Cerrado plants with Antimicrobial Activity: a systematic literature review

Authors

DOI:

https://doi.org/10.33448/rsd-v10i16.22753

Keywords:

Savannah; Bactericide; Fungicide; Plant extract; Microdilution; Microbial resistance.

Abstract

The objective was to describe and relate compounds from Cerrado plants with inhibitory action against pathogenic microorganisms for humans and animals. Therefore, a preliminary search was carried out in the Health Sciences Descriptors (DeCS) to define the words to be used in the literature survey. It defined as key words, “Antimicrobial or Bactericide or Fungicide” and “Plant or Vegetal” and “Cerrado or Cerrado Biome”. Through the Medical Subject Headings (MeSH) tool, it selected studies in which the combination of keywords were identified in the titles and/or abstracts of the studies. The search for articles was performed in the Science Direct, Web of Science and PubMed databases. Initially 48 studies were revealed, after reading in full were included for analysis, 10 articles published between the years (2017-2021). After evaluating the studies, 13 plant species belonging to 8 botanical families with antimicrobial potential were identified, with Fabaceae being the family with the highest number of species. For the extraction of compounds, plant leaves were the most used organ and ethanol, as a solvent. The major bioactive plant compounds were terpenes and phenolic compounds. The secondary metabolites detected in plant extracts showed different forms of action for microbial inhibition, under different concentrations. Plant compounds from the Cerrado are promising as alternatives to conventional antimicrobials, being important for the production of new drugs. The studies analyzed demonstrated that there are plant species native to the Cerrado that have already been studied with notorious antimicrobial potential.

References

Alarcón LD, Peña AE, Quintero A, Meza M, Usubillaga A, Velasco J. (2009). Composición y actividad antibacteriana del aceite esencial de Myrcia fallax (Rich.) Dc de Venezuela. Revista de la Sociedad Química del Perú, 75 (2), 221-227.

Andrade, L. B. S., Julião, M. S. S., Vera Cruz, R. C., Rodrigues, T. H. S., Fontenelle, R. O. S., & Silva, A. L. C. (2018). Antioxidant and antifungal activity of carnauba wax powder extracts, Industrial Crops and Products, 12 (5), 220-227.

Andrade-Ochoa S., Nevárez-Moorillón G.V, Sánchez-Torres L.E. (2015). Relação quantitativa estrutura-atividade de moléculas constituintes de diferentes óleos essenciais com atividade antimicobacteriana contra Mycobacterium tuberculosis e Mycobacterium bovis. BMC Complem Altern Med, 1 (5), 333-342.

Bonilla, A., Duque, C., Garzón, C., Takaishi, Y., Yamaguchi, K., Hara, N., Fujimoto, Y., (2005). Champanones, yellow pigments from the seeds of champa (Campomanesia lineatifolia), Phytochemistry, 66 (14), 1736-1740.

Bouarab-Chibane, L., Forquet. V., Lantéri, P., Clément,Y., Léonard-Akkari, L., Oulahal, N., Degraeve, P. E., Bordes, C. 2019. Antibacterial Properties Of Polyphenols: Characterization And Qsar (Quantitative Structure–Activity Relationship) Models. Front. Microbiol, 9 (9), 1457-1474.

Boudet A. (2007). Evolução e estado atual da pesquisa em compostos fenólicos. Fitoquímica. Jornal phytochem. 68 (2), 2722–2735. doi: 10.1016 /.06.012.

Brandão, M. GL et al. (2009). Traditional uses of American plant species from the 1st edition of Brazilian Official Pharmacopoeia. Revista Brasileira de Farmacognosia, 19 (2), 478-487.

Brandelli, C. L. C., Vieira, P. de B., Macedo, A. J., Tasca, T. (2013). Remarkable Anti-Trichomonas vaginalis activity of plants traditionally used by the MbyáGuarani indigenous group in Brazil. BioMed Research International, 20 (13), 1-7. https://doi.org/10.1155/2013/826370.

Brasil, 2010. Ministério do Meio Ambiente. Plano de Ação para Prevenção e Controle do Desmatamento e das Queimadas. 2010. http://www.mma.gov.br/estruturas/201/_ arquivos/ppcerrado_201.pdf accessed 14.11.18.

Campos, D. A., Ribeiro, A. C., Costa, E. M., Fernandes, J. C., Tavaria, F. K., Araruna, F. B., Eiras, C., Eaton, P., Leite, J. R. S. A., & Manuela Pintado, M. (2012). Study of antimicrobial activi tyandatomic force microscopy imaging of the action mechanism of cashewtreegum. Carbohydr. Polym., 90 (5), 270-274.

Cardoso C. A L., Salmazzo G. R., Honda N. K., Prates C. B., Vieira M. C., and Roberta Gomes Coelho. (2010). Antimicrobial Activity of the Extracts and Fractions of Hexanic Fruits of Campomanesia Species (Myrtaceae). Journal Of Medicinal Food J Med Food, 13 (5), 1273–1276.

Carneiro, N. S. et al. (2017). Chemical composition, antioxidant and antibacterial activities of essential oils from leaves and flowers of Eugenia klotzschiana Berg (Myrtaceae). Anais da Academia Brasileira de Ciências, 89 (03), 1907-1915.

Carvalho, A. P. A., & Conte-Junior, C. A. (2021). Health benefitsofphytochemicalsfromBraziliannativefoodsandplants: Antioxidant, antimicrobial, anti-cancer, andriskfactorsofmetabolic/endocrinedisorderscontrol, Trends in Food Science & Technology, 11(1), 534-548.

Cascaes, M. C., Guilhon, G. M. , Zoghbi, M. G., Andrade, E. H. A., Santos, L. S., Silva, J. K. R. , Uetanabaro A. P.T., Araújo I. S. (2021). Flavonoids, antioxidant potential and antimicrobial activity of Myrcia rufipila mcvaugh leaves (myrtaceae). Nat Prod Res., 35 (10), 1717-1721.

Couto R.C., Pedrosa T.M.G., Nogueira J.M. (2009). Infecção hospitalar e outras complicações não-infecciosas da doença - epidemiologia, controle e tratamento. Rio de Janeiro, Brasil: Guanabara Koogan.

Cowan M. (1999). Produtos vegetais como agentes antimicrobianos. Clin Microbiol Rev., 12 (2), 564–582.

Dexheimer, G. M., Pozzobon, A. (2017). Atividade biológica de plantas da família Myrtaceae: revisão sistemática de artigos entre 1989 e 2015. Revista Cubana de Plantas Medicinales, 22 (2), 321-327.

Dias M, Monteiro MS. (2010). Antibióticos e Resistência bacteriana, Velhas Questões Novo Desafio. Cadernos Otorrinolaringologia, 21 (9), 1-10.

Dorman H.J.D., Deans S.G. (2000). Agentes antimicrobianos de plantas: atividade antibacteriana de óleos voláteis de plantas. J Appl Microbiol, 88 (2), 308-316.

Durigan, G., Melo, A. C. G., Max, J. C. M., Vilas Boas, O., Contieri, W. A.; Ramos, V. S. (2011). Manual para recuperação da vegetação de Cerrado. São Paulo, Brasil: SMA.

Fischbach, M.A.; Walsh, C.T. (2009). Antibiotics For Emergingpathogens. Science, 32 (5), 1089-1093.

Galvão, T. F., Andrade, T. S., Harrad, P. D. (2015). Principais itens para relatar Revisões sistemáticas e Meta-análises: A recomendação PRISMA. Epidemiol. Serv. Saúde, 24 (2), 335-342.

Gazoni, V. F., Balogun, S. O., Arunachalam, K., Oliveira, D. M., Filho, V, C., Lima, S. R., Colodel, E. Soares, M., I. M, Ascêncio, S. D., & Martins, D. T. O. (2018). Assessment of toxicity and differential antimicrobial activity of methanol extract of rhizome of Simaba ferruginea A. St.-Hil.and its isolate canthin-6-one, Journal of Ethnopharmacology, 22(3), 122-134.

Iriti M., Colnaghi G., Chemat F., Smadja J., Faoro F., Visinoni F. A. (2006). Histo-citoquímica e microscopia eletrônica de varredura de tricomas glandulares de lavanda após hidrodestilação convencional e assistida por microondas de óleos essenciais: Um estudo comparativo. Flavor Fragr. J., 21 (3), 704–712.

Kauffmann, C., Soares, A. P. V., Arossi, K., Pacheco, L. A., Buhl, B., Freitas, E. M., Hoehne, L., Castro, L. C., Gnoatto, S. C. B., Ethur, E. M. (2017). Potencial Antimicrobiano e Antibiofilme in Vitro de Espécies do Gênero Eugenia, Myrtaceae, Nativas do Sul do Brasil. Caderno pedagógico, 14 (2), 110-127.

Lc B. B. C. , P. Marcelino, S. S., W. Felix, O., Mc Moura, E. Viana, P., F. Soares, G., P Guedes, P., Th Napoleão, M, S. C. (2018). Lectinas Como Agentes Antimicrobianos. Journal Of Aplied Microbiology, 22 (3), 238-1252.

Limberger RP, Apel MA, Sobral M, Schapoval ES, Henriques AT. (1998) Investigação da atividade antimicrobiana do óleo volátil de espécies da família Myrtaceae. Revista Brasileira de Farmácia, 79 (2), 49-52.

Loureiro, R. J., et al. (2016). O uso de antibióticos e as resistências bacterianas: brevesnotassobre a suaevolução. Revista Portuguesa de saúde pública, 34 (1), 77-84.

Kępa M., Wojtyczka R.D., Idzik D., Dziedzic A., Wąsik T.J. (2016). Catechin hydrate aumenta a ação antibacteriana de antibióticos selecionados contra cepas clínicas de Staphylococcus aureus . Moléculas, 21 : 244

Maclean, R. C., & San Millan, A. (2019) The evolution of antibiotic resistance. Science, 365 (6458), 1082-1083.

Mark, S. B., & Antony D. (2006). Buss. Natural products . The future scaffolds for novel antibiotics? Biochemical Pharmacology, 71(7), 919-929.

Medeiros JR, Medeiros N, Medeiros H, Davin LB, Lewis NG. (2003). Composition of the bioactive essential oils from the leaves of Eugenia stipitata McVaugh ssp. sororia from the Azores. Journal of Essential Oil Research, 15 (4), 293-5.

Mulyaningsih , S., Sporer, F., Zimmermann, S., Reichling, J., & Wink, M. (2010). Synergisticpropertiesoftheterpenoidsaromadendreneand 1,8-cineole fromtheessentialoilofEucalyptusglobulusagainstantibiotic-susceptibleandantibiotic-resistantpathogens. Phytomedicine, 17 (13), 1061-1066.

Nobre, C. B., Sousa, E. O., Silva, J. M. F.L., Coutinho, H. D. M., & Costa, J. G. M. (2018). Chemical composition and antibacterial activity of fixed oils of Mauritiaflexuosa and Orbignyaspeciosa associated with aminoglycosides, European Journal of Integrative Medicine, 23 (1), 84-89.

Oliveira, V. B. et al. (2012). Native foods from Brazilian biodiversity as a source of bioactive compounds. Food Research International, 48 (1), 170-179.

Organização Mundial De Saúde. (2019). Antibióticos: resistência de microrganismos é grave ameaça à saúde global.htps://portal.fiocruz.br/noticia/antibioticos-resistencia-de-microrganismos-e-grave-ameaca-saude-global

Oz M., Lozon Y., Sultan A., Yang KHS, Galadari S. (2015). Effects of monoterpenes on ion channels of excititable cells. Pharmacol. Ther, 15 (2), 83–97.

Patridge E , Gareiss P , Kinch MS , Hoyer D . (2016). Uma análise de medicamentos aprovados pela FDA: produtos naturais e seus derivados. Drug Discov Today, 2(1), 204 - 207.

Pavan, F. R., Leite, C. Q. F., Coelho, R. G., Coutinho, I. D., Honda, N. K., Cardoso, C. A. L., Vilegas, W., Leite, S. R. de A., Sato, D. N. (2009). Evaluation of anti Mycobacterium tuberculosis activity of Campomanesia adamantium (Myrtaceae), Química Nova 32 (5).

Prakash, B., Kumar. A., Prem Pratap Singh, &Songachan, L.S. (2020). Antimicrobial andantioxidant properties of phytochemicals: Current status and future perspective,Editor(s): Bhanu Prakash, Functional and Preservative Properties of Phytochemicals. Academic Press, 1-45.

Quideau S., Deffieux D., Douat-Casassus C., Pouységu L. (2011). Polifenóis Vegetais: Propriedades Químicas, Atividades Biológicas e Sintese. Chem. Int. Ed. Engle, 17 (1), 586–621.

Rocha, A. R. F., Sousa, H. G., Vale Júnior, E. P., Lima, F. L., Costa, A. S. G., Araújo, A. R., Leite, J. R. S. A., Martins, F. A., Oliveira, M. B. P. P., Plácido, A., Filho, F. S. S., & Lago, E. C. (2021). Extract sand fractions of Croton L. (Euphorbiaceae) species with antimicrobial activi tyandanti oxidant potential, LWT, 139 (1).

Rodríguez-Baño, J., Rossolini, G. M, Schultsz, C., Tacconelli, E., Murthy, S., Ohmagari, N., Holmes, A., Bachmann, T., Goossens, H., Canton, R., Roberts, A. P., Henriques-Normark, B., Clancy, C. J., Huttner, B., Fagerstedt, P., Lahiri, S., Kaushic, C., Hoffman, S. J., Warren, M., Zoubiane, G., Essack, S., Laxminarayan, R., Plant, L. (2021). Antimicrobial resistance research in a post-pandemic world: Insights on antimicrobial resistance research in the COVID-19 pandemic. Journal of Global Antimicrobial Resistance, 25 (1), 5-7.

Sá, S., Chaul, L.T., Alves,V. F., Fiuza, T.S., Tresvenzol, L. M. F., Vaz, B. G., Ferri, P. H., Borges, L. L., & Paula, J. R. (2018). Phytochemistry and antimicrobial activity of Campomanesiaadamantium, Revista Brasileira de Farmacognosia, Volume 28, Issue 3, Pages 303- 11.

Sandelowski M, Barroso J. Handbook for synthesizing qualitati ve research. Brainerd: Bang Printi ng; 2007.

Silva, D. H. S., Castro-Gamboa, I.,&Bolzani, V. S. (2010). 3.05 Plant Diversity from Brazilian Cerrado and Atlantic Forest as a Tool for Prospecting Potential Therapeutic Drugs, Editor(s): Hung-Wen (Ben) Liu, Lew Mander, Comprehensive Natural Products II, Elsevier, 95-133.

Silva, S. C. C. C., Braz, E. M. A., Carvalho, F. A. A., Brito, C. A. R. S., Brito, L. M., Barreto, H. M., Filho, E. C. S., & Silva, D. A. (2020) Antibacterial and cytotoxic properties from esterified Sterculia gum, International Journal of Biological Macromolecules, 164 (1), 606-615.

Simonetti, E.; Ethur, M.E.; Castro, L.C.; Kauffmann, C.; Giacomin, A.C.; Ledur, A.; Arossi, K.; Pacheco, L.A.; Goettert, M.I.; Faleiro, D.; Freitas, E.M. (2016) Avaliação da atividade antimicrobiana de extratos de Eugenia anomala e Psidium salutare (Myrtaceae) frente à Escherichia coli e Listeria monocytogenes. Rev. Bras. Pl. Med., 18 (1), 9-18.

Sobral, M., Proença, C., Souza, M., Mazine, F., Lucas, E. (2015). Myrtaceae in Lista de Espécies da Flora do Brasil. Jardim Botânico do Rio de Janeiro. Disponível em http://floradobrasil.jbrj.gov.br/jabot/floradobrasil/ FB171.

Stefanello M.É., Cervi A.C., Ito I.Y., Salvador M.J., Wisniewski Jr A., Simionatto E.L. (2008). Chemical composition and antimicrobial activity of essential oils of Eugenia chlorophylla (Myrtaceae). Journal of Essential Oil Research, 20 (1), 75-8.

Stone Sá, Luíza T. Chaul a, Virgínia F. Alves b, Tatiana S. Fiuzac, Leonice M.F. Tresvenzol a, Boniek G. Vaz d, Pedro H. Ferri d, Leonardo L. Borges e,f , José R. Paula. (2018). Phytochemistry and antimicrobial activity of Campomanesia adamantium. Revista Brasileira de Farmacognosia, 28 (1), 303–311

Tavares, T. D., Antunes, J. C., Padrão, J., Ribeiro, A. I., Zille, A. , Amorim, M. T. P., Ferreira, F., Felgueiras, H. P. (2020). Activity Of Specialized Biomolecules Against Gram-Positive And Gram-Negative Bacteria. Antibiotics, 9 (6), 314 – 321.

Teixeira, N. et al. (2019). Edible fruits from Brazilian biodiversity: A review on their sensorial characteristics versus bioactivity as tool to select research. Food research international, 119 (1), 325-348.

Vizzotto, M., Krolow, A. C. R., & Weber, G. E. B. (2010). Metabólitos secundários encontrados em plantas e sua importância. Embrapa Clima Temperado-Documento 316, 1 (1), 1-16. Disponível em https://www.infoteca.cnptia.embrapa.br/bitstream/doc/886074/1/documento316.pdf

Waters, V. J.,Kidd, T. J., Canton, R., Ekkelenkamp, M. B., Johansen, H. K., LiPuma, J. J., Bell, S. C., Elborn, J. S., Flume, P. A., VanDevanter, D. R., &Gilligan, P. (2019). Antimicrobial Resistance International Working Group in Cystic Fibrosis. Reconciling Antimicrobial Susceptibility Testingand Clinical Response in Antimicrobial Treatment of Chronic Cystic Fibrosis LungInfections. Clinical Infectious Diseases, 69 (10).

Zacchino SA, Butassi E., Liberto MD, Raimondi M., Postigo A., Sortino M. (2017). Plant phenolics and terpenoids as adjuvants of antibacterial and antifungal drug. Fitomedicina, 15 (1), 27–48.

Downloads

Published

04/12/2021

How to Cite

BELÉM, G. M. .; CARDOSO FILHO, O.; FONSECA, F. S. A. da .; DUARTE, E. R. . Cerrado plants with Antimicrobial Activity: a systematic literature review. Research, Society and Development, [S. l.], v. 10, n. 16, p. e07101622753, 2021. DOI: 10.33448/rsd-v10i16.22753. Disponível em: https://rsdjournal.org/index.php/rsd/article/view/22753. Acesso em: 25 apr. 2024.

Issue

Vol. 10 No. 16

Section

Agrarian and Biological Sciences

License

Copyright (c) 2021 Gladyane Mendes Belém; Otavio Cardoso Filho; Francine Souza Alves da Fonseca; Eduardo Robson Duarte

Creative Commons License

This work is licensed under a Creative Commons Attribution 4.0 International License.

Authors who publish with this journal agree to the following terms:

1) Authors retain copyright and grant the journal right of first publication with the work simultaneously licensed under a Creative Commons Attribution License that allows others to share the work with an acknowledgement of the work's authorship and initial publication in this journal.

2) Authors are able to enter into separate, additional contractual arrangements for the non-exclusive distribution of the journal's published version of the work (e.g., post it to an institutional repository or publish it in a book), with an acknowledgement of its initial publication in this journal.

3) Authors are permitted and encouraged to post their work online (e.g., in institutional repositories or on their website) prior to and during the submission process, as it can lead to productive exchanges, as well as earlier and greater citation of published work.