The snails and slugs used for experiments included species that occur sympatrically with A. thaliana (Arion fucus, Deroceras laeve, Deroceras reticulatum, Helix pomatia, Lehmannia marginata, Malacolimax tenellus, Helicella itala, Perforatella incarnata, Trochulus hispidus, Monacha cartusiana, Succinea putris, Xerolenta obvia), as well as one exotic species (Achatina fulica). All mollusks were cultivated in a climate chamber (Snijders scientific, Tilburg, The Netherlands), under constant humidity of 80%, a temperature of 16–20°C, and short day conditions (9.5 h light/13.5 h dark). All slugs and snails were collected around Jena (GPS: 50.92050°N, 11.61162°E) and Martinfeld (51.28634°N, 10.17949°E, Thuringia, Germany). No specific permissions or approvals were required for collecting slugs and snails at these locations and no dangered or protected species were collected. Achatina fulica is an important pest in many tropical countries and was provided by Dr. Gustavo Bonaventura. Different numbers of snails were separated in large plastic boxes (OKT easyfresh, Sternwede, Germany; 26.5×13×15 cm) dependent on their size. Slugs were maintained in smaller boxes (10.5×4×8 cm) and the number of individuals in one box depended on their size and social compatibility. Potatoes, lettuce and cucumber were provided, with the addition of cuttlebone for calcium (ArtNr.5050, TRIXIE Heimtierbedarf GmbH & Co. KG, Tarp, Germany). The food was changed twice a week and the boxes were cleaned and provided with fresh tissue paper and moistened with tap water.

Arabidopsis thaliana plants for experiments were grown in a standard growth substrate (Fruhstorfer Nullerde:vermiculite:sand, 8∶1:1) in a climate chamber (21°C, 55% relative humidity and 130 µmol m⁻²s⁻¹ photosynthetically active radiation) with a photoperiod of 10 h light/14 h dark.

Observations were made under short day conditions, 10 hours light (white light: 380–800 nm) and 14 hours dark (infrared light: 725–925 nm). D. reticulatum behavior was recorded using a Logitech Webcam 600 and the program Webcam XP. Four individuals were placed in a plastic box (26.5×13×15 cm) filled with soil, wood, stones and one A. thaliana (Col-0) plant. Every ten minutes, the behavior of D. reticulatum was recorded by taking a picture of the setup. Pictures were edited with Adobe Photoshop CS5 12.0 and converted into time-lapse videos with VirtualDub 1.9.11.0. File size was reduced using Mac X Free MP4 Video converter.

Locomotion mucus of different slugs and snails were collected by allowing them to crawl over pre-cleaned fastener (Velcro, http://www.velcro.com/Products/For-Fabrics/Sew-On/Sew-On.aspx) that was washed with water and 99% Ethanol and dried at 80°C for 5 h prior to use. To collect only freshly produced mucus, all slugs and snails were allowed to crawl over tissue paper before slime was collected. After initial screening, the analysis of D. reticulatum mucus was replicated four times. Phytohormones were extracted as described in [6]. In brief, the fastener (with and without mucus) was extracted with 1 mL Ethyl acetate (spiked with labeled internal standards for salicylic acid (50 ng per sample), abcisic acid (50 ng per sample), jasmonic acid (JA, 10 ng per sample) and JA-isoleucine (50 ng per sample)), vortexed for 10 min and centrifuged at 16.000 g. Supernatant was evaporated and re-dissolved in 200 µL 70% MeOH. LC-MS analysis was done as described [17]. Leaf treatments were done as described in GUS-staining experiments. Leaves were harvested at indicated time points, flash frozen in liquid nitrogen and extracted as described above, with the exception that 500 µL 70% MeOH was used for re-dissolving the dried leaf extracts.

PR1::GUS plants were provided by Philippe Reymond (Department of Plant Molecular Biology, University of Lausanne, CH-1015 Lausanne, Switzerland). Leaves of four weeks old A. thaliana PR1::GUS plants were wounded with a fabric pattern wheel and locomotion mucus was applied by allowing D. reticulatum to crawl over the wounded leaves. Wounding alone and application of water served as control. Water application was done by gently striking the leaf with one finger (with glove) to mimic slug movement. GUS staining was performed 48 h after treatments as described previously [7]. Briefly, leaves were incubated overnight at 37°C in X-Gluc solution (Sigma) and de-stained twice in 99% Ethanol, followed by incubation in chloral hydrate solution (80 g chloral hydrate, 10 ml glycerol, 30 ml water) until leaves were completely transparent. Pictures were taken with a Canon Powershot SD1000 camera (www.canon.de).

In addition to its well-known occurrence in plant tissues, SA is widely found in the animal kingdom. Mammals contain levels of SA in their blood and in addition to its origin from plant material; there is evidence that SA can be synthesized from ingested benzoic acid [27]. Whether the SA we found in the locomotion mucus of D. reticulatum is sequestered from plant material or synthesized via plant-derived benzoic acid by the slugs requires further work. Supplying food of D. reticulatum with labeled SA or precursors of SA will help to answer these questions. Since several genera of bacteria are known to synthesize SA [28], [29], this metabolite could also be provided by microbes living in the mucus of D. reticulatum. Treating D. reticulatum with antibiotics may reveal its potential microbial origin.

SA is an important plant hormone that regulates various aspects of plant growth and development, including regulation of photosynthesis [30]–[33] and cell expansion [34]. SA mediates plant defense against biotrophic and hemibiotrophic pathogens and some sucking insects [35]. Priming of SA-related defense responses increases disease resistance and plant fitness in the field [36]; however, activating the SA-pathway reduces plant growth and fitness in pathogen-free environments [37], [38]. These data demonstrate that SA can profoundly influence plant interactions with their environment. Whether SA provided by D. reticulatum to plant tissues changes plant growth or their resistance to pathogens and herbivores requires further research. When D. reticulatum was provided with A. thaliana as sole food source, the slugs supplied locomotion mucus for more than one day before they started consuming leaves (Video S1). It is tempting to speculate that the gap in feeding was caused by the time required to suppress anti-herbivore defenses via SA in the mucus. However, A. thaliana might also not present a suitable food source for D. reticulatum and our observations were done under very artificial conditions. Whether D. reticulatum applies mucus to other plant species prior to leaf consumption in natural settings and if this alters plant growth and defense against herbivores and pathogens requires further observations.

The potent analgesic and antipyretic activities of plant tissue extracts, such as willow bark, in humans had been known for many centuries before the identification of SA, as the likely active compound [39]. SA is also used as medical tinctures against warts [40], [41]. Interestingly, rubbing the slime of slugs over warts has been used as anti-wart treatments as described in folklore books in the 19^th century [42]. The concentration of SA that we found in the locomotion mucus of D. reticulatum is several orders of magnitude lower than that of in commercially available wart treatments. Other slug secretions, such as the thick mucus secreted by slugs as defense during attack, may contain higher concentrations of SA, which may justify its use as wart cures. These secretions are currently being investigated.