THE METAMORPHOSIS OF VISUAL SYSTEMS IN THE SEA LAMPREY

doi:10.1085/jgp.40.6.901

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ARTICLE

THE METAMORPHOSIS OF VISUAL SYSTEMS IN THE SEA LAMPREY

George Wald ¹

¹ From the Biological Laboratories, Harvard University, Cambridge

The life cycle of the sea lamprey, Petromyzon marinus, includestwo metamorphoses. At the end of a period spent as a blind larva,buried in the mud of streams, a first metamorphosis preparesit to migrate downstream to the sea or a lake for its growthphase. Then, following a second metamorphosis, it migrates upstreamas a sexually mature adult to spawn and die.

The downstreammigrants have a visual system based upon rhodopsin and vitaminA₁, whereas that of the upstream migrants is based upon porphyropsinand vitamin A₂. The livers contain vitamin A₁ at all stages.

Thesea lamprey therefore exhibits a metamorphosis of visual systems,like those observed earlier among amphibia. The presence ofporphyropsin in this member of the most primitive living groupof vertebrates, as in fishes and amphibia, supports the notionthat porphyropsin may have been the primitive vertebrate visualpigment. Its association with fresh water existence throughoutthis range of organisms also is consistent with the view thatthe vertebrate stock originated in fresh water. The observationthat in the life cycle of the lamprey rhodopsin precedes porphyropsinis not at variance with the idea that porphyropsin is the moreprimitive pigment, since this change is part of the second metamorphosis,marking the return to the original environment. The observationthat in lampreys, fishes, and amphibia, porphyropsin maintainsthe same general association with fresh water, and rhodopsinwith marine and terrestrial habit, suggests that a single geneticmechanism may govern this association throughout this wide spanof organisms.

Submitted on February 7, 1957

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