Background
Diarrhea causes millions of deaths each year as a result of the action of a wide range of pathogens, including enterotoxin-producing strains of bacteria such as
Escherichia coli or
Vibrio cholerae [
1]. The pathogens are mainly spread by water or food contaminated with human or animal feces, and from person to person. The
V. cholerae infections result in severe diarrhea that, without proper treatment, can kill within a few hours. Children and the elderly in developing countries constitute the largest groups of fatalities. Cholera outbreaks are related to poor sanitation and usually occur after cataclysm or during a war when access to clean water is limited. The most recent cholera outbreak started in October 2016 in Yemen. Over 8 months, 101,820 cases of cholera were registered with 791 deaths [
2]. In developed countries, only sporadic, often imported cases of
V. cholerae infection occur [
3‐
5] but diarrhea from pathogenic
E. coli strains producing similar toxins regularly result in thousands of hospital patients, for example a 2011 outbreak affecting Germany and its’ neighboring countries also resulted in 50 deaths [
6]. The
E. coli infections are usually not as dangerous as cholera but still cause many problems, especially for travelers, children and the elderly [
1]. The main virulence factor of the above-mentioned bacteria is the production of toxins belonging to the AB
5 family, such as cholera (CTX) or heat-labile enterotoxins (LT and LT-II). The toxins are expressed and secreted as a response to bacterial quorum sensing once a colony has reached a mature size [
7]. Structurally, the AB
5 toxins contain a catalytic subunit A
1 linked by a short A
2 peptide to a pentameric subunit B that binds to gangliosides located on human cell surfaces [
8]. After secretion from the bacteria, the toxin binds to gangliosides and is then internalized from the plasma membrane by endocytosis and undergoes retrograde trafficking through the trans-Golgi network to the lumen of the endoplasmic reticulum. Here, subunit A is dissociated from the holotoxin, refolded and released to the cytoplasm where it causes constitutive activation of adenylate cyclase, resulting in activation and the conversion of ATP to cAMP. The high concentration of cAMP results in the opening of cAMP-dependent chloride channels and secretion of chloride ions into the lumen of the small intestine. Accumulation of chloride causes secretion of sodium ions into the lumen of the small intestine across the tight junction. An increased concentration of sodium chloride in the small intestine lumen creates an osmotic gradient that results in water outflow into the small intestine lumen across the tight junction [
9]. This is the point when diarrheal symptoms start. Table
1 gives a list of different stages of
V. cholerae infection where a pharmaceutical intervention may provide relief of cholera symptoms/infection. Each stage involves a number of potential molecular targets. It is possible to block the multi-step mechanism of action of cholera toxin at several different stages. Toxin neutralization after release by the bacteria and before internalization by human cells is one of the most accessible targets for a natural remedy or functional food to act on, and these stages are highlighted in bold in Table
1. Targeting a protein in human cells (italics, Table
1) is more challenging and more difficult to gain approval while the targeting of bacteria (normal text, Table
1) raises questions due to the growing knowledge of the importance of the diversity and health of the gut microbiome.
Table 1
Stages of V. cholerae infection
1. Initial anchoring | Anti-adherence Anti-invasion |
Aegle marmelos
| |
2. Stress induction | Luminescent assay | Several plant extracts, including Rosmarinus officinalis | |
3. Bacteriostatic | Various | Various | |
4. Bacteriocidal |
5. Quorum sensing | Native bioluminescence | Small molecule screen | |
6. CTX expression and secretion | rtPCR ELISA of Cell free culture supernatant | Capsaicin Several plants | |
7. CTX disassembly |
PAGE
|
(−)-Epicatechin from
Chiranthodendron pentadactylon
|
[19]
|
8. CTX aggregation |
Centrifugation, PAGE
|
Plant derived polyphenols
| |
9. Inhibition of GM1 binding |
GM
1
ELISA
|
Screening of 297 Chinese herbs
| |
10. Intracellular trafficking
|
Biotinlabeled CTX based assay
|
Resveratrol - found in red grapes, berries and peanuts
| |
11. CTA inhibitor
| | | |
12. Channel blocker
|
Patch clamp
|
Mixture including agarwood and clove
| |
99. Tasteb | Patient based | apple | |
Various plant species are traditionally used by many societies to alleviate and cure diarrhea. The properties of traditional plant extracts are worth exploring as they can stop or kill bacterial growth, neutralize or deactivate enterotoxins, or provide useful microelements and vitamins [
23]. Over the years, the healing properties of many plants have been superseded by synthetic pharmaceuticals, often derived from the active constituents of plants. Bacterial pathogens are becoming more resistant to commonly applied antibiotics and it is important to find new sources of antibacterial agents. However, this is unattractive in the case of cholera due to the development costs of a new drug and the fact that the disease can develop rapidly in a patient. Plant extracts do not provide the power of modern antibiotics. Instead, plant extracts may provide an attenuation of the many steps in the
V. cholerae infection lifecycle, including the latent, early stages of the disease, moderate the effects of diarrhea and lead to improved survival and recovery rates. The citations given in Table
1 are to works describing the methodology to test plant extracts at each stage of the cholera infection, with the exception of the quorum sensing stage that used a small molecule library. If we can identify plant extracts that act at different stages of the
V. cholerae infection lifecycle then it is possible that mixtures of plant extracts will provide a synergistic effect on the infected population, as well as individuals. This may help patients at different stages of infection, including asymptomatic carriers. The range of active metabolites produced by plants potentially treats a broad range of pathogenic strains and it will be more difficult for bacteria to develop resistance than with modern antibiotics. Furthermore, plant extracts based on accepted traditional medicines or functional foods will be more quickly, and cheaply, developed and applied.
In this study, we focus on the anti-enterotoxic activities of common European species belonging to the
Rosaceae family:
Agrimonia eupatoria L. (common agrimony),
Fragaria vesca L. (wild strawberry)
, Rubus fruticosus L. (blackberry)
, Rubus idaeus L. (raspberry) and
Rosa canina L. (rose), which for centuries were used in Poland as natural medicines for diarrhea [
24‐
28]. The recommended doses, methods of infusion preparation and references are listed in Table
2. Neither the pathogenic target of these herbs is known, nor their mechanism of action. However, Poland suffered from regular cholera outbreaks in the 19th and early 20th centuries [
29], and sporadic cases are still reported with non-O1
V. cholerae strains found in contaminated bodies of water [
5]. Therefore, in this study, we wanted to analyze if the above-mentioned plant extracts have antimicrobial activities and/or can neutralize cholera toxin binding to receptors. In doing so, we obtained some positive results and also found that assays employing CTX gave less positive results than CTB.
Table 2
Traditional preparation of plant infusions for the treatment of diarrhea in Poland
Agrimonia eupatoria L. | agrimony | aerial parts | 1.5–4 | ≤ 250 | 6–16 | The stated amount of boiling water is poured over the dry plant powder, covered and incubated for 15 min to 8 h | 2–3 | |
Rubus fruticosus L. | blackberry | leaves | 1–2 | 250 | 4–8 | 3b | |
Rubus idaeus L. | raspberry | leaves | 1.5–8 | 150 | 10–53.3 | 2–3 | |
Rosa canina L. | rosehip | fruit | 2–5 | 150 | 13.3–33.3 | ≥ 3 | |
Fragaria vesca L. | wild strawberry | leaves | 1–2 | 250 | 4–8 | 3b | |
Methods
Plant material and extraction
The plants were dried from their natural state, and cut or chopped. All plant materials were authenticated and tested to comply with British and European food/pharmacopeia standards by the supplier, Bristol Botanicals Limited (Bristol, UK). The list of the used species and batch numbers are presented in Table
3. The aqueous extracts were prepared by pouring 25 mL of boiling Milli-Q (MQ) grade water onto 1 g of plant material, allowed to cool to room temperature, and left to stand for over 18 h. The extracts were decanted and passed consecutively through filter paper and 0.4 μm cellulose acetate filters (Whatman, UK). To further minimize contamination or degradation, the plant extracts were frozen and lyophilized to dryness, after which the extraction yields were calculated (Table
3), and then stored at − 20 °C. The lyophilized materials gave consistent data over several months.
Table 3
Yields of prepared plant extracts
Agrimonia eupatoria L. | agrimony | aerial parts | MHS002/ 110,324 | 12.6 | 19.8 | 5 |
Rubus fruticosus L. | blackberry | leaves | MHS016/ 100,621 | 14.2 | 17.6 | 2.5 |
Rubus idaeus L. | raspberry | leaves | MHS121/ 177,905 | 19.4 | 12.9 | 2.5 |
Rosa canina L. | rosehip | rosehip (fine cut) | MHS125/ 7640 | 29.5 | 8.5 | > 10 |
Fragaria vesca L. | wild strawberry | leaves | MHS144/ 184,439 | 11.3 | 22.1 | 2.5 |
Mammalian cell culture
Primary human skin fibroblasts (line C688) were obtained from the Department of Metabolic Diseases, The Children’s Memorial Health Institute in Warsaw, Poland [
30]. Ganglioside GM
1 molecules, receptors for CTX, are one component of fibroblast membranes. C688 cells were cultured in Dulbecco’s Modified Eagle’s Medium (DMEM) (Sigma, USA) with 10% fetal bovine serum (FBS, Gibco, South America), 100 units/mL penicillin and 100 μg/mL streptomycin (Sigma, USA) at 37 °C in a humidified atmosphere containing 5% CO
2, on 100 mm
tissue-culture treated dishes (Corning BD, USA) until 80–90% confluence. To dissociate the adherent cells, dishes were rinsed with phosphate buffered saline solution pH 7.5 (PBS, 10 mM Na
2HPO
4, 1.76 mM KH
2PO
4, 2.7 mM KCl, 136 mM NaCl) and incubated with 2 mL (0.5 mg/mL) of porcine trypsin (Sigma, USA) for 7 min at 37 °C. Cells were collected by centrifugation (500 g for 3 min), resuspended in fresh medium and counted under a light microscope (Zeiss Observer Z1, Germany) using a Bürker chamber.
Cytotoxic effect of plant extracts (MTT method)
The cytotoxic activity of plant extracts was determined using the standard MTT method (according to a Sigma protocol). We seeded 5 × 10
3 C688 cells/well into 96 well plates and cultured them as described above. The next day, the medium was discarded and cells were treated with 200 μL of several different concentrations of plant extracts diluted in DMEM with 1% FBS (range 5 to 0.078 mg/mL). After 24 h incubation at 37 °C, the medium was discarded and wells were washed twice in PBS, pH 7.5. To determine cell viability, 20 μL of 5 mg/mL MTT ((3-[4,5-dimethylthiazol-2-yl]-2,5-diphenyltetrazolium bromide), Sigma, USA) in PBS and 180 μL of DMEM without FBS were added to the wells and incubated for 4 h at 37 °C. Then, the medium was carefully discarded and 200 μL of 40 mM HCl in isopropanol was added. After 10 min incubation, the absorbance was measured at 570 nm with the background wavelength set to 630 nm using a SpectraMax M5
e plate reader. All experiments were carried out in triplicate. The percentage of viable cells was calculated using Eq.
1:
$$ \%\mathrm{viable}\ \mathrm{cells}={\mathrm{A}}_1\ \mathrm{X}\ 100\%/{\mathrm{A}}_0 $$
(1)
where A0 is the value of the absorbance for control conditions (which was considered 100%) and A1 is the value of the absorbance for tested samples, reduced by the value of background.
Microbial strains
The aqueous plant extracts were tested against four bacterial strains: Escherichia coli ATCC 25922, E. coli O44 (834/04, collection of National Medicine Institute, Warsaw, Poland), Vibrio cholerae O395-tacCTB strain (Chiron Srl./Novartis) and Lactobacillus rhamnosus (ATCC 53103).
Broth microdilution assay
The antimicrobial activity of plant extracts was determined by a standard microdilution technique using 96-well microtiter plates. Bacterial inoculates were prepared from 12 h liquid cultures grown on Mueller-Hinton (MH) broth. The plant extracts were dissolved in MH medium to a concentration of 2.5 mg/mL and a series of six, two-fold dilutions of plant extracts in MH broth (range 2.5–0.078 mg/mL) were prepared across the microtiter plates. To each well, 10 μL of inoculum (~ 0.2 × 10
5 bacterial cells / well) was added. The wells were filled with MH broth to 200 μL total volume. As a negative control, plant extracts were replaced with MH broth and as a positive control – bacteria were incubated with 35 μg/mL of chloramphenicol. After 18 h incubation at 37 °C, the absorbance of each well was measured at 600 nm using a SpectraMax M5
e plate reader. The bacterial growth was calculated with Eq.
2:
$$ \%\mathrm{bacterial}\ \mathrm{growth}={\mathrm{A}}_1\ \mathrm{X}\ 100\%/{\mathrm{A}}_0 $$
(2)
where A1 = sample absorbance, A0 = absorbance of negative control.
Using this scale, 0% is total bacterial growth inhibition and 100% is the bacterial growth in the absence of plant extracts. The plant extract concentration that resulted in a bacterial growth reduction by more than 80% was interpreted as a minimal inhibitory concentration (MIC), while a reduction by more than 50% was defined as a concentration that limited bacterial growth.
To determine the minimal bactericidal concentrations (MBC) of the plant extracts, 2 μL of suspension after 18 h culture was applied to MH agar plates and cultured at 37 °C for 18 h. The lowest concentration of plant extract without bacterial colonies was interpreted as the MBC. The experiments were performed in triplicate.
cAMP assay
The cAMP levels in cultured C688 cells were determined using a cAMP-Glo Max Assay (Promega, USA), according to the manufacturer’s protocol. Cells were grown in tissue culture treated 96-well, white plates with clear, flat bottoms (Brand, Germany). To each well, 103 C688 cells were added and cultured overnight under standard conditions. The next day, the medium was discarded and a mixture of 2.5 mg/mL plant extract or gallic acid and 25 nM CTX (2.125 μg/mL) in DMEM supplemented with 30 mM MgCl2 was added to each well. The plates were incubated for 2 h at 37 °C in 5% CO2. Next, the proper amount of detection solution and kinase glo reagent were added. The luminescence (RLU) was measured using a SpectraMax M5e plate reader. As controls, cells were incubated with only: plant extracts, CTX, or DMEM. The cAMP level was calculated as a change in RLU (ΔRLU) for the sample incubated with only plant extract/gallic acid/DMEM and the sample incubated with a mixture of plant extract/gallic acid/DMEM and CTX. Each sample was tested in three repeats.
Ganglioside GM1- CTX binding assay
The ganglioside GM
1- CTX interaction was analyzed according to a published protocol based on the ELISA method ([
18], with modification). The 96-well, clear, flat-bottom immune-plates (Nunc, Denmark) were coated with 25 ng ganglioside GM
1 resuspended in 50 μL ethanol and incubated at 37 °C for 2 h, to dryness. The wells were washed three times with 200 μL wash buffer (0.05% Tween 20 in PBS, pH 7.5), blocked with 200 μL blocking buffer (0.5% bovine serum albumin (BSA, Sigma, USA) in PBS) for 18 h at 4 °C, and washed three more times with 200 μL wash buffer. Wells coated with ganglioside GM
1 were incubated with 2.5, 1.25, 0.625, 0.3, 0.15, 0.075 mg/mL of plant extracts and 0.25 μg/mL CTX for 2 h, in a total volume 200 μL. As negative controls, three wells coated with GM
1 were incubated with CTX to provide maximal measurements or with 2.5 mg/mL plant extract to provide baseline measurements. To prepare a positive control, the binding sites of CTB were blocked with free GM
1 as an inhibitor, by pre-incubating CTX with GM
1 for 1 h. The resulting, inactivated CTX was added to wells coated with GM
1 and incubated as described above. The wells were washed three times with 200 μL of wash buffer followed by incubation with 50 μL of anti-CTB antibody (Invitrogen), diluted 1:4000 in 0.5% bovine serum albumin (BSA), for 90 min at room temperature. After triple washing, wells were incubated for 75 min at room temperature with 50 μL of secondary anti-mouse antibody conjugated with horse radish peroxidase (Sigma), diluted 1:15,000 in 0.5% BSA. Wells were washed three times with wash buffer, once with PBS and then dried. To visualize the CTX bound to GM
1, 100 μL 3,3′,5,5′-Tetramethylbenzidine (Millipore, USA) was added to each well and incubated for 15 min. To stop the reaction, 100 μL of stop solution (0.5 M H
2SO
4) was added and the absorbance was measured at 450 nm using a SpectraMax M5
e plate reader. Each assay was repeated six times.
Ganglioside GM1 and CTB-FITC binding assay
The protocol to this method is similar as for CTX (above). Instead of unlabeled CTX, 1.25 μg/mL of CTB-FITC (Sigma, Israel), CTB labeled with a fluorescent fluorescein derivative, was incubated with the appropriate concentration of plant extracts (2.5–0.075 mg/m, serial dilutions) in a total volume of 200 μL. After 2 h incubation at room temperature, wells were washed three times with PBS. Next, 200 μL of PBS was added and the intensity of fluorescence was measured at 490 nm excitation and 525 nm emission, using an Infinite M1000 PRO plate reader (Tecan). Each assay was repeated six times.
Fluorescence activated cell sorting (FACS) assay: quantitative assay
This assay was performed to analyze the ability of plant extracts to inhibit the binding of CTB-FITC to ganglioside GM1 naturally embedded in the extracellular surfaces of fibroblasts (C688). C688 cells (5 × 104) were re-suspended in DMEM and incubated for 60 min at 37 °C with 2.5 mg plant extract and 0.25 μg CTB-FITC in 1 mL total volume. As controls, we used: (i) cells exposed only to toxin, which was treated as a negative control, (ii) cells exposed only to plant extract, which allowed us to account for autofluorescence from the plant extract and (iii) cells treated with inactivated FITC-CTB, obtained by pre-incubation of 0.5 μg/mL GM1 and 0.25 μg/mL FITC-CTB for 1 h, which was treated as a positive control. To all samples, 50 μg/mL propidium iodide (PI, Sigma, USA) was added to determine cell viability. The number of stained cells and the intensity of the fluorescence of 104 cells were analyzed by flow cytometry (FACSCalibur, Becton Dickinson, USA) in two channels: FL-1 (green) for FITC and FL-3 (red) for PI. The data were analyzed using CellQuest acquisition/analysis software. Each sample was tested in three independent assays.
Fluorescent microscopy – qualitative assay
This assay was performed to visualize the activity of the plant extract and CTB-FITC on cells containing ganglioside GM1. C688 cells (5 × 103) were seeded onto cover glass slips and cultured for 18 h according to the described procedure. Cells adherent to the glass were washed in PBS and incubated at 37 °C for 1 h with 5.0, 2.5 or 1.25 mg/mL plant extract and 0.25 μg/mL CTB-FITC in 500 μL DMEM, and then fixed with 3% paraformaldehyde. The nuclei were stained with 0.3 mg/mL of 2-(4-Amidinophenyl)-6-indolecarbamidine dihydrochloride (DAPI, Sigma, Israel). The cover glass slips were stuck to microscope slides using MOVIOL solution and observed under a Fluorescent Microscope (Axio Observer Z1, Zeiss). Each sample was tested in three independent repeats.
Discontinuous polyacrylamide gel electrophoresis under denaturing conditions (SDS-PAGE)
Our protocol is based on a published method with some modifications [
31]. CTX (2 μg) was incubated with 1 mg plant extracts in a twofold diluted range (1–0.0015 mg) for 1 h at room temperature. The total sample volume was 12 μL. Next, samples were applied to 10% denatured gels and, using the Tris/Tricine discontinuous electrophoresis system ([
32], with modifications), run for 90 min at 90 V (15 min) and next at 130 V. The gels were washed and stained with Blue BANDit Protein Stain reagent (VWR, USA). As a negative control, we used CTX without plant extracts. To avoid false positive results and eliminate thresholds we used plant extracts without CTX. As positive controls, CTX was incubated with ganglioside GM
1 solution (2–0.03 μg) and gallic acid (0.1–0.0015 mg). The experiments were performed in triplicate
Statistical analyses
Data were obtained from three or six measurements, as defined in the specific sections, and were expressed as the means ± standard deviation. Statistical analyses were performed using one-way ANOVA, followed by the Bonferroni-Holm post hoc test [
33]. Statistically significant differences between groups were defined as
p-values less than 0.05 with the Bonferroni-Holm correction.
Discussion
Oral Rehydration Therapy (ORT) is commonly used and recommended by WHO for the treatment of acute diarrhea, including cholera. This therapy is based on solutions of oral rehydration salts (ORS) containing: glucose, sodium, chloride, potassium and citrate. ORT is used to protect the organism against dehydration caused by excessive fluid losses by vomiting and watery stools, but does not act against bacteria and their toxins [
40]. The incorporation of plant extracts into ORS formulae can give several potential benefits such as providing a broad range of antimicrobial and anti-toxin compounds, as well as a taste that might be better accepted by young children, Table
1. On this basis, we investigated the properties of plant extracts used in Poland to treat non-specific diarrhea.
The MTT assay and separate staining of C688 cells with PI indicated that the cytotoxicity of all the plant extracts was above 2.5 mg/mL. Assuming that the traditional preparation generates similar extraction yields, Table
3, cytotoxic effects were observed above the traditional doses for all plant extracts except rosehip. The safe concentration for rosehip is calculated as 13 g/L preparation compared with a traditional preparation of 10–53 g/L, Table
2. Overall, there appeared to be no correlation between various phytochemical analyses (phenolic or flavonoid contents, two antioxidant measures, Additional file
1) and the results of any of the antimicrobial or anti-toxin assays.
According to published data, agrimony [
12], blackberry leaf [
13] and raspberry leaf [
13,
14] show a weak antimicrobial activity against
E. coli strains. Our results are consistent with this data, Fig.
1. Specific, mild bacteriostatic potentials against
V. cholerae were recorded for four of the plant extracts, Table
4, at or below concentrations used in traditional remedies. A bacteriostatic effect was measured just above the traditional preparation range for blackberry leaf. The specific growth inhibition may help beneficial bacterial colonies, for example
L. rhamnosus that was unaffected by the plant extracts, compete with
V. cholerae and delay the onset of diarrheal episodes. However, the bacteriostatic properties may contribute to asymptomatic carriers [
41,
42]. Therefore, we cannot conclude if the bacteriostatic properties of the plant extracts are beneficial, or not, in a traditional cure of diarrhea related to cholera.
The toxic action of cholera toxin is related with the continuous production of cAMP, which leads to the opening of chloride channels and secretion of chloride anions [
9]. To test if plant extracts prevent cAMP activation by CTX, the intracellular level of cAMP in cell cultures was measured. According to our data, all plant extracts suppressed the cholera toxin action on cAMP levels at levels below the traditional dose. This assay covers a broad number of stages in Table
1, as well as a number of intracellular steps for the internalization of the CTX through the endosomes, Golgi apparatus to endoplasmic reticulum and secretion to the cytoplasm. Several different assays were used to better define the action of the plant extracts.
Cell based assays (Figs.
5 and
6) utilizing CTB-FITC as a fluorescent marker provided results consistent with antibody detected CTB and CTX in the immobilized GM
1 assays in Figs.
3 and
4, and the cAMP results (Fig.
2). Positive effects on the inhibition of CTB-FITC binding by plant extracts to C688 cells were observed. Two phenomena could be distinguished by flow cytometry and fluorescence microscopy. At higher plant extract doses, a lower labeling of C688 cells was reported by both methods. At intermediate levels, fluorescence microscopy revealed that while CTB-FITC labeled the C688 cells, the process of cellular internalization was probably blocked because CTB-FITC does not accumulate in the perinuclear region. With respect to flow cytometry data, blocking of cellular internalization would not be recognized as a positive effect of the plant extracts as the cells are still fluorescently labeled. Flow cytometry is a faster, more economical tool for screening plant extracts but may miss some beneficial plant extracts. Fluorescence microscopy adds detail to the flow cytometry data, perhaps accounting for the aggregation properties of some of the plant extracts revealed by native PAGE. High plant extract doses may fully aggregate the toxin and block the CTB/CTX recognition sites for GM
1 receptors but intermediate plant extract concentrations may produce aggregates with remaining active GM
1 binding sites that allow for cellular labeling. Regarding traditional levels, positive results were observed for low to mid traditional concentrations of agrimony and raspberry leaf. In the higher range of traditional concentrations, positive results were obtained for blackberry leaf and rosehip. Positive results for wild strawberry leaf were obtained only for concentrations greater than traditionally used.
Several plant extracts have been documented to interact with cholera-like toxins through different mechanisms. The Mexican plant
Chiranthodendron pentadactylon Larrreat [
31] and the Chinese plant
Chaenomeles speciosa [
43] can block the binding site of heat-labile enterotoxin produced by
E. coli (LTX). The active compounds of these plants include gallic [
19] oleanolic, ursolic and betulinic acids [
43], and (−)-epicatechin [
31]. These compounds bind to the toxin binding site for gangliosides (GM
1 and others), and thus cause toxin inactivation by competition. It was also shown that plant polyphenols, such as applehenon from apples, reduced the amount of cholera toxin bound to receptors and suppressed toxin internalization, probably by toxin aggregation [
18]. SDS-PAGE analysis reveals that agrimony, raspberry leaf, blackberry leaf and wild strawberry leaf extracts cause aggregation of the toxin. This mechanism appears similar as after incubation of the toxin with ganglioside GM
1, Fig.
7. Probably, active compounds of agrimony, blackberry leaf and wild strawberry leaf bind to the cholera toxin and block the binding site or change the toxin conformation, suppressing its binding to GM
1 in the ELISA and cell-based assays. The raspberry leaf active compounds also cause aggregation, but do not block toxin binding to the cell surface. However, according to fluorescence microscopy and cAMP data, it does inhibit toxin internalization. SDS-PAGE analysis showed that rosehip extract (at 10 mg/mL concentration) behaves like gallic acid, Fig.
7. It remains to be seen if the different effects of rosehip and the other tested extracts have a synergistic effect.
According to our data, all plant extracts inhibited CTB binding to GM1 more strongly than CTX. This effect might be related to the toxin structure. Possibly, when the CTA is bound to CTB, part of the CTB structure is masked by CTA against the plant extracts compound action. When the CTB is alone, it has larger, unprotected surfaces, which can be easily accessed by plant compounds that cause changes in toxin conformation and reduce the ability to bind to GM1. Another explanation is that the plant extract interacts with the fluorescent marker of CTB-FITC, reducing its fluorescent properties. Although we cannot define the exact mechanisms related to the different effects of CTB-FITC and CTX, our data do suggest that assays involving CTB-FITC alone may overestimate the inhibitory power of plant extracts and chemical compounds on cholera toxins.
In the context of universal ORT formulations, the plant extracts should be safe for all sections of society including children, the elderly and pregnant/lactating women, as well as people suffering with long-term diseases that are incompatible with certain foodstuffs (diabetic, allergic). Extracts of raspberry leaf, in addition to being used as traditional medicine for diarrhea, are also widely used during pregnancy. While some reports indicate that raspberry leaf extracts are safe during pregnancy [
44] other reports sow doubts or caution [
45,
46]. Strawberry leaf is listed as an emmenagogue in a thorough review of plant based remedies used as abortifactants, contraceptives and sterilizers [
47] although the original citation [
48] itself cites the emmenagogue use as being historical (Ostermann, V. (1894) La vita in Friuli, Vols. I, II. Reprinted 1974, Del Bianco Ed., Udine, Italy). While traditional medicine may have been used for several centuries, the lack of properly conducted medical studies precludes the incorporation of any of the plant extracts into a universal ORS formula without further safety studies.
The obtained results indicate that the traditional application of: agrimony, raspberry leaf, blackberry leaf, rosehip and wild strawberry leaf infusions in treating bacterial diarrhea might be effective against diseases related to AB
5 enterotoxins, such as cholera. These plant extracts can inhibit bacterial growth, block the toxin binding to receptors, inhibit toxin internalization to the host cell and suppress cAMP overproduction (Table
5).
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