Adaptation to Biocides Cetrimide and Chlorhexidine in Bacteria from

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Adaptation to biocides cetrimide and chlorhexidine in bacteria from organic foods: association with tolerance to other antimicrobials and physical stresses Rebeca Gadea, Nicolas Glibota, Ruben Pérez Pulido, Antonio Galvez, and Elena Ortega J. Agric. Food Chem., Just Accepted Manuscript • DOI: 10.1021/acs.jafc.6b04650 • Publication Date (Web): 08 Feb 2017 Downloaded from http://pubs.acs.org on February 9, 2017

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Journal of Agricultural and Food Chemistry

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Adaptation to biocides cetrimide and chlorhexidine in bacteria from organic foods:

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association with tolerance to other antimicrobials and physical stresses

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Rebeca Gadea, Nicolás Glibota, Rubén Pérez Pulido, Antonio Gálvez*, Elena Ortega

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Área de Microbiología. Departamento de Ciencias de la Salud. Facultad de Ciencias

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Experimentales. Universidad de Jaén. 23071-Jaén, Spain.

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*Corresponding author. Present address: Área de Microbiología. Departamento de

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Ciencias de la Salud. Facultad de Ciencias Experimentales. Edif. B3. Universidad de

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Jaén. Campus Las Lagunillas s/n. 23071-Jaén, Spain. Tel.: 34-953-212160; fax: 34-

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953-212943.

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E-mail address: [email protected]

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ACS Paragon Plus Environment


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ABSTRACT

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Chlorhexidine (CH) and quaternary ammonium compounds (QAC), like cetrimide (CE)

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are widely used as disinfectants because of their broad antimicrobial spectrum.

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However, their frequent use for disinfection in different settings may promote bacterial

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drug resistance against both biocides and clinically relevant antibiotics. This study

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analyzes the effects of step-wise exposure to cetrimide (CE) and chlorhexidine (CH) of

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bacteria from organic foods and previously classified as biocide-sensitive. Gradual

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exposure of these strains to biocides resulted in mainly transient decreased antimicrobial

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susceptibility to other antibiotics and to biocides. Biocide-adapted bacteria also exhibit

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alterations in physiological characteristics, mainly decreased heat tolerance, or gastric

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acid tolerance in CE-adapted strains, while bile resistance does not seem to be

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influenced by biocide adaptation. Results from this study suggest that changes in

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membrane fluidity may be the main mechanism responsible for the acquisition of stable

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tolerance to biocides.

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Keywords: biocides; chlorhexidine; cetrimide; adaptation; antibiotics; resistance genes

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INTRODUCTION

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Biocides have been extensively used as disinfectants by the pharmaceutical, chemical,

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and food industries. Non-negligible amounts are also used for domestic and

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environment purposes. Chlorhexidine (CH) and quaternary ammonium compounds

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(QAC), as cetrimide (CE) are biocides widely used because of their broad antimicrobial

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spectrum.

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Chlorhexidine is likely the most widely used biocide in antiseptic products,

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particularly in handwashing and oral products1 but also as a disinfectant and

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preservative. The uptake of chlorhexidine by bacteria occurs within 20 seconds2,

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causing damage of the outer cell layers.3 At the cytoplasmic membrane level,

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chlorhexidine has a biphasic effect on membrane permeability, inducing an initial high

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rate of leakage that is followed by a reduction of leakage as the concentration of

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chlorhexidine increases, due to coagulation of the cytosol.4

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QACs have also been used for a variety of clinical purposes, and for hard-

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surface cleaning and deodorization. QACs cause a loss of integrity and structural

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organization of the bacterial cytoplasmic membrane,5,6 together with other cell

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damaging effects.7 The QAC cetrimide has also been found to discharge the pH

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component of the Proton Motive Force at bacteriostatic concentrations.8 Unlike

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chlorhexidine, however, no biphasic effect on protoplast lysis has been observed.

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While the strong killing effects of biocides are clinically and industrially

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beneficial, their frequent use may lead to the development of bacterial drug resistance9

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not only against biocides but also against clinically relevant antibiotics.10 In fact,

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reduced sensitivity to chlorhexidine digluconate, benzalkonium chloride and Irgasan(®)

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has been associated with resistance to carbapenems, aminoglycosides, tetracycline and

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ciprofloxacin in Acinetobacter baumannii in previous studies.11 We have also



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previously described increased tolerance to biocides and antibiotics in bacteria from

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organic foods after exposure to phenolic biocides.12 Moreover, methods for the

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detection of antibiotic residues in foods continue to be described.13 Even so, residues of

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biocides can cause an increase in the dissemination and accumulation of antibiotic-

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resistant bacteria or antibiotic resistance genes along the food chain.

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This study aimed at analyzing the effects of step-wise exposure of biocide-

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sensitive bacteria from organic foods to chlorhexidine (CH) and cetrimide (CE), and to

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determine possible modifications in sensitivity to antibiotics, environmental stress and

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membrane fluidity following adaptation to these biocides.

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MATERIAL AND METHODS

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Antimicrobials. The biocides and antibiotics employed for the assays together

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with their commercial suppliers were described in a previous study:12 benzalkonium

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chloride

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didecyldimethylammonium bromide (AB), triclosan (TC), hexachlorophene [2,2′-

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methylenebis(3, 4,6-trichlorophenol)] (CF), chlorhexidine (CH), ampicillin (AM),

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ceftazidime (CAZ), cefotaxime (CTX), imipenem (IPM), ciprofloxacin (CIP),

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sulfamethoxazol (SXT), sulfamethoxazol/trimethoprim (TMP/SXT), tetracycline (TE),

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and nalidixic acid (NA) (for Salmonella).

(BC),

cetrimide

(CE),

hexadecylpyridinium

chloride

(HDP),

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Bacterial strains. A collection of 76 biocide-sensitive strains previously

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isolated from 39 foods certified as organically grown according to European regulations

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(http://www.wipo.int/edocs/lexdocs/laws/en/eu/eu122en.pdf)14 were used in this study

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(Table S1). Strains were grown in Brain Heart Infusion (BHI) broth (Scharlab,

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Barcelona, Spain) for 15 h at 37°C.


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Strain identification. Most strains were identified in previous studies.13 Only

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Chryseobacterium sp. UJA48q was identified in the present study, using the

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methodology previously reported.15,16

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Strain adaptation to biocides. Strains were adapted to the biocides cetrimide

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(CE) and chlorhexidine (CH) by serial inoculation on Trypticase Soy Broth (TSB;

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Scharlab) supplemented with a range of concentrations of the biocides as described

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previously.12,17 The suspensions from the last tubes with recorded bacterial growth were

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seeded on TSA plates and the bacterial colonies were collected, resuspended in 1 ml

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BHI broth (Scharlab) containing 20% glycerol and stored at -80 °C. The stability of the

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adaptive tolerance and minimum inhibitory concentrations (MICs) after 5, 10, 15 and 20

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passages were also determined as described previously.12

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Determination of adaptive tolerance, sensitivity to biocides and antibiotics.

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The MICs for other biocides and for antibiotics of wildtype, CE- and CH-adapted

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strains were determined in TSB (Scharlab) by the broth microdilution method using 96-

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well microtiter plates inoculated in triplicate with bacterial suspensions adjusted to

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5x105 colony-forming units (CFU)/ml as described previously.12 For biocide dilutions

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with high turbidity, the minimum bactericidal concentration (MBC) was determined.12

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The final concentrations used for antibiotics correspond to the MICs and twice

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the MICs interpretative standard of antibiotic-resistant strains defined by Clinical and

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Laboratory Standards Institute.18

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PCR detection of resistance genes. The following efflux pump genes were

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investigated by PCR amplification: acrB and mdfA,19; sugE,20 yhiUV and evgA,21

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emeA,22 qacA/B, qacC, qacG, qacH and qacJ,23 qacE∆1,24 efrA and efrB,

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mepA, norA, norB, norC, sdrM and sepA.26


25

mdeA,


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Genes conferring resistance to β-lactam antibiotics (bla, mecA), chloramphenicol

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(cat),26,27 aminoglycosides (aac(6_)-Ie-aph(2_)-Ia, aph(2_)-Ib, aph(2_)-Ic, aph(2_)-Id,

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aph(3_)-IIIa, and ant(4_)-Ia genes,28 macrolides (the ermA, ermB, ermC, ereA, ereB,

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msrA/B, mphA, and mefA genes),29 and lincosamide and streptogramin A (lsa gene)30,31

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were also investigated.

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Determination of the role of efflux pumps in biocide resistance. Gram-

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positive strains showing high-resistance phenotype were inspected for restored

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sensitivity to the compounds in the presence of 25 µg/ml reserpine (Sigma-Aldrich) as

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efflux pump inhibitor.32

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Determination of growth capacity. Growth capacity of wildtype and biocide-

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adapted strains was determined on 96-well microtiter plates inoculated in triplicate with

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approx. 104 CFU/ml of each tested strain as described previously.12 The corresponding

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sterility controls were included.

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Determination of heat tolerance. Bacterial cell suspensions (approx. 106

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CFU/ml in 2 ml peptone water) in triplicate were incubated for 5 min at 60, 65 and 70

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°C.12,33 After heating, samples were serially diluted and surface-plated on TSA to

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determine viable cell concentrations.

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Determination of resistance to simulated gastric fluid and bile salts.

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Wildtype and biocide-adapted cells (approx. 106 CFU/ml in TSB) were tested in

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triplicate for survival in simulated gastric acid fluid and bile salts according to Kim et

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al.34 and Gadea et al.12 Viable cell counts were determined at time zero and after

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incubations by serial dilution and surface plating on TSA.

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Fluorescent anisotropy measurements. Membrane fluidity of intact whole

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cells was measured by fluorescence anisotropy with the hydrophobic probe 1,6-

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diphenyl-1,3,5-hexatriene (DPH) (Sigma-Aldrich, Madrid, Spain) as described by


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Alonso-Hernando, Alonso-Calleja, and Capita (2010).36 The determinations of

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fluorescence anisotropy (Cary Eclipse Fluorescence Spectrophotometer; Varian Inc.,

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CA, USA) were optimised as described previously12.

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Statistical analysis. Data on heat tolerance, growth capacity and fluorescence

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anisotropy were compared with a Student t-test (Statgraphics Centurion Version XVII-

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X64; StatPoint Technologies, Inc., USA) in order to detect statistically significant

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differences. Principal component analysis (PCA) with Pearson correlation coefficient (r)

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was used to analyze biocide tolerance data after exposure to CE or CH (MATLAB

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R2011b 7.13 version; MathWorks, USA). Significant correlations (P

Adaptation to Biocides Cetrimide and Chlorhexidine in Bacteria from

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