Métabolomique, effets biologiques et caractère invasif de la macroalgue Asparagopsis taxiformis

Greff, Stéphane

28 November 2016

Considérées comme des menaces pour les écosystèmes marins tropicaux et subtropicaux, les proliférations de macroalgues sont susceptibles de modifier le fonctionnement et la structure des récifs coralliens. Le genre Asparagopsis (Rhodophyta) est connu pour être largement distribué, introduit et parfois invasif dans certaines régions comme en Méditerranée occidentale. Le premier objectif était de corréler le métabolisme spécialisé et la bioactivité de l’algue à son génotype, et éventuellement à son caractère proliférant. Aucune corrélation génétique/métabolomique n’a été démontrée, ce qui laisse entendre que le métabolisme macroalgal serait principalement influencé par l'environnement et/ou sa flore microbienne associée. En milieu tempéré, A. taxiformis et A. armata présentent des signatures métabolomiques globalement similaires et associées à une bioactivité significativement plus importante qu'en milieu tropical. Cependant, même lorsqu’elle a été introduite, une même lignée génétique et un même phénotype chimique peuvent présenter des caractères proliférants opposés. En milieu tropical, les extraits de macroalgues testés in situ sur 4 espèces de coraux n'ont provoqué que de faibles blanchissements. En milieu tempéré, aucun effet biologique de l’algue n’a été enregistré sur le corail Astroides calycularis. Par contre des expériences en aquarium ont permis de montrer qu’A. taxiformis pouvait exprimer un métabolisme spécifique avec une bioactivité augmentée après 10 jours de contact avec ce corail. En conclusion, qu’elle soit indigène ou introduite, A. taxiformis exerce peu d’effets sur la santé des coraux, et le caractère invasif de cette algue reste une source de débat. / Considered as a major threat for sub–tropical and tropical ecosystems, macroalgal proliferations are susceptible to modify the structure and the functioning of coral reefs. The genus Asparagopsis (Rhodophyta) is known to be widespread, introduced and sometimes invasive in certain regions such as the Western Mediterranean Sea. The first objective of this thesis was to correlate the algal specialized metabolism and its bioactivity with its genotype, and eventually with its proliferation trait. No correlation between genetics and metabolomics has been demonstrated, which would suggest the main influence of environmental factors and/or the associated microbial diversity on the algal metabolism. In temperate regions, A. taxiformis and A. armata showed similar metabolomic fingerprints with bioactivities significantly higher than in tropical regions. However, even when it is introduced, a given genetic lineage and a given chemical phenotype can exhibit opposite proliferative traits. In tropical areas, algal extracts tested in situ on 4 coral species did not lead to any coral bleaching. In temperate areas, no biological effect of the alga was recorded on Astroides calycularis. However, some aquarium experiments allowed to show that A. taxiformis can express a specific metabolism, with an increased bioactivity after 10–days of contact with this coral. To conclude, either indigenous or introduced, A. taxiformis poorly affects corals’ health, and thus the invasiveness of this alga remains a matter of debate.

Asparagopsis

Empreintes métabolomiques

Bioactivité

Interactions macroalgue–corail

Asparagopsis

Metabolomic fingerprinting

Bioactivity

Coral–macroalgal interaction

Ethnobotany, Pharmacology, and Metabolomics of Antidiabetic Plants used by the Eeyou Istchee Cree, Lukomir Highlanders, and Q’eqchi’ Maya

Ferrier, Jonathan

15 January 2014

A study was undertaken of plants used for treatment of diabetic symptoms by traditional healers of the Eeyou Istchee Cree (Canada), Lukomir Highlanders (Bosnia & Herzegovina), and Q’eqchi’ Maya (Belize). All antidiabetic plants were ranked by syndromic importance value (SIV) based on 15 symptoms, all of which were recognized by the Cree and Maya and 8 by the Highlanders. The Cree used only 18 species, the Highlanders 41, and the Maya 150, numbers which reflect the diversity of flora in their region. Vaccinium (Ericaceae) was one of the few genera in all three regions and the only consensus genus between the Cree and Highlander study sites. The Q’eqchi’ Maya ethnobotany did not present any cross-cultural consensus genera with Cree or Highlander medicinal plants, perhaps due to major biogeographic differences. In ethnopharmacological studies, Vaccinium species and Q’eqchi’ antidiabetic plants were tested in an assay relevant to diabetes, the advanced glycation endproduct (AGE) inhibition assay. Boreal and tropical Vaccinium species were potent inhibitors of AGEs and demonstrated concentration dependent inhibition, with a half maximal inhibitory concentration (IC50) range of 5.93–100 µg/mL. Phenolic content ranged from 80.3 to 201 µg/mL in boreal samples and from 1470 to 2170 µg/mL in tropical samples. Tropical species have a greater phenolic content and AGE inhibition. Seven Q’eqchi’ antidiabetic plant species were tested and all plant extracts showed AGE-inhibition. The IC50s ranged from 40.8 to 733 µg/mL, and the most active was Tynanthus guatemalensis Donn.. Tynanthus guatemalensis IC50 was about fives times greater (less active) than the mean ± SE IC50 reported for six tropical Vaccinium species of Vaccinium (8.77 ± 0.79 μg/mL). The highest consensus and most active Maya antidiabetic plant, Tynanthus guatemalensis Donn. Sm. was discovered to be an important plant recorded in archeological artifacts from the Late Classic Maya period (~750 CE). Ancient Maya used a cross shaped sign (k’an glyph) as a decorative element on Late Classic polychrome vessels and murals. The sign was believed to be the xylem template for a plant used as a flavouring in cacao drinks. However, the plant was incorrectly identified in the literature as Pimenta dioica (L.) Merr. (common name: Allspice) based on a common name and aromatic plant quality – not from a botanical voucher specimen. Pimenta dioica wood does not have a cross shape visible in the xylem but a unique character visible after a cross section of T. guatemalensis, is the xylem's cross shape organization. Wood of T. guatemalensis' also has an "allspice" aroma. Tynanthus guatemalensis is most likely the true botanical template behind the ancient Maya k’an glyph and this finding would show the continuity of use of this medicinal plant from ancient to modern times. Vaccinium was selected for an in depth phytochemical analysis using modern metabolomic methods. Nuclear magnetic resonance (1H NMR) was used to evaluate leaf extract spectra to provide information on (1) the taxonomic identity and (2) quantities of bioactive metabolites across multiple sites. Spectra clearly differentiated leaf samples of V. angustifolium, V. boreale, V. corymbosum, V. macrocarpon, V. myrtilloides, V. myrtillus, V. ovalifolium, and V. uliginosum according to generic, subgeneric, specific, phenotypic circumscriptions. Quantification of chlorogenic acid and hyperoside were replicated with a method that is highly reproducible across multiple sites with different NMR equipment. This methodology provides an important new approach to taxonomy and quality control for plants and natural health products.

Ethnobotany

Pharmacology

Metabolomics

Lukomir, Bosnia and Herzegovina

Post war ethnobotany

Diabetes

Q'eqchi' Maya

Eeyou Istchee Cree

Advanced glycation endproducts

UPLC MS QTOF

Nuclear Magnetic Resonance (NMR)

Chemotaxonomy

Phylogenetic tree

Vaccinium

Ericaceae

Tynanthus guatemalensis

Allspice

Chibayal

K'an hieroglyph template

Lukomir Highlanders

Pimenta dioica

Cross-cultural ethnobotany

Toledo District Belize

Eeyou Istchee Territory

Traditional Medicine

Chemosystematics

Metabolomic fingerprinting

Metabolomic leafprinting

Ethnobotany, Pharmacology, and Metabolomics of Antidiabetic Plants used by the Eeyou Istchee Cree, Lukomir Highlanders, and Q’eqchi’ Maya

Ferrier, Jonathan

January 2014

A study was undertaken of plants used for treatment of diabetic symptoms by traditional healers of the Eeyou Istchee Cree (Canada), Lukomir Highlanders (Bosnia & Herzegovina), and Q’eqchi’ Maya (Belize). All antidiabetic plants were ranked by syndromic importance value (SIV) based on 15 symptoms, all of which were recognized by the Cree and Maya and 8 by the Highlanders. The Cree used only 18 species, the Highlanders 41, and the Maya 150, numbers which reflect the diversity of flora in their region. Vaccinium (Ericaceae) was one of the few genera in all three regions and the only consensus genus between the Cree and Highlander study sites. The Q’eqchi’ Maya ethnobotany did not present any cross-cultural consensus genera with Cree or Highlander medicinal plants, perhaps due to major biogeographic differences. In ethnopharmacological studies, Vaccinium species and Q’eqchi’ antidiabetic plants were tested in an assay relevant to diabetes, the advanced glycation endproduct (AGE) inhibition assay. Boreal and tropical Vaccinium species were potent inhibitors of AGEs and demonstrated concentration dependent inhibition, with a half maximal inhibitory concentration (IC50) range of 5.93–100 µg/mL. Phenolic content ranged from 80.3 to 201 µg/mL in boreal samples and from 1470 to 2170 µg/mL in tropical samples. Tropical species have a greater phenolic content and AGE inhibition. Seven Q’eqchi’ antidiabetic plant species were tested and all plant extracts showed AGE-inhibition. The IC50s ranged from 40.8 to 733 µg/mL, and the most active was Tynanthus guatemalensis Donn.. Tynanthus guatemalensis IC50 was about fives times greater (less active) than the mean ± SE IC50 reported for six tropical Vaccinium species of Vaccinium (8.77 ± 0.79 μg/mL). The highest consensus and most active Maya antidiabetic plant, Tynanthus guatemalensis Donn. Sm. was discovered to be an important plant recorded in archeological artifacts from the Late Classic Maya period (~750 CE). Ancient Maya used a cross shaped sign (k’an glyph) as a decorative element on Late Classic polychrome vessels and murals. The sign was believed to be the xylem template for a plant used as a flavouring in cacao drinks. However, the plant was incorrectly identified in the literature as Pimenta dioica (L.) Merr. (common name: Allspice) based on a common name and aromatic plant quality – not from a botanical voucher specimen. Pimenta dioica wood does not have a cross shape visible in the xylem but a unique character visible after a cross section of T. guatemalensis, is the xylem's cross shape organization. Wood of T. guatemalensis' also has an "allspice" aroma. Tynanthus guatemalensis is most likely the true botanical template behind the ancient Maya k’an glyph and this finding would show the continuity of use of this medicinal plant from ancient to modern times. Vaccinium was selected for an in depth phytochemical analysis using modern metabolomic methods. Nuclear magnetic resonance (1H NMR) was used to evaluate leaf extract spectra to provide information on (1) the taxonomic identity and (2) quantities of bioactive metabolites across multiple sites. Spectra clearly differentiated leaf samples of V. angustifolium, V. boreale, V. corymbosum, V. macrocarpon, V. myrtilloides, V. myrtillus, V. ovalifolium, and V. uliginosum according to generic, subgeneric, specific, phenotypic circumscriptions. Quantification of chlorogenic acid and hyperoside were replicated with a method that is highly reproducible across multiple sites with different NMR equipment. This methodology provides an important new approach to taxonomy and quality control for plants and natural health products.

Ethnobotany

Pharmacology

Metabolomics

Lukomir, Bosnia and Herzegovina

Post war ethnobotany

Diabetes

Q'eqchi' Maya

Eeyou Istchee Cree

Advanced glycation endproducts

UPLC MS QTOF

Nuclear Magnetic Resonance (NMR)

Chemotaxonomy

Phylogenetic tree

Vaccinium

Ericaceae

Tynanthus guatemalensis

Allspice

Chibayal

K'an hieroglyph template

Lukomir Highlanders

Pimenta dioica

Cross-cultural ethnobotany

Toledo District Belize

Eeyou Istchee Territory

Traditional Medicine

Chemosystematics

Metabolomic fingerprinting

Metabolomic leafprinting