Vertebrate visual opsin explained

Vertebrate visual opsins are a subclass of ciliary opsins and mediate vision in vertebrates. They include the opsins in human rod and cone cells. They are often abbreviated to opsin, as they were the first opsins discovered and are still the most widely studied opsins.[1]

Opsins

See main article: opsin. Opsin refers strictly to the apoprotein (without bound retinal). When an opsin binds retinal to form a holoprotein, it is referred to as Retinylidene protein. However, the distinction is often ignored, and opsin may refer loosely to both (regardless of whether retinal is bound).

Opsins are G-protein-coupled receptors (GPCRs) and must bind retinal ⁠— typically 11-cis-retinal ⁠— in order to be photosensitive, since the retinal acts as the chromophore. When the Retinylidene protein absorbs a photon, the retinal isomerizes and is released by the opsin. The process that follows the isomerization and renewal of retinal is known as the visual cycle. Free 11-cis-retinal is photosensitive and carries its own spectral sensitivity of 380nm.[2] However, to trigger the phototransduction cascade, the process that underlies the visual signal, the retinal must be bound to an opsin when it is isomerized. The retinylidene protein has a spectral sensitivity that differs from that of free retinal and depends on the opsin sequence.

While opsins can only bind retinal, there are two forms of retinal that can act as the chromophore for vertebrate visual opsins:

Animals living on land and marine fish form their visual pigments exclusively with retinal 1. However, many freshwater fish and amphibians can also form visual pigments with retinal 2, depending on the activation of the enzyme retinal-3,4-desaturase (GO:0061899). Many of these species can switch between these chromophores during their life cycle, to adapt to a changing habitat.[3] [4]

Function

Isomerization of 11-cis-retinal into all-trans-retinal by light induces a conformational change in the protein that activates the phototransduction pathway.

Subclasses

There are two classes of vertebrate visual opsin, differentiated by whether they are expressed in rod or cone photoreceptors.

Cone opsins

Opsins expressed in cone cells are called cone opsins. The cone opsins are called photopsins when unbound to retinal and iodopsins when bound to retinal. Cone opsins mediate photopic vision (daylight). Cone opsins are further subdivided according to the spectral sensitivity of their iodopsin, namely the wavelength at which the highest light absorption is observed (λmax).

NameCellλ (nm)Human variant
Long-wave sensitiveLWSCone500–570OPN1LW "red" erythrolabe (564nm)
OPN1MW "green" chlorolabe (534nm)
Short-wave sensitive 1SWS1Cone355–445OPN1SW "blue" cyanolabe (420nm)
(extinct in monotremes)
Short-wave sensitive 2SWS2Cone400–470(extinct in therian mammals)
Rhodopsin-like 2Rh2Cone480–530(Extinct in mammals)

Rod opsins

See main article: rhodopsin. Opsins expressed in rod cells are called rod opsins. The rod opsins are called scotopsins when unbound to retinal and rhodopsins or porphyropsins when bound to retinal (1 and 2, respectively). Rod opsins mediate scotopic vision (dim light).[5] Compared to cone opsins, the spectral sensitivity of rhodopsin is quite stable, not deviating far from 500 nm in any vertebrate.

Evolution

Extant vertebrates typically have four cone opsin classes (LWS, SWS1, SWS2, and Rh2) as well as one rod opsin class (rhodopsin, Rh1), all of which were inherited from early vertebrate ancestors. These five classes of vertebrate visual opsins emerged through a series of gene duplications beginning with LWS and ending with Rh1, according to the cladogram to the right; this serves as an example of neofunctionalization. Each class has since evolved into numerous variants.[6] [7] Evolutionary relationships, deduced using the amino acid sequence of the opsins, are frequently used to categorize cone opsins into their respective class. Mammals lost Rh2 and SWS2 classes during the nocturnal bottleneck. Primate ancestors later developed two LWS opsins (LWS and MWS), leaving humans with 4 visual opsins in 3 classes.

History

George Wald received the 1967 Nobel Prize in Physiology or Medicine for his experiments in the 1950s that showed the difference in absorbance by these photopsins (see image).[8]

See also

Notes and References

  1. Terakita A . The opsins . Genome Biology . 6 . 3 . 213 . 1 March 2005 . 15774036 . 1088937 . 10.1186/gb-2005-6-3-213 . free .
  2. Fasick . Jeffry I. . Robinson . Phyllis R. . Adaptations of Cetacean Retinal Pigments to Aquatic Environments . Frontiers in Ecology and Evolution . 23 June 2016 . 4 . 10.3389/fevo.2016.00070. free .
  3. George Wald (1939): The Porphyropsin Visual System. In: The Journal of General Physiology. Bd. 22, S. 775–794. PDF
  4. Andrew T. C. Tsin & Janie M. Flores (1985): The in vivo Regeneration of Goldfish Rhodopsin and Porphyropsin. In: J. Exp. Biol. Bd. 122, S. 269–275. PMID 3723071 PDF
  5. Shichida Y, Matsuyama T . Evolution of opsins and phototransduction . Philosophical Transactions of the Royal Society of London. Series B, Biological Sciences . 364 . 1531 . 2881–2895 . October 2009 . 19720651 . 2781858 . 10.1098/rstb.2009.0051 .
  6. Hunt DM, Carvalho LS, Cowing JA, Davies WL . Evolution and spectral tuning of visual pigments in birds and mammals . Philosophical Transactions of the Royal Society of London. Series B, Biological Sciences . 364 . 1531 . 2941–2955 . October 2009 . 19720655 . 2781856 . 10.1098/rstb.2009.0044 .
  7. Trezise AE, Collin SP . Opsins: evolution in waiting . Current Biology . 15 . 19 . R794–R796 . October 2005 . 16213808 . 10.1016/j.cub.2005.09.025 . free . 2005CBio...15.R794T .
  8. Web site: The Nobel Foundation. The Nobel Prize in Physiology or Medicine 1967. Nobelprize.org. Nobel Media AB 2014. 12 December 2015.