Hostname: page-component-78c5997874-94fs2 Total loading time: 0 Render date: 2024-11-10T15:07:44.122Z Has data issue: false hasContentIssue false
  • English
  • Français

Differential effectiveness of berry polyphenols as anti-giardial agents

Published online by Cambridge University Press:  03 August 2011

J.-P. ANTHONY ,
L. FYFE ,
D. STEWART  and
G. J. McDOUGALL
J.-P. ANTHONY
Affiliation:
Dietetics, Nutrition and Biological Sciences, Queen Margaret University, Clerwood Terrace, Edinburgh EH12 8TS, UK Scottish Parasite Diagnostic Laboratory, House on the Hill Reference Laboratories, Stobhill Hospital, Balornock Road, Glasgow G21 3UW, UK
L. FYFE
Affiliation:
Dietetics, Nutrition and Biological Sciences, Queen Margaret University, Clerwood Terrace, Edinburgh EH12 8TS, UK
D. STEWART
Affiliation:
Plant Products and Food Quality Programme, The James Hutton Institute, Invergowrie, Dundee DD2 5DA, UK
G. J. McDOUGALL*
Affiliation:
Plant Products and Food Quality Programme, The James Hutton Institute, Invergowrie, Dundee DD2 5DA, UK
*
*Corresponding author: Plant Products and Food Quality Programme, The James Hutton Institute, Invergowrie, Dundee DD2 5DA, UK. Fax: +44 1382 562426. Tel: +44 1382 562731. E-mail: Gordon.mcdougall@hutton.ac.uk
Rights & Permissions [Opens in a new window]

Summary

Following previous work on the anti-giardial effect of blueberry polyphenols, a range of polyphenol-rich extracts from berries and other fruits was screened for their ability to kill Giardia duodenalis, an intestinal parasite of humans. Polyphenol-rich extracts were prepared from berries using solid-phase extraction and applied to trophozoites of Giardia duodenalis grown in vitro. All berry extracts caused inhibition at 166 μg gallic acid equivalents (GAE)/ml phenol content but extracts from strawberry, arctic bramble, blackberry and cloudberry were as effective as the currently used drug, metronidazole, causing complete trophozoite mortality in vitro. Cloudberry extracts were found to be the most effective causing effectively complete trophozoite mortality at 66 μg GAE/ml. The polyphenol composition of the more effective berry extracts suggested that the presence of ellagitannins could be an important factor. However, the potency of cloudberry could be related to high ellagitannin content but also to the presence of substantial amounts of unconjugated p-coumaric acid and benzoic acid. These in vitro effects occur at concentrations easily achievable in the gut after berry ingestion and we discuss the likelihood that berry extracts could be effective anti-giardial agents in vivo.

Keywords

berrypolyphenolGiardia duodenalisellagitannintrophozoitemortality
Type
Research Article
Information
Parasitology , Volume 138 , Issue 9 , August 2011 , pp. 1110 - 1116
Copyright
Copyright © Cambridge University Press 2011. The online version of this article is published within an Open Access environment subject to the conditions of the Creative Commons Attribution-NonCommercial-ShareAlike licence <http://creative commons.org/licenses/by-nc-sa/2.5/>. The written permission of Cambridge University Press must be obtained for commercial re-use.

INTRODUCTION

Giardia duodenalis is a flagellated protozoan parasite that colonizes and reproduces in the human intestine, causing giardiasis, of which the most common symptom is serious diarrhoea. Effective drug treatment for G. duodenalis is available, using orally administered metronidazole, but there is evidence of resistance (e.g. Harris et al. Reference Harris, Plummer and Lloyd2001; Upcroft et al. Reference Upcroft, Dunn, Wright, Benakli, Upcroft and Vanelle2006). In addition, side effects such as nausea and headaches combined with an unpalatable metallic taste reduce patient compliance. In poorer countries where giardiasis is endemic, this condition affects both child development and mortality and chemotherapy may be minimally effective due to continual re-infection from the environment and therefore novel drugs and treatments are sought (Rossignol, Reference Rossignol2010).

Plants and plant products have been used as traditional remedies for various ailments in numerous countries, with little or no side effects (Jones, Reference Jones1996). Wild blueberries (Vaccinium myrtillus) and wild strawberries (Fragaria vesca) have been historically used to treat ‘fluxes’ (or florid diarrhoea) in the UK (see Anthony et al. Reference Anthony, Fyfe, Stewart, McDougall and Smith2007). The true causes of such diarrhoea/fluxes cannot be confirmed but certainly could be caused by enteropathogens (Cox, Reference Cox2002) such as Giardia and Cryptosporidium.

The anti-microbial properties of plant products have been recognized for numerous years, and recently there has been renewed interest in berries and their phenolic constituents such as anthocyanins and ellagitannins (e.g. Nohynek et al. Reference Nohynek, Alakomi, Kähkönen, Heinonen, Helander, Oksman-Caldentey and Puupponen-Pimiä2006). Polyphenol-rich berry extracts inhibited the growth of enteropathogenic bacteria such as Salmonella, Escherichia, Staphylococcus, Helicobacter, Bacillus, Clostridium and Campylobacter species, and were bacteriostatic for 3 Staphylococcus aureus strains (Puupponen-Pimia et al. Reference Puupponen-Pimiä, Nohynek, Alakomi and Oksman-Caldentey2005).

Trophozoites from infective cysts infect the duodenum, attaching onto enterocytes via a combination of hydrodynamic forces and their ventral ‘sucking’ disc and through lectins specific for D-glucosyl and D-mannose residues (Inge et al. Reference Inge, Edson and Farthing1988). Berry extracts may inhibit the adhesion and colonization of Giardia to human enterocytes. Proanthocyanidins found in cranberry juice (Vaccinium macrocarpon, and in other Vaccinium species) have potent bacterial anti-adhesion activity (Howell et al. Reference Howell, Reed, Krueger, Winterbottom, Cunningham and Leahy2005) and the proanthocyanidin, Geranin D, from Geranium niveum has potent anti-giardial activity (Calzada et al. Reference Calzada, Cedillo-Rivera, Bye and Mata2001) Plant products have been demonstrated to possess anti-protozoan effects, but relatively little is known. Garlic extract inhibits G. duodenalis trophozoite growth in vitro (Lun et al. Reference Lun, Burri, Menzinger and Kaminsky1994) and treatment with garlic extract can reduce clinical signs and symptoms more rapidly than metronidazole, the current drug of choice (Soffar and Mokhtar, Reference Soffar and Mokhtar1991). Whole garlic extract co-cultured with trophozoites causes internalization of flagella and ventral disc fragmentation (Harris et al. Reference Harris, Plummer, Turner and Lloyd2000; Anthony et al. Reference Anthony, Fyfe and Smith2005). Isoflavones, especially formononetin from Dalbergia frutescens, have potent anti-giardial activity in vitro (Khan et al. Reference Khan, Avery, Burandt, Goins, Mikell, Nash, Azadegan and Walker2000) with a possible mode of action being the detachment of Giardia trophozoites in vitro and ex vivo through the inhibition of flagellar motility (Lauwaet et al. Reference Lauwaet, Andersen, Van de Ven, Eckmann and Gillin2010).

Previous work investigated a pressed extract of blueberries, a commercial drink made from this extract and a polyphenolic-rich extract for their ability to influence G. duodenalis trophozoite viability in vitro and confirmed the effectiveness of the polyphenolic components (Anthony et al. Reference Anthony, Fyfe, Stewart, McDougall and Smith2007). This study examines the effects of polyphenol-rich extracts from a range of berry species with disparate composition on Giardia viability in vitro.

MATERIALS AND METHODS

Extraction of berries

Blackcurrants (Ribes nigrum L. variety 8982-6) were obtained from Bradenham Hall, Norfolk, UK and blueberries (Vaccinium myrtillus L. variety Berkeley) were grown at SCRI. Cloudberries (Rubus chamaemorus L.), arctic bramble (Rubus stellatus×R. arcticus), lingonberries (Vaccinium vitis-idaea), sea buckthorn (Hippophae rhamnoides) and rowan berries (Sorbus aucuparia L. c.v. Sahharnaja) were obtained from Dr Harri Kokko, University of Kuopio. Pomegranates (Punica granatum L.) were purchased from a local supermarket. Strawberries (Fragaria ananassa variety Elsanta) were obtained from local farmers.

The berries were extracted by the protocol outlined previously (McDougall et al. Reference McDougall, Kulkarni and Stewart2009) with minor changes. Briefly, the berries were homogenized in an equal volume to weight of 0.2% (v/v) acetic acid in 50% acetonitrile/ultra-pure water (UPW) in a Waring blender (5 times for 15 sec on full power). The extract was filtered through tripled muslin then centrifuged at 2800 g for 10 min at 4°C to remove suspended polysaccharides.

The extracts were each applied to separate C18 solid-phase extraction (SPE) units (Strata C18-E, GIGA units, 10 g capacity Phenomenex Ltd, Macclesfield, UK) pre-washed in 0.2% (v/v) formic acid in acetonitrile then pre-equilibrated in 0.2% (v/v) formic acid in UPW. The unbound material, which contained the free sugars, organic acids and vitamin C, was collected. The units were washed with 3 column volumes of UPW then the polyphenol-enriched bound extracts eluted with 0.1% (v/v) formic acid in acetonitrile.

Phenol content was measured using a modified Folin–Ciocalteu method (Deighton et al. Reference Deighton, Brennan, Finn and Davies2000) and quantified as gallic acid equivalents (GAE). Anthocyanin content was measured using the 2-wavelength method outlined previously (Deighton et al. Reference Deighton, Brennan, Finn and Davies2000). The C18-bound extracts were evaporated to dryness in a Speed-Vac (Thermo-Finnegan Ltd) as required.

Culture of G. duodenalis trophozoites

Trophozoites of the BVM strain of G. duodenalis were maintained axenically in flat-sided 110 mm×16 mm culture tubes at 37°C, in a modified TYI-S-33 medium (Anthony et al. Reference Anthony, Fyfe, Stewart, McDougall and Smith2007) supplemented with 10% (v/v) heat-inactivated foetal bovine serum. Subculturing was performed routinely at 72–96 h intervals. After 72 h of culture, trophozoites were harvested by chilling culture vessels in iced water for 20 min. For addition to G. duodenalis cultures, aliquots of dried berry polyphenol extracts were reconstituted in TYIS-33 at a concentration of 2 mg ml−1 then passed through a sterile 0.22 μm filter (Sartorius).

Experiments were performed in sterile, 96-well microtitre plates covered with plate-sealer film and lids. To 100 μl of trophozoite culture (∼2.7×104 trophozoites) 200 μl of berry extract diluted in TYI-S-33 was added to give suitable final concentrations. The microtitre plates were sealed and incubated for 24 h at 37°C, after which the trophozoites were enumerated. The positive control consisted of 2.7×104 trophozoites in 300 μl of TYI-S-33 containing 67 μg ml−1 metronidazole (found to be the minimal inhibitory concentration within this system that killed 100% of trophozoites) and the negative controls consisted of 2.7×104 trophozoites in 300 μl of TYI-S-33 in the absence of berry extracts or metronidazole. All assays were carried out in triplicate.

Trophozoite enumeration was performed using an improved Neubauer haemocytometer and trophozoite viability determined by Trypan blue inclusion/exclusion. Briefly, trophozoites were harvested from wells by chilling the plate on iced water for 20 min and the contents of triplicate wells were combined into 1.5 ml microcentrifuge tubes, and then centrifuged (10 sec, bench top centrifuge 5410, Eppendorf GmbH, Germany). The supernatant was aspirated to waste and the pellet resuspended in 100 μl of TYI-S-33 and 100 μl of 0.4% Trypan blue solution (Gibco, UK) and mixed thoroughly. After mixing, 10 μl were dispensed into both chambers of an improved Neubauer haemocytometer, allowed to settle (30–60 sec) then assessed.

Trophozoite viability was determined under bright-field microscopy at a total magnification of ×400 using the following formula: (L÷(L+D))×100 where L is the number of live trophozoites (unstained) and D the number of dead trophozoites (stained with Trypan blue) with 3 counts of 100–200 trophozoites being taken and repeated twice.

Liquid Chromatography Mass Spectrometry (LC-MS) analysis

Samples containing 20 μg phenols (GAE) were analysed on an LCQ-Deca system, comprising Surveyor auto-sampler, pump and photo-diode array detector (PDAD) and a ThermoFinnigan mass spectrometer iontrap as described previously (McDougall et al. Reference McDougall, Kulkarni and Stewart2009). The PDAD scanned discrete channels at 280 nm, 365 nm and 520 nm. The samples (20 μl) were applied to a C-18 column (Synergi Hydro C18 with polar-end capping, 4.6 mm×150 mm, Phenomenex Ltd, UK) and eluted over a gradient of 5% acetonitrile (0.5% formic acid) to 30% acetonitrile (0.5% formic acid) over 60 min at a rate of 400 μl/min. The LCQ-Deca LC–MS was fitted with an ESI (electrospray ionization) interface and analysed the samples in positive and negative ion mode. There were 2 scan events; full scan analysis followed by data dependent MS/MS of most intense ions using collision energies (source voltage) of 45%. The capillary temperature was set at 250°C, with sheath gas at 60 psi and auxiliary gas at 15 psi. The MS was tuned against solutions of ellagic acid (negative mode) and cyanidin-3-O-glucoside (positive mode). Only negative mode data are shown.

Putative identifications of polyphenols are based on previous work in cloudberry (McDougall et al. Reference McDougall, Martinussen and Stewart2008, Reference McDougall, Kulkarni and Stewart2009) and previous literature (Mullen et al. Reference Mullen, Yokota, Lean and Crozier2003; Hager et al. Reference Hager, Howard, Liyanage, Lay and Prior2008; Gasperotti et al. Reference Gasperotti, Masuero, Vrhovsek, Guella and Mattivi2010). Benzoic acid, p-coumaric acid and ellagic acid were employed as standards to confirm the identity of peaks. Peaks identified as ellagitannins were quantified using the MS system (Xcalibur) software and their PDA peak areas summed. This figure was divided by the total peak area of all polyphenol peaks to give an estimate of relative ellagitannin content. This estimate was carried out on 3 replicate injections of the arctic bramble and the cloudberry samples. This comparison was facilitated as the same ellagitannin peaks were largely present in cloudberry and arctic bramble.

RESULTS

Strawberry, blackberry, cloudberry and arctic bramble were as effective in killing Giardia as the positive control, metronidazole, at 50 μg GAE/well (Fig. 1). These effects were not due to changes in pH as the polyphenol-enriched extracts were effectively devoid of organic acids and did not alter the pH of the medium. There was no correlation between anthocyanin content and effectiveness as both cloudberry (<0.1%) and blackberry (58.0%) anthocyanin content; (see Supplementary data, Table S1, Online version only) caused complete trophozoite killing at 50 μg GAE well−1.

Fig. 1. Effect of berry extracts on Giardia viability. Trophozoites (2.7×104 trophozoites per well) were incubated for 24 h in the presence or absence of berry polyphenol extracts at 50 μg GAE per well. Untreated trophozoites and metronidazole (67 μg ml−1) treated trophozoites were used as controls. All values are averages of triplicate experiments±standard error. All berry extracts significantly reduced the survival of G. duodenalis trophozoites when compared to untreated trophozoites (P⩽0.05).

The most effective berry extracts were re-assayed at lower concentrations to assess dose-response effects (Fig. 2). This revealed an order of effectiveness of blueberry < strawberry < blackberry=arctic bramble < cloudberry. Cloudberry extracts were most effective and caused high levels of killing at 20 μg GAE well−1 when the other extracts had lost activity.

Fig. 2. Dose effects of selected berry extracts on Giardia viability. Trophozoites (2.7×104 trophozoites per well) were incubated for 24 h in the presence or absence of berry polyphenol extracts at various concentrations. Untreated trophozoites and metronidazole (67 μg ml−1) treated trophozoites were used as controls. Control metronidazole treatments caused 100% trophozoite mortality with a replication error averaging at 2.6% and all berry polyphenol extracts caused a dose-dependent reduction in trophozoite viability.

LC-MS analysis (Fig. 3) confirmed that ellagitannins were the predominant polyphenolic components in the cloudberry extracts (Table 1) but also identified significant amounts of benzoic acid and p-coumaric acid. As an example, the mass spectral properties leading to the identification of peak 6 as Sanguiin H6 are discussed in more detail in supplementary data (Supplementary Fig. S1, Online version only). Smaller amounts of flavonol derivatives (e.g. quercetin-3-O-glucuronide) could also be identified. The ellagitannin content of the cloudberry extract was estimated at approximately 72.0±1.4% compared to 44.1±0.8% for the less effective extract from the related arctic bramble. Although this value is only an estimate (calculated from a ratio of the peak area due to ellagitannins and ellagic acid divided by the total peak area of all identified phenolic components), it certainly reflects the higher content of non-ellagitannin contents such as anthocyanins in arctic bramble (see Supplementary data, Table S1).

Fig. 3. LC-MS trace of cloudberry extract. All peak assignments relate to Table 1. pCA, p-coumaric acid and BA, benzoic acid. The figure in the top right corner is the full-scale deflection value for the PDA.

Table 1. Putative identification of ellagitannin peaks in cloudberry extract

(All MS data are from negative mode ionization. The major signal is given in bold. Putative identifications are based on previous work on cloudberry (McDougall et al. Reference McDougall, Martinussen and Stewart2008, Reference McDougall, Kulkarni and Stewart2009) and previous literature (Mullen et al. Reference Mullen, Yokota, Lean and Crozier2003; Gasperotti et al. Reference Gasperotti, Masuero, Vrhovsek, Guella and Mattivi2010; Hager et al. Reference Hager, Howard, Liyanage, Lay and Prior2008). More detailed information about the identification of peak 6 as sanguiin H6 is shown in the Supplementary data (Fig. S1), Online version only.)

Indeed, the high ellagitannin content of cloudberry has been noted previously in this laboratory (McDougall et al. Reference McDougall, Martinussen and Stewart2008) and in previous work (Kähkönen et al. Reference Kähkönen, Hopia and Heinonen2001; Kopenen et al. Reference Koponen, Happonen, Mattila and Törrönen2007). For example, Kähkönen et al. (Reference Kähkönen, Hopia and Heinonen2001) estimated the ET content in different cloudberry samples that ranged from 65 to 88% of total phenol content. However, the ellagitannin content of arctic bramble has not been published previously.

DISCUSSION

Berry extracts have long been known to interfere with human microbial pathogens. One of the most widely known is the inhibitory effect of proanthocyanidins from cranberry (Howell et al. Reference Howell, Reed, Krueger, Winterbottom, Cunningham and Leahy2005), and lingonberry (Kontiokari et al. Reference Kontiokari, Sundqvist, Nuutinen, Pokka, Koskela and Uhari2001), on bacterial urinary tract infections. Berry extracts rich in ellagitannins have also been noted as being particularly effective against human pathogenic micro-organisms (Heinonen et al. Reference Heinonen2007) with cloudberry being the most effective against the widest range of bacteria and yeasts (Nohynek et al. Reference Nohynek, Alakomi, Kähkönen, Heinonen, Helander, Oksman-Caldentey and Puupponen-Pimiä2006). This builds on work that outlined anti-microbial activity of ellagitannins from other plant sources (Latte and Kolodziej, Reference Latte and Kolodziej2000; Asres et al. Reference Asres, Bucar, Edelsbrunner, Kartnig and Hoger2001; Machado et al. Reference Machado, Leal, Amaral, dos Santos, da Silva and Kuster2002; Parashar et al. Reference Parashar, Gupta, Gupta and Kumar2009, and reviewed by Yoshida et al. Reference Yoshida, Hatano, Ito, Okuda and Quideau2009).

Indeed, ellagitannin-rich extracts and purified ellagitannins have been reported to have effects on human protozoan parasites such as Trypanosoma (Shuaibu et al. Reference Shuaibu, Wuyep, Yanagi, Hirayama, Ichinose, Tanaka and Kouno2008), Plasmodium species (Dell'Agli et al. Reference Dell'Agli, Galli, Corbett, Taramelli, Lucantoni, Habluetzel, Maschi, Caruso, Giavarini, Romeo, Bhattacharya and Bosisio2009) and Leishmania species (Kolodziej and Kiderlen, Reference Kolodziej and Kiderlen2005). Ellagic acid, which can be formed by ellagitannin degradation, has also been shown to be effective against Plasmodium species in vivo and in vitro (Soh et al. Reference Soh, Witkowski, Olagnier, Nicolau, Berry and Benoit-Vical2009). Ellagic acid was also identified as an active anti-giardial agent in Rubus coriifolius (Alanis et al. Reference Alanis, Calzada, Cedillo-Rivera and Meckes2003). In addition, other studies have shown toxicity of ellagitannins against the nematode, C. elegans (Yamasaki et al. Reference Yamasaki, Sato, Mori, Mohamed, Fujii and Tsukioka2002).

Here we have shown that the polyphenol-rich extracts of strawberry, blackberry, cloudberry and arctic bramble were as effective as metronidazole in the in vitro killing of G. duodenalis trophozoites and that cloudberry proved to be the most effective. The minimum concentration of cloudberry phenolics found to be effective against Giardia trophozoites in this study was between 10 and 20 μg GAE per well (which equates to 33–66 μg ml−1). Considering that cloudberries can provide around 150 mg GAE/100 g fruit (approx. 1500 μg ml−1: Kähkönen et al. Reference Kähkönen, Hopia and Heinonen2001), the amount of phenolic material entering the small intestine could easily reach levels shown to be effective in vitro, even allowing for partial degradation in the stomach (Clifford and Scalbert, Reference Clifford and Scalbert2000). In studies with ileostomy volunteers, Gonzalez-Barrio et al. (Reference Gonzalez-Barrio, Borges, Mullen and Crozier2010) have shown that a large proportion of ingested raspberry polyphenols were recovered in ileal fluid and, moreover, about a quarter of the main ellagitannin component, Sanguiin H6, survived digestion in the upper gastrointestinal tract.

As well as having a high percentage of ellagitannins, cloudberries are notable for having substantial levels of unconjugated p-coumaric acid and benzoic acid (Maatta-Riihinen et al. Reference Maatta-Riihinen, Kamal-Eldin and Torronen2004). p-Coumaric acid has been shown to have a weak effect on Giardia trophozoites (Calzada and Alanis, Reference Calzada and Alanís2007) and the coumaric acid derivative (melilotoside) was identified as an active anti-giardial agent from Teloxys graveolens (Calzada et al. Reference Alanis, Calzada, Cedillo-Rivera and Meckes2003). The presence of p-coumaric and benzoic acid may potentiate the effects on Giardia caused by the ellagitannins but perhaps by a different and synergistic mechanism (Fyfe et al. Reference Fyfe, Armstrong and Stewart1998; Puupponen-Pimiä et al. Reference Puupponen-Pimiä, Nohynek, Meier, Kähkönen, Heinonen, Hopia and Oksman-Caldentey2001). In addition, quercetin derivatives, also identified in cloudberry, may also contribute to anti-giardial activity (Amaral et al. Reference Amaral, Ribeiro, Barbosa-Filho, Reis, Nascimento and Macedo2006; Calzada and Alanis Reference Calzada and Alanís2007).

In conclusion, this study has confirmed that berry polyphenols can influence Giardia survival in vitro and suggests that ellagitannins are most effective. Tannin-rich preparations may also have efficacious effects on diarrhoeal symptoms (Palombo, Reference Palombo2006) often associated with Giardia infection. Unlike many plant sources of anti-giardial agents (e.g. Amaral et al. Reference Amaral, Ribeiro, Barbosa-Filho, Reis, Nascimento and Macedo2006), berries are a natural and palatable foodstuff and therefore have few issues with toxicity, side effects or acceptance. However, further work is required to uncover whether these in vitro effects described here can be transferred to the in vivo situation and contribute to giardiasis treatment.

ACKNOWLEDGEMENTS

SCRI receives grant-in-aid from the Scottish Government Rural and Environment Research and Analysis Directorate (RERAD). In memoriam of Huw Vaughn Smith who sadly passed away in October 2010 and contributed greatly to parasitology and to the analysis presented in this manuscript.

References

REFERENCES

Alanis, A. D., Calzada, F., Cedillo-Rivera, R. and Meckes, M. (2003). Anti-protozoal activity of the constituents of Rubus coriifolius. Phytotherapy Research 17, 681682.CrossRefGoogle Scholar
Amaral, F. M. M., Ribeiro, M. N. S., Barbosa-Filho, J.-M., Reis, A. S., Nascimento, F. R. F. and Macedo, R. O. (2006). Plants and chemical constituents with giardicidal activity. Brazilian Journal of Pharmacognosy 16, 696720.CrossRefGoogle Scholar
Anthony, J.-P., Fyfe, L. and Smith, H. V. (2005). Plant essential oils - a resource for antiparasitic agents? Trends in Parasitology 21, 462468.CrossRefGoogle ScholarPubMed
Anthony, J.-P., Fyfe, L., Stewart, D., and McDougall, G. J. and Smith, H. V. (2007). The effect of blueberry extracts on Giardia duodenalis viability and spontaneous excystation of Cryptosporidium parvum oocysts, in vitro. Methods 42, 339348.CrossRefGoogle ScholarPubMed
Asres, K., Bucar, F., Edelsbrunner, S., Kartnig, T. and Hoger, G. (2001). Investigations on anti-mycobacterial activity of some Ethiopian medicinal plants. Phytotherapy Research 15, 323326.CrossRefGoogle Scholar
Calzada, F. and Alanís, A. D. (2007). Additional antiprotozoal flavonol glycosides of the aerial parts of Helianthemum glomeratum. Phytotherapy Research 21, 7880.CrossRefGoogle ScholarPubMed
Calzada, F., Cedillo-Rivera, R., Bye, R. and Mata, R. (2001). Geranins C and D, additional new anti-protozoal A-type proanthocyanidins from Geranium niveum. Planta Medica 67, 677680.CrossRefGoogle Scholar
Calzada, F. C., Velazquez, R., Cedillo-Rivera, R. and Esquivel, B. (2003). Antiprotozoal activity of the constituents of Teloxys graveolens. Phytotherapy Research 17, 731732.CrossRefGoogle ScholarPubMed
Clifford, M. N. and Scalbert, A. (2000). Ellagitannins–nature, occurrence and dietary burden. Journal of the Science of Food and Agriculture 80, 11181125.3.0.CO;2-9>CrossRefGoogle Scholar
Cox, F. E. G. (2002). History of human parasitology. Clinical Microbiology Reviews 15, 595612.CrossRefGoogle ScholarPubMed
Deighton, N., Brennan, R., Finn, C. and Davies, H. V. (2000). Antioxidant properties of domesticated and wild Rubus species. Journal of the Science of Food and Agriculture 80, 13071313.3.0.CO;2-P>CrossRefGoogle Scholar
Dell'Agli, M., Galli, G. V., Corbett, Y., Taramelli, D., Lucantoni, L., Habluetzel, A., Maschi, O., Caruso, D., Giavarini, F., Romeo, S., Bhattacharya, D. and Bosisio, E. (2009). Anti-plasmodial activity of Punica granatum L. fruit rind. Journal of Ethnopharmacology 125, 279285.CrossRefGoogle Scholar
Fyfe, L., Armstrong, F. and Stewart, J. (1998). Inhibition of Listeria monocytogenes and Salmonella enteriditis by combinations of plant oils and derivatives of benzoic acid: the development of synergistic antimicrobial combinations. International Journal of Antimicrobial Agents 9, 195199.CrossRefGoogle Scholar
Gasperotti, M., Masuero, D., Vrhovsek, U., Guella, G. and Mattivi, F. (2010). Profiling and accurate quantification of Rubus ellagitannins and ellagic acid conjugates using direct UPLC-Q-TOF HDMS and HPLC-DAD analysis. Journal of Agricultural and Food Chemistry 58, 46024616.CrossRefGoogle ScholarPubMed
Gonzalez-Barrio, R., Borges, G., Mullen, W. and Crozier, A. (2010). Bioavailability of anthocyanins and ellagitannins following consumption of raspberries by healthy humans and subjects with an ileostomy. Journal of Agricultural and Food Chemistry 58, 39333939.CrossRefGoogle ScholarPubMed
Hager, T. J., Howard, L. R., Liyanage, R., Lay, J. O. and Prior, R. L. (2008). Ellagitannin composition of blackberry as determined by HPLC–ESI–MS and MALDI–TOF–MS. Journal of Agricultural and Food Chemistry 56, 661669.CrossRefGoogle ScholarPubMed
Harris, J. C., Plummer, S., Turner, M. P. and Lloyd, D. (2000). The microaerophilic flagellate Giardia intestinalis: Allium sativum (garlic) is an effective antigiardial. Microbiology 146, 31193127.CrossRefGoogle ScholarPubMed
Harris, J. C., Plummer, S. and Lloyd, D. (2001). Antigiardial drugs. Applied Microbiology and Biotechnology 57, 614619.Google ScholarPubMed
Heinonen, M. (2007). Antioxidant activity and antimicrobial effect of berry phenolics - a Finnish perspective. Molecular Nutrition & Food Research 51, 684691.CrossRefGoogle ScholarPubMed
Howell, A. B., Reed, J. D., Krueger, C. D., Winterbottom, R., Cunningham, D. G. and Leahy, M. (2005). A-type cranberry proanthocyanidins and uropathogenic bacterial anti-adhesion activity. Phytochemistry 66, 22812291.CrossRefGoogle ScholarPubMed
Inge, P. M., Edson, C. M. and Farthing, M. J. M. (1988). Attachment of Giardia lamblia to rat intestinal epithelial cells. Gut 29, 795801.CrossRefGoogle ScholarPubMed
Jones, F. A. (1996). Herbs - useful plants. Their role in history and today. European Journal of Gastroenterology & Hepatology 8, 12271231.CrossRefGoogle ScholarPubMed
Kähkönen, M. P., Hopia, A. I. and Heinonen, M. (2001). Berry phenolics and their antioxidant activity. Journal of Agricultural and Food Chemistry 49, 40764082.CrossRefGoogle ScholarPubMed
Khan, I. A., Avery, M. A., Burandt, C. L., Goins, D. K., Mikell, J. R., Nash, T. E., Azadegan, A. and Walker, L. A. (2000). Anti-giardial activity of isoflavones from Dalbergia frutescens bark. Journal of Natural Products 63, 14141416.CrossRefGoogle Scholar
Kolodziej, H. and Kiderlen, A. F. (2005). Anti-leishmanial activity and immune modulatory effects of tannins and related compounds on Leishmania parasitised RAW 264.7 cells. Phytochemistry 66, 20562071.CrossRefGoogle Scholar
Kontiokari, T., Sundqvist, K., Nuutinen, M., Pokka, T., Koskela, M., and Uhari, M. (2001). Randomised trial of cranberry-lingonberry juice and Lactobacillus GG drink for the prevention of urinary tract infections in women. British Medical Journal 322, 15711573.CrossRefGoogle ScholarPubMed
Koponen, J. M., Happonen, A. M., Mattila, P. H. and Törrönen, A. R. (2007). Contents of anthocyanins and ellagitannins in selected foods consumed in Finland. Journal of Agricultural and Food Chemistry 55, 16121619.CrossRefGoogle ScholarPubMed
Latte, K. P. and Kolodziej, H. (2000). Antifungal effects of hydrolysable tannins and related compounds on dermatophytes, mould fungi and yeasts. Zeitschrift für Naturforschung C- A Journal of Biosciences 55, 467472.CrossRefGoogle ScholarPubMed
Lauwaet, T., Andersen, Y., Van de Ven, L., Eckmann, L. and Gillin, F. D. (2010). Rapid detachment of Giardia lamblia trophozoites as a mechanism of antimicrobial action of the isoflavone formononetin. Journal of Antimicrobial Chemotherapy 65, 531534.CrossRefGoogle ScholarPubMed
Lun, Z. R., Burri, C., Menzinger, M. and Kaminsky, R. (1994). Antiparasitic activity of diallyl trisulfide (Dasuansu) on human and animal pathogenic protozoa (Trypanosoma sp., Entamoeba histolytica and Giardia lamblia) in vitro. Annales de la Societe Belge de Medecine Tropicale 74, 5159.Google ScholarPubMed
Maatta-Riihinen, K. R., Kamal-Eldin, A. and Torronen, R. (2004). Identification and quantification of phenolic compounds in berries of Fragaria and Rubus species (family Roseaceae). Journal of Agricultural and Food Chemistry 52, 61786187.CrossRefGoogle Scholar
Machado, T. D., Leal, I. C. R., Amaral, A. C. F., dos Santos, K. R. N., da Silva, M. G. and Kuster, R. M. (2002). Antimicrobial ellagitannin of Punica granatum fruits. Journal of the Brazilian Chemical Society 13, 606610.CrossRefGoogle Scholar
McDougall, G. J., Kulkarni, N. N. and Stewart, D. (2009). Berry polyphenols inhibit pancreatic lipase activity in vitro. Food Chemistry 115, 193199.CrossRefGoogle Scholar
McDougall, G., Martinussen, I. and Stewart, D. (2008). Towards fruitful metabolomics: high throughput analyses of polyphenol composition in berries using direct infusion mass spectrometry. Journal of Chromatography B 871, 362369.CrossRefGoogle ScholarPubMed
Mullen, W., Yokota, T., Lean, M. E. J. and Crozier, A. (2003). Analysis of ellagitannins and conjugates of ellagic acid and quercetin in raspberry fruits by LC-MSn. Phytochemistry 64, 617624.CrossRefGoogle ScholarPubMed
Nohynek, L. J., Alakomi, H. L., Kähkönen, M. P., Heinonen, M., Helander, K. M., Oksman-Caldentey, K. M. and Puupponen-Pimiä, R. H. (2006). Berry phenolics: Antimicrobial properties and mechanisms of action against severe human pathogens. Nutrition and Cancer-an International Journal 54, 1832.CrossRefGoogle ScholarPubMed
Palombo, E. A. (2006). Phytochemicals from traditional medicinal plants used in the treatment of diarrhoea: modes of action and effects on intestinal function. Phytotherapy Research 20, 717724.CrossRefGoogle ScholarPubMed
Parashar, A., Gupta, C., Gupta, S. K. and Kumar, A. (2009). Antimicrobial ellagitannin from pomegranate (Punica granatum) fruits. International Journal of Fruit Science 9, 226231.CrossRefGoogle Scholar
Puupponen-Pimiä, R., Nohynek, L., Alakomi, H. L. and Oksman-Caldentey, K. M. (2005). Bioactive berry compounds – novel tools against human pathogens. Applied Microbiology and Biotechnology 67, 818.CrossRefGoogle ScholarPubMed
Puupponen-Pimiä, R., Nohynek, L., Hartmann-Schmidlin, S., Kähkönen, M., Heinonen, M., Maatta-Riihinen, K. and Oksman-Caldentey, K. M. (2005). Berry phenolics selectively inhibit the growth of intestinal pathogens. Journal of Applied Microbiology 98, 9911000.CrossRefGoogle ScholarPubMed
Puupponen-Pimiä, R., Nohynek, L., Meier, C., Kähkönen, M., Heinonen, M., Hopia, A. and Oksman-Caldentey, K.-M. (2001). Antimicrobial properties of phenolic compounds from berries. Journal of Applied Microbiology 90, 494507.CrossRefGoogle ScholarPubMed
Rossignol, J. F. (2010). Cryptosporidium and Giardia: treatment options and prospects for new drugs. Experimental Parasitology 124, 4553.CrossRefGoogle ScholarPubMed
Shuaibu, M. N., Wuyep, P. T. A., Yanagi, T., Hirayama, K., Ichinose, A., Tanaka, T. and Kouno, I. (2008). Trypanocidal activity of extracts and compounds from the stem bark of Anogeissus leiocarpus and Terminalia avicennoides. Parasitology Research 102, 697703.CrossRefGoogle ScholarPubMed
Soh, P. N., Witkowski, B., Olagnier, D., Nicolau, M. L., Berry, A. and Benoit-Vical, F. (2009). In vitro and in vivo properties of ellagic acid in malaria treatment. Antimicrobial Agents and Chemotherapy 53, 11001106.CrossRefGoogle ScholarPubMed
Soffar, S. A. and Mokhtar, G. M. (1991). Evaluation of the antiparasitic effect of aqueous garlic (Allium sativum) extract in Hymenolepiasis nana and giardiasis. Journal of the Egyptian Society of Parasitology 21, 497502.Google ScholarPubMed
Upcroft, J. A., Dunn, L. A., Wright, J. M., Benakli, K., Upcroft, P. and Vanelle, P. (2006). 5-Nitroimidazole drugs effective against metronidazole-resistant Trichomonas vaginalis and Giardia duodenalis. Antimicrobial Agents and Chemotherapy 50, 344347.CrossRefGoogle ScholarPubMed
Yamasaki, T., Sato, M., Mori, T., Mohamed, A. S. A., Fujii, K. and Tsukioka, J. (2002). Toxicity of tannins towards the free-living nematode Caenorhabditis elegans and the brine shrimp Artemia salina. Journal of Natural Toxins 11, 165171.Google ScholarPubMed
Yoshida, T., Hatano, T., Ito, H. and Okuda, T. (2009). Structural diversity and antimicrobial activities of ellagitannins. In Chemistry and Biology of Ellagitannins: An Underestimated Class of Bioactive Plant Polyphenols (ed. Quideau, S.), pp. 55–93. World Scientific Publishing, London, UK.CrossRefGoogle Scholar
Figure 0

Fig. 1. Effect of berry extracts on Giardia viability. Trophozoites (2.7×104 trophozoites per well) were incubated for 24 h in the presence or absence of berry polyphenol extracts at 50 μg GAE per well. Untreated trophozoites and metronidazole (67 μg ml−1) treated trophozoites were used as controls. All values are averages of triplicate experiments±standard error. All berry extracts significantly reduced the survival of G. duodenalis trophozoites when compared to untreated trophozoites (P⩽0.05).

Figure 1

Fig. 2. Dose effects of selected berry extracts on Giardia viability. Trophozoites (2.7×104 trophozoites per well) were incubated for 24 h in the presence or absence of berry polyphenol extracts at various concentrations. Untreated trophozoites and metronidazole (67 μg ml−1) treated trophozoites were used as controls. Control metronidazole treatments caused 100% trophozoite mortality with a replication error averaging at 2.6% and all berry polyphenol extracts caused a dose-dependent reduction in trophozoite viability.

Figure 2

Fig. 3. LC-MS trace of cloudberry extract. All peak assignments relate to Table 1. pCA, p-coumaric acid and BA, benzoic acid. The figure in the top right corner is the full-scale deflection value for the PDA.

Figure 3

Table 1. Putative identification of ellagitannin peaks in cloudberry extract

(All MS data are from negative mode ionization. The major signal is given in bold. Putative identifications are based on previous work on cloudberry (McDougall et al. 2008, 2009) and previous literature (Mullen et al.2003; Gasperotti et al.2010; Hager et al.2008). More detailed information about the identification of peak 6 as sanguiin H6 is shown in the Supplementary data (Fig. S1), Online version only.)
Supplementary material: PDF

Anthony Supplementary Material

Table1.pdf

Download Anthony Supplementary Material(PDF)
PDF 15.6 KB