Biology:Parietal eye

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Short description: Part of the epithalamus
The parietal eye (very small grey oval between the regular eyes) of a juvenile bullfrog (Lithobates catesbeianus)
Adult green anole (Anolis carolinensis) clearly showing the parietal eye (small grey/clear oval) at the top of its head.
Parietal eye of the Merrem's Madagascar swift (Oplurus cyclurus) is surrounded by a black-and-white spot on the skin, giving it the "three-eyed" appearance

A parietal eye, also known as a third eye or pineal eye, is a part of the epithalamus present in some vertebrates. The eye is located at the top of the head, is photoreceptive and is associated with the pineal gland, regulating circadian rhythmicity and hormone production for thermoregulation.[1] The hole in the head which contains the eye is known as a pineal foramen or parietal foramen, since it is often enclosed by the parietal bones.

Presence in various animals

The parietal eye is found in the tuatara, most lizards, frogs, salamanders, certain bony fish, sharks, and lampreys.[2][3][4] It is absent in mammals, but was present in their closest extinct relatives, the therapsids, suggesting it was lost during the course of the mammalian evolution due to it being useless in endothermic animals.[5] It is also absent in the ancestrally endothermic ("warm-blooded") archosaurs such as birds. The parietal eye is also lost in ectothermic ("cold-blooded") archosaurs like crocodilians, and in turtles, which may be grouped with archosaurs in Archelosauria.[6] Despite being lepidosaurs, as lizards and tuatara are, snakes lack a parietal eye.[7][8]


The third eye, where present, is always much smaller than the main paired eyes, and, in living species, it is always covered by skin, and is usually not readily visible externally.[9]

The parietal eye is a part of the epithalamus, which can be divided into two major parts; the epiphysis (the pineal organ, or pineal gland if mostly endocrine) and the parapineal organ (often called the parietal eye, or if it is photoreceptive, the third eye). These structures arise as a single anterior evagination of the pineal organ or as a separate outgrowth of the roof of the diencephalon, but during development it divides into two more or less bilaterally symmetric organs which rotate their location to become a caudal pineal organ and a parapineal organ. In some species, it protrudes through the skull.[10][11] The parietal eye uses a different biochemical method of detecting light from that of rod cells or cone cells in a normal vertebrate eye.[12]

Many of the oldest fossil vertebrates, including ostracoderms, placoderms, crossopterygians, and even early tetrapods, had a socket in the skull that appears to have held a functional third eye. This socket remains as a foramen between the parietal bones even in many living amphibians and reptiles, although it has vanished in birds and mammals.

Lampreys have two parietal eyes, one that developed from the parapineal organ and the other from the pineal organ. These are one behind the other in the centre of the upper surface of the braincase. Because lampreys are among the most primitive of all living vertebrates, it is possible that this was the original condition among vertebrates, and may have allowed bottom-dwelling species to sense threats from above.[9]

Saniwa, an extinct varanid lizard, probably had two parietal eyes, one that developed from the pineal organ and the other from the parapineal organ. Saniwa is the only known jawed vertebrate to have both a pineal and a parapineal eye. In most vertebrates, the pineal organ forms the parietal eye, however, in lepidosaurs, it is formed from the parapineal organ, which suggests that Saniwa re-evolved the pineal eye.[13]

Comparative anatomy

The parietal eye of amphibians and reptiles appears relatively far forward in the skull; thus it may be surprising that the human pineal gland appears far away from this position, tucked away between the corpus callosum and cerebellum. Also the parietal bones, in humans, make up a portion of the rear of the skull, far from the eyes. To understand this, note that the parietal bones formed a part of the skull lying between the eyes in sarcopterygians and basal amphibians, but have moved further back in higher vertebrates.[14] Likewise, in the brain of the frog, the diencephalon, from which the pineal stalk arises, appears relatively further forward, as the cerebral hemispheres are smaller but the optic lobes are far more prominent than the human mesencephalon, which is part of the brain stem.[15] In humans the optic tract, commissure, and optic nerve bridge the substantial distance between eyes and diencephalon. Likewise the pineal stalk of Petromyzon elongates very considerably during metamorphosis.[16]

Analogs in other species

Crustaceans have a single eye atop the head as a nauplius (first-stage larva). The eye has a lens and senses the direction of light but cannot resolve more details in images. Later, more sophisticated segmented eyes develop on sides of the head while the initial eye stays for some time. So, it is possible to say that, at some stage of development, crustaceans also have a "third eye". Some species, like the brine shrimp, retain the primary eye, being three-eyed in the adult stage. Most arthropods have simple eyes, called ocelli, between their main, compound eyes.[17]

See also


  1. Eakin, R. M (1973). The Third Eye. Berkeley: University of California Press. 
  2. Dodt, Eberhard (1973). "The Parietal Eye (Pineal and Parietal Organs) of Lower Vertebrates" (in en). Visual Centers in the Brain. Handbook of Sensory Physiology. 7 / 3 / 3 B. Springer, Berlin, Heidelberg. pp. 113–140. doi:10.1007/978-3-642-65495-4_4. ISBN 9783642654978. 
  3. Uetz, Peter (2003-10-07). "Sphenodontidae". The EMBL reptile database. European Molecular Biology Laboratory, heidelberg. 
  4. Gundy, GC; Wurst, GZ (1976). "The occurrence of parietal eyes in recent Lacertilia (Reptilia)". Journal of Herpetology 10 (2): 113–121. doi:10.2307/1562791. 
  5. Benoit, Julien; Abdala, Fernando; Manger, Paul R.; Rubidge, Bruce S. (2016-03-17). "The Sixth Sense in Mammalian Forerunners: Variability of the Parietal Foramen and the Evolution of the Pineal Eye in South African Permo-Triassic Eutheriodont Therapsids". Acta Palaeontologica Polonica 61 (4): 777–789. doi:10.4202/app.00219.2015. ISSN 0567-7920. 
  6. Emerling, Christopher A. (2017-03-01). "Archelosaurian Color Vision, Parietal Eye Loss, and the Crocodylian Nocturnal Bottleneck". Molecular Biology and Evolution 34 (3): 666–676. doi:10.1093/molbev/msw265. ISSN 1537-1719. PMID 27940498. 
  7. Infectious diseases and pathology of reptiles : color atlas and text. Elliott R. Jacobson. Boca Raton. 2007. pp. 21. ISBN 978-1-4200-0403-8. OCLC 317753687. 
  8. Tosini, Gianluca (1997-10-01). "The pineal complex of reptiles: Physiological and behavioral roles". Ethology Ecology & Evolution - ETHOL ECOL EVOL 9 (4): 314. doi:10.1080/08927014.1997.9522875. 
  9. 9.0 9.1 Romer, Alfred Sherwood; Parsons, Thomas S. (1977). The Vertebrate Body. Philadelphia, PA: Holt-Saunders International. pp. 471–473. ISBN 978-0-03-910284-5. 
  10. Light-sensitive organs that evaginate from the diencephalon - NCBI
  11. Zug, George; Vitt, Laurie Vitt; Caldwell, Janalee (2002). Herpetology: An introductory biology of amphibians and reptiles (Second ed.). San Diego, CA: Academic Press. p. 75. ISBN 978-0-12-782622-6. 
  12. Xiong, Wei-Hong; Solessio, Eduardo C.; Yau, King-Wai (1998). "An unusual cGMP pathway underlying depolarizing light response of the vertebrate parietal-eye photoreceptor". Nature Neuroscience 1 (5): 359–365. doi:10.1038/1570. PMID 10196524. Retrieved 2007-02-22. 
  13. Smith, Krister T.; Bhullar, Bhart-Anjan S.; Köhler, Gunther; Habersetzer, Jörg (2 April 2018). "The only known jawed vertebrate with four eyes and the bauplan of the pineal complex". Current Biology 28 (7): 1101–1107.e2. doi:10.1016/j.cub.2018.02.021. ISSN 0960-9822. PMID 29614279. 
  15. "Edible Frog Brain Clipart". 
  16. Journal of morphology - Google Books. 1887. Retrieved 2011-09-08. 
  17. Mayer, Georg (2006-12-01). "Structure and development of onychophoran eyes: What is the ancestral visual organ in arthropods?". Arthropod Structure & Development 35 (4): 231–245. doi:10.1016/j.asd.2006.06.003. ISSN 1467-8039. PMID 18089073.