OPN1LW

OPN1LW
Available structures
PDB	Ortholog search: PDBe RCSB
List of PDB id codes
	1KPX
Identifiers
Aliases	OPN1LW , CBBM, CBP, COD5, RCP, ROP, opsin 1 (cone pigments), long-wave-sensitive, opsin 1, long wave sensitive
External IDs	OMIM: 300822 MGI: 1097692 HomoloGene: 68064 GeneCards: OPN1LW
Gene location (Human)
Chr.	X chromosome (human)
End	154,159,032 bp
Gene location (Mouse)
Chr.	X chromosome (mouse)
End	73,194,366 bp
RNA expression pattern
	Top expressed in
	ganglionic eminence; ; blood; ; left uterine tube; ; lobe of thyroid gland; ; left lobe of thyroid gland; ; ascending aorta; ; prostate;
	Top expressed in
	retinal pigment epithelium; ; outer nuclear layer; ; knee joint; ; soleus muscle; ; skeletal muscle tissue; ; quadriceps femoris muscle; ; superior frontal gyrus; ; cerebellar cortex;
	More reference expression data
	More reference expression data
Gene ontology
Molecular function	G protein-coupled receptor activity ; photoreceptor activity ; signal transducer activity ; G protein-coupled photoreceptor activity ;
Cellular component	integral component of membrane ; integral component of plasma membrane ; membrane ; photoreceptor outer segment ; photoreceptor disc membrane ;
Biological process	positive regulation of cytokinesis ; signal transduction ; visual perception ; retinoid metabolic process ; response to stimulus ; phototransduction ; detection of visible light ; G protein-coupled receptor signaling pathway ; cellular response to light stimulus ;
	Sources:Amigo / QuickGO
Orthologs
	5956
	14539
	ENSG00000102076
	ENSMUSG00000031394
	P04000
	O35599
	NM_020061
	NM_008106
	NP_064445
	NP_032132
	Wikidata
View/Edit Human	View/Edit Mouse

Last updated September 04, 2023

OPN1LW is a gene on the X chromosome that encodes for long wave sensitive (LWS) opsin, or red cone photopigment.^[5] It is responsible for perception of visible light in the yellow-green range on the visible spectrum (around 500-570nm).^[6]^[7] The gene contains 6 exons with variability that induces shifts in the spectral range.^[8] OPN1LW is subject to homologous recombination with OPN1MW, as the two have very similar sequences.^[8] These recombinations can lead to various vision problems, such as red-green colourblindness and blue monochromacy.^[9] The protein encoded is a G-protein coupled receptor with embedded 11-cis-retinal, whose light excitation causes a cis-trans conformational change that begins the process of chemical signalling to the brain.^[10]

Gene

OPN1LW produces red-sensitive opsin, while its counterparts, OPN1MW and OPN1SW, produce green-sensitive and blue-sensitive opsin respectively.^[7] OPN1LW and OPN1MW are on the X chromosome at position Xq28.^[11] They are in a tandem array, composed of a single OPN1LW gene which is followed by one or more OPN1MW genes.^[11] The locus control region (LCR; OPSIN-LCR) regulates expression of both genes, with only the OPN1LW gene and nearby adjacent OPN1MW genes being expressed and contributing to the colour vision phenotype.^[11] The LCR can not reach further than the first or second OPN1MW genes in the array.^[11] The slight difference in OPN1LW and OPN1MW absorption spectra is due to a handful of amino acid differences between the two highly similar genes.^[8]

Exons

OPN1LW and OPN1MW both have six exons.^[8] Amino acid dimorphisms on exon 5 at positions 277 and 285 are the most influential on the spectral differences observed between LWS and MWS pigments.^[8] There are 3 amino acid changes on exon 5 for OPN1LW and OPN1MW that contribute to the spectral shift seen between their respective opsin: OPN1MW has phenylalanine at positions 277 and 309, and alanine at 285; OPN1LW have tyrosine at position 277 and 309, and threonine at position 285.^[8] The identity of the amino acids at these positions in exon 5 is what determines the gene as being M class or L class.^[8] On exon 3 at position 180 both genes can contain serine or alanine, but the presence of serine produces longer wavelength sensitivity, a consideration in the making of color-matching functions.^[8]^[12] Exon 4 has two spectral tuning positions: 230 for isoleucine (longer peak wavelength) or threonine, and 233 for alanine (longer peak wavelength) or serine.^[8]

Homologous recombination

The arrangement of OPN1LW and OPN1MW, as well as the high similarity of the two genes, allows for frequent recombination between the two.^[8] Unequal recombination between female X chromosomes during meiosis is the main cause of the varying number of OPN1LW genes and OPN1MW genes among individuals, as well as being the cause of inherited colour vision deficiencies.^[8] Recombination events usually begin with misalignment of an OPN1LW gene with an OPN1MW gene and are followed by a certain type of crossover, which can result in many different gene abnormalities. Crossover in regions between OPN1LW and OPN1MW genes can produce chromosome products with extra OPN1LW or OPN1MW genes on one chromosome and reduced OPN1LW or OPN1MW genes on the other chromosome.^[8] If crossover occurs within the misaligned genes of OPN1LW and OPN1MW, then a new array will be produced on each chromosome consisting of only partial pieces of the two genes.^[8] This would create colour vision deficiencies if either chromosome were passed onto a male offspring.^[8]

Protein

The LWS type I opsin is a G-protein coupled receptor (GPCR) protein with embedded 11-cis retinal.^[11] It is a transmembrane protein that has seven membrane domains, with the N-terminal being extracellular and the C-terminal being cytoplasmic.^[5] The LWS pigment has a maximum absorption of about 564nm, with an absorption range of around 500-570 nm.^[6] This opsin is known as the red opsin because it is the most sensitive to red light out of the three cone opsin types, not because its peak sensitivity is for red light.^[7] The peak absorption of 564nm actually falls in the yellow-green section of the visible light spectrum.^[7] When the protein comes in contact with light at a wavelength within its spectral range, the 11-cis-retinal chromophore becomes excited.^[10] The amount of energy in the light breaks the pi bond that holds the chromophore in its cis configuration, which causes photoisomerization and a shift to the trans configuration.^[10] This shift is what begins the chemical reaction sequence responsible for getting the LWS cone signal to the brain.^[10]

Function

LWS opsin resides in disks of the outer segment of LWS cone cells, which mediate photopic vision along with MWS and SWS cones.^[10]^[13] Cone representation in the retina is substantially smaller than rod representation, with the majority of cones localizing in the fovea.^[13] When light within the LWS opsin spectral range reaches the retina, the 11-cis-retinal chromophore within the opsin protein becomes excited.^[10] This excitation causes a conformational change in the protein and triggers a series of chemical reactions.^[10] This reaction series passes from the LWS cone cells into horizontal cells, bipolar cells, amacrine cells, and finally ganglion cells before continuing to the brain via the optic nerve.^[10] Ganglion cells compile the signal from the LWS cones with all other cone signals that occurred in response to the light that was seen, and pass the overall signal into the optic nerve.^[6] The cones themselves do not process colour, it is the brain that decides what colour is being seen by the signal combination it receives from the ganglion cells.^[10]

Evolutionary history

Before humans evolved to be a trichromatic species, our vision was dichromatic and consisted of only the OPN1LW and OPN1SW genes.^[8] OPN1LW is thought to have undergone a duplication event that lead to an extra copy of the gene, which then evolved independently to become OPN1MW.^[8] OPN1LW and OPN1MW share almost all of their DNA sequences, whereas OPN1LW and OPN1SW share less than half, suggesting that the long wave and medium wave genes diverged from each other much more recently than with OPN1SW.^[11] The emergence of OPN1MW is directly associated with dichromacy evolving to trichromacy.^[6] The presence of both LSW and MSW opsins improves colour recognition time, memorization for coloured objects, and distance-dependent discrimination, giving trichromatic organisms an evolutionary advantage over dichromatic organisms when searching for nutrient-rich food sources.^[6] Cone pigments are the product of ancestral visual pigments, which consisted of only cone cells and no rod cells.^[10] These ancestral cones evolved to become the cone cells we know today (LWS, MWS, SWS), as well as rod cells.^[10]

Vision impairments

Red-green colour blindness

Many genetic changes of the OPN1LW and/or OPN1MW genes can cause red-green colourblindness.^[9] The majority of these genetic changes involve recombination events between the highly similar genes of OPN1LW and OPN1MW, which can result in deletion of one or both of these genes.^[9] Recombination can also result in the creation of many different OPN1LW and OPN1MW chimeras, which are genes that are similar to the original, but have different spectral properties.^[14] Single base-pair changes in OPN1LW can also inflict red-green colourblindness, but this is uncommon.^[9] The severity of vision loss in a red-green colourblind individual is influenced by the Ser180Ala polymorphism.^[14]

Protanopia

Protanopia is caused by defective or total loss of the OPN1LW gene function, causing vision that is entirely dependent on OPN1MW and OPN1SW.^[8] Affected individuals have dichromatic vision, with the inability to fully differentiate between green, yellow, and red colour.^[8]

Protanomaly

Protanomaly occurs when a partially functional hybrid OPN1LW gene replaces the normal gene.^[9] Opsins made from these hybrid genes have abnormal spectral shifts that impair colour perception for colours in the OPN1LW spectrum.^[9] Protanomaly is one form of anomalous trichromacy.^[8]

Blue cone monochromacy

Blue cone monochromacy is caused by a loss of function of both OPN1LW and OPN1MW.^[9] This is commonly caused by mutations in the LCR, which would result in no expression of OPN1LW or OPN1MW.^[9] With this visual impairment, the individual can only see colours in the spectrum for SWS opsins, which fall in the blue range of light.^[9]

Related Research Articles

Rhodopsin, also known as visual purple, is a protein encoded by the RHO gene and a G-protein-coupled receptor (GPCR). It is the opsin of the rod cells in the retina and a light-sensitive receptor protein that triggers visual phototransduction in rods. Rhodopsin mediates dim light vision and thus is extremely sensitive to light. When rhodopsin is exposed to light, it immediately photobleaches. In humans, it is regenerated fully in about 30 minutes, after which the rods are more sensitive. Defects in the rhodopsin gene cause eye diseases such as retinitis pigmentosa and congenital stationary night blindness.

<span class="mw-page-title-main">Color vision</span> Ability to perceive differences in light frequency

Color vision, a feature of visual perception, is an ability to perceive differences between light composed of different frequencies independently of light intensity. Color perception is a part of the larger visual system and is mediated by a complex process between neurons that begins with differential stimulation of different types of photoreceptors by light entering the eye. Those photoreceptors then emit outputs that are propagated through many layers of neurons and then ultimately to the brain. Color vision is found in many animals and is mediated by similar underlying mechanisms with common types of biological molecules and a complex history of evolution in different animal taxa. In primates, color vision may have evolved under selective pressure for a variety of visual tasks including the foraging for nutritious young leaves, ripe fruit, and flowers, as well as detecting predator camouflage and emotional states in other primates.

<span class="mw-page-title-main">Tetrachromacy</span> Type of color vision with four types of cone cells

Tetrachromacy is the condition of possessing four independent channels for conveying color information, or possessing four types of cone cell in the eye. Organisms with tetrachromacy are called tetrachromats.

Trichromacy or trichromatism is the possessing of three independent channels for conveying color information, derived from the three different types of cone cells in the eye. Organisms with trichromacy are called trichromats.

<span class="mw-page-title-main">Cone cell</span> Photoreceptor cells responsible for color vision made to function in bright light

Cone cells, or cones, are photoreceptor cells in the retinas of vertebrates' eyes, including the human eye. They respond differently to light of different wavelengths, and the combination of their responses is responsible for color vision. Cones function best in relatively bright light, called the photopic region, as opposed to rod cells, which work better in dim light, or the scotopic region. Cone cells are densely packed in the fovea centralis, a 0.3 mm diameter rod-free area with very thin, densely packed cones which quickly reduce in number towards the periphery of the retina. Conversely, they are absent from the optic disc, contributing to the blind spot. There are about six to seven million cones in a human eye, with the highest concentration being towards the macula.

Monochromacy is the ability of organisms or machines to perceive only light intensity without respect to spectral composition. Such organisms and machines are colorblind in most the literal sense of the word. Organisms with monochromacy are called monochromats.

Retinal is a polyene chromophore. Retinal, bound to proteins called opsins, is the chemical basis of visual phototransduction, the light-detection stage of visual perception (vision).

Melanopsin is a type of photopigment belonging to a larger family of light-sensitive retinal proteins called opsins and encoded by the gene Opn4. In the mammalian retina, there are two additional categories of opsins, both involved in the formation of visual images: rhodopsin and photopsin in the rod and cone photoreceptor cells, respectively.

Animal opsins are G-protein-coupled receptors and a group of proteins made light-sensitive via a chromophore, typically retinal. When bound to retinal, opsins become Retinylidene proteins, but are usually still called opsins regardless. Most prominently, they are found in photoreceptor cells of the retina. Five classical groups of opsins are involved in vision, mediating the conversion of a photon of light into an electrochemical signal, the first step in the visual transduction cascade. Another opsin found in the mammalian retina, melanopsin, is involved in circadian rhythms and pupillary reflex but not in vision. Humans have in total nine opsins. Beside vision and light perception, opsins may also sense temperature, sound, or chemicals.

A locus control region (LCR) is a long-range cis-regulatory element that enhances expression of linked genes at distal chromatin sites. It functions in a copy number-dependent manner and is tissue-specific, as seen in the selective expression of β-globin genes in erythroid cells. Expression levels of genes can be modified by the LCR and gene-proximal elements, such as promoters, enhancers, and silencers. The LCR functions by recruiting chromatin-modifying, coactivator, and transcription complexes. Its sequence is conserved in many vertebrates, and conservation of specific sites may suggest importance in function. It has been compared to a super-enhancer as both perform long-range cis regulation via recruitment of the transcription complex.

Blue-sensitive opsin is a protein that in humans is encoded by the OPN1SW gene.

Peropsin, a visual pigment-like receptor, is a protein that in humans is encoded by the RRH gene. It belongs like other animal opsins to the G protein-coupled receptors. Even so, the first peropsins were already discovered in mice and humans in 1997, not much is known about them.

Green-sensitive opsin is a protein that in humans is encoded by the OPN1MW gene. OPN1MW2 is a similar opsin.

RPE-retinal G protein-coupled receptor also known as RGR-opsin is a protein that in humans is encoded by the RGR gene. RGR-opsin is a member of the rhodopsin-like receptor subfamily of GPCR. Like other opsins which bind retinaldehyde, it contains a conserved lysine residue in the seventh transmembrane domain. RGR-opsin comes in different isoforms produced by alternative splicing.

Retinal pigment epithelium-specific 65 kDa protein, also known as retinoid isomerohydrolase, is an enzyme of the vertebrate visual cycle that is encoded in humans by the RPE65 gene. RPE65 is expressed in the retinal pigment epithelium and is responsible for the conversion of all-trans-retinyl esters to 11-cis-retinol during phototransduction. 11-cis-retinol is then used in visual pigment regeneration in photoreceptor cells. RPE65 belongs to the carotenoid oxygenase family of enzymes.

Retinaldehyde-binding protein 1 (RLBP1) also known as cellular retinaldehyde-binding protein (CRALBP) is a 36-kD water-soluble protein that in humans is encoded by the RLBP1 gene.

The evolution of color vision in primates is highly unusual compared to most eutherian mammals. A remote vertebrate ancestor of primates possessed tetrachromacy, but nocturnal, warm-blooded, mammalian ancestors lost two of four cones in the retina at the time of dinosaurs. Most teleost fish, reptiles and birds are therefore tetrachromatic while most mammals are strictly dichromats, the exceptions being some primates and marsupials, who are trichromats, and many marine mammals, who are monochromats.

Blue cone monochromacy (BCM) is an inherited eye disease that causes severe color blindness, poor visual acuity, nystagmus and photophobia due to the absence of functional red (L) and green (M) cone photoreceptor cells in the retina. BCM is a recessive X-linked disease and almost exclusively affects males.

Congenital red–green color blindness is an inherited condition that is the root cause of the majority of cases of color blindness. It has no significant symptoms aside from its minor to moderate effect on color vision. It is caused by variation in the functionality of the red and/or green opsin proteins, which are the photosensitive pigment in the cone cells of the retina, which mediate color vision. Males are more likely to inherit red–green color blindness than females, because the genes for the relevant opsins are on the X chromosome. Screening for congenital red–green color blindness is typically performed with the Ishihara or similar color vision test. There is no cure for color blindness.

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.

References

1 2 3 GRCh38: Ensembl release 89: ENSG00000102076 - Ensembl, May 2017
1 2 3 GRCm38: Ensembl release 89: ENSMUSG00000031394 - Ensembl, May 2017
↑ "Human PubMed Reference:". National Center for Biotechnology Information, U.S. National Library of Medicine.
↑ "Mouse PubMed Reference:". National Center for Biotechnology Information, U.S. National Library of Medicine.
1 2 "OPN1LW opsin 1, long wave sensitive [Homo sapiens (human)]". NCBI. Retrieved November 16, 2017.
1 2 3 4 5 Hofmann L, Palczewski K (2015). "Advances in understanding the molecular basis of the first steps in color vision". Progress in Retinal and Eye Research. 49: 46–66. doi:10.1016/j.preteyeres.2015.07.004. PMC 4651776 . PMID 26187035.
1 2 3 4 Merbs SL, Nathans J (1992). "Absorption spectra of human cone pigments". Nature. 356 (6368): 433–5. Bibcode:1992Natur.356..433M. doi:10.1038/356433a0. PMID 1557124. S2CID 4238631.
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 Neitz J, Neitz M (2011). "The genetics of normal and defective color vision". Vision Research. 51 (7): 633–51. doi:10.1016/j.visres.2010.12.002. PMC 3075382 . PMID 21167193.
1 2 3 4 5 6 7 8 9 "OPN1LW gene". U.S National Library of Medicine. Genetics Home Reference. Retrieved November 29, 2017.
1 2 3 4 5 6 7 8 9 10 11 Imamoto Y, Shichida Y (2014). "Cone visual pigments". Biochimica et Biophysica Acta (BBA) - Bioenergetics. 1837 (5): 664–73. doi: 10.1016/j.bbabio.2013.08.009 . PMID 24021171.
1 2 3 4 5 6 Deeb SS (2006). "Genetics of variation in human color vision and the retinal cone mosaic". Current Opinion in Genetics & Development. 16 (3): 301–7. doi:10.1016/j.gde.2006.04.002. PMID 16647849.
↑ "Molecular genetics and single-gene dichromats". cvrl.ioo.ucl.ac.uk.
1 2 "Rods and cones of the human eye". Ask a Biologist. ASU School of Life Sciences. 14 April 2010. Retrieved November 29, 2017.
1 2 Deeb, SS (2005). "The molecular basis of variation in human color vision". Clinical Genetics. 67 (5): 369–377. doi:10.1111/j.1399-0004.2004.00343.x. PMID 15811001. S2CID 24105079.