Overcoming deterrent metabolites by gaining essential nutrients: A lichen / snail case study Author Gadea, Alice ∗, & Univ Rennes, CNRS, ISCR (Institut des Sciences Chimiques de Rennes), UMR 6226, F- 35000 Rennes, France & Univ Rennes, CNRS, ECOBIO (Ecosystèmes, Biodiversité, évolution), UMR 6553, F- 35000 Rennes, France Author Charrier, Maryvonne Author Fanuel, Mathieu Author Clerc, Philippe Author Daugan, Corentin Author Sauvager, Aurélie Author Rogniaux, Hélène Author Boustie, Joël Author Lamer, Anne-Cécile Le Author Devehat, Françoise Lohézic - Le text Phytochemistry 2019 2019-08-31 164 86 93 http://dx.doi.org/10.1016/j.phytochem.2019.04.019 journal article 10.1016/j.phytochem.2019.04.019 1873-3700 10483014 2.1. Morphological and chemical characterisation of Usnea taylorii 2.1.1. Description of Usnea taylorii morphology Microscopic analysis of the fruticose lichen Usnea taylorii reveals a specific morphology that deserves a detailed description to better understand the location of metabolites ( Fig. 1a; a complete morphological description of the lichen is available in Text S1). Apothecia (the reproductive parts of the lichen) are located at the apex of the Usnea branches and are characterised by their large diameter ( 2–17 mm ) and their jet-black pigmented disc. In cross-section, underneath the black epithecium, asci containing spores are present in the hymenium, covering the algal layer ( Fig. 1b ). The thallus in cross-section shows a very thin cortex, protecting a discontinuous algal layer. The central axis of U. taylorii is divided into several smaller axial strands by the protruding medullae, which are surrounded by some algae. Between these axial strands, lax medulla is observed ( Fig. 1c ). 2.1.2. Chemical characterisation of Usnea taylorii The extraction yields with acetone ranged between 0.5 and 1.0% of specialised metabolites for the six replicates of dried lichen materials with a mean value of 0.8 ± 0.2%. Preliminary experiments showed that more than 95% of the specialised compounds were extracted from the lichen U. taylorii by rinsing intact air-dried thalli in acetone. Thalli had only one or two main specialised metabolites. The concentration of usnic acid ranged from 2.5 to 5.4 mg g −1 dry mass ( DM ) of lichen, with a mean value ± s.d. of 4.1 ± 1.1 mg g −1 DM (n = 6). Sugar and polyol profiling was also performed. A low diversity was observed, with only four metabolites quantified. Arabitol was the most important polyol, reaching 138.4 ± 25.8 mg g −1 DM (mean value ± s.d., Table S1 , Fig. 2 ). Preliminary LDI-MS analysis of an acetone extract of Usnea taylorii confirmed that the (+)-usnic acid was the only specialised metabolite detected through its deprotonated molecule ( m/z 343) along with a fragment ion at m/z 329 ([M-Me] - ) ( Fig. S1 ). Usnic acid was consequently imaged through the m/z 343 ion. D-arabitol, the major polyol quantified by GC, was also imaged by mass spectrometry. However, because D-arabitol does not absorb at the wavelength of the laser used for LDI-MSI, a MALDI matrix solution was sprayed on U. taylorii slices and images were obtained using MALDI-MSI (through its sodium adduct observed at m/z 175). Fig. 2. Chemical structures of the two main metabolites of Usnea taylorii : the specialised metabolite (+)-usnic acid and the primary metabolite (polyol) Darabitol. Fig. 3. Distribution of usnic acid ([M-H] - ion; m/z 343) in samples of U. taylorii . a. Intact branch; b. Grazed branch (cross sections); c. Intact apothecium, d. Grazed apothecium (longitudinal sections). Each panel features side by side the optical image of the lichen section (left side) and the mass spectrometry imaging results (right side). The grazing marks were highlighted by blue arrows. Intensity scale was adjusted to maximise the visualisation of usnic acid. (For interpretation of the references to colour in this figure legend, the reader is referred to the Web version of this article.) In situ LDI-MSI experiments applied to a slice of Usnea taylorii 's branch revealed that usnic acid was located in the peripheral layer of the thallus, i.e., in the cortex and in the uppermost parts of the medulla including the photobiont layer ( Fig. 3a ). Likewise, usnic acid was allocated to the external layers of the apothecium (epithecium, hymenium and the underside of the apothecium) ( Fig. 3c ). D-arabitol was present mainly in the lax medulla, the cortex and the algal layer ( Fig. 4a ), but occurred in lower intensities in the axial strands of the lichen branches. In apothecia, the signal corresponding to D-arabitol was stronger in the layer containing the lax medulla and algae than in the external layers of apothecium (epithecium and hymenium) ( Fig. 4b ). To perform a comparison between lichen parts eaten by snails or not, some branches and apothecia were sliced and analysed by LDI-MSI. Snails consumed parts of the cortex, the algal layer and the lax medulla of the branches. In apothecia, epithecium, hymenium as well as the underside of the apothecium were grazed. All these tissues contain usnic acid ( Fig. 3b and d ) and D-arabitol ( Fig. 4 ).