New research reveals factors driving the evolution of remarkable eyes in deep-sea amphipods Hyperiid amphipods are a small but anatomically diverse group of shrimp-like crustaceans with remarkable adaptations for life in the ocean’s twilight zone. A team of researchers from MBARI, the Smithsonian National Museum of Natural History, GEOMAR, the University of Western Australia, and the Florida Museum of Natural History leveraged 30 years of video observations from MBARI’s robotic submersibles to study the evolution of eye complexity in hyperiid amphipods. The team recently published their findings in the Proceedings of the Royal Society B.Researchers mapped their observations of hyperiid amphipods against depth, association behavior (associating in orange, free-swimming in purple), and eye structure (complex in blue, simple in yellow, and reduced in green). Illustration courtesy of Vanessa StenversWhile water depth is an important factor in driving animal adaptations in the deep sea, scientists increasingly recognize that behavioral ecology may be just as important. Some hyperiid amphipods are symbiotic hitchhikers on gelatinous animals, while others have a free-swimming, predatory lifestyle. Combining a literature review, blackwater scuba photography, and submersible observations, the team has demonstrated that association behavior is linked to both eye diversity and camouflage.Approximately one-third of hyperiid genera have adopted a free-swimming lifestyle, challenging the longstanding assumption that these amphipods only live on or in close association with gelatinous animals. The evolution of a free-swimming lifestyle correlates with body transparency and eye structure in hyperiids living in the upper waters of the ocean’s twilight, or mesopelagic, zone. In this environment, free-swimming hyperiids need to see both prey and predators without being seen themselves. Without a gelatinous host for protection, they use body transparency to further hide from predators. Eyes cannot be made completely transparent because pigment is required to absorb light. Some hyperiids have managed to compress the eye structures containing visual pigments—their retinas—that could make them visible against the backdrop of downwelling light in these twilight waters. Free-swimming hyperiids that live in deeper waters of the midnight, or bathypelagic, zone, have evolved an opaque appearance. Here, a crimson color absorbs bioluminescent light produced by their neighbors and serves as camouflage. Hyperiids in these dark depths have reduced eyes adapted to see bright flashes of bioluminescence instead of the dim and low-contrast shadows of predators and prey in the upper mesopelagic zone.Hyperiid amphipods are abundant in the midwater environment. Recognizing the true abundance of free-swimming, predatory species requires scientists to reconsider the ecological role of hyperiids in midwater communities. These results underscore the value of direct observations for uncovering evolutionary and ecological processes in the largest living space on Earth. Research Publication:Stenvers, V.L., J.M. Hemmi, K.L. Schlining, R. Collins, L. Iannello, H.F. Waters, C.A. Choy, S.H.D. Haddock, B.H. Robison, H.-J. Hoving, K.J. Osborn. 2026. In situ observations reveal a link between association behaviour, camouflage, and eye complexity in midwater amphipods. Proceedings of the Royal Society B, 293: 20252837. https://doi.org/10.1098/rspb.2025.2837For additional information or images relating to this article, please email pressroom@mbari.org. Share Like this? Share it! Share on Facebook Share on Twitter Share on LinkedIn Share on Email
News Senior Scientist Francisco Chavez shares MBARI science at international conferences News Brief 07.10.26
News MBARI hosts Oceano Azul Foundation to develop new ocean science and conservation collaborations News Brief 07.01.26
News MBARI researchers participate in new conference dedicated to midwater science and technology News Brief 06.23.26