Analysis of Lichen Metabolites, a Variety of Approaches

Pogam, Pierre Le; Herbette, Gaëtan; Boustié, Joël

doi:10.1007/978-81-322-2181-4_11

Cited by 11 publications

(11 citation statements)

References 205 publications

(151 reference statements)

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“…Valuation of lichens unique metabolites for therapeutic purposes is generating an increasing interest (Shukla et al, 2010) pledging for the development of refined dereplication tools to focus on minor and unknown metabolites. Liquid chromatography-electrospray ionisation-mass spectrometry (LC-ESI-MS) remains the most common dereplication approach in lichenology, often associated with detection in MS/MS or MS n mode (Le Pogam et al, 2015a). Since many lichen metabolites are shown to crystallise on the external surfaces of hyphae (Boustie et al, 2011), new trends in lichenology include in situ analysis to get information directly from the natural complex matrix (Le Pogam et al, 2015a).…”

Section: Introductionmentioning

confidence: 99%

In situDART-MS as a Versatile and Rapid Dereplication Tool in Lichenology: Chemical Fingerprinting ofOphioparma ventosa

et al. 2016

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Section: Introductionmentioning

confidence: 99%

In situDART-MS as a Versatile and Rapid Dereplication Tool in Lichenology: Chemical Fingerprinting ofOphioparma ventosa

et al. 2016

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“…Chemical analyses were performed in three routinely used solvent systems: A (toluene/ dioxane/ acetic acid: 180:45:5), B (n-hexane/MTBE/ formic acid-65:40:10) and C (toluene/ acetic acid-200:30) [16,17]. After brief drying, the plates are visualized on UV light (254 nm and 365 nm) and are sprayed with a stable solution of anisaldehyde sulfuric reagent (ANS: anisaldehyde/acetic acid/methanol/sulfuric acid-0.5:10:85:5) until wet, and then heated at 110ºC until development of spots, which were visualized on visible light [18]. We identified when possible the family class according to the colors and retention value (Rf).…”

Section: Thin-layer Chromatography (Tlc)mentioning

confidence: 99%

“…The plates were then eluted using two solvent systems: i) D (ethyl acetate/formic acid /acetic acid /water -100/11/11/27); ii) E (butanol-1/acetone/water-5/4/1) [16]. Then, plates were sprayed with two different spray reagents: thymol sulfuric acid [18] and anisaldehyde sulfuric acid (anisaldehyde/acetic acid/methanol/sulfuric acid-0.5:10:85:5).…”

Section: Thin-layer Chromatography (Tlc)mentioning

confidence: 99%

The Use of Anisaldehyde Sulfuric Acid as an Alternative Spray Reagent in TLC Analysis Reveals Three Classes of Compounds in the Genus <em>Usnea</em> Adans. (Parmeliaceae, lichenized Ascomycota)

Gerlach¹,

Gadea²,

Silveira³

et al. 2018

Preprint

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Presence and identity of secondary metabolites are two of the main components of lichen taxonomy. Aromatic compounds formed via the acetyl-polymalonate pathway are the most studied lichen substances. In addition, compounds derived from the mevalonic acid pathway (e.g. terpenes and steroids) are sometimes detected in the medulla. However, their identity and value as diagnostic characters in the genus Usnea are yet poorly understood despite the fact that they were mentioned in several taxonomical papers. We conclude that i) aside from the previously recognized polyphenolic compounds, carbohydrates and steroids are also detected in the medulla of some Usnea species; ii) the use of sulfuric anisaldehyde reagent greatly improves the detection of terpenes, carbohydrates and steroids compared with the sulfuric acid reagent routinely used in thin layer chromatography; iii) among carbohydrates, we detected arabitol and sucrose in the medulla; iv) steroids and terpenes remain unidentified and deserve further investigations.

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“…A further strategy to improve the information granted by the aforementioned separative techniques is the subsequent detection by mass spectrometry. If HPLC-MS of lichen extracts is now widely used for lichen dereplication, with the possible detection of xanthones, no TLC-MS reports have yet been made to the best of the authors’ knowledge [77]. To date, no standardized liquid chromatography-UV-mass spectrometry methodology has been published on lichen metabolites.…”

Section: Analytical Chemistry: From Detection To Structure Elucidamentioning

confidence: 99%

Xanthones of Lichen Source: A 2016 Update

Pogam

Boustié

2016

Molecules

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An update of xanthones encountered in lichens is proposed as more than 20 new xanthones have been described since the publication of the compendium of lichen metabolites by Huneck and Yoshimura in 1996. The last decades witnessed major advances regarding the elucidation of biosynthetic schemes leading to these fascinating compounds, accounting for the unique substitution patterns of a very vast majority of lichen xanthones. Besides a comprehensive analysis of the structures of xanthones described in lichens, their bioactivities and the emerging analytical strategies used to pinpoint them within lichens are presented here together with physico-chemical properties (including NMR data) as reported since 1996.

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Analysis of Lichen Metabolites, a Variety of Approaches

Cited by 11 publications

References 205 publications

In situDART-MS as a Versatile and Rapid Dereplication Tool in Lichenology: Chemical Fingerprinting ofOphioparma ventosa

In situDART-MS as a Versatile and Rapid Dereplication Tool in Lichenology: Chemical Fingerprinting ofOphioparma ventosa

The Use of Anisaldehyde Sulfuric Acid as an Alternative Spray Reagent in TLC Analysis Reveals Three Classes of Compounds in the Genus <em>Usnea</em> Adans. (Parmeliaceae, lichenized Ascomycota)

Xanthones of Lichen Source: A 2016 Update

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