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Revista do Instituto de Medicina Tropical de São Paulo

versión On-line ISSN 1678-9946

Rev. Inst. Med. trop. S. Paulo vol.60  São Paulo  2018  Epub 23-Abr-2018

http://dx.doi.org/10.1590/s1678-9946201860018 

Original Article

Evaluation of E. coli inhibition by plain and polymer-coated silver nanoparticles

D'Andrea Ashmore1 

Atul Chaudhari2 

Brandi Barlow1 

Brett Barlow1 

Talia Harper1 

Komal Vig1 

Michael Miller3 

Shree Singh1 

Edward Nelson4 

Shreekumar Pillai1 

1Alabama State University, Center for Nanobiotechnology Research, Montgomery, Alabama, USA

2USDA, ARS, NEA, BARC, ABBL, Beltsville, Maryland, USA

3Auburn University, Harrison School of Pharmacy, AU Research Instrumentation Facility, Auburn, Alabama, USA

4Nanosurf, Inc., Woburn, Massachusetts, USA

ABSTRACT

Escherichia coli causes various ailments such as septicemia, enteritis, foodborne illnesses, and urinary tract infections which are of concern in the public health field due to antibiotic resistance. Silver nanoparticles (AgNP) are known for their biocompatibility and antibacterial activity, and may prove to be an alternative method of treatment, especially as wound dressings. In this study, we compared the antibacterial efficacy of two polymer-coated silver nanoparticles either containing 10% Ag (Ag 10% + Polymer), or 99% Ag (AgPVP) in relation to plain uncoated silver nanoparticles (AgNP). Atomic force microscopy was used to characterize the nanoparticles, and their antibacterial efficacy was compared by the minimum inhibitory concentration (MIC) and bacterial growth curve assays, followed by molecular studies using scanning electron microscopy (SEM) and (qRT- PCR). AgNP inhibited the growth of E. coli only at 0.621 mg/mL, which was double the concentration required for both coated nanoparticles (0.312 mg/mL). Similarly, bacterial growth was impeded as early as 8 h at 0.156 mg/mL of both coated nanoparticles as compared to 0.312 mg/mL for plain AgNP. SEM data showed that nanoparticles damaged the cell membrane, resulting in bacterial cell lysis, expulsion of cellular contents, and complete disintegration of some cells. The expression of genes associated with the TCA cycle (aceF and frdB) and amino acid metabolism (gadB, metL, argC) were substantially downregulated in E. coli treated with nanoparticles. The reduction in the silver ion (Ag+) concentration of polymer-coated AgNP did not affect their antibacterial efficacy against E. coli.

KEYWORDS: Escherichia coli; Polymer coated; Nanosilver

INTRODUCTION

Microorganisms possess several mechanisms of resistance that interfere with the effectiveness of antibiotics. Indiscriminate use of antibiotics for the treatment of bacterial infections has caused resistant strains of broad spectrum gram negative (-) bacteria such as E. coli which are difficult to treat1. Nanoparticles have been under scrutiny due to their anti-inflammatory, antibacterial, and antimicrobial properties. Nanoparticles range in size from 1-100 nm and function at a molecular and cellular level. Electronic and structural properties of nanoparticles significantly differ from the respective bulk particles2,3. There are important components in the utilization of nanoparticles that include cellular uptake, adsorption, and metal ion release. Once the nanoparticles are released into the cell, the nanoparticles are engulfed through a process called endocytosis. The release can sometimes cause a severe cellular side effect called oxidative stress4.

Silver nanoparticles (AgNP) have been of interest because the agent possesses many of the properties that are common to nanoparticles1,4,5. Silver nanoparticles have shown to be promising in wound healing, implantations, wound disinfection, sensing, catalysis, the coating of other surfaces, etc.610. The small size of AgNP is representative of a massive surface area, which increases the interaction of nanoparticles and the microorganism1,4. The nanoparticles are able to enter the cell membrane in an easier way due to a greater surface area with respect to volume ratio of smaller nanoparticles. The mechanism by which silver nanoparticles act is not fully understood. Some studies indicate that the AgNP may cause antibacterial cell death due to silver ions that prevent DNA replication or inactivating cellular proteins. There are also interactions with the cell membrane in which the structure is damaged resulting in cell death3,11. Other theories suggest that silver nanoparticles cause cell death through cell lysis and thiol reactions that inactivate enzymes3,12. Another possible mechanism may be due to oxidative stress, inflammation, and DNA damage13. Toxicity has been a subject of concern in regard to application of silver nanoparticles within the human body7,14. The smaller nanoparticles have the strongest antimicrobial activity; however, they are the most cytotoxic ones. Silver nanoparticles are typically coupled with other agents to improve efficacy and reduce cytotoxicity1.

Silver nanoparticles have been modified by coating with polymers such as polyvinylpyrrolidone (PVP), polyethylene glycol (PEG), polyvinyl alcohol (PVA), citrate and sodium dodecyl sulfate (SDS) acting as capping and stabilizing agents to improve antibacterial activity11,1520. The coating of a particular surface and its effects are based on the size and surface area12. The protective coating created by polymers such as PVP, PEG, PVA, citrate, and SDS promotes the interaction of the AgNP with the bacterial cells12. Although polymer coating does not directly increase bactericidal activity, it stabilizes the silver particles so that they do not autoaggregate to a larger biomass which hinders biological activity21. There are several studies that show the antibacterial effectiveness of AgNP with capping agents where the MIC was lower. For example, a study was conducted that showed AgNP stabilized with PVP and PVA showed lower MIC values than the original AgNP22. In yet another study, the effectiveness of PVP capped AgNP was more obvious than citrate or SDS capped AgNP19,23. Many studies have shown the antibacterial effectiveness of AgNP capped with several stabilizing agents and a silver ion (Ag+) concentration of 99.99%. However, there are currently no studies that investigate the antibacterial activity of AgNP with a silver ion (Ag+) concentration of 10% and coated with a polymer.

In the current study, we used three different nanoparticles that included Ag 99% +PVP (AgPVP), Ag 10% + Polymer, and plain uncoated AgNP in order to determine the antibacterial effectiveness of reduced silver ion (Ag+) concentrations in coated silver nanoparticles relative to plain AgNP against E. coli. We characterized the 3 nanoparticles by Atomic Force microscopy. Then, we assessed the antibacterial activity of all 3 AgNPs by using the MIC and growth curve assays. In addition, in order to understand the probable mechanisms of action of AgPVP, Ag 10% + Polymer, and AgNP, we performed electron microscopy and molecular studies using quantitative reverse transcriptase polymerase chain reaction (qRT-PCR).

MATERIAL AND METHODS

Description and sources of AgPVP, Ag 10% + Polymer, and AgNP

Ag 10% + Polymer were purchased from Nanostructured & Amorphous Materials, Inc. (Houston, TX 77084, USA). The Ag 10 % + Polymer contained (90% w) Nanopowder, 25 Particle size: <= 15 nm, Composition: 10% Silver + 90% synthetic Polymer, Stock #7023Hz, Lot #7023-123109. AgPVP and AgNP were purchased from US Research Nanomaterials, Inc. (Houston, TX, USA). The AgPVP contained 99.99% Ag, (20 nm w/~ 0.2 PVP, Stock #US1037, CAS #7440-22-4=. The AgNP contained Ag 99.99%, (20 nm, metal basis), Stock #US 1038, CAS #7440-22-4

Atomic force microscopy

Nanoparticle colloidal solutions were deposited on freshly cleaved mica and left to air dry. AFM measurements were performed in air using a Nanosurf Flex-Axiom (Nanosurf AG, Liestal, Switzerland) in dynamic mode using a commercially available ACST-A cantilever (AppNano, Mountain View, CA). After acquisition, all AFM images were line-flattened. Nanoparticle sizes were measured using the software provided by the manufacturer.

Bactericidal experiments

Escherichia coli clinical isolate Serotype 6 (ATCC® 25922) was purchased from American Type Culture Collection (ATCC, VA USA) and used for the bacterial experiments. The bacteria were grown at 37 °C in Luria-Bertoni (LB) broth (Difco, Sparks, MD, USA) overnight in an orbital shaker and the optical density (OD) was measured at 600 nm. The antibacterial activity of AgPVP, Ag 10% + Polymer, and AgNP were determined using the minimum inhibitory concentration (MIC) assay. An in-depth evaluation of the antibacterial activity of Escherichia coli was done utilizing the growth curve assay. Morphological changes in Escherichia coli treated with AgPVP, Ag 10% + Polymer, and AgNP were assessed by scanning electron microscopy (SEM). The evaluation of genes expression was performed using the quantitative real time reverse transcriptase polymerase chain reaction (qRT-PCR).

Determination of MIC

The MIC values of AgPVP, Ag 10% + Polymer, and AgNP were examined in quadruple wells of 96-well microtiter plates using the broth microdilution assay24. Escherichia coli cultures were serially diluted to a log phase of 1 x 106 CFU/mL and then exposed to two-fold decreasing concentrations of AgPVP, Ag 10% + Polymer, and AgNP starting at 1.25 mg/mL until 0.039 mg/mL. The serial dilutions were made in LB broth used as a diluent. All the plates consisted of 6 dilutions of the AgPVP, Ag 10% + Polymer, and AgNP dispersion solutions, 1 negative control, (no AgPVP, Ag 10% + Polymer, AgNP or bacterial culture), and 1 positive control (bacterial culture without AgPVP, Ag 10% + Polymer, and AgNP). The 96-well plates were sealed with a parafilm cover that offered some ventilation and incubated at 37 °C for 24 h.

The MIC was determined after incubation by the turbidity of the culture media in the wells. The concentration of the first well without turbidity was considered as the minimum inhibitory concentration. The inhibition of bacterial growth was measured by reading the Optical Density (OD) of the cultures at an absorbance at 600 nm with a TECAN Sunrise™ enzyme-linked immunoabsorbent assay (ELISA) plate reader (Tecan US, Inc. Morrisville, NC, USA). All of the experiments were repeated at least three times.

Quantitative growth analysis of Escherichia coli

Escherichia coli were quantified in sequence at times point 0, 4, 8, 16, and 24 h after exposure to AgPVP, Ag 10% + Polymer, and AgNP. Twenty milliliters of bacterial culture containing 1 x 105 CFU/mL were exposed to 1.25, 0.621, 0.312, or 0.156 mg/mL of AgPVP, Ag 10% + Polymer, and AgNP which were based on the MIC values of AgPVP, Ag 10% + Polymer, and AgNP. The bacterial cultures were incubated at 37 °C with shaking at 300 rpm and the optical densities at 600 nm (OD 600) were obtained at 0, 4, 8, 16, and 24 h. Growth curves were generated by plotting OD vs. time points in increasing time increments using a graphing software (Sigma Plot, Systat Software, San Jose, CA).

Electron microscopy

Scanning electron microscopy (SEM, Zeiss EVO 50, Carl Zeiss Meditech, Oberkochen, Germany) was used to observe the changes of Escherichia coli treated with AgPVP, Ag 10% + Polymer, and AgNP. Non-treated cells were used as a control. Bacterial cells (1 x 105 CFU/mL) were treated with 0.312 mg/mL of AgNP or 0.156 mg/mL of AgPVP or Ag 10% + Polymer separately for 16 h in an orbital shaker (180 rpm) at 37 °C. After treatment, the bacterial cells were harvested by centrifugation (14,000 x g for 15 min.), washed in PBS, fixed in a mixture of 2.5% glutaraldehyde plus 1% formaldehyde for 24 h, followed by further fixation in 1% aqueous osmium tetroxide for 1 h. The pellets were then subjected to dehydration in various grades of ethanol (30, 50, 70, 80, 90, 95 and 100%). After treatment with 100% ethanol, 5 μL of each sample were placed on an SEM stub, air dried, and sputter coated with a gold-palladium alloy for SEM analysis (Zeiss EVO 50, Carl Zeiss Meditec, Oberkochen, Germany).

Molecular studies using qRT-PCR

The mRNA expression levels of E. coli genes associated with the citric acid (TCA) Cycle, amino acid metabolism, virulence, DNA repair and transcription were evaluated using qRT-PCR25,26. The primers used to amplify each gene and their origins are indicated in Table 1 2740. Escherichia coli (1 x 105 CFU/mL) were treated with AgPVP, AgNP, and Ag 10% + Polymer and incubated in an orbital shaker at 37 °C, followed by complete RNA extraction using Ambion® RNA extraction kits (Thermo Fischer Scientific Inc., USA). The RNA was quantified by the Nanovue Plus spectrophotometer (GE Healthcare Life Sciences, Pittsburg, PA) at 260 nm/280 nm and cDNA synthesis was performed in a 40 μL reaction volume using the Applied Biosystems High Capacity cDNA Reverse transcriptase Kit (Life Technologies, Grand Island, NY). The expression of various genes such as those associated with the TCA Cycle (acef, frdB), amino acid metabolism (argC, metL, gadB), virulence (fliC, msbB), and DNA repair and transcription (mfD) were quantified by qRT-PCR using the SYBR® Select Mastermix (Life Technologies, Grand Island, NY) according to the manufacturer's instructions. DNA samples were quantified and amplified in the Applied Biosystems® ViiA 7 real-time PCR system (Life Technologies). The PCR process consisted of an initial denaturation step at 95 °C for 2 min, followed by 40 cycles of 95 °C for 5 s, 56 °C for 25 s and 72 °C for 30 s. The amplification efficacy of each primer set in relation to the endogenous control gene (16sRNA) was between 95-98% (data not shown). Data generated from three independent experiments were used to determine the relative gene expression compared to non-treated samples by the 2 – ΔΔCt method25,26.

Table 1 Primers used 

Gene Forward 5′-3′ Reverse 5′-3′ Function
aceF CAGATGCCTCGCTTCAATAGT CAGCTCGATGATGCCTTTCT TCA Cycle2730
frdB CACGGTAAGAAGGAGCGTATG TCTACTTTGCCCTGCTGAATG TCA Cycle3133
metL CGACAGCGGCGATACTATTT GATCCACCAGCTCGGTAAAC Amino Acid Metabolism30
gadB CACGGTAAGAAGGAGCGTATG TCTACTTTGCCCTGCTGAATG Amino Acid Metabolism30,34
argC CCTGGCAACCAGACATAAGA CATATGCGGATGGCGATTTAC Amino Acid Metabolism30,35
fliC ACAGCCTCTCGCTGATCACTCAA GCGCTGTTAATACGCAAGCCAGAA Virulence30,36,37
msbB ATCGCTTTAACGCCGCCAAAGTTC TACGTTCTGGAAAGCAGAGCGACA Virulence30,38
mfD TCAGGAAGCTGGAAGGTAATG GGACCATCAAGGCGGTAAT DNA Repair and Transcription30,39,40

Statistical analyses

Analyzed data were expressed as the mean ± standard deviation (SD) performed using the GraphPad Prism Version 4 software (GraphPad Software, Inc., La Jolla, CA). The statistical differences for the growth curve assays were determined by using two-way ANOVA. The fold change expression of genes was analyzed by the Student's t-test. The differences were considered to be statistically significant when the P-values were < 0.05 or highly significant at P < 0.01.

RESULTS

Atomic Force Microscopy

AFM analysis of AgPVP, Ag 10% + Polymer, and AgNP is shown in Figure 1. The average radius of the Ag10% + polymer particles ranged from 23 to 27 nm, whereas for the AgPVP, it ranged from 30 to 33 nm and, for the AgNP, it ranged from 30 to 42 nm. Overall, it appeared that the polymer-coated nanoparticles (Figure 1B and C) were more spherical and uniformly dispersed, whereas the AgNP were irregular in shape and varied more in their size (Figure 1A). The polymer coating was more apparent on the Ag10% + polymer samples (Figure 1C).

Figure 1 Atomic force spectroscopy analysis Ag NP (A), AgPVP (B), Ag 10% + polymer (C) 

Antibacterial activity of AgPVP, Ag 10% + Polymer and AgNP

We tested the antibacterial activity of AgPVP, Ag 10% + Polymer, and AgNP. The MIC values for AgPVP, Ag 10% + Polymer, and AgNP were between 0.312 mg/mL and 0.625 mg/mL for E. coli (Table 2). The growth curve assay of E. coli exposed to varying concentrations of AgNP exhibited inhibition in a time and concentration dependent manner. The concentration in which the inhibition was noticeable was at 0.312 mg/mL (Figure 2A). In contrast, E. coli bacterial cells treated with Ag 10% + Polymer and AgPVP demonstrated significant inhibition at a lower concentration of .156 mg/mL (Figure 2B and 2C). The comparison is exhibited by the reduction of bacterial numbers and growth as time progressed.

Table 2 Minimum inhibitory concentration (MIC) 

Bacterium Nanoparticle MIC (mg/mL) MBC (mg/mL)
AgNP 0.62-0.31 0.62
E. coli AgPVP 0.31-0.15 0.31
Ag 10% +polymer 0.31-0.15 0.31

Figure 2 Bacterial growth curve assay and quantitative analysis of E. coli exposed to various concentrations of AgNP, AgPVP, Ag 10% + Polymer. A) Bacterial growth curve of E. coli exposed to AgNP using optical density measurements; B) Bacterial growth curve exposed to AgPVP using optical density measurements; C) Bacterial growth curve exposed to Ag 10% + Polymer using optical density measurements. Bacteria were grown in LB broth containing various concentrations of AgNP, AgPVP, and Ag 10% + Polymer and all the cultures were incubated at 37°C with shaking at 180 rpm and the optical density measurements at 600 nm (OD600) and CFU/mL counts were done at 0, 4, 8, 16, 24 h. The results are means of three experiments with p ≤ 0.05 indicating significant differences, or p = 0.01 indicating highly significant differences. Error bars represent standard deviations determined from at least 3 duplicates 

EM analysis of Escherichia coli exposed to AgPVP, Ag 10% + Polymer and AgNP

The SEM images of healthy and treated bacterial cells are shown in Figures 3, 4 and 5. The SEM evaluation indicated that treatment with AgPVP induced a morphological change of E. coli (Figure 3C and D). EM data revealed that there was a disruption of the outer cell membrane by AgNP, and cell lysis of E. coli seen with bacterial cells treated with AgPVP (Figure 3C and D), AgNP (Figure 4C and D) and Ag 10% + Polymer (Figure 5C and D). The bacterial cells treated with Ag 10% + Polymer showed dramatic cell lysis with extensive cellular debris (Figure 5C and D).

Figure 3 Evaluation of morphological changes in bacteria upon their interaction with AgPVP. A) Untreated bacterial cells at 15 K magnification; B) Untreated bacterial cells at 25 K magnification; C) Bacterial cells treated with AgPVP at 15 K magnification; D) Bacterial cells treated with AgPVP at 25 K magnification. 

Figure 4 Evaluation of morphological changes in bacteria upon their interaction with AgNP. A) Untreated bacterial cells at 15 K magnification; B) Untreated bacterial cells at 25 K magnification; C) Bacterial cells treated with AgNP at 15 K magnification; D) Bacterial cells treated with AgNP at 25 K magnification. 

Figure 5 Evaluation of morphological changes in bacteria upon their interaction with Ag 10 % + Polymer. A) Untreated bacterial cells at 15 K magnification; B) Untreated bacterial cells at 25 K magnification; C) Bacterial cells treated with Ag 10% + Polymer at 15 K magnification; D) Bacterial cells treated with Ag 10% + Polymer at 25 K magnification. 

Molecular studies of Escherichia coli exposed to AgPVP, Ag 10% + Polymer and AgNP

Gene expression associated with amino acid metabolism, TCA Cycle, virulence, DNA replication and repair were investigated to explore the antibacterial activity of AgPVP, Ag 10% + Polymer, and AgNP. Bacterial cells treated with AgNP showed a significant downregulation of the genes associated with the TCA cycle (aceF, gadB) and amino acid metabolism (metL, frdB, and argC) (Figure 6). There was also substantial upregulation of a gene associated with virulence (fliC and msbB). AgPVP treated bacteria cells similarly showed significant downregulation of genes related to the TCA cycle (aceF and gadB) and amino acid metabolism (metL, frdB and argC) (Figure 5). AgPVP treated bacteria had substantial upregulation of the virulence gene (msbB), as well as a gene associated with DNA repair and transcription (mfD) (Figure 6). Similar changes were seen in cells treated with Ag 10% + Polymer with downregulation of the TCA cycle (aceF and gadB) and amino acid metabolism (metL, frdB, and argC) (Figure 6). However, the upregulation of virulence (msbB) and DNA repair and transcription (mfD) was considerable in comparison to bacterial cells treated with AgNP and AgPVP (Figure 6).

Figure 6 Gene expression studies in E. coli exposed to AgNP, AgPVP, Ag 10% + Polymer. A) represents gene expression of aceF, gadB, metL, frdB, argC, fliC, msbB, and mfD upon exposure to AgNP; B) represents gene expression of aceF, gadB, metL, frdB, argC, fliC, msbB, and mfD upon exposure to AgPVP, and Ag 10% + Polymer; C) represents gene expression of aceF, gadB, metL, frdB, argC, fliC, msbB, and mfD upon exposure to Ag 10% + Polymer. All values were expressed as fold change expressions compared to non-treated bacteria. Error bars represent standard deviations of the results determined with at least 3 biological replicates. 

DISCUSSION

The usage of AgNP has gained popularity, however, the known cytotoxicity to human cells has warranted some hesitation in the use of AgNP as an alternative therapy1,2,26,41,42. However, some studies have shown that several strains of E. coli isolated from environmental samples such as horse dung, were highly susceptible to AgNP43.

The results of our study showed that the polymer coating of AgNP does not reduce their antibacterial activity against E. coli. More importantly, the reduction in the concentration of silver ions (Ag+) in the polymer functionalized (Ag 10% + polymer) did not reduce the antibacterial efficacy. The findings reported here are in alignment with previous studies regarding the antibacterial activity of functionalized and coated AgNP which indicated an enhanced level of antibacterial activity and reduction in cytotoxicity13,4448. There have been very few findings that are contrary to our research regarding the lack of antibacterial activity of capped or functionalized AgNPs. Jain et al.48 have shown that the removal of protein capping from AgNPs improved their antibacterial activity. Membrane damage and ROS generation studies implicated that protein-capped and bare silver nanoparticles exhibit a distinct mode of action. Apparently, protein shells prevented silver ions from generating ROS since the protein shell did not allow the AgNP to interact directly with the membranes48. However, the present study results indicated that uncapped and bare nanoparticles were less effective as compared to polymer-coated silver nanoparticles. Our study validated that AgPVP and Ag 10% + Polymer were just as destructive against E. coli as AgNP, but with a two-fold reduction in the MIC value. Thus, the Ag 10% + Polymer had only 10% of the concentration of the silver, but it was twice as effective as the AgNP and similar in efficacy to the AgPVP. This could result in potentially beneficial silver formulations with enhanced antibacterial activity but lower silver ion concentrations.

Nanoparticles may have different levels of activity based on structural or chemical factors45,47. Studies have suggested that the agglomeration of AgNP may turn them into less toxic substances due to the smaller surface area to volume ratio in contact with the nanoparticles4851. The aggregation of the AgNP also lessens the antibacterial activity, however, capping or polymer functionalization enhances antibacterial activity45,48. The size and shape of nanoparticles can also play a significant role in their antibacterial activity. Smaller nanoparticles have the capacity to pass through the cell membrane while larger nanoparticles do not1,2,50,52. Typically, the most effective nanoparticles are those that have a size equal or less than 30 nm52,53. In our study, the Ag 10% + polymer-coated NP had dimensions less than 30 nm, whereas the AgPVP and plain uncoated AgNP were more than 30 nm in size. Additionally, the plain AgNP was irregular in shape, and not uniformly distributed with a mixture of small and large particles greater than 40 nm. By comparison, AgPVP and Ag 10% + polymer NP were circular in morphology and uniformly dispersed. This could explain why these NP were more effective than the plain uncoated AgNP. Interestingly, a previous study has shown that AgNP coated with PVP are more stable when the PVP concentration is at least 1% or higher54.

In this study, we focused on the antibacterial activity of polymer-coated and plain Ag nanoparticles. The plain silver nanoparticles had 99% Ag, and PVP coated nanoparticles had 99% Ag plus 1% polymer, whereas the Ag 10% + polymer had only 10% of silver and 90% of polymer. Although polymer coating does not directly affect bactericidal activity, the effect of various concentrations of polymer coating could influence the outcome. Here we evaluated commercially available coated nanoparticles with the view to choose the one with the best antibacterial activity at the lowest concentration of silver. The effect of varying the polymer concentration remains to be determined. However, the present study provides insightful evidence that coating of the AgNP did not affect their antibacterial activity. Moreover, the results of the present study may suggest that the coating of AgNP indeed offers stabilization of the AgNP and thus may have a beneficiary effect on improving the antibacterial activity of AgNP.

The structural changes of E. coli were explored after exposure to AgPVP, Ag 10% + Polymer, and AgNP using electron microscopy. The SEM images showed that E. coli exposed to AgPVP and Ag 10% + Polymer had more bacteria with damaged cell membranes and lysis. E. coli treated with AgNP on the other hand displayed an irregularly shaped appearance with nanoparticles attached to the cell membrane and fewer damaged or lysed cells. This suggests that AgPVP and polymer functionalized NP may be more effective in penetrating the cell through damaged membranes disrupting several functions such as DNA replication, cell metabolism, cell division, etc. and cause expulsion of cellular content55,56. Silver ions have also been implicated in the inhibition of uptake of phosphorous, causing the release of mannitol, phosphate, and amino acids such as proline and glutamine outside the cell membrane through the production of reactive oxygen species (ROS)53,55,56.

We investigated the expression of many genes of E. coli. associated with the TCA cycle (aceF, gadB), amino acid metabolism (argC, metL, and gadB), virulence (fliC, msbB), and DNA repair and transcription (mfD) (Table 1). The genes associated with the TCA cycle (aceF) and amino acid metabolism (gadB) were significantly downregulated with the treatment of AgPVP, Ag 10% + Polymer, and AgNP. However, there was the upregulation of genes responsible for virulence and DNA replication and repair. There was significant upregulation in flic with a 3-fold difference in bacterial cells treated with AgNP, but flic upregulation was not significantly higher with bacterial cells treated with AgPVP and Ag 10% + Polymer.

The upregulation of the genes required for virulence (msbB and flic) and DNA replication and transcription (mfdD) may be due to a stress related response of the bacteria to the damaging effect of the various nanoparticles. It appears that the Ag 10% + polymer NP had the highest upregulation of some of these genes suggesting that they caused more stress and damage to the bacteria than AgNP or AgPVP.

CONCLUSION

Our results indicate that capping of AgNP with PVP or functionalization with a polymer did not interfere with their antibacterial activity. The MIC and bacterial growth assay substantiated evidence that the concentration of the AgNP required to inhibit E. coli was reduced with polymer-coated AgNP when treating E. coli. The physical changes seen by SEM analysis of E. coli treated with various AgNP suggest that the proposed mechanisms of action include silver ions (Ag+) causing cell membrane damage or possible disruption. Finally, the molecular studies provided evidence that E. coli bacterial cells treated with AgNP, AgPVP and Ag 10% + Polymer had reduced expression of various metabolism associated genes, whereas there was upregulation of some virulence and DNA repair associated genes. The upregulation was more significant in bacterial cells exposed to Ag10% + polymer. Further research on the toxicity and molecular mechanism of action will be needed to determine the in vivo antibacterial efficacy of polymer-coated AgNP with a lower silver ion (Ag+) concentration.

ACKNOWLEDGMENTS

This research was supported by grants from the National Science Foundation-CREST (HRD-1241701), NSF-HBCUUP (HRD-1135863) and National Institutes of Health-MBRS-RISE (1R25GM106995-01). The department of Biological Sciences at ASU is acknowledged for providing the physical laboratory space to conduct the experiments.

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Recibido: 30 de Octubre de 2017; Aprobado: 15 de Febrero de 2018

Correspondence to: Shreekumar Pillai, Alabama State University, Center for Nanobiotechnology Research, 1627 Harris Way, 36101-0271, Montgomery, Alabama, USA Tel: +1 334 229-7501 E-mail: spillai@alasu.edu

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