham, p. 81-104.

[19] KOSANIĆ M, RANKOVIĆ B, STANOJKOVIĆ T, RANČIĆ A & MANOJLOVIĆ N. 2014. Cladonia lichens and their major metabolites as possible natural antioxidante, antimicrobial and anticâncer agentes. LWT-Food Sci Technol 59: 518-525.

[20] KUETE V. 2010. Potential of Cameroonian plants and derived products against microbial infections: a review. Planta Med 76: 1479-1491.

[21] LIN H, ANNAMALAI T, BANSOD P, TSE-DINH Y & SUN D. 2013. Synthesis and antibacterial evaluation of anziaic acid and its analogues as topoisomerase I inhibitors. Med Chem Com 4: 1613-1618.

[22] MARTINS MCB, DE LIMA MJG, SILVA FP, AZEVEDO-XIMENES E, DA SILVA NH & PEREIRA EC. 2010. Cladia aggregata (lichen) from Brazilian Northeast: Chemical characterization and antimicrobial activity. Braz Arch Biol Technol 53: 115-122.

[23] MAURYA IK, SINGH S, TEWARI R, TRIPATHI M, UPADHYAY S & JOSHI Y. 2018. Antimicrobial activity of Bulbothrix setschwanensis (Zahlbr.) Hale lichen by cell wall disruption of Staphylococcus aureus and Cryptococcus neoformans. Microb Pathog 115: 12-18.

[24] MICHELETTI AC, BEATRIZ A, DE LIMA DP, HONDA NK, PESSOA CO, DE MORAES MO, LOTUFO LV, MAGALHÃES EYF & CARVALHO NCP. 2009. Constituintes químicos de Parmotrema lichexanthonicum Eliasaro & Adler: isolamento, modificações estruturais e avaliação das atividades antibiótica e citotóxica. Quim Nova 32: 12-20.

[25] MOURA JB, VARGAS AC, GOUVEIA GV, GOUVEIA JJS, RAMOS-JÚNIOR JC, BOTTON SA, PEREIRA EC & COSTA MM. 2017. In vitro antimicrobial activity of the organic extract of Cladonia substellata Vainio and usnic acid against Staphylococcus spp. obtained from cats and dogs. Pesq Vet Bras 37: 368-378.

[26] OSYCZKA P. 2006. The lichen genus Cladonia (Cladoniaceae, lichenized Ascomycota) from Spitsbergen. Pol Polar Res 27: 207-242.

[27] OWEN L & LAIRD K. 2018. Synchronous application of antibiotics and essential oils: dual mechanisms of action as a potential solution to antibiotic resistance. Crit Rev Microbiol 44: 414-435.

[28] PERRY NB, BENN MH, BRENNAN NJ, BURGESS EJ, ELIS G, GALLOWAY DJ, LORIMER SD & TANGNEY S. 1999. Antimicrobial, antiviral and cytotoxic activity of New Zeland lichens. Lichenologist 31: 627-633.

[29] PICCONI P, HIND C, JAMSHIDI S, NAHAR K, CLIFFORD M, WAND ME, SUTTON JM & RAHMAN KM. 2017. Triaryl Benzimidazoles as a New Class of Antibacterial Agents against Resistant Pathogenic Microorganisms. J Med Chem 60: 6045-6059.

[30] RAI M, INGLE AP, RANDIT R, PARALIKAR P, GUPTA I, CHAUD MV & DOS SANTOS CA. 2017. Synergistic antimicrobial potential of essential oils in combination with nanoparticles: Emerging trends and future perspectives. Int J Pharm 532: 67-78.

[31] RANKOVIĆ BR, KOSANIĆ MM & STANOJKOVIĆ TP. 2011. Antioxidant, antimicrobial and anticâncer octivity of the lichens Cladonia furcata, Lecanora atra and Lecanora muralis. BMC Complementary Altern Med 11: 97-104.

[32] RAVAGLIA LM, GONÇALVES K, OYAMA NM, COELHO RG, SPIELMANN AA & HONDA NK. 2014. Radical-scavenging activity, toxicity against A. salina, and NMR profiles of extracts of lichens collected from Brazil and Antarctica. Quim Nova 37: 1015-1021.

[33] REDDY SD ET AL. 2019. Comprehensive analysis of secondary metabolites in Usnea longissima (lichenized ascomycetes, Parmeliaceae) using UPLC-ESI-QTOF-MS/MS and pro-apoptotic activity of barbatic acid. Molecules 24: 2270-2288.

[34] RONDEVALDOVA J, HUMMELOVA J, TAUCHEN J & KOKOSKA L. 2018. In vitro antistaphylococcal synergistic effect of isoflavone metabolite demethyltexasin with amoxicillin and oxacillin. Microb Drug Resist 24: 24-29.

[35] SHRESTHA G, RAPHAEL J, LEAVITT SD & ST. CLAIR L. 2014. In vitro evaluation of the antibacterial activity of extracts from 34 species of North American lichens. Pharm Biol 52: 1262-1266.

[36] SHRESTHA G, THOMPSON A, ROBISON R & ST. CLAIR L. 2016. Letharia vulpina, a vulpinic acid containing lichen, targets cell membrane and cell division processes in methicillin-resistant Staphylococcus aureus. Pharm Biol 54: 413-418.

[37] STUDZIŃSKA-SROKA E, GALANTY A & BYLKA W. 2017. Atranorin - an interesting lichen secondary metabolite. Mini-Rev Med Chem 17: 1633-1645.

[38] WEGENER HC. 2012. Antibiotic resistance—linking human and animal health. In: IMPROVING FOOD SAFETY THROUGH A ONE HEALTH APPROACH: Workshop Summary. Washington, DC: The National Academies Press, p. 331-349.

[39] WHO – WORLD HEALTH ORGANIZATION. 2018. Available at: http://www.who.int/mediacentre/factsheets/fs194/en/
» http://www.who.int/mediacentre/factsheets/fs194/en/

Species	Chemical constituents	references
Cladonia borealis Stenroos (CGMS 52970)	usnic, barbatic and 4-O-demethylbarbatic acids	Osyczka 2006OSYCZKA P. 2006. The lichen genus Cladonia (Cladoniaceae, lichenized Ascomycota) from Spitsbergen. Pol Polar Res 27: 207-242.
Cladonia confusa R. Santesson (CGMS 40953)	usnic and perlatolic acids	Honda et al. 2016bHONDA NK, GONÇALVES K, BRANDÃO LFG, COELHO RG, MICHELETTI AC, SPIELMAN AA & CANÊZ LS. 2016b. Screening of lichen extracts using tyrosinase inhibition and toxicity against Artemia salina. Orbital: Electron J Chem 8: 181-188.
Cladonia crispatula (Nyl.) Ahti (CGMS 39230)	thamnolic acid	Honda et al. 2016bHONDA NK, GONÇALVES K, BRANDÃO LFG, COELHO RG, MICHELETTI AC, SPIELMAN AA & CANÊZ LS. 2016b. Screening of lichen extracts using tyrosinase inhibition and toxicity against Artemia salina. Orbital: Electron J Chem 8: 181-188.
Cladonia furcata (Hudson) Schrader (CGMS 39229)	atranorin, fumarprotocetraric acid	Honda et al. 2016bHONDA NK, GONÇALVES K, BRANDÃO LFG, COELHO RG, MICHELETTI AC, SPIELMAN AA & CANÊZ LS. 2016b. Screening of lichen extracts using tyrosinase inhibition and toxicity against Artemia salina. Orbital: Electron J Chem 8: 181-188.
Punctelia canaliculata (Lynge) Krog (CGMS 40952)	atranorin, protolichesterinic and caperatic acids	Honda et al. 2016bHONDA NK, GONÇALVES K, BRANDÃO LFG, COELHO RG, MICHELETTI AC, SPIELMAN AA & CANÊZ LS. 2016b. Screening of lichen extracts using tyrosinase inhibition and toxicity against Artemia salina. Orbital: Electron J Chem 8: 181-188.
Parmotrema lichexanthonicum Eliasaro e Adler (CGMS 52969)	atranorin, lichexanthone, salazinic and consalazinic acids	Micheletti et al. 2009MICHELETTI AC, BEATRIZ A, DE LIMA DP, HONDA NK, PESSOA CO, DE MORAES MO, LOTUFO LV, MAGALHÃES EYF & CARVALHO NCP. 2009. Constituintes químicos de Parmotrema lichexanthonicum Eliasaro & Adler: isolamento, modificações estruturais e avaliação das atividades antibiótica e citotóxica. Quim Nova 32: 12-20.
Pseudoparmelia sphaerospora (Nyl.) Hale (CGMS 49837)	atranorin, hypostictic and secalonic acids	Honda et al. 2010HONDA NK, PAVAN FR, COELHO RG, LEITE SRA, MICHELETTI AC, LOPES TIB, MISUTSU MY, BEATRIZ A, BRUM RL & LEITE CQF. 2010. Antimycobacterial activity of lichen substances. Prytomedicine 17: 328-332., Guterres et al. 2017GUTERRES ZR, HONDA NK, COELHO RG, ALCANTARA GB & MICHELETTI AC. 2017. Antigenotoxicity of depsidones isolated from brazilian lichens. Orbital: Electron J Chem 9: 50-54.
Ramalina anceps Nyl. (CGMS 49839)	usnic and stictic acids	Honda et al. 2015HONDA NK, LOPES TIB, COSTA RCS, COELHO RG, YOSHIDA NC, RIVAROLA CRV, MARCELLI MP & SPIELMANN AA. 2015. Radical-scavenging Potential of Phenolic Compounds from Brazilian Lichens. Orbital: Electron J Chem 7: 99-107.
Stereocaulon ramulosum (Sw.) Räusch (CGMS 40957)	atranorin, perlatolic and anziaic acids	Honda et al. 2016bHONDA NK, GONÇALVES K, BRANDÃO LFG, COELHO RG, MICHELETTI AC, SPIELMAN AA & CANÊZ LS. 2016b. Screening of lichen extracts using tyrosinase inhibition and toxicity against Artemia salina. Orbital: Electron J Chem 8: 181-188.
Usnea jamaicensis Ach. (CGMS 49838)	usnic, psoromic and 2’-O-demethylpsoromic acids	Guterres et al. 2017GUTERRES ZR, HONDA NK, COELHO RG, ALCANTARA GB & MICHELETTI AC. 2017. Antigenotoxicity of depsidones isolated from brazilian lichens. Orbital: Electron J Chem 9: 50-54.
Canoparmelia cryptochlorophaea (Hale) Elix (CGMS 37949)	atranorin, cryptochlorophaeic and caperatic acids	Fleig et al. 2008FLEIG M, GRÜNINGER W, MAYER WE & HAMPP R. 2008. Lichens of the Araucaria Forest of Rio Grande do Sul. Pró-Mata: Field Guide Nr. 3, Tübingen: University of Tübingen, 219 p., Ravaglia et al. 2014RAVAGLIA LM, GONÇALVES K, OYAMA NM, COELHO RG, SPIELMANN AA & HONDA NK. 2014. Radical-scavenging activity, toxicity against A. salina, and NMR profiles of extracts of lichens collected from Brazil and Antarctica. Quim Nova 37: 1015-1021.
Concamerella pachyderma (Hue) W.L. Culb. & C.F. Culb. (CGMS 52968)	atranorin and protocetraric acid	Fleig et al. 2008FLEIG M, GRÜNINGER W, MAYER WE & HAMPP R. 2008. Lichens of the Araucaria Forest of Rio Grande do Sul. Pró-Mata: Field Guide Nr. 3, Tübingen: University of Tübingen, 219 p.

Extract/ Isolated Compound	MIC (µg/mL)
Extract/ Isolated Compound	S. aureus (NEWP 0023)	S. aureus (clinic)	E. faecalis (NEWP 0012)	E. faecium (clinic)	E. coli (NEWP 0022)
C. borealis	7.8	7.8	7.8	7.8	≥ 250
C. confusa	15.6	7.8	7.8	7.8	≥ 250
C. crispatula	250	125	≥ 250	≥ 250	≥ 250
C. furcata	250	250	≥ 250	≥ 250	≥ 250
P. canaliculata	62.5	62.5	125	125	≥ 250
P. lichexanthonicum	250	≥ 500	≥ 250	≥ 250	≥ 250
P. sphaerospora	250	250	≥ 250	125	≥ 250
R. anceps	125	125	62.5	125	≥ 250
S. ramulosum	7.8	7.8	7.8	7.8	≥ 250
U. jamaicensis	62.5	62.5	15.6	62.5	≥ 250
C. cryptochlorophaea	31.25	7.8	7.8	7.8	≥ 250
C. pachyderma	250	250	≥ 250	≥ 250	125
Protocetraric acid	≥ 250	nt	≥ 250	nt	nt
Perlatolic acid	3.9	7.8	3.9	15.6	nt
Usnic acid	3.9	3.9	1.95	7.8	nt
Psoromic acid	≥ 250	≥ 250	≥ 250	≥ 250	nt
Secalonic acid	≥ 250	≥ 250	≥ 250	≥ 250	nt
Barbatic acid	31.3	31.3	7.8	31.3	nt
Salazinic acid	≥ 250	≥ 250	31.25	125	nt
Hypostictic acid	125	≥ 250	62.5	≥ 250	nt
Norstictic acid	≥ 250	125	62.5	125	nt
Atranorin	≥ 250	≥250	≥ 250	≥ 250	nt
Gentamicin	0.5	0.5	7.5	60	1.9

Brasil

Brasil

Antibacterial potencial of 12 Lichen species

Abstract

INTRODUCTION

MATERIALS AND METHODS

Lichens and isolated compounds

Chemical composition of the extracts

Antibacterial assays

RESULTS AND DISCUSSION

CONCLUSION

ACKNOWLEDGMENTS

REFERENCES

SUPPLEMENTARY MATERIAL

Publication Dates

History

Extract	Active compounds
Extract	S. aureus (NEWP0023)	S. aureus (clinic)	E. faecalis (NEWP0012)	E. faecium (clinic)
C. borealis	usnic, barbatic and 4-O-demethylbarbatic acids	nt	usnic, barbatic and 4-O-demethylbarbatic acids	usnic, barbatic and 4-O-demethylbarbatic acids
C. confusa	usnic and perlatolic acids	usnic and perlatolic acids	usnic and perlatolic acids	usnic and perlatolic acids
S. ramulosum	atranorin, perlatolic and anziaic acids	atranorin, perlatolic and anziaic acids	atranorin, perlatolic and anziaic acids	perlatolic and anziaic acids
C. cryptochlorophaea	cryptochlorophaeic and caperatic acids	cryptochlorophaeic acid	cryptochlorophaeic acid	cryptochlorophaeic and caperatic acids

Extract	Main Compounds and Proportion
R. anceps	norstictic acid
U. jamaicensis	usnic acid and psoromic acid (1:5)
C. borealis	usnic acid and barbatic acid (1:1)
C. confusa	usnic acid and perlatolic acid (1:1.5)