Etmopteridae bioluminescence: dorsal pattern specificity and aposematic use

• Published in: Zoological letters Vol. 5; no. 1; p. 9
• Main Authors: Duchatelet, Laurent, Pinte, Nicolas, Tomita, Taketeru, Sato, Keiichi, Mallefet, Jérôme
• Format: Journal Article
• Language: English
• Published: England BioMed Central Ltd 06.03.2019; BioMed Central; BMC
• Subjects: Aposematism; Bioluminescence; Camouflage; CAT scans; Communication; Computed tomography; Diagnostic imaging; Dorsal pattern; Etmopteridae; Fish; Glands; Intraspecific recognition; Luminescence; Magnetic resonance imaging; Morphology; Oceans; Organisms; Pelagic zone; Predation; Rostrum; Sharks; Skin; Spines; Venom; Venoms; Bioluminescence; Etmopteridae; Aposematism; Dorsal pattern; Spines; Intraspecific recognition
• ISSN: 2056-306X; 2056-306X
• DOI: 10.1186/s40851-019-0126-2

In the darkness of the ocean, an impressive number of taxa have evolved the capability to emit light. Many mesopelagic organisms emit a dim ventral glow that matches with the residual environmental light in order to camouflage themselves (counterillumination function). Sharks use their luminescence mainly for this purpose. Specific lateral marks have been observed in Etmopteridae sharks (one of the two known luminous shark families) suggesting an inter/intraspecific recognition. Conversely, dorsal luminescence patterns are rare within these deep-sea organisms. Here we report evidence that and have dorsal luminescence patterns. These dorsal patterns consist of specific lines of luminous organs, called photophores, on the rostrum, dorsal area and at periphery of the spine. This dorsal light seems to be in contrast with the counterilluminating role of ventral photophores. However, skin photophores surrounding the defensive dorsal spines show a precise pattern supporting an aposematism function for this bioluminescence. Using in situ imaging, morphological and histological analysis, we reconstructed the dorsal light emission pattern on these species, with an emphasis on the photogenic skin associated with the spine. Analyses of video footage validated, for the first time, the defensive function of the dorsal spines. Finally, we did not find evidence that Etmopteridae possess venomous spine-associated glands, present in Squalidae and Heterondontidae, via MRI and CT scans. This work highlights for the first time a species-specific luminous dorsal pattern in three deep-sea lanternsharks. We suggest an aposematic use of luminescence to reveal the presence of the dorsal spines. Despite the absence of venom apparatus, the defensive use of spines is documented for the first time in situ by video recordings.