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Adaptation to benzalkonium chloride and ciprofloxacin affects biofilm formation potential, efflux pump and haemolysin activity of Escherichia coli of dairy origin

Published online by Cambridge University Press:  06 July 2012

Ankita Pagedar ,
Jitender Singh  and
Virender K. Batish
Ankita Pagedar*
Affiliation:
Dairy Microbiology Division, National Dairy Research Institute (NDRI), Karnal (Haryana) 132001, India Present Address: Department of Microbiology, Ashok and Rita Patel Institute of Integrated Studies and Research in Biotechnology and Allied Sciences (ARIBAS), New Vallabh Vidya Nagar-388121, Gujarat, India
Jitender Singh
Affiliation:
Dairy Microbiology Division, National Dairy Research Institute (NDRI), Karnal (Haryana) 132001, India Present Address: Product and Process Development Group, National Dairy Development Board (NDDB), Anand-388001, Gujarat, India
Virender K. Batish
Affiliation:
Dairy Microbiology Division, National Dairy Research Institute (NDRI), Karnal (Haryana) 132001, India
*
*For correspondence; e-mail: ankitapagedar@gmail.com
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Abstract

The present study investigates the effect of adaptive resistance to ciprofloxacin (Cip) and benzalkonium chloride (BC) on biofilm formation potential (BFP), efflux pump activity (EPA) and haemolysin activity of Escherichia coli isolates of dairy origin. All the isolates, irrespective of antimicrobial susceptibility, developed significant adaptive resistance (P < 0·05). All the resistant phenotypes (antibiotic resistant: AR; & biocide resistant: BR) were stronger biofilm former and post-adaptation, an insignificant change was observed in their BFP. Whereas, post-adaptation, non-resistant isolates (antibiotic non-resistant: ANR; biocide non-resistant: BNR) transformed from poor or moderate to strong biofilm formers. Post-adaptive percentage increase in EPA was highly significant in non-resistant categories (P < 0·01) and significant at P < 0·05 in BR category. Interestingly, post-adaptive increase in EPA in BR isolates was more than that in AR yet, the latter exhibited greater adaptive resistance than the former. These findings indicated prevalence of some other specific resistance mechanism/s responsible for adaptive resistance against Cip. Strain specific variations were observed for stability of adaptive resistance and haemolysin activity for all the categories. Our findings especially in reference to post-adaptation upgradation of BFP status of non-resistant isolates seems to be providing an insight into the process of conversion of non-resistant isolate into resistant ones with enhanced BFP. These observations emphasize the serious implications of sub-lethal residual levels of antimicrobials in food environments and suggest a role of food chain in emergence of antimicrobial resistances.

Keywords

Adaptive resistanceefflux pump activityEscherichia colidairy biofilmhaemolysinbenzalkonium chlorideciprofloxacin
Type
Research Article
Information
Journal of Dairy Research , Volume 79 , Issue 4 , November 2012 , pp. 383 - 389
Copyright
Copyright © Proprietors of Journal of Dairy Research 2012

In food industry Escherichia coli strains are common contaminants and indicator of poor hygiene and sanitary conditions. Beyond sanitary issues, Esch. coli serotype such as O157:H7 and others are a leading cause of outbreaks associated with foods including dairy products. The journey of raw material such as milk, from farm to product processing facility provides multiple portals for the organism to enter the supply chain. At a farm level, it is a common practice to use fluoroquinolones such as ciprofloxacin (Cip) to contain microbial risks. However, their usage at sub-judicious concentrations may adapt the organism even to higher concentrations of antibiotics (van der Horst et al. Reference van der Horst, Schuurmans, Smid, Koenders and Ter Kuile2011). In this regard, a previous report has documented prevalence of Cip resistance in 21·5% of food origin Esch. coli in Republic of Ireland, which was the highest in Europe (url: http://www.safefood.eu/en/Publication/Research-reports/The-problem-of-Antimicrobial-Resistance-in-the-food-chain/ accessed on 27 July 2011). The next level in a food chain where food microflora is subjected to antimicrobial compounds is clean-in-place protocols in a food processing facility. A routine sanitary regime may involve application of biocides such as benzalkonium chloride (BC) and sodium hypochlorite to disinfect processing equipment and surfaces (Langsrud et al. Reference Langsrud, Sundheim and Holck2004). However, various circumstances such as carry over contamination of water, improper rinse and protective action of food might reduce their effective concentrations. These sub-lethal concentrations have been reported to induce adaptations against related and unrelated antimicrobial compounds in the organism (van der Horst et al. Reference van der Horst, Schuurmans, Smid, Koenders and Ter Kuile2011). In this context an earlier study has shown that BC adapted strains of Pseudomonas aeruginosa of dairy origin could develop cross resistance against Cip (Pagedar et al. Reference Pagedar, Singh and Batish2011).

A previous study has shown strong biofilm forming clinical isolates of Esch. coli to exhibit reduced susceptibility to Cip (Naves et al. Reference Naves, del Prado, Huelves, Gracia, Ruiz, Blanco, Dahbi, Blanco, del Carmen Ponte and Soriano2008). Similarly, the biofilms of Esch. coli have also been found to be resistant to biocides such as BC and other disinfectants (Ntsama-Essomba et al. Reference Ntsama-Essomba, Bouttier, Ramaldes, Dubois-Brissonnet and Fourniat1997). Overall, it is a well established fact that the metabolic changes and protective effect of biofilm matrix create a conducive environment for biofilm inhabitants to adapt to higher concentrations of antimicrobial compounds (Brown & Gilbert, Reference Brown and Gilbert1993). However, there is hardly any report discussing the phenomenon in reverse order i.e. the effect of antimicrobial adaptation on biofilm formation potential of the organism. Such a study may provide useful information from a food safety as well as a clinical point of view if such adaptations confer any survival advantage to microorganisms.

In Esch. coli, resistance-nodulation division-type efflux pumps [AcrB, AcrF, MdtB (YegN), MdtC (YegO), YhiV (MdtF)] are widely distributed and play a significant role in both intrinsic and acquired resistances against compounds such as detergents, ethidium bromide (EtBr) and antibiotics (Bohnert et al. Reference Bohnert, Schuster, Fahnrich, Trittler and Kern2007). In Esch. coli efflux mediated fluoroquinolone and BC resistance has already been reported (Bore et al. Reference Bore, Hébraud, Chafsey, Chambon, Skjaeret, Moen, Møretrø, Langsrud, Rudi and Langsrud2007; van der Horst et al. Reference van der Horst, Schuurmans, Smid, Koenders and Ter Kuile2011). Apart from antimicrobial resistance, EPA has also been held responsible for enhancing the virulence of enteroaggregative Esch. coli by promoting aggregation (Imuta et al. Reference Imuta, Nishi, Tokuda, Fujiyama, Manago, Iwashita, Sarantuya and Kawano2008). In our previous study, we established the role of EPA in imparting adaptive and cross resistance against BC and Cip to food origin Ps. aeruginosa (Pagedar et al. Reference Pagedar, Singh and Batish2011). However, in reference to food origin Esch. coli we could not come across any study on these lines.

In Esch. coli, haemolysin is one of the major virulence factors along with shiga-like toxin, attaching and effacing lesions (Skals et al. Reference Skals, Jorgensen, Leipziger and Praetorius2009). Alpha haemolysin releasing Esch. coli have been reported to colonise and cause urinary tract infection (Rijavec et al. Reference Rijavec, Muller-Premru, Zakotnik and Zgur-Bertok2008). A similar report in context to prostitis causing Esch. coli strains established a close association (P = 0·03) between in vitro BFP and haemolysin activity (Soto et al. Reference Soto, Smithson, Martinez, Horcajada, Mensa and Vila2007). The underlying basis for the association of susceptibility to antibiotics and virulence is still unclear. There are contrary reports regarding acquisition of virulence before (Johnson et al. Reference Johnson, Kuskowski, Gajewski, Soto, Horcajada, Jimenez de Anta and Vila2005) or after development or acquisition of resistances (Horcajada et al. Reference Horcajada, Soto, Gajewski, Smithson, Jimenez de Anta, Mensa, Vila and Johnson2005; Piatti et al. Reference Piatti, Mannini, Balistreri and Schito2008). In the present study, the affect of adaptation to BC and Cip was studied on haemolysin activity of Esch. coli strains of dairy background.

As evident from the literature review, generic Esch. coli isolates of food origin have hardly been explored in reference to adaption to antimicrobial agents and subsequent effect on BFP, EPA, and haemolytic activity. Such a study may provide useful information on the role of food microflora in emergence and spread of antimicrobial resistance. Moreover, food processing conditions and parameters might modulate the organism to adapt some specific phenotypes that might not be encountered in a clinical setup. Hence, the present investigation was undertaken to investigate the effect of adaptation to Cip and BC on BFP, EPA and haemolysin activity and correlation if any, in Esch. coli isolates of dairy origin.

Materials and Methods

Test Organisms, growth conditions and biofilm formation assay

Biofilm samples (slime like substance) were collected after clean–in-place regime from raw milk line (E1), pasteurizer inlet (E2), outlet (E3) and, milk tank (E4) of a small scale and commercial scale dairy handling 50 000 and 1 million litres of milk per day, respectively. The clean-in-place protocol that was being followed in both the dairies involved routine application of NaOH (1%) at 75 °C for 5 min, warm water rinse, HNO3 (0·5%) at 60 °C for 5 min and, water rinse. The weekly cleaning protocol involved use of NaOCl (200 ppm) at 60 °C for 5 min and warm water rinse. The sample swabs from each isolation point were immersed immediately in TSB and transported to the laboratory in an ice box for further analysis. Presumptively, all the isolates which, (a) fermented lactose with gas production within 48 h at 35 °C, (b) appeared as Gram-negative non-sporeforming rods and (c) showed IMViC patterns of + + −− were considered to be Esch. coli strains. These isolates were further confirmed by streaking onto eosine methylene blue agar and only colonies with typical sheen were retained. A total of 81 Esch. coli isolates was obtained and these were designated on the basis of their isolation source (I/II)-sampling point (E-1/2/3/4) and number during the process of isolation. All the isolates (n = 81) were subjected to biofilm formation assay as previously described and categorised as ‘strong’, ‘moderate’, ‘weak’ or ‘no biofilm’ formers (Pagedar et al. Reference Pagedar, Singh and Batish2010). Prior to each experiment, desired cell counts were obtained by adjusting absorbance (620 nm) to 0·12 (approx. 108 cfu/ml) and subsequent dilution and plating onto plate count agar. All the assays were carried out in triplicate and means were considered for subsequent analysis. Reagents and media were procured from HiMedia Labs, Mumbai, India unless specified otherwise.

Determination of minimum inhibitory concentrations (MIC)

From each isolation point of two sources, two each of the strongest and the weakest biofilm formers were selected for further antimicrobial resistance studies (n = 32) [(2 + 2)4 × 2=32] against Cip and BC. Susceptibility to Cip was determined in terms of MIC by macrobroth dilution method. The stock solution of antibiotic (10 000 mg/l) was prepared in sterile water, filter sterilized and aseptically diluted in tubes containing 3 ml Mueller Hinton broth to obtain a suitable dilution. The respective culture counts for the experiment (105 cfu/ml) were obtained as discussed in previous section. The Mueller Hinton broth tubes with varying antibiotic concentrations were inoculated with 105 cfu/ml of respective cultures and incubated at 37 °C for 24 h. MIC was recorded as the lowest concentration of antibiotic at which OD-620 nm of the test was equivalent to that of the uninoculated control tube. To determine the resistance against BC, inoculum was prepared as described above and added at a final concentration of 105 cfu/ml to Mueller Hinton broth containing 0–500 ppm of BC (in steps of 50). The biocide exposure was for 15 min at room temperature and then samples were neutralised by 10 times dilution in neutralising solution [0·3% lecithin, 3% Tween 80, 0·5% sodium thiosulphate, 0·1% l-histidine, 0·034% potassium dihydrogen phosphate] (Van der veen & Abee, Reference Van der Veen and Abee2010). The tubes were subsequently incubated at 37 °C for 24 h and MIC was determined against uninoculated control tube. The MIC of antibiotic Cip was tested in geometric progression from 0·25 to 1024 μg/ml for parent strains of AR category and in steps of 0·25 μg/ml for parent strains of ANR category. For adapted strains of both the categories (AR & ANR), MIC of Cip was determined in steps of 5 μg/ml. The MICs were median value of experiments performed three times in triplicate, which were repeated until a median value was obtained. On the basis of their respective MIC of Cip and BC these isolates were arbitrarily categorised into antibiotic/biocide resistant (AR/BR), and non-resistant (ANR/BNR). The AR category comprised the isolates exhibiting MIC ⩾ 4, while conventionally sensitive and intermediate isolates (having MIC ⩽ 2) were grouped together in ANR category (CLSI, 2011). For BC, the isolates exhibiting MIC ⩾ 200 ppm were characterised as resistant while other as non-resistant (Velázquez et al. Reference Velázquez, Barbini, Escudero, Estrada and de Guzmán2009). Throughout the study, Esch. coli MTCC 739110 (ATCC 10536) was used as a reference strain. Four each of AR, BR, ANR and BNR, total 16 out of 32 isolates, were randomly selected for further investigation as box and whisker plots [XL-statistics v4.5 (http://www.man.deakin.edu.au/rodneyc/XLStats.htm)] indicated no significant effect of sources and isolation point on antimicrobial resistance pattern.

Development and stability of the acquired adaptive resistance

Adaptation of AR and ANR isolates was initiated by growing them in nutrient broth containing Cip at respective sub-MICs level (first well showing growth below MIC) and then increasing concentrations of Cip in steps of 5 mg/l. Similarly, BR and BNR isolates were adapted to BC in steps of 10 ppm. The procedure was repeated every 24 h until the cultures adapted to higher concentrations of respective antimicrobials. The stability of adapted resistance was evaluated by MIC determination up to 30 d by daily subculturing in nutrient broth devoid of Cip and BC.

Estimation of Efflux pump activity and haemolysin activity at pre and post adapted stages

For EPA evaluation of the selected isolates (n = 16) at pre and post-adaptation level, EtBr was used as model systems as per method described previously (Pagedar et al. Reference Pagedar, Singh and Batish2011). Briefly, preselected isolates were grown overnight at 37 °C on tryptic soy agar (TSA) plates containing 0·5 μg/ml of EtBr (Banglore Genei, India). On irradiation of these plates on an ultra violet transilluminator, cells that accumulated EtBr fluoresced pink (negative for EPA), whereas cells with partial accumulation appeared pale pink. Cells that did not accumulate EtBr were white and considered positive for EPA. Prior to EPA quantitation, EtBr sub-MICs were determined by appropriately diluting the overnight grown isolates (108 cfu/ml) of AR, ANR, BR, & BNR categories and spread plating onto TSA (37 °C/48 h) containing gradient of EtBr (0–100 μg/ml in steps of 10 μg/ml). The lowest concentration of EtBr in TSA plate with no colonies was considered as EtBr MIC. To quantify EPA, overnight grown cultures (108 cfu/ml) were inoculated into TSB with respective sub-MIC (MIC-1) EtBr concentrations (μg/ml) at room temperature for 0·5 h. Subsequently, cells were pelleted, washed, excited at 530 nm and fluorescence emission was observed at 600 nm (Raherison et al. Reference Raherison, Gonzalez, Renaudin, Charron, Bébéar and Bébéar2002). Accumulation of EtBr was calculated using standard curve equation after subtraction of natural fluorescence of the cells.

For pre and post-adaption estimation of haemolysin activity, supernatant of preselected overnight grown cultures (108 cfu/ml) were diluted in 1:1 ratio using sterile saline and an aliquot of 100 μl was mixed with 100 μl of freshly prepared defibrinated, 3% citrated red blood cell solution in 96 well microtitre plate. The plates were incubated at 37 °C/1 h and respective absorbances were measured at 540 nm using microplate reader (ECIL, Microscan, India). The haemolysin activity (μg of haemolysin/ml) was calculated in reference to control using the standard curve equation obtained by pure haemolysin (H9395, Sigma Aldrich, Missouri, USA).

Statistical analysis

The statistical analysis (Two way ANOVA, box and whisker plots, median, arithmetic mean and sd) was performed using XL-statistics v4.5 (http://www.man.deakin.edu.au/rodneyc/XLStats.htm) ‘Significance’ expressed at the 5% level (P < 0·05) or mentioned otherwise.

Results

Biofilm formation and MIC against Ciprofloxacin and Benzalkonium Chloride

Evaluation of the selected isolates for their BFP revealed that the originally resistant (AR and BR) phenotypes were strong biofilm formers. Post-adaptation change in BFP of the resistant category was not significant; hence it was not considered for statistical analysis in terms of correlation with other traits evaluated (MIC, EPA, haemolysin and stability). On the contrary, as a result of adaptation, non-resistant categories (ANR and BNR) exhibited a significant increase in BFP (P ⩽ 0·1), which led to upgrading their categorisation status from ‘weak/moderate’ to ‘moderate/strong’ biofilm former (Table 1a & b).

Table 1. Biofilm formation, adaptive resistance, resistance stability, efflux pump and haemolytic activity of ciprofloxacin resistant (AR) and non-resistant (ANR) (1a), and benzalkonium chloride resistant (BR) and non-resistant (BNR) (1b) isolates at pre- and post-adaptive stages

Indicates the median value of three experiments

The MIC of antibiotic Cip was tested in geometric progression from 0·25 to 1024 μg/ml for parent strains of AR category and in steps of 0·25 μg/ml for parent strains of ANR category (due to very high susceptibility of this group to Cip). For adapted strains MIC of Cip was determined in steps of 5 μg/ml for both categories

EPA was determined in steps of 10 μg/ml of EtBr

The MIC of biocide BC was evaluated in steps of 50 ppm for parent strains (both categories) and in steps of 10 ppm for adapted strains (both categories)

Development and stability of the acquired adaptive resistance

In the current investigation, irrespective of initial susceptibility of Esch. coli isolates, slow growth was observed during initial passages while developing adaptive resistance to both BC and Cip. In addition to a general trend, strain specific behaviours were also observed. Two isolates I-E3-8 and II-E4-82 exhibited the same pre-adaptive MIC to Cip (8 mg/l) and BC (250 ppm), however post-adaptation resistance to Cip was greater in I-E3-8 (50 mg/lin comparison with 25 in II-E4-82) while that against BC was greater in II-E4-82 (340 ppm in comparison with 320 ppm for I-E3-8). For all the adapted isolates, the stability of developed adaptive resistances was analysed by passage in antibiotic- or biocide-free medium. From Table 1a & b, it is evident that, the extent of developed adaptive resistance was greater in ANR followed by AR, BNR and BR isolates. Regarding the stability of the adaptive resistance, the strain dependent variation resulted in wide variation and thus, no trend in the stability of adaptive resistance could be established for any particular category.

Effect of adaptive resistance on EPA and haemolysin activity

As a result of adaptation to antimicrobials, highly significant increase in EPA could be observed for the non-resistant isolates (ANR and BNR) (P = 0·005) and BR category (P < 0·05). Only AR category exhibited an insignificant post-adaptive increase in EPA (P = 0·36) which is indicative of some specific mechanism responsible for conferring antibiotic resistance rather than a broad spectrum mode as in biocide resistance. The above mentioned observation was reinforced when EPA and adaptive resistances of the isolates were compared. During adaptation to Cip, the moderate percentage increase in EPA (range of 33–67% in ANR; 16–50% in AR) and yet, the remarkable adaptive resistance (range of 900–4900% in ANR; 212–525% in AR) again indicates that EPA certainly could not account as sole mechanism for the adaptive resistance. Interestingly, adaptation to BC presented altogether a different scenario. The BR and BNR isolates exhibited almost similar percentage increase in EPA (range of 50–85% in BR; 57–80% in BNR) and a marginal difference in developed adaptive resistance (28–35% in BR; 40–160% in BNR). Overall in resistant categories, post adaptive increase in EPA of AR was significantly lower than that of BR (P < 0·05), still AR developed greater adaptive resistance than BR (P < 0·02).

The percentage increase in EPA was compared statistically with the percentage increase in adaptive resistance of ANR and BR only (P < 0·05). In reference to haemolysin activity, strain specific variation was observed and therefore this trait was not considered for statistical analysis.

Discussion

Emergence of antimicrobial resistance is a global problem and findings of the current study suggest a role for the food chain in it. Strong BFP of all the parent isolates of resistant phenotypes (AR & BR) indicates that there may be a direct relationship between BFP and antimicrobial resistance. These findings are in line with previous reports which have established that biofilm formation leads to increased tolerance to antimicrobial agents (Drenkard & Ausubel Reference Drenkard and Ausubel2002; Pagedar et al. Reference Pagedar, Singh and Batish2011). Post-adaptation, only a marginal increase in the BFP status of resistant phenotypes (AR & BR) was observed. However, due to paucity of the published literature on adaptation of resistant phenotypes, we could not discuss these findings. Our findings regarding substantially improved BFP of non-resistant category after adaptation can be corroborated with similar observations in earlier studies with coagulase positive staphylococci (Qu et al. Reference Qu, Daley, Istivan, Garland and Deighton2010) and Ps. aeruginosa (Drenkard & Ausubel Reference Drenkard and Ausubel2002) of clinical origin.

Apparently, exposure to antimicrobial agents induces stress response in microorganisms. In Esch. coli a master regulator RpoS is known to regulate stress responses (Hengge, Reference Hengge2009). It has been reported to up-regulate the expression of csgD operon responsible for curli production, which is an important factor in biofilm formation and surface adhesion (Gualdi et al. Reference Gualdi, Tagliabue and Landini2007). In the present study, substantially enhanced biofilm production by non-resistant isolates (post-adaptation), may be due to the over expression of curli gene through RpoS regulation, in response to antimicrobial stress. This speculation seems to be feasible as originally resistant isolates (AR & BR) probably experienced lesser stress during adaptation, and hence displayed only marginal increase in biofilm formation.

These findings imply that in a food industry, non judicious usage of antimicrobial compounds may facilitate transformation of non-resistant isolates to resistant ones, thus imposing a food safety threat. Our assumptions draw support from a recent study which concluded that biofilms of BC adapted Esch. coli become thicker on re-exposure to the biocide (Machado et al. Reference Machado, Lopes, Sousa and Pereira2012). Contrary to our observations, the effect of BC adaptation on BFP of Listeria monocytogenes has been reported to be insignificant (Romanova et al. Reference Romanova, Gawande, Brovko and Griffiths2007).

Post-adaptation, a remarkable resistance developed in all the isolates irrespective of initial resistant phenotypes. Various mechanisms (specific and non-specific) are involved in conferring antimicrobial resistances to microorganisms. Intrinsic resistance against fluoroquinolone like Cip is due to several specific mechanisms (Arias et al. Reference Arias, Seral, Gude and Castillo2010), whereas only few non-specific mechanisms like modification of membrane composition, and EPA are responsible for conferring biocide (BC) resistance (Kendall & Sperandio, Reference Kendall and Sperandio2007). Interestingly, our findings depict that although the post-adaptive increments in EPA of BR isolates were larger than those of AR, the AR exhibited greater adaptive resistance against Cip than BR against BC. Probably simultaneous action of multiple mechanisms along with EPA contributed towards notable adaptive resistance against Cip in AR isolates. On the other hand, intrinsic EPA seems to be the only predominant mechanism conferring resistance against BC in BR isolates. We tried to understand this unexpected behaviour of BR isolates during adaptation, on the basis of findings of a previous study by Ma et al. (Reference Ma, Alberti, Lynch, Nikaido and Hearst1996). They observed that during adaptation and/or general stress conditions, efflux pump encoded by acrAB was up-regulated by only four times whereas its repressor (acrR) by 10 times in Esch. coli. In such a scenario it seems possible that even an increase in EPA may not be reflected in phenotypic resistance pattern as observed in the current study. In this study, a significant increase in EPA observed for non-resistant phenotypes (ANR & BNR), implies a pivotal role of EPA in conferring adaptive resistance to the isolates of this category. Moreover, beyond adaptive resistance, EPA has also been shown to confer cross resistance against Cip and BC in Ps. aeruginosa of dairy origin (Pagedar et al. Reference Pagedar, Singh and Batish2011).

Previous studies have shown that during adaptation, the expression of acrAB was up-regulated but only in the initial phase of adaptation whereas the expression of stress response genes continued to increase throughout the adaptation and render the strains resistant against oxidising agents (Bohnert et al. Reference Bohnert, Schuster, Fahnrich, Trittler and Kern2007; Bore et al. Reference Bore, Hébraud, Chafsey, Chambon, Skjaeret, Moen, Møretrø, Langsrud, Rudi and Langsrud2007). Such findings further imply that the residuals or sub-lethal concentrations of antimicrobials (e.g. BC and Cip) in industries would aid the microorganisms to develop resistance against not only the strong detergents like BC used in dairy plant cleaning regime but routinely used oxidising agents also. Further, when such adaptively biocide resistant strains are implicated in foodborne illness, the therapeutic treatment becomes difficult as BC adapted strains have previously been reported to develop cross resistance to fluoroquinolones and other clinically relevant antibiotic (Langsrud et al. Reference Langsrud, Sundheim and Holck2004; Bore et al. Reference Bore, Hébraud, Chafsey, Chambon, Skjaeret, Moen, Møretrø, Langsrud, Rudi and Langsrud2007). Our findings regarding presence of antibiotic resistant isolates signifies that antimicrobial resistance mechanisms adopted by microorganisms in response to stresses imposed by food chain conditions seems to be conferring resistance against clinically relevant antimicrobial compounds. Surprisingly, we could not come across any report wherein EPA and antimicrobial resistance pattern of dairy or food origin Esch. coli stains were studied. However, any such correlation between BFP and antimicrobial resistance was ruled out in clinical origin Esch. coli (Marhova et al. Reference Marhova, Kostadinova and Stoitsova2010). Strain specific behaviour and lack of a correlation with other factors studied signifies that adaptation has a limited and/or strain specific effect on the haemolysin production. A number other factors such as growth conditions and genetic makeup of the organism has been shown to play important role in determining and regulation of haemolysin production (Tiwari et al. Reference Tiwari, Deol, Rishi and Grewal2002).

In conclusion, the present study showed development of higher and more stable adaptive resistance against BC and Cip by Esch. coli isolates exposed to sub-lethal concentrations of antimicrobial agents. Some adaptive strains also exhibited enhanced BFP, EPA and virulence potential (haemolysin activity). The findings emphasize that antimicrobials should be used at specified doses in appropriate manner to avoid emergence of resistance which may subsequently lead to increased virulence. A significant threat is imposed when such virulence factors or resistances are horizontally transferred to high risk pathogens.

Ankita Pagedar duly acknowledges the Director, National Dairy Research Institute, Karnal, India, for the lab facilities and The Indian Council of Agricultural Research, India for the financial assistance in the form of senior research fellowship. The authors are thankful to Mr Snehal Ingale, Asst. Prof., ARIBAS, New V.V. Nagar, Gujarat, India, for his expert advice regarding statistical analysis.

References

Arias, A, Seral, C, Gude, MJ & Castillo, FJ 2010 Molecular mechanisms of quinolone resistance in clinical isolates of Aeromonas caviae and Aeromonas veronii bv. Sobria. International Microbiology 13 135141Google Scholar
Bohnert, JA, Schuster, S, Fahnrich, E, Trittler, R & Kern, WV 2007 Altered spectrum of multidrug resistance associated with a single point mutation in the Escherichia coli RND-type MDR efflux pump YhiV (MdtF). Journal of Antimicrobial Chemotherapy 59 12161222Google Scholar
Bore, E, Hébraud, M, Chafsey, I, Chambon, C, Skjaeret, C, Moen, B, Møretrø, T, Langsrud, Ø, Rudi, K & Langsrud, S 2007 Adapted tolerance to benzalkonium chloride in Escherichia coli K-12 studied by transcriptome and proteome analyses. Microbiology 153 935946Google Scholar
Brown, MRW & Gilbert, P 1993 Sensitivity of biofilms to antimicrobial agents. Journal of Applied Bacteriology 74 87S97SGoogle Scholar
Clinical and Lab Standards Institute (CLSI) 2011 Methods for Dilution Antimicrobial Susceptibility Tests for Bacteria That Grow Aerobically; Approved Standard—Eighth Edition. M07-A8. Performance Standards for Antimicrobial Susceptibility Testing; Twenty-First Informational Supplement M100-S21 31(1). Clinical and Lab Standards Institute, Wayne, Pennsylvania, USAGoogle Scholar
Drenkard, E & Ausubel, FM 2002 Pseudomonas biofilm formation and antibiotic resistance are linked to phenotypic variation. Nature 416 740743Google Scholar
Gualdi, L, Tagliabue, L & Landini, P 2007 Biofilm formation-gene expression relay system in Escherichia coli: modulation of sigmaS-dependent gene expression by the CsgD regulatory protein via sigmaS protein stabilization. Journal of Bacteriology 189 80348043Google Scholar
Hengge, R 2009 Proteolysis of σS (RpoS) and the general stress response in Escherichia coli. Research in Microbiology 160 667676CrossRefGoogle ScholarPubMed
Horcajada, JP, Soto, S, Gajewski, A, Smithson, A, Jimenez de Anta, MT, Mensa, J, Vila, J & Johnson, JR 2005 Quinolone resistant uropathogenic Escherichia coli strains from phylogenetic group B2 have fewer virulence factors than their susceptible counterparts. Journal of Clinical Microbiology 43 29622964Google Scholar
Imuta, N, Nishi, J, Tokuda, K, Fujiyama, R, Manago, K, Iwashita, M, Sarantuya, J & Kawano, Y 2008 The Escherichia coli efflux pump TolC promotes aggregation of enteroaggregative Esch. coli 042. Infection and Immunity 76 12471256Google Scholar
Johnson, JR, Kuskowski, MA, Gajewski, A, Soto, S, Horcajada, JP, Jimenez de Anta, MT & Vila, J 2005 Extended virulence genotypes and phyelonephritis or prostatitis. Journal of Infectious Disease 191 4650Google Scholar
Kendall, MM & Sperandio, V 2007 Quorum sensing by enteric pathogens. Current Opinion Gastroenterology 23 1015Google Scholar
Langsrud, S, Sundheim, G & Holck, AL 2004 Cross-resistance to antibiotics of Escherichia coli adapted to benzalkonium chloride or exposed to stress-inducers. Journal of Applied Microbiology 96 201208Google Scholar
Ma, D, Alberti, M, Lynch, C, Nikaido, H & Hearst, JE 1996 The local repressor AcrR plays a modulating role in the regulation of acrAB genes of Escherichia coli by global stress signals. Molecular Microbiology 19 101112Google Scholar
Machado, I, Lopes, SP, Sousa, AM & Pereira, MO 2012 Adaptive response of single and binary Pseudomonas aeruginosa and Escherichia coli biofilms to benzalkonium chloride. Journal of Basic Microbiology 52 4352Google Scholar
Marhova, M, Kostadinova, S & Stoitsova, S 2010 Biofilm-forming capabilities of urinary Escherichia coli isolates. Biotechnology 24 589593Google Scholar
Naves, P, del Prado, G, Huelves, L, Gracia, M, Ruiz, V, Blanco, J, Dahbi, G, Blanco, M, del Carmen Ponte, M & Soriano, F 2008 Correlation between virulence factors and in vitro biofilm formation by Escherichia coli strains. Microbial Pathogenesis 45 8691Google Scholar
Ntsama-Essomba, C, Bouttier, S, Ramaldes, M, Dubois-Brissonnet, F & Fourniat, J 1997 Resistance of Escherichia coli growing as biofilms to disinfectants. Veterinary Research 28 353363Google Scholar
Pagedar, A, Singh, J & Batish, VK 2010 Surface hydrophobicity, nutritional contents affect Staphylococcus aureus biofilms and temperature influences its survival in preformed biofilms. Journal of Basic Microbiology 50(S1) 98106CrossRefGoogle ScholarPubMed
Pagedar, A, Singh, J & Batish, VK 2011 Efflux mediated adaptive and cross resistance to ciprofloxacin and benzalkonium chloride in Pseudomonas aeruginosa of dairy origin. Journal of Basic Microbiology 51 289295Google Scholar
Piatti, G, Mannini, A, Balistreri, M & Schito, AM 2008 Virulence factors in urinary Escherichia coli strains: phylogenetic background and quinolone and fluoroquinolone resistance. Journal of Clinical Microbiology 46 480487Google Scholar
Qu, Y, Daley, AJ, Istivan, TS, Garland, SM & Deighton, MA 2010 Antibiotic susceptibility of coagulase-negative staphylococci isolated from very low birth weight babies: comprehensive comparisons of bacteria at different stages of biofilm formation. Annals of Clinical Microbiology and Antimicrobials 27 916Google Scholar
Raherison, S, Gonzalez, P, Renaudin, H, Charron, A, Bébéar, C & Bébéar, CM 2002 Evidence of active efflux in resistance to ciprofloxacin and to ethidium bromide by Mycoplasma hominis. Antimicrobial Agents and Chemotherapy 46 672679Google Scholar
Rijavec, M, Muller-Premru, M, Zakotnik, B & Zgur-Bertok, D 2008 Virulence factors and biofilm production among Escherichia coli strains causing bacteraemia of urinary tract origin. Journal of Medical Microbiology 57 13291334Google Scholar
Romanova, NA, Gawande, PV, Brovko, LY & Griffiths, MW 2007 Rapid methods to assess sanitizing efficacy of benzalkonium chloride to Listeria monocytogenes biofilms. Journal of Microbiological Methods 71 231237Google Scholar
Skals, M, Jorgensen, NR, Leipziger, J & Praetorius, HA 2009 α-Haemolysin from Escherichia coli uses endogenous amplification through P2X receptor activation to induce hemolysis. Proceedings of National Academy Science, USA 106 40304035Google Scholar
Soto, SM, Smithson, A, Martinez, JA, Horcajada, JP, Mensa, J & Vila, J 2007 Biofilm formation in uropathogenic Escherichia coli strains: Relationship with prostatitis, urovirulence factors and antimicrobial resistance. Journal of Urology 177 365368Google Scholar
Tiwari, RP, Deol, K, Rishi, P & Grewal, JS 2002 Factors affecting haemolysin production and Congo red binding in Salmonella enterica serovar Typhimurium DT 98. Journal of Medical Microbiology 51 503509Google Scholar
van der Horst, MA, Schuurmans, JM, Smid, MC, Koenders, BB & Ter Kuile, BH 2011 De novo acquisition of resistance to three antibiotics by Escherichia coli. Microbial Drug Resistance 17 141147Google Scholar
Van der Veen, S & Abee, T 2010 Importance of SigB for Listeria monocytogenes static and continuous-flow biofilm formation and disinfectant resistance. Applied Environmental Microbiology 76 7854.Google Scholar
Velázquez, LC, Barbini, NB, Escudero, ME, Estrada, CL & de Guzmán, AMS 2009 Evaluation of chlorine, benzalkonium chloride and lactic acid as sanitizers for reducing Escherichia coli O157:H7 and Yersinia enterocolitica on fresh vegetables. Food Control 20 262268Google Scholar
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Table 1. Biofilm formation, adaptive resistance, resistance stability, efflux pump and haemolytic activity of ciprofloxacin resistant (AR) and non-resistant (ANR) (1a), and benzalkonium chloride resistant (BR) and non-resistant (BNR) (1b) isolates at pre- and post-adaptive stages