Apes (including
humans) and
Old World monkeys normally have only three types of cone cell, and are therefore
trichromats. However, human tetrachromacy is suspected to exist in a small percentage of the population. Trichromats have three types of cone cells, each type being sensitive to a corresponding portion of the spectrum as shown in the diagram. But at least one woman has been implied to be a tetrachromat. possibly indicating trichromacy, and suggesting they were able to create or re-enable a third opponent channel. This would support the theory that humans should be able to utilize a fourth opponent channel for tetrachromatic vision. However, the original publication's claims about plasticity in the optic nerve have also been disputed.
Tetrachromacy in carriers of CVD It has been theorized that females who carry
recessive opsin alleles that can cause
color vision deficiency (CVD, color blindness) could possess tetrachromacy. Female
carriers of anomalous trichromacy (mild color blindness) possess
heterozygous alleles of the genes that encode the
L-opsin or
M-opsin. These alleles often have a different
spectral sensitivity, so if the carrier expresses both opsin alleles, they may exhibit tetrachromacy. In humans, two
cone cell pigment genes are present on the The
classical type 2 opsin gene OPN1MW and
OPN1MW2. People with two X chromosomes could possess multiple cone cell pigments, perhaps born as full tetrachromats who have four simultaneously-functioning kinds of cone cell, each type with a specific pattern of responsiveness to different wavelengths of light in the range of the visible spectrum. One study suggested that 15% of the world's women might have the type of fourth cone whose sensitivity peak is between the standard red and green cones, theoretically giving a significant increase in color differentiation. Another study suggests that as many as 50% of women and 8% of men may have four photopigments and corresponding potentially increased chromatic discrimination. In 2010, after twenty years' study of women with four types of cones (non-functional tetrachromats), neuroscientist Gabriele Jordan identified a woman (subject
cDa29) who could detect a greater variety of colors than trichromats could, corresponding with a functional or "true" tetrachromat. Specifically, she has been shown to be a trichromat in the range 546–670 nm where people with normal vision are essentially dichromats due to negligible response of
S cones to those wavelengths. Thus, if
S cones of 'cDa29' provide independent color perception dimension as they normally do, that would confirm her being a tetrachromat when the whole spectrum is considered. Variation in cone pigment genes is widespread in most human populations, but the most prevalent and pronounced tetrachromacy would derive from female carriers of major red / green pigment anomalies, usually classed as forms of "
color blindness" (
protanomaly or
deuteranomaly). The biological basis for this phenomenon is
X-inactivation of heterozygotic alleles for retinal pigment genes, which is the same mechanism that gives the majority of female
New World monkeys trichromatic vision. In humans,
preliminary visual processing occurs in the neurons of the retina. It is not known how these nerves would respond to a new color channel: Whether they would handle it separately, or just combine it with one of the existing channels. Similarly, visual information leaves the eye by way of the optic nerve, and a variety of final image processing takes place in the brain; it is not known whether the optic nerve or the areas of the brain have any capacity to effectively respond if presented with a stimulus from a
new color signal. Tetrachromacy may also enhance vision in dim lighting, or in looking at a screen.
Conditional tetrachromacy Despite being trichromats, humans can experience slight tetrachromacy at low
light intensities, using their
mesopic vision. In mesopic vision, both
cone cells and
rod cells are active. While rods typically do not contribute to color vision, in these specific light conditions, they may give a small region of tetrachromacy in the color space. Human rod cell sensitivity is greatest at 500 nm (bluish-green) wavelength, which is significantly different from the peak
spectral sensitivity of the cones (typically 420, 530, and 560 nm).
Blocked tetrachromacy Although many birds are tetrachromats with a fourth color in the ultraviolet, humans cannot see ultraviolet light directly because the
lens of the eye blocks most light in the wavelength range of 300–400 nm; shorter wavelengths are blocked by the
cornea. The
photoreceptor cells of the
retina are sensitive to
near ultraviolet light, and people lacking a lens (a condition known as
aphakia) see near ultraviolet light (down to 300 nm) as whitish blue, or for some wavelengths, whitish violet, probably because all three types of cones are roughly equally sensitive to ultraviolet light (with blue cone cells slightly more sensitive). While an extended visible range does not denote tetrachromacy, some believe that visual pigments are available with sensitivity in
near-UV wavelengths that would enable tetrachromacy in the case of
aphakia. However, there is no peer-reviewed evidence supporting this claim. ==Other animals==