Virginie Treyvaud Amiguet

A consensus ethnobotany of the Q’eqchi’ Maya of Southern Belize

An ethnobotany study in collaboration with Q’eqchi’ Maya healers of Southern Belize led to a collection of 169 medicinal plant species, belonging to 67 different families. The data show the use of a majority of species from primary or secondary semi-evergreen rainforests of Southern Belize, rather than weedy species. The medicinal uses of the plants were grouped into 17 usage categories. The frequency of use for each plant and the informant consensus factor for each usage category reveals a consensus among the healers on the use of plant species as well as on the diseases treated. These results suggest a well-defined medicinal tradition.ResumenUne étude ethnobotanique en collaboration avec les guérisseurs Mayas Q’eqchi’ du Sud du Belize a mené à la récolte de 169 espèces de plantes médicinales appartenant à 67 families différentes. Les données montrent l’utilisation d’une majorité d’espèces provenant des forêts tropicales humides primaires ou secondaires du Sud du Belize, plutôt que de mauvaises herbes. Les utilisations médicinales de ces plantes ont été classées dans 17 catégories d’usage. La fréquence d’utilisation de chaque plante et le facteur de consensus calculé pour chaque catégorie d’usage révèle un haut degré de consensus parmi les guérisseurs aussi bien pour l’utilisation des plantes que pour les maladies traitées par ces dernières. Ces résultats suggèrent une tradition médicinale bien définie.

Echinacea purpurea. Aerial Parts Contain Multiple Antiviral Compounds

Abstract Stems, leaves, and flowers of Echinacea purpurea. (L.) Moench (Heliantheae: Asteraceae) were fractionated by various solvents and the fractions evaluated for antiviral activity in relation to chemical composition and distribution within the plant. All of the aqueous fractions contained potent activity against herpes simplex virus and influenza virus. However, although some of this activity could be attributed to polysaccharide and cichoric acid components, their individual contributions could not account for the total antiviral activity; other potent antivirals must be present. In addition, the ethanol- and ethyl acetate–soluble fractions from leaves and stem contained an uncharacterized but potent antiviral photosensitizer, which was absent from the flower extract. None of the fractions, however, contained anti-rhinovirus activity. Thus, part of the alleged benefits of Echinacea purpurea. extracts can be attributed to the presence of anti-influenza and anti-HSV compounds, and some of these activities are likely to be present in various commercial tinctures, teas, capsules, and tablets.

Characterization of Antiviral Activities in Echinacea. Root Preparations

Abstract The roots of three commonly used taxa of Echinacea.—E. purpurea., E. pallida. var. pallida., and E. pallida. var. angustifolia.—were extracted and fractionated by means of accelerated solvent extraction to reflect the most commonly used methods for commercial preparations. These fractions were analyzed by HPLC for their content of caffeic acid derivatives and alkamides and for antiviral activities against three viruses often implicated in colds and influenza. Aqueous extracts of E. purpurea. root contained a relatively potent activity against herpes simplex virus (HSV) and influenza virus (FV) but not against rhinovirus (RV). These fractions had low amounts of caffeic acids and alkamides. The ethyl acetate fraction contained significant but weak activity against both HSV and FV and contained significant levels of cichoric acid. In contrast, E. pallida. var. angustifolia. gave no water-soluble antiviral activity, but the ethanolic and ethyl acetate fractions contained significant activity against all three viruses, and this activity correlated with the presence of alkamides. E. pallida. var. pallida., however, gave no antiviral activity in any of the fractions, and this observation accorded well with the near absence of the marker compounds. Thus, we have detected a relatively potent water-soluble antiviral activity in E. purpurea. root, together with the weaker antiviral cichoric acid; an antiviral alkamide fraction in E. pallida. var. angustifolia.; but no antiviral activity in E. pallida. var. pallida.. Therefore, different types of Echinacea. root preparations, such as tinctures, tablets, and teas, based on different species and extraction methods, would be expected to offer quite different antiviral profiles.

A regression analysis of q’eqchi’ Maya medicinal plants from southern Belize

A previous study provided a general quantitative analysis of 169 collected medicinal plants used by the Q’eqchi’ Maya healers of southern Belize. This paper is focused on a statistical analysis of this ethnobotanical information using the method developed by Moerman (1991). The residual values obtained from the regression analysis of the Q’eqchi’ medicinal plant species versus the species listed in the checklist of the vascular plants of Belize (Balick, Nee, and Atha, 2001) placed the Piperaceae, the Rubiaceae, and the Asteraceae in the first three ranks, and the Poaceae, the Cyperaceae, and the Orchidaceae in the last three ranks. The results were compared with three northern temperate regions (Kashmir, Korea, and North America) and three southern neotropical regions (Chiapas, Ecuador, and Veracruz). The coefficients of correlation between the checklist of vascular plants of Belize and the other six floras showed, as expected, high values for regions with similar climatic type. Thus, high correlations were determined between the tropical vegetation of Belize and those of Chiapas, Ecuador, and Veracruz. The coefficients were lower with the three temperate floras but still quite high. The same analysis was done with the medicinal plants only and led to much lower coefficients, but once again, the higher results were obtained for Chiapas and Veracruz. In this case, the last rank for Ecuador demonstrated that the selection of plants in traditional medicine by the indigenous people is a complex phenomenon which depends not only on the composition of the flora but also on culture-specific factors.RésuméUne précédente étude a fourni une analyse quantitative générale de 169 plantes médicinales utilisées par les guérisseurs Maya Q’eqchi’ du sud du Belize. Ce document se concentre sur l’analyse statistique des informations ethnobotaniques selon la méthode développée par Moerman (1991). Les valeurs résiduelles obtenues à partir des analyses de régression des plantes médicinales Q’eqchi’ vis-à-vis des espèces mentionnées dans la liste des plantes vasculaires du Belize (Balick, Nee, et Atha, 2001) ont placé les Piperacées, les Rubiacées et les Asteracées aux trois premières places, et les Poacées, les Cyperacées et les Orchidacées aux trois dernières places. Les résultats ont été comparés avec ceux de trois régions tempérées du nord (Cachemire, Corée, et Amérique du Nord) et de trois régions néotropicales du sud (Chiapas, Équateur, et Veracruz). Les coefficients de corrélation entre les plantes listées dans le manuel des plantes vasculaires du Belize et les six autres flores ont montré comme attendu de hautes valeurs pour les régions possédant un type climatique similaire. Ainsi, une haute corrélation a été démontrée entre la végétation tropicale du Belize et celles du Chiapas, de l’Équateur, et du Veracruz. Les coefficients étaient plus bas avec les trois régions tempérées mais tout de même passablement élevés. La même analyse a été effectuée avec les plantes médicinales et a mené à des coefficients beaucoup plus bas, mais encore une fois, les résultats les plus élevés ont été obtenus pour le Chiapas et le Veracruz. Dans ce cas, la dernière position de l’Équateur a souligné que la sélection des plantes par les indigènes dans la médecine traditionnelle est un phénomène complexe qui dépend non seulement de la composition de la flore mais aussi de facteurs spécifiques à la culture.

Disruption of fungal cell wall by antifungal Echinacea extracts

In addition to widespread use in reducing the symptoms of colds and flu, Echinacea is traditionally employed to treat fungal and bacterial infections. However, to date the mechanism of antimicrobial activity of Echinacea extracts remains unclear. We utilized a set of ∼4,600 viable gene deletion mutants of Saccharomyces cerevisiae to identify mutations that increase sensitivity to Echinacea. Thus, a set of chemical-genetic profiles for 16 different Echinacea treatments was generated, from which a consensus set of 23 Echinacea-sensitive mutants was identified. Of the 23 mutants, only 16 have a reported function. Ten of these 16 are involved in cell wall integrity/structure suggesting that a target for Echinacea is the fungal cell wall. Follow-up analyses revealed an increase in sonication-associated cell death in the yeasts S. cerevisiae and Cryptococcus neoformans after Echinacea extract treatments. Furthermore, fluorescence microscopy showed that Echinacea-treated S. cerevisiae was significantly more prone to cell wall damage than non-treated cells. This study further demonstrates the potential of gene deletion arrays to understand natural product antifungal mode of action and provides compelling evidence that the fungal cell wall is a target of Echinacea extracts and may thus explain the utility of this phytomedicine in treating mycoses.