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Termite usage associated with antibiotic therapy: enhancement of aminoglycoside antibiotic activity by natural products of Nasutitermes corniger (Motschulsky 1855)

BMC Complementary and Alternative Medicine volume 9, Article number: 35 (2009) Cite this article

Abstract

Background

Several species from Insecta are used as remedies. Among these species, the termite Nasutitermes corniger is commonly used in traditional medicine in Northeast Brazil. The present work tests the modifying antibiotic activity of Nasutitermes corniger, a termite used in folk medicine in Northeastern region of Brazil.

Methods

Chlorpromazine and decocts of N. corniger were collected from two different plant species used in the traditional medicine were tested for their antimicrobial activity against strains of Escherichia coli resistant to aminoglycosides. The growth of two bacterial strains of E. coli was tested using decocts and chlorpromazine alone or associeted with aminogycosides.

Results

The MIC and MBC values were ≥1024 μg/ml for both strains of E. coli assayed. A significant synergism was observed between both decocts and chlorpromazine when assyed with neomycin. This synergism with neomycin indicates the involvement of an efflux system in the resistance to this aminoglycoside.

Conclusion

Therefore it is suggested that natural products from N. corniger could be used as a source of zoo-derived natural products with modifying antibiotic activity to aminoglycosides, being a new weapon against the bacterial resistance to antibiotics.

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Background

Although medicinal plants are well studied around the world, animals or animal parts have been broadly used in Brazilian traditional medicine and have played a significant role in healing practices [1, 2]. Several species from Insecta have been used as remedies [14]. Among these species, the Neotropical termite Nasutitermes corniger is commonly used in traditional medicine in Northeast Brazil. N. corniger is distributed from southern Mexico to northern Argentina and the West Indies and is spread from the semi-arid to tropical rain forest ecosystems [59]. In South America, this species is highly adaptable to colonizing contrasting habitats in urban, agricultural, and natural environments [10, 11]. N. corniger builds arboreal carton nests with a population that can exceed 400,000 individuals/nest, and density that ranges from 22.1 to 47.1 nest/ha in tropical rain forests [10, 12, 13]. Based on morphologic, genetic and biogeographic evidence, N. costalis has been revised as a synonym of N. corniger, like the congeneric species N. araujoi, N. globiceps and N. tatarendae which are also synonyms of N. corniger [8, 9].

With the increase in microbial resistance to antibiotics, the use of natural products represent an interesting alternative for treatment [14, 15]. Many products have been evaluated not only for direct antimicrobial activity, but also as resistance modifying agents [16, 17]. Several chemical compounds, from synthetic or biological sources, such as phenothiazines and natural products, have direct activity against many bacteria, enhancing the activity of a specific antibiotic, reversing the natural resistance of specific bacteria to several antibiotics, promoting the elimination of plasmids from bacteria such as Escherichia coli, and inhibiting drug-transport functions of the plasma membrane. Inhibition of plasma membrane-based efflux pumps has been observed as well [18, 19]. The enhancement of antibiotic activity or the reversal of antibiotic resistance by natural or synthetic non-conventional antibiotics results in the classification of these compounds as modifiers of antibiotic activity. Aminoglycosides are potent bactericidal antibiotics that target the bacterial ribosome and development of bacterial resistance to aminoglycosides is widely recognized as a serious health threat [18]. In E. coli, the main mechanisms of resistance to aminoglycosides are active drug efflux and enzymatic inactivation [19].

The aim of the present study was to evaluate the decoctions of N. corniger obtained from two different trees (Commiphora leptophloeos Mart J. B. Gillet and Anacardium occidentale L.) as resistance-modifying agents against E. coli.

Methods

Strains

The strain used was the clinical isolate Escherichia coli (EC27), resistant to neomycin and gentamicin (low level) and to amikacin and kanamycin. The strain Escherichia coli (EC - ATCC8539) was used as the positive control. All strains were maintained in heart infusion agar slants (HIA, Difco), and prior to assay, the cells were grown overnight at 37°C in brain heart infusion (BHI, Difco).

Zoological and plant material

Nasutitermes corniger was collected in the county of Alagoa Nova, Paraíba, Brazil (21°58'N, 89°36'W) during the month of June 2007. The samples were authenticated by Prof. Alexandre Vasconcellos at the Botany, Ecology and Zoology Department, UFRN. A voucher specimen (CICB 68 and CICB 69) was deposited in the Isoptera Collection of the Bioscience Center, Universidade Federal do Rio Grande do Norte - UFRN. The botanical identification of the plants was performed at the "Herbarium Prof. Lauro Pires Xavier" (JPB), Department of Systematics and Ecology, in the Universidade Federal da Paraíba, Brazil, where voucher specimens were preserved under the reference numbers JPB 37775 for Commiphora leptophloeos and JPB 37745 for Anacardium occidentale.

Preparation of N. corniger decoctions from Commiphora leptophloeos (DCL) and Anacardium occidentale (DAO)

Two hundred grams of termites with nests were collected and powdered. The powdered material was extracted by maceration using 100 mL of sterile water as solvent at room temperature. The mixture was allowed to stand for 72 h at room temperature. Decoctions were then filtered and assayed to determine antibacterial activity.

Drugs

Chlorpromazine, gentamicin, kanamycin, amikacin and neomycin were obtained from SIGMA. All drugs were dissolved in sterile water.

Drug susceptibility test and determination of fractional inhibitory concentration (FIC)

The minimum inhibitory concentrations (MICs) of the decoctions, antibiotics and chlorpromazine (CPZ) were determined in BHI by the microdilution assay using suspensions of 105 cfu/mL and a drug concentration range of 1024 to 1 μg/mL (two-fold serial dilutions) [20]. The MIC was defined as the lowest concentration at which no growth was observed. For the evaluation of the decoctions as a modulator of antibiotic resistance, the MICs of the antibiotics were determined in the presence of the decoctions and CPZ at a sub-inhibitory concentration and the FIC calculated. The fractional inhibitory concentration (FIC) was used to interpret the dilution method results and was calculated as follows [21]: FIC of drug A = MIC drug A in combination with decoction or CPZ/MIC drug A alone. Synergy was defined as FIC < 0.5; indifference was defined as 4 > FIC > 0.5; and antagonism was defined as an FIC > 4. The plates were incubated for 24 h at 37°C. CPZ was used as the positive control for efflux pump modulation, due to the fact it affects the function of efflux pumps. All experiments were realized in duplicate.

Results

Both decoctions showed no substantial antibacterial activity at 1024 μg/mL against the strains tested (MIC ≥ 2048 μg/mL). However, when the decoction of termites from C. leptophloeos was added to the growth medium at 256 μg/mL (≥1/8 MIC), a reduction of the MIC for gentamicin and neomycin was observed in the strain E. coli 27 (but not in ATCC 8539), demonstrating a synergistic or additive effect of this natural product with these aminoglycosides (Table 1). The decoction of termites from A. occidentale L. shown synergism only against neomycin (Table 2), demonstrating the influence of the plant substrate in the pharmacological properties of this natural product of termites.

Table 1 Evaluation of the Modifying Antibiotic Activity of the Decoct of insects from Commiphora leptophloeos (256 μg/mL) and CPZ (16 μg/mL) against aminoglycosides.
Full size table
Table 2 Evaluation of the Modifying Antibiotic Activity of the Decoct of insects from Anacardium occidentale (256 μg/mL) and CPZ (16 μg/mL) against aminoglycosides.
Full size table

Synergism between CPZ and gentamicin was not observed, which is suggestive of the occurrence of another resistance mechanism. Another possibility is a pump that can be affected by the termite decoction from C. leptophloeos in the case of gentamicin (Table 1).

Discussion

Evidence of antimicrobial activity of products isolated from termites has been reported. Peptides such as spinigerin and termicin, isolated from Pseudocanthotermes spiniger, showed antifungal and antibacterial activity [22]. Studies on the molecular biology and bioinformatics of the Australian termites of the genus Nasutitermes demonstrated their potential as producers of antimicrobial peptides [23, 24]. However, as far as we know, no antimicrobial activity of natural products from N. corniger in terms of synergism with aminoglycosides or any other antibiotic has been reported so far.

Phenothiazines, such as chlorpromazine, act on the plasma membrane of bacteria affecting efflux pumps and causing alterations in permeability, thereby enhancing the activity of antibiotics, including the aminoglycosides [2527]. Efflux pumps are known as resistance mechanisms of E. coli since the 1980s, belonging to the RND family (resistance nodulation division) and representing a mechanism of multidrug resistance (MDR), which has led to antibiotic resistance to aminoglycosides [28, 29].

Animals have been methodically tested by pharmaceutical companies as sources of drugs for modern medical science, and the current number of animal sources for producing essential medicines is quite impressive. The chemical constituents and pharmacological actions of some animal products are already known to some extent, and ethnopharmacological studies focused on animal medicines could be very important in clarifying the eventual therapeutic usefulness of this class of biological remedies [30, 31]. As pointed out by Alves and Rosa, further ethnopharmacological studies are necessary to increase our understanding of the links between traditional uses of faunistic resources and conservation biology, public health policies, sustainable management of natural resources and biological prospecting [1].

Conclusion

The results obtained indicate that decoctions of N. corniger (and possibly of other termites) could be a source of natural products with antibiotic modifying activity to be used against multidrug resistant bacteria.

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Authors and Affiliations

  1. Universidade Regional do Cariri, Laboratório de Microbiologia e Biologia Molecular, Crato (CE), 63105-000, Brazil

    Henrique DM Coutinho

  2. Universidade Federal do Rio Grande do Norte, Departamento de Botânica, Ecologia e Zoologia, Natal (RN), 59072-900, Brazil

    Alexandre Vasconcellos

  3. Universidade Federal de Campina Grande, Unidade Acadêmica de Saúde, Cuité (PB), Brazil

    Micheline A Lima

  4. Universidade Federal da Paraíba - UFPB; Departamento de Biologia Molecular - DBM, 58051-900, Brazil

    Geraldo G Almeida-Filho

  5. Departamento de Biologia, Universidade Estadual da Paraíba, Campina Grande, Paraíba (PB), 58109-753, Brazil

    Rômulo RN Alves

Authors
  1. Henrique DM Coutinho
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  2. Alexandre Vasconcellos
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  3. Micheline A Lima
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  4. Geraldo G Almeida-Filho
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  5. Rômulo RN Alves
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Corresponding author

Correspondence to Henrique DM Coutinho.

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Competing interests

The authors declare that they have no competing interests.

Authors' contributions

HDMC carried out the microbial tests; AV review the article and carried out the collection and identification the termite; MAL and GGA-F participated in the design of the study; RRNA conceived of the study, and participated in its design and coordination and helped to draft the manuscript. All authors read and approved the final manuscript.

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Coutinho, H.D., Vasconcellos, A., Lima, M.A. et al. Termite usage associated with antibiotic therapy: enhancement of aminoglycoside antibiotic activity by natural products of Nasutitermes corniger (Motschulsky 1855). BMC Complement Altern Med 9, 35 (2009). https://doi.org/10.1186/1472-6882-9-35

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BMC Complementary Medicine and Therapies

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