,
Chamaeleo calyptratus. Structural green and blue colours are generated by overlaying chromatophore types to reflect filtered light. The term
chromatophore was adopted (following Sangiovanni's
chromoforo) as the name for pigment-bearing cells derived from the neural crest of cold-blooded
vertebrates and cephalopods. The word itself comes from the
Greek words '
() meaning "colour," and ' () meaning "bearing". In contrast, the word
chromatocyte ('''' () meaning "cell") was adopted for the cells responsible for colour found in birds and mammals. Only one such cell type, the
melanocyte, has been identified in these animals. It was only in the 1960s that chromatophores were well enough understood to enable them to be classified based on their appearance. This classification system persists to this day, even though the
biochemistry of the pigments may be more useful to a scientific understanding of how the cells function. Colour-producing molecules fall into two distinct classes:
biochromes and
structural colours or "schemochromes". The biochromes include true pigments, such as
carotenoids and
pteridines. These pigments selectively absorb parts of the
visible light spectrum that makes up white light while permitting other
wavelengths to reach the eye of the observer. Structural colours are produced by various combinations of diffraction, reflection or scattering of light from structures with a scale around a quarter of the wavelength of light. Many such structures interfere with some wavelengths (colours) of light and transmit others, simply because of their scale, so they often produce
iridescence by creating different colours when seen from different directions. Whereas all chromatophores contain pigments or reflecting structures (except when there has been a
mutation, as in
albinism), not all pigment-containing cells are chromatophores.
Haem, for example, is a biochrome responsible for the red appearance of blood. It is found primarily in
red blood cells (erythrocytes), which are generated in bone marrow throughout the life of an organism, rather than being formed during embryological development. Therefore, erythrocytes are not classified as chromatophores.
Xanthophores and erythrophores Chromatophores that contain large amounts of
yellow pteridine pigments are named xanthophores; those with mainly
red/
orange carotenoids are termed erythrophores. Therefore, the distinction between these chromatophore types is not always clear. Most chromatophores can generate pteridines from
guanosine triphosphate, but xanthophores appear to have supplemental biochemical pathways enabling them to accumulate yellow pigment. In contrast, carotenoids are
metabolised and transported to erythrophores. This was first demonstrated by rearing normally green frogs on a diet of
carotene-restricted
crickets. The absence of carotene in the frogs' diet meant that the red/orange carotenoid colour 'filter' was not present in their erythrophores. This made the frogs appear blue instead of green.
Iridophores and leucophores Iridophores, sometimes also called guanophores, are chromatophores that reflect light using plates of crystalline chemochromes made from
guanine. When illuminated they generate iridescent colours because of the constructive interference of light. Fish iridophores are typically stacked guanine plates separated by layers of cytoplasm to form microscopic, one-dimensional,
Bragg mirrors. Both the orientation and the optical thickness of the chemochrome determines the nature of the colour observed and can be highly regulated by different concentrations of the hormone, Acetylcholine (ACh). By using biochromes as coloured filters, iridophores create an optical effect known as
Tyndall or
Rayleigh scattering, producing bright-
blue or -
green colours. The key enzyme in melanin synthesis is
tyrosinase. When this protein is defective, no melanin can be generated resulting in certain types of albinism. In some amphibian species there are other pigments packaged alongside eumelanin. For example, a novel deep (wine) red-colour pigment was identified in the melanophores of
phyllomedusine frogs. Some species of anole lizards, such as the
Anolis grahami, use melanocytes in response to certain signals and hormonal changes, and is capable of becoming colors ranging from bright blue, brown, and black. This was subsequently identified as
pterorhodin, a pteridine
dimer that accumulates around eumelanin core, and it is also present in a variety of
tree frog species from
Australia and
Papua New Guinea. While it is likely that other lesser-studied species have complex melanophore pigments, it is nevertheless true that the majority of melanophores studied to date do contain eumelanin exclusively. Humans have only one class of pigment cell, the mammalian equivalent of melanophores, to generate skin, hair, and eye colour. For this reason, and because the large number and contrasting colour of the cells usually make them very easy to visualise, melanophores are by far the most widely studied chromatophore. However, there are differences between the biology of melanophores and that of
melanocytes. In addition to eumelanin, melanocytes can generate a yellow/red pigment called
phaeomelanin. '', generates its
violet stripe with an unusual type of chromatophore.
Cyanophores Nearly all the vibrant blues in animals and plants are created by
structural coloration rather than by pigments. However, some types of
Synchiropus splendidus do possess vesicles of a
cyan biochrome of unknown chemical structure in cells named cyanophores. and atypical
dichromatic chromatophores, named
erythro-iridophores have been described in
Pseudochromis diadema. == Pigment translocation ==