Genotypic and phenotypic detection of efflux pump in Rhodococcus equi

Gressler, Letícia Trevisan; Vargas, Agueda Castagna de; Costa, Mateus Matiuzzi da; Pötter, Luciana; Silveira, Bibiana Petri da; Sangioni, Luis Antônio; Botton, Sônia de Avila

doi:10.1590/S1517-83822014000200040

Abstract

The req_39680 gene, associated to a putative efflux system, was detected in 60% (54/90) of R. equi isolates by PCR. The phenotypic expression of efflux mechanism was verified in 20% of the isolates using ethidium bromide. For the first time, the expression of efflux mechanism was demonstrated in R. equi.

ethidium bromide; efflux pump; multidrug resistance; Rhodococcus equi; vapA

SHORT COMMUNICATION

Genotypic and phenotypic detection of efflux pump in Rhodococcus equi

Letícia Trevisan Gressler^I; Agueda Castagna de Vargas^I; Mateus Matiuzzi da Costa^II; Luciana Pötter^III; Bibiana Petri da Silveira^I; Luis Antônio Sangioni^I; Sônia de Avila Botton^I

^IDepartamento de Medicina Veterinária Preventiva, Universidade Federal de Santa Maria, Santa Maria, RS, Brazil

^IILaboratório de Imunologia e Microbiologia, Universidade Federal do Vale do São Francisco, Petrolina, PE, Brazil

^IIIDepartamento de Zootecnia, Universidade Federal de Santa Maria, Santa Maria, RS, Brazil

^{Correspondence} Correspondence: S.A. Botton Departamento de Medicina Veterinária Preventiva Universidade Federal de Santa Maria Avenida Roraima 1000, Prédio 44, Sala 5007 97105-900, Santa Maria, RS, Brazil E-mail: sabott20@gmail.com

ABSTRACT

The req_39680 gene, associated to a putative efflux system, was detected in 60% (54/90) of R. equi isolates by PCR. The phenotypic expression of efflux mechanism was verified in 20% of the isolates using ethidium bromide. For the first time, the expression of efflux mechanism was demonstrated in R. equi.

Key words: ethidium bromide, efflux pump, multidrug resistance, Rhodococcus equi, vapA.

Efflux systems or efflux pumps are transporter proteins of toxic compounds classified into five families according to their primary structure and energy-coupling mechanism: i. Major Facilitator Superfamily - MFS, ii. Adenosine Triphosphate-Binding Cassette - ABC, iii. Small Multidrug Resistance Family - SMR, iv. Resistance-Nodulation-Cell Division Superfamily - RND, and v. Multidrug and Toxic Compound Extrusion Family - MATE (Kumar and Schweizer, 2005). These proteins were firstly described in Escherichia coli associated with tetracycline resistance profile (Mcmurray et al., 1980).

Although several genes encoding efflux pumps can be found on plasmids, there are other efflux pump genes located on the chromosome, which provide for the bacterium an intrinsic mechanism that allows survival in a hostile environment (e.g. the presence of antimicrobials) (Webber and Piddock, 2003). Then, the efflux pumps are related to acquired and intrinsic resistance to several antimicrobials in different bacterial species (Li and Nikaido, 2004). Cross-resistance was already described in efflux systems, i.e. the exposure to any one agent that belongs to the substrate profile of an efflux pump can allows its over-expression and consequent cross-resistance to different substrates (Webber and Piddock, 2003). These systems are also considered as a major mechanism of resistance among multidrug-resistant pathogenic microorganisms in veterinary medicine (Paulsen, 2003).

Rhodococcus equi is a facultative intracellular pathogen that infects animals and immunocompromised human patients (Takai et al., 1991; Takai et al., 2000). This bacterium is the etiological agent of rhodococcosis, an important disease that typically affects foals less than six months of age, causing severe lesions including pyogranulomatous pneumonia and mesenteric lymphadenitis (Prescott, 1991). In R. equi, the most important virulence factor is associated with the presence of virulence proteins (Vap) encode by large plasmids (Takai et al., 1995), which have been used to classify isolates as virulent (VapA); intermediately virulent (VapB) and avirulent (without virulence plasmid) (Ribeiro et al., 2005).

Currently, the treatment of rhodococcosis usually consists of a combined application of macrolides, such as erythromycin, azithromycin or clarithromycin, associated with rifampicin (Muscatello, 2012). However, the increasing resistance in R. equi isolates to various antimicrobials, including the macrolides group, has been reported (Takai et al., 1997; Asoh et al., 2003; Buckley and Stanbridge, 2007; Venner et al., 2012). The microorganisms' resistance to macrolides has been associated to basically three events: presence of methylases, efflux pump activity and enzymatic inactivation (Sutcliffe et al., 1996).

In R. equi, the presence of four putative multidrug efflux proteins was mentioned in the reference strain R. equi 103S (Letek et al., 2010). This study reported the sequence of a chromosomal gene known as req_39680, which encodes a protein with 308 amino acids, related to putative cation efflux system. Similar efflux mechanism was described in mycobacteria being related to the development of high level drug-resistance (Schmalstieg et al., 2012); however, studies about efflux systems activity have not been described in R. equi. Herein, we identified the presence of the req_39680 gene, as well as verified the phenotypic expression of efflux mechanism in soil, feces of healthy animals and clinical R. equi isolates.

R. equi isolates were obtained from ten horse-breeding farms, located in the Brazilian states of Rio Grande do Sul (RS) and Paraná (PR). The isolates were obtained from soil (n = 30), feces of healthy animals (n = 30) and foals clinical (n = 30) samples from 1991 to 2012. The clinical samples were recovered from post-mortem pulmonary lesions subsequent to antimicrobial treatment. The reference strains R. equi ATCC 33701P + (vapA positive), R. equi ATCC 33701P - (vapA negative) and Staphylococcus aureus ATCC 25923 were used as control in both phenotypic and genotypic assays. Mycobacterium goodii SB314/96 and Nocardia sp. SB57/2008 were used as negative control in the genotypic assays.

Among 90 bacterial isolates analyzed, 70 were identified phenotypic and genotypically previously by Monego et al. (2009), being classified as vapA positive R. equi (n = 26) and vapA negative R. equi (n = 44). These isolates were lyophilized and stored at -20 °C until the tests were performed. Additionally, 20 soil samples (≈ 10 g) were collected, especially for this study, in January of 2012 in three different horse-breeding farms in RS. These samples were collected from mare-foal paddocks (n = 20) and stored in sterile plastic bags until the bacteriology culturing. The soil samples were growing in nalidixic acid-novobiocin-actidione (cycloheximide)-potassium tellurite (NANAT) selective medium described by Woolcock et al. (1980). Colonies with R. equi profile were submitted to phenotypic identification (Quinn et al., 1994) and genotypic analysis for genus, species and vapA gene (Takai et al., 1995). All the R. equi soil isolates were classified as vapA negative and also were lyophilized and stored at -20 °C until testing.

In order to evaluate the characteristics of the protein encoded by req_39680 gene prior to the genotypic tests, it was performed a bioinformatics analysis. The sequence of the protein was recovered from R. equi 103S (GenBank access YP_004008630.1) and submitted to analysis by the Phyre V 2.0 (Protein Homology/Analogy Recognition Engine) program (http://www.sbg.bio.ic.ac.uk/phyre2/html/page.cgi?id=index).

Following, the polymerase chain reaction (PCR) method was used to detect the req_39680 gene in the R. equi isolates. Primarily, each strain was grown on Müeller Hinton agar (Himedia^® Laboratories) and incubated at 37 °C for 24 h. Three to five colonies were suspended in 500 μL of Milli-Q water and submitted to DNA extraction by cethyltrimethylammonium bromide (CTAB) protocol (Sambrook and Russell, 2001). The extracted DNA was measured using the Picopet 01 DNA Calculator (Cambridge, England). The PCR primers employed were: forward - RE1 (5'-CCGCGATCCCTCGACACACG-3') and reverse - RE2 (5'-CCCACCCGCATCCGCAAGAT-3'). Both primers were designed using Primer-BLAST program (http://www.ncbi.nlm.nih.gov/tools/primer-blast/) based on DNA sequence of the reference strain R. equi 103S (GenBank access: NC_014659.1) (http://www.ncbi.nlm.nih.gov) in order to amplify the complete gene. The PCR was carried out in a total volume of 25 μL containing: 10 μmoles of each primer, 200 μM of deoxynucleotides (dNTPs, Invitrogen^®), 1 U of DNA polymerase (GoTaq, Invitrogen^®), 1X of the 5X enzyme buffer, and 60 ng of DNA sample. The amplifications were performed using PTC-100 Programmable Thermal Controller (MJ Research) with the following cycling profile: initial denaturation at 94°C/1min, 35 cycles of 94 °C/30 s, 63 °C/30 s and 72 °C/1 min 30 s, and a final extension at 72 °C/5 min. PCR products (10 μL) were run in 1% agarose gel, stained with ethidium bromide, visualized under UV light and photo documented by L-PIX ST (Loccus^® Brazil). All PCR products were purified, in quadruplicate, with the PureLink PCR Purification Kit (Invitrogen^®) and sent for DNA sequencing with the same primers for req_39680 gene. DNA sequencing was performed in an automated sequencer ABI-PRISM 3100 Genetic Analyzer (ACT Gene Molecular Analysis Ltd., Biotechnology Center/UFRGS, Porto Alegre, RS). DNA consensus sequences were generated by Gap program of the Staden package 4 software (Staden et al., 2000) and analyzed by Basic Local Alignment Search Tool (BLAST) (NCBI/DNASIS software version 2.5, Software Engineering Co. Ltd., SanBruno, California, US).

The phenotypic expression of efflux mechanism was performed in agar containing ethidium bromide (EtBr). This assay was based on the use of a fluorescent cationic dye (EtBr) to visualize the efflux mechanism in bacterial cells (adapted from Martins et al., 2006). Six R. equi isolates from clinical (n = 2), feces (n = 2) and soil (n = 2) samples were tested with different concentrations of EtBr (0.2, 0.4, 0.8, 1.0, 1.2, 1.4, 1.6, 1.8 and 2.0 g/mL) in order to determine the toxicity level of this dye for cells. Each group had an isolate presenting req_39680 gene. The reference strain S. aureus ATCC 25923 was used as positive control according Couto et al. (2008). All microorganisms were cultivated in tryptic soy agar (TSA) medium (Himedia^® Laboratories) for 24 h at 37 °C. A single colony of each bacterium was transferred to tryptic soy broth (TSB) medium (Himedia^® Laboratories) and maintained at 37 °C overnight. For each microorganism, an inoculum suspension was prepared in 0.9% saline, adjusted to the turbidly of 0.5 on the McFarland' scale, and absorbance readings were performed in a spectrophotometer at 600 nm-wavelength. Subsequently, dilutions in TSB were carried out to obtain an inoculum containing approximately 1,000 CFU/mL. This inoculum was applied with swab on plates containing EtBr incorporated into the TSA and incubated at 37 °C for 48 h under aerobic conditions. Afterward, these plates were visualized on UV light. Both viability of cells and capacity of detection of efflux systems at the different concentrations were observed. The 0.2 μg/mL EtBr concentration was selected to be used in all isolates (90), since provided the adequate physiological conditions to development of the R. equi. All tests were performed in duplicate. After the visualization of the results on UV light the plates were photo documented by PIX-L ST (Loccus^® Brazil). Bacteria were considered positive to efflux system expression when the fluorescent colonies were not observed under UV light and negative when the colonies showed fluorescence.

The data were analyzed by SAS statistical software (SAS, 2001). The nonparametric Chi-square test was used to calculate the difference in the req_39680 gene frequency among R. equi isolates from different sources. Likewise, it was used the Spearman correlation analysis in order to evaluate the correlation between the presence of this gene with the phenotypic expression of efflux mechanism, as well as the occurrence of vapA gene. The minimum significance level considered was p < 0.05.

The protein encoded by req_39680 gene demonstrated 100% confidence and 96% coverage with MATE family transporter protein; it was classified as multi antimicrobial extrusion protein and characterized as cation-bound multidrug and toxin compound extrusion protein when analyzed by Phyre V 2.0. This finding is very relevant since MATE family transporter proteins are categorized among the multidrug efflux transporter families present in various pathogenic microorganisms (Kuroda and Tsuchiya, 2009). Based on these results we selected the req_39680 gene to perform this study using R. equi isolates.

The req_39680 gene was detected in 60% (54/90) of R. equi isolates tested (Table 1), as well as in R. equi ATCC 33701. This result corroborates with the described by Rahman et al. (2003), which demonstrated that R. equi ATCC 33701 has 12 putative genes encoding efflux proteins, as well as 25 proteins of the ABC family, some of which are related to drug resistance. All PCR- products amplified a specific DNA fragment of approximately 840 bp (Figure 1). The identity of R. equi PCR products was confirmed by DNA sequence consensus analyses, which showed 100% of identity with the reference strain R. equi 103S (GenBank access NC_014659.1). A DNA sequence from a Brazilian R. equi isolate (SB 54/97) was deposited in GenBank (access JX_512957).

Thumbnail

The req_39680 gene was detected in R. equi isolates from clinical (66.7%), soil (66.7%) and feces (46.7%) samples. No difference was observed in the frequency of the gene among R. equi isolates from different sources, thus it is present in a comparable proportion of isolates recovered from all three sources. We suppose that the presence of the req_39680 gene is not an adaptation to the host but may be just as relevant to its saprophytic status, given that aerosols from soil or fecal derived strains are the most likely source of rhodoccocal pneumonia (Muscatello et al., 2006). Likewise, according Letek et al. (2010) some antimicrobial resistance genes may be associated to efflux systems in clinical isolates as well as other environmental rhodococci. Other members of the genus Rhodococcus, such as Rhodococcus erythropolis and Rhodococcus fascians, assure their survival in the environment through the efflux pumps (Desomer et al., 1992; Nagy et al., 1997). According Martinez (2009) drug resistance determinants present in soil organisms typically may have an important impact on the clinical management of microbial infections

The assessment of phenotypic expression of efflux mechanism by methodologies using EtBr as substrate is widely employed in phenotypic studies to verify efflux pumps (Li and Nikaido, 2004); however, it is based on qualitative results and have also show limitation due to physiological characteristics of each microorganism (Martins et al., 2006). In this sense, we firstly standardized the phenotypic expression of efflux mechanism assay with different EtBr concentrations, in order to know the concentration that did not affect the best growth of the bacterial cells. We suggest that this methodological approach could be a useful to further screening assays of efflux systems in R. equi, furthermore, this is an instrument-free method for the demonstration of efflux pump activity of bacteria (Martins et al., 2006).

The efflux mechanism by extruding of EtBr was detected in 20% (18/90) of R. equi isolates tested, including: 61.1% (11/18) clinical, 22.2% (4/18) soil and 16.7% (3/18) feces isolates (Table 1). Although the req_39680 gene has been detected in all positive samples for efflux mechanism by extruding of EtBr, we cannot establish a relationship between efflux and presence or absence of req_39680 gene. On the other hand, 66.6% (36/54) of req_39680 gene positive R. equi isolates did not show phenotypic expression of efflux mechanism. We suppose that this mechanism may be expressed by these isolates in other circumstances to be evaluated. In this respect, Viveiros et al. (2005) demonstrated that an E. coli strain sensitive to tetracycline became resistant due to the efflux mechanism induced after slow and gradual exposure to the antibiotic and this expression was reverted by serial transfer to drug-free medium or by exposure to inhibitors of efflux pumps.

A high correlation index (0.66; p < 0.0001) was verified between the presence of the req_39680 gene and phenotypic expression of efflux mechanism in clinical isolates. However, no correlation was observed in R. equi isolates from feces and soil. We believe that the fact of these clinical samples have been recovered from foals post-mortem pulmonary lesions, subsequent to antimicrobial treatment against R. equi, may be driving an expression of the efflux mechanism in the host. The treatment failures observed in infections by R. equi may be associated to the extrusion of chemical compounds (e.g. antimicrobials) once resistance mechanisms to macrolides also include two families of efflux pumps (Roberts et al., 1999), increasing the chances of failure in infection control.

According to Letek et al. (2010) the correlation between the presence of virulence and antimicrobial resistance genes in R. equi is not well documented. As stated by these same authors, it is possible the occurrence of a direct regulatory interaction or only a random effect between these genes. In this study, no correlation was observed between the presence of both vapA and req_39680 genes in R. equi isolates. This finding may be better explained by the location of req_39680 gene, since it has a chromosomal locus and the vapA is a plasmidial gene.

In conclusion, the req_39680 gene is equally distributed among R. equi isolates from different sources and a high correlation index between phenotypic expression of efflux mechanism and presence of req_39680 gene was observed in clinical samples. Thus, there is a potential possibility of efflux systems to be an emerging form of adaptation to pathogenic and saprophytic life by R. equi isolates; however, additional studies are required to confirm this hypothesis.

Submitted: April 29, 2013

Approved: March 14, 2014

All the content of the journal, except where otherwise noted, is licensed under a Creative Commons License CC BY-NC.

Asoh N, Watanabe H, Fines-Guyon M, Watanabe K, Oishi K, Kositsakulchai W, Sanchai T, Kunsuikmengrai K, Kahintapong S, Khantawa B, Tharavichitkul P, Sirisanthana T, Nagatake T (2003) Emergence of rifampin-resistant Rhodococcus equi with several types of mutations in the rpoB gene among AIDS patients in northern Thailand. J Clin Microbiol 41:2337-2340.
Buckley TE, Stanbridge S (2007) Resistance studies of erythromycin and rifampin for Rhodococcus equi over a 10-year period. Irish Vet J 60:728-731.
Couto I, Costa SS, Viveiros M, Martins M, Amaral L (2008) Efflux-mediated response of Staphylococcus aureus exposed to ethidium bromide. J Antimicrob Chemoth 62:504-513.
Desomer J, Vereecke D, Crespi M, Van Montagu M (1992) The plasmid-encoded chloramphenicol-resistance protein of Rhodococcus fascians is homologuos to the transmembrane tetracycline efflux proteins. Mol Microbiol 6:2377-2385.
Kumar A, Schweizer HP (2005) Bacterial resistance to antibiotics: Active efflux and reduced uptake. Adv Drug Deliver Rev 57:1486-1513.
Kuroda T, Tsuchiya T (2009) Multidrug efflux transporters in the MATE family. Biochim Biophys Acta 1794:763-768.
Letek M, González P, MacArthur I, Rodríguez H, Freeman TC, Valero-Rello A, Blanco M, Buckley T, Cherevach I, Fahey R, Hapeshi A, Holdstock A, Leadon D, Navas J, Ocampo A, Quail MA, Sanders M, Scortti MM, Prescott JF, Fogarty U, Meijer WG, Parkhill J, Bentley SD, Vázquez-Boland JA (2010) The genome of a pathogenic Rhodococcus: Cooptive virulence underpinned by key gene acquisitions. Plos Genet 6:e1001145.
Li XZ, Nikaido H (2004) Efflux-mediated drug resistance in bacteria. Drugs 64:159-204.
Martinez JL (2009) The role of natural environments in the evolution of resistance traits in pathogenic bacteria. P Roy Soc B-Biol Sci 276:2521-2530.
Martins M, Santos B, Martins A, Viveiros M, Couto I, Cruz A, Pagés J, Molnar J, Fanning S, Amaral L (2006) An instrument-free method for the demonstration of efflux pump activity of bacteria. In vivo 20:657-664.
Mcmurray LM, Petrucci RE, Levy SB (1980) Active efflux of tetracycline encoded by four genetically different tetracycline resistance determinants in Escherichia coli Proc Nat Acad Sci USA 77:3974-3977.
Monego F, Maboni F, Krewer C, Vargas A, Costa M, Loreto E (2009) Molecular characterization of Rhodococcus equi from horse-breeding farms by means of multiplex PCR for the vap gene family. Curr Microbiol 58:399-403.
Muscatello G, Gerbaud S, Kennedy C, Gilkerson JR, Buckley T, Klay M, Leadon DP, Browning GF (2006) Comparison of concentrations of Rhodococcus equi and virulent R. equi in air of stables and paddocks on horse breeding farms in a temperate climate. Equine Vet J 38(3):263-265
Muscatello G (2012) Rhodococcus equi pneumonia in the foal-Part 2: Diagnostics, treatment and disease management. Vet J 192:27-33.
Nagy I, Schoofs G, Vanderleyden J, Mot R (1997) Transposition of the IS21-related element IS1415 in Rhodococcus erythropolis J Bacteriol 179:4635-4638.
Paulsen IT (2003) Multidrug efflux pumps and resistance: Regulation and evolution. Curr Opin Microbiol 6:446-451.
Prescott JF (1991) Rhodococcus equi: An animal and human pathogen. Clin Microbiol Rev 4:20-34.
Quinn, P.J.; Carter, M.E.; Markey, B.; Carter, G.R. (1994). Corynebacterium species and Rhodococcus equi In: Quinn, P.J., Carter, M.E., Markey, B., Carter, G.R. (eds) Clinical Veterinary Microbiology. Wolfe, London, pp 137-143.
Rahman MT, Herron LL, Kapur V, Meijer WG, Byrne BA, Ren J, Nicholson VM, Prescott JF (2003) Partial genome sequencing of Rhodococcus equi ATCC 33701. Vet Microbiol 94:143-158.
Ribeiro MG, Seki I, Yasuoka K, Kaduda T, Sasaki Y, Tsubaki S, Takai S (2005) Molecular epidemiology of virulent Rhodococcus equi from foals in Brazil: Virulence plasmids of 85-kb type I, and a new variant, 87-kb Type III. Comp Immunol Microb 28:53-61.
Roberts MC, Sutcliffe J, Courvalin P, Jensen LB, Rood J, Seppala H (1999) Nomenclature for macrolide and macrolide-lincosamide streptogramin B antibiotic resistance determinants. Antimicrob Agents Chemother 43:2823-2830.
Sambrook J, Russell DW (2001) Molecular Cloning: A Laboratory Manual, Cold Spring Harbor Laboratory Press, New York, 2344 pp.
SAS (2001) Statistical analysis system user's guide: Statistics. Version 8.2, Cary: Statistical Analysis System Institute, 1686 pp.
Schmalstieg AM, Srivastava S, Belkaya S, Deshpande D, Meek C, Leff R, Oers NSC, Gumbo T (2012) The antibiotic-resistance arrow of time: Efflux pump induction is a general first step in the evolution of Mycobacterial drug-resistance. Antimicrob Agents Chemother 56:4806-4815.
Staden R, Beal KF, Bonfield JK (2000) The Staden Package, 1998. Met Mol Biol 132:115-130.
Sutcliffe J, Grebe T, Tait-Kamradt A, Wondrack L (1996) Detection of erythromycin-resistant determinants by PCR. Antimicrob Agents Ch 40(11):2562-2566.
Takai S, Ohbushi S, Koike K, Tsubaki S, Oishi H, Kamada M (1991) Prevalence of virulent Rhodococcus equi in isolates from soil and feces of horses from horse-breeding farms with and without endemic infections. J Clinical Microbiol 29:2887-2889.
Takai S, Ikeda T, Sasaki Y, Watanabe Y, Ozawa T, Tsubaki S, Sekizaki T (1995) Identification of virulent Rhodococcus equi by amplification of gene coding 15 to 17 kilodalton antigens. J Clinical Microbiol 33:1624-1627.
Takai S, Takeda K, Nakano Y, Karasawa T, Furugoori J, Sasaki Y, Tsubaki S, Higuchi T, Anzai T, Wada R, Kamada M (1997) Emergence of rifampicin-resistant Rhodococcus equi in an infected foal. J Clinical Microbiol 35:1904-1908.
Takai S, Hines SA, Sekizaki T, Nicholson VM, Alperin DA, Osaki M, Takamatsu D, Nakamura M, Suzuki K, Ogino N, Kakuda T, Dan H, Prescott J (2000) DNA sequence and comparison of virulence plasmids from Rhodococcus equi ATCC 33701 and 103. Infect Immun 68:6840-6847.
Venner M, Rödiger A, Laemmer M, Giguère S (2012) Failure of antimicrobial therapy to accelerate spontaneous healing of subclinical pulmonary abscesses on a farm with endemic infections caused by Rhodococcus equi Vet J. 192(3):293-298.
Viveiros M, Jesus A, Brito M, Leandro C, Martins M, Ordway D, Molnar AM, Molnar J, Amaral L (2005) Inducement and reversal of tetracycline resistance in Escherichia coli K-12 and expression of proton gradient-dependent multidrug efflux pump genes. Antimicrob Agent Chemother 49:3578-3582.
Webber MA, Piddock LJV (2003) The importance of efflux pumps in bacterial antibiotic resistance. J Antimicrob Chemother 51:9-11.
Woolcock JB, Mutimer MD, Farmer AMT (1980) Epidemiology of Corynebacterium equi in horses. Res Vet Sci 28:87-90.

Correspondence:

S.A. Botton

Departamento de Medicina Veterinária Preventiva

Universidade Federal de Santa Maria

Avenida Roraima 1000, Prédio 44, Sala 5007

97105-900, Santa Maria, RS, Brazil

E-mail:

sabott20@gmail.com

Publication Dates

Publication in this collection
30 Sept 2014
Date of issue
June 2014

History

Accepted
14 Mar 2014
Received
29 Apr 2013

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

[1] Asoh N, Watanabe H, Fines-Guyon M, Watanabe K, Oishi K, Kositsakulchai W, Sanchai T, Kunsuikmengrai K, Kahintapong S, Khantawa B, Tharavichitkul P, Sirisanthana T, Nagatake T (2003) Emergence of rifampin-resistant Rhodococcus equi with several types of mutations in the rpoB gene among AIDS patients in northern Thailand. J Clin Microbiol 41:2337-2340.

[2] Buckley TE, Stanbridge S (2007) Resistance studies of erythromycin and rifampin for Rhodococcus equi over a 10-year period. Irish Vet J 60:728-731.

[3] Couto I, Costa SS, Viveiros M, Martins M, Amaral L (2008) Efflux-mediated response of Staphylococcus aureus exposed to ethidium bromide. J Antimicrob Chemoth 62:504-513.

[4] Desomer J, Vereecke D, Crespi M, Van Montagu M (1992) The plasmid-encoded chloramphenicol-resistance protein of Rhodococcus fascians is homologuos to the transmembrane tetracycline efflux proteins. Mol Microbiol 6:2377-2385.

[5] Kumar A, Schweizer HP (2005) Bacterial resistance to antibiotics: Active efflux and reduced uptake. Adv Drug Deliver Rev 57:1486-1513.

[6] Kuroda T, Tsuchiya T (2009) Multidrug efflux transporters in the MATE family. Biochim Biophys Acta 1794:763-768.

[7] Letek M, González P, MacArthur I, Rodríguez H, Freeman TC, Valero-Rello A, Blanco M, Buckley T, Cherevach I, Fahey R, Hapeshi A, Holdstock A, Leadon D, Navas J, Ocampo A, Quail MA, Sanders M, Scortti MM, Prescott JF, Fogarty U, Meijer WG, Parkhill J, Bentley SD, Vázquez-Boland JA (2010) The genome of a pathogenic Rhodococcus: Cooptive virulence underpinned by key gene acquisitions. Plos Genet 6:e1001145.

[8] Li XZ, Nikaido H (2004) Efflux-mediated drug resistance in bacteria. Drugs 64:159-204.

[9] Martinez JL (2009) The role of natural environments in the evolution of resistance traits in pathogenic bacteria. P Roy Soc B-Biol Sci 276:2521-2530.

[10] Martins M, Santos B, Martins A, Viveiros M, Couto I, Cruz A, Pagés J, Molnar J, Fanning S, Amaral L (2006) An instrument-free method for the demonstration of efflux pump activity of bacteria. In vivo 20:657-664.

[11] Mcmurray LM, Petrucci RE, Levy SB (1980) Active efflux of tetracycline encoded by four genetically different tetracycline resistance determinants in Escherichia coli Proc Nat Acad Sci USA 77:3974-3977.

[12] Monego F, Maboni F, Krewer C, Vargas A, Costa M, Loreto E (2009) Molecular characterization of Rhodococcus equi from horse-breeding farms by means of multiplex PCR for the vap gene family. Curr Microbiol 58:399-403.

[13] Muscatello G, Gerbaud S, Kennedy C, Gilkerson JR, Buckley T, Klay M, Leadon DP, Browning GF (2006) Comparison of concentrations of Rhodococcus equi and virulent R. equi in air of stables and paddocks on horse breeding farms in a temperate climate. Equine Vet J 38(3):263-265

[14] Muscatello G (2012) Rhodococcus equi pneumonia in the foal-Part 2: Diagnostics, treatment and disease management. Vet J 192:27-33.

[15] Nagy I, Schoofs G, Vanderleyden J, Mot R (1997) Transposition of the IS21-related element IS1415 in Rhodococcus erythropolis J Bacteriol 179:4635-4638.

[16] Paulsen IT (2003) Multidrug efflux pumps and resistance: Regulation and evolution. Curr Opin Microbiol 6:446-451.

[17] Prescott JF (1991) Rhodococcus equi: An animal and human pathogen. Clin Microbiol Rev 4:20-34.

[18] Quinn, P.J.; Carter, M.E.; Markey, B.; Carter, G.R. (1994). Corynebacterium species and Rhodococcus equi In: Quinn, P.J., Carter, M.E., Markey, B., Carter, G.R. (eds) Clinical Veterinary Microbiology. Wolfe, London, pp 137-143.

[19] Rahman MT, Herron LL, Kapur V, Meijer WG, Byrne BA, Ren J, Nicholson VM, Prescott JF (2003) Partial genome sequencing of Rhodococcus equi ATCC 33701. Vet Microbiol 94:143-158.

[20] Ribeiro MG, Seki I, Yasuoka K, Kaduda T, Sasaki Y, Tsubaki S, Takai S (2005) Molecular epidemiology of virulent Rhodococcus equi from foals in Brazil: Virulence plasmids of 85-kb type I, and a new variant, 87-kb Type III. Comp Immunol Microb 28:53-61.

[21] Roberts MC, Sutcliffe J, Courvalin P, Jensen LB, Rood J, Seppala H (1999) Nomenclature for macrolide and macrolide-lincosamide streptogramin B antibiotic resistance determinants. Antimicrob Agents Chemother 43:2823-2830.

[22] Sambrook J, Russell DW (2001) Molecular Cloning: A Laboratory Manual, Cold Spring Harbor Laboratory Press, New York, 2344 pp.

[23] SAS (2001) Statistical analysis system user's guide: Statistics. Version 8.2, Cary: Statistical Analysis System Institute, 1686 pp.

[24] Schmalstieg AM, Srivastava S, Belkaya S, Deshpande D, Meek C, Leff R, Oers NSC, Gumbo T (2012) The antibiotic-resistance arrow of time: Efflux pump induction is a general first step in the evolution of Mycobacterial drug-resistance. Antimicrob Agents Chemother 56:4806-4815.

[25] Staden R, Beal KF, Bonfield JK (2000) The Staden Package, 1998. Met Mol Biol 132:115-130.

[26] Sutcliffe J, Grebe T, Tait-Kamradt A, Wondrack L (1996) Detection of erythromycin-resistant determinants by PCR. Antimicrob Agents Ch 40(11):2562-2566.

[27] Takai S, Ohbushi S, Koike K, Tsubaki S, Oishi H, Kamada M (1991) Prevalence of virulent Rhodococcus equi in isolates from soil and feces of horses from horse-breeding farms with and without endemic infections. J Clinical Microbiol 29:2887-2889.

[28] Takai S, Ikeda T, Sasaki Y, Watanabe Y, Ozawa T, Tsubaki S, Sekizaki T (1995) Identification of virulent Rhodococcus equi by amplification of gene coding 15 to 17 kilodalton antigens. J Clinical Microbiol 33:1624-1627.

[29] Takai S, Takeda K, Nakano Y, Karasawa T, Furugoori J, Sasaki Y, Tsubaki S, Higuchi T, Anzai T, Wada R, Kamada M (1997) Emergence of rifampicin-resistant Rhodococcus equi in an infected foal. J Clinical Microbiol 35:1904-1908.

[30] Takai S, Hines SA, Sekizaki T, Nicholson VM, Alperin DA, Osaki M, Takamatsu D, Nakamura M, Suzuki K, Ogino N, Kakuda T, Dan H, Prescott J (2000) DNA sequence and comparison of virulence plasmids from Rhodococcus equi ATCC 33701 and 103. Infect Immun 68:6840-6847.

[31] Venner M, Rödiger A, Laemmer M, Giguère S (2012) Failure of antimicrobial therapy to accelerate spontaneous healing of subclinical pulmonary abscesses on a farm with endemic infections caused by Rhodococcus equi Vet J. 192(3):293-298.

[32] Viveiros M, Jesus A, Brito M, Leandro C, Martins M, Ordway D, Molnar AM, Molnar J, Amaral L (2005) Inducement and reversal of tetracycline resistance in Escherichia coli K-12 and expression of proton gradient-dependent multidrug efflux pump genes. Antimicrob Agent Chemother 49:3578-3582.

[33] Webber MA, Piddock LJV (2003) The importance of efflux pumps in bacterial antibiotic resistance. J Antimicrob Chemother 51:9-11.

[34] Woolcock JB, Mutimer MD, Farmer AMT (1980) Epidemiology of Corynebacterium equi in horses. Res Vet Sci 28:87-90.

Brasil

Brasil

Genotypic and phenotypic detection of efflux pump in Rhodococcus equi

Abstract

Publication Dates

History