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Placozoa

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Distribution of Placozoa (Kingdom: Animalia, Phylum: Placozoa), based on Eitel (2013) doi:10.1371/journal.pone.0057131

Bird neurons

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[1]

Primates

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 Primates 
 Haplorhini 
 Simiiformes 
 Catarrhini 
 Hominoidea 
 Hominidae 
 Homininae 
 Hominini 

humans (genus Homo)

chimpanzees (genus Pan)

 Gorillini 

gorillas (genus Gorilla)

orangutans (subfamily Ponginae)

gibbons (family Hylobatidae)

Old World monkeys (superfamily Cercopithecoidea)

New World monkeys (parvorder Platyrrhini)

 Tarsiiformes 

tarsiers (superfamily Tarsioidea)

 Strepsirrhini 
Lemuriformes[a] 

lemurs (superfamily Lemuroidea)

lorises and allies (superfamily Lorisoidea)

Animals that are monochromats

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Placentalia (placental mammals)

Existing Article

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It used to be confidently claimed that most mammals other than primates were monochromats. In the last half-century, however, evidence of at least dichromatic color vision in a number of mammalian orders has accumulated. While typical mammals are dichromats, with S and L cones, two of the orders of sea mammals, the pinnipeds (which includes the seal, sea lion, and walrus) and cetaceans (which includes dolphins and whales) clearly are cone monochromats, since the short-wavelength sensitive cone system is genetically disabled in these animals.[dubiousdiscuss] The same is true of the owl monkeys, genus Aotus.

Researchers Leo Peichl, Guenther Behrmann, and Ronald H. H. Kroeger report that of the many animal species studied, there are three carnivores that are cone monochromats: raccoon, crab-eating raccoon and kinkajou and a few rodents are cone monochromats because they are lacking the S-cone.[2] These researchers also report that the animal's living environment also plays a significant role in the animals' eyesight. They use the example of water depth and the smaller amount of sunlight that is visible as one continues to go down. They explain it as follows, "Depending on the type of water, the wavelengths penetrating deepest may be short (clear, blue ocean water) or long (turbid, brownish coastal or estuarine water.)" [2] Therefore, the variety of visible availability in some animals resulted in them losing their S-cone opsins.

Vertebrate visual opsins

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M/LWS - 490-570 nm duplicated in Haplorhini (dry-nosed primates) to M and L

SWS1 - 355-450 nm absent in all monotremes (platypus, echidna)

SWS2 - 400-490 nm - absent in all placental mammals and marsupials

Rh2 - 460-530 nm - absent in all mammals

Rh1 - 460-530 nm rhodopsin - dim-light vision

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Vertebrates are normally tetrachromats, with four-color vision (and four opsins), having inherited this condition from the first vertebrate. Jawed vertebrates (all vertebrates except lampreys and hagfish) also have rhodopsin for vision in low-light situations. All five opsins combined are generally known as the vertebrate opsins. One of these five opsins (Rh2, blue-green) was lost in the first mammal (or one of its ancestors) making the earliest mammals trichromats. The ancestor of monotremes (egg-laying mammals platypus and echidna) lost another opsin (SWS1, ultraviolet), making them dichromats, while the ancestor of live-bearing mammals (Theria = placental mammals + marsupials) lost the blue opsin SWS2, also making them dichromats. As a result, mammals are normally dichromats, with rod opsin (Rh1) and two cone opsins, LWS (green, yellow or red) and either SWS1 (ultraviolet, violet) in placental mammals, or SWS2 (blue) in egg-laying mammals.

In Haplorhini (tarsiers, monkeys, and apes, including humans) a gene duplication resulted in a high incidence of trichromacy, with LWS duplicated to M- and L-cone opsins.

Placental mammals are divided into three major clades, Xenarthra, Afrotheria, and Boreoeutheria. All xenarthrans are rod monochromats. They comprise sloths, anteaters and armadillos, and constitute the smallest of the three clades of placental mammals.

13 species of cetaceans (dolphins and whales) are rod monochromats. All other cetacians are S-cone monochromats.

[4][5]

Placental mammal opsins

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Cladogram 4

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Placentalia
Afrotheria

LWS

SWS1

RH1

Boreoeutheria

LWS

SWS1

RH1

Xenarthra

RH1

References

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  1. ^ Olkowicz, Seweryn; Kocourek, Martin; Lučan, Radek K.; Porteš, Michal; Fitch, W. Tecumseh; Herculano-Houzel, Suzana; Němec, Pavel (2016). "Birds have primate-like numbers of neurons in the forebrain". Proceedings of the National Academy of Sciences. 113 (26): 7255–7260. doi:10.1073/pnas.1517131113. ISSN 0027-8424.
  2. ^ a b Peichl, Leo; Behrmann, Gunther; Kroger, Ronald H. H. (April 2001). "For whales and seals the ocean is not blue: a visual pigment loss in marine mammals". European Journal of Neuroscience. 13 (8): 9. doi:10.1046/j.0953-816x.2001.01533.x. Retrieved 22 November 2013.
  3. ^ Mooney, Victoria L.; Szundi, Istvan; Lewis, James W.; Yan, Elsa C. Y.; Kliger, David S. (2012). "Schiff Base Protonation Changes in Siberian Hamster Ultraviolet Cone Pigment Photointermediates". Biochemistry. 51 (12): 2630–2637. doi:10.1021/bi300157r. ISSN 0006-2960.
  4. ^ Hunt, D. M.; Carvalho, L. S.; Cowing, J. A.; Davies, W. L. (2009). "Evolution and spectral tuning of visual pigments in birds and mammals". Philosophical Transactions of the Royal Society B: Biological Sciences. 364 (1531): 2941–2955. doi:10.1098/rstb.2009.0044. ISSN 0962-8436.
  5. ^ Trezise, Ann E.O.; Collin, Shaun P. (2005). "Opsins: Evolution in Waiting". Current Biology. 15 (19): R794–R796. doi:10.1016/j.cub.2005.09.025. ISSN 0960-9822. PMID 16213808.


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