The gustatory system allows animals to distinguish between safe and harmful food and to gauge different foods' nutritional value.
Digestive enzymes in saliva begin to dissolve food into base chemicals that are washed over the papillae and detected as tastes by the taste buds. The tongue is covered with thousands of small bumps called
papillae, which are visible to the naked eye. Within each papilla are hundreds of taste buds. As of the early 20th century, Western physiologists and psychologists believed that there were four basic tastes: sweetness, sourness, saltiness, and bitterness. The concept of a "savory" taste was not present in Western science at that time, but was postulated in Japanese research. One study found that salt and sour taste mechanisms both detect, in different ways, the presence of
sodium chloride (salt) in the mouth. Acids are also detected and perceived as sour. The detection of salt is important to many organisms, but especially mammals, as it serves a critical role in ion and water
homeostasis in the body. It is specifically needed in the
mammalian kidney as an osmotically active compound that facilitates passive re-uptake of water into the blood. Because of this, salt elicits a pleasant taste in most humans. Sour and salt tastes can be pleasant in small quantities, but in larger quantities become more and more unpleasant to taste. For sour taste, this presumably is because the sour taste can signal under-ripe fruit, rotten meat, and other spoiled foods, which can be dangerous to the body because of bacteria that grow in such media. Additionally, sour taste signals
acids, which can cause serious tissue damage. Sweet taste signals the presence of
carbohydrates in solution. Since carbohydrates have a very high
calorie count (saccharides have many bonds, therefore much energy), they are essential to the human body, which evolved to seek out the high-calorie foods. They are used as direct energy (
sugars) and storage of energy (
glycogen). Many non-carbohydrate molecules trigger a sweet response, leading to the development of many artificial sweeteners, including
saccharin,
sucralose, and
aspartame. It is still unclear how these substances activate the sweet receptors and what adaptative significance this has had. The savory taste (known in Japanese as ), identified by Japanese chemist
Kikunae Ikeda, signals the presence of the
amino acid L-glutamate. The amino acids in proteins are used in the body to build muscles and organs, and to transport molecules (
hemoglobin),
antibodies, and the organic catalysts known as
enzymes. These are all critical molecules, and it is important to have a steady supply of amino acids; consequently, savory tastes trigger a pleasurable response, encouraging the intake of
peptides and
proteins.
Pungency (piquancy or hotness) had traditionally been considered a sixth basic taste. In 2015, researchers suggested a new basic taste of
fatty acids called "fat taste", although "oleogustus" and "pinguis" have both been proposed as alternate terms.
Sweetness Sweetness, usually regarded as a pleasurable sensation, is produced by the presence of
sugars and substances that mimic sugar. Sweetness may be connected to
aldehydes and
ketones, which contain a
carbonyl group. Sweetness is detected by a variety of
G protein coupled receptors (GPCR) coupled to the
G protein gustducin found on the
taste buds. At least two different variants of the "sweetness receptors" must be activated for the brain to register sweetness. Compounds the brain senses as sweet are compounds that can bind with varying bond strength to two different sweetness receptors. These receptors are T1R2+3 (heterodimer) and T1R3 (homodimer), which account for all sweet sensing in humans and animals.
Taste detection thresholds for sweet substances are rated relative to
sucrose, which has an index of 1. This channel was identified in 2018 as
otopetrin 1 (OTOP1). The transfer of positive charge into the cell can itself trigger an electrical response. Some weak acids such as acetic acid can also penetrate taste cells; intracellular hydrogen ions inhibit potassium channels, which normally function to hyperpolarize the cell. By a combination of direct intake of hydrogen ions through OTOP1 ion channels (which itself depolarizes the cell) and the inhibition of the hyperpolarizing channel, sourness causes the taste cell to fire action potentials and release neurotransmitter. The most common foods with natural
sourness are
fruits, such as
lemon,
lime,
grape,
orange,
tamarind, and bitter
melon. Fermented foods, such as
wine,
vinegar or
yogurt, may have sour taste. Children show a greater enjoyment of sour flavors than adults, and
sour candy containing citric acid or
malic acid is common.
Saltiness Saltiness taste seems to have two components: a low-salt signal and a high-salt signal. The low-salt signal causes a sensation of deliciousness, while the high-salt signal typically causes the sensation of "too salty". The low-salt signal is understood to be caused by the
epithelial sodium channel (ENaC), which is composed of three subunits. ENaC in the taste cells allow sodium
cations to enter the cell. This on its own depolarizes the cell, and opens
voltage-dependent calcium channels, flooding the cell with positive calcium ions and leading to
neurotransmitter release. ENaC can be blocked by the drug
amiloride in many mammals, especially rats. The sensitivity of the low-salt taste to amiloride in humans is much less pronounced, leading to conjecture that there may be additional low-salt receptors besides ENaC to be discovered. as do the additional bitter ingredients found in some alcoholic beverages including
hops in
beer and
gentian in
bitters.
Quinine is also known for its bitter taste and is found in
tonic water. Bitterness is of interest to those who study
evolution, as well as various health researchers since a large number of natural bitter compounds are known to be toxic. The ability to detect bitter-tasting, toxic compounds at low thresholds is considered to provide an important protective function. Plant leaves often contain toxic compounds, and among
leaf-eating primates there is a tendency to prefer immature leaves, which tend to be higher in protein and lower in fiber and poisons than mature leaves. Amongst humans, various
food processing techniques are used worldwide to detoxify otherwise inedible foods and make them palatable. Furthermore, the use of fire, changes in diet, and avoidance of toxins has led to neutral evolution in human bitter sensitivity. This has allowed several loss of function mutations that has led to a reduced sensory capacity towards bitterness in humans when compared to other species. The threshold for stimulation of bitter taste by quinine averages a concentration of 8 μ
M (8 micromolar). The taste thresholds of other bitter substances are rated relative to quinine, which is thus given a reference index of 1. For example,
brucine has an index of 11, is thus perceived as intensely more bitter than quinine, and is detected at a much lower solution threshold. Research has shown that TAS2Rs (taste receptors, type 2, also known as T2Rs) such as
TAS2R38 coupled to the
G protein gustducin are responsible for the human ability to taste bitter substances. They are identified not only by their ability to taste for certain "bitter"
ligands, but also by the morphology of the receptor itself (surface bound, monomeric). Over 670 bitter-tasting compounds have been identified, on a
bitter database, of which over 200 have been assigned to one or more specific receptors. It is speculated that the selective constraints on the TAS2R family have been weakened due to the relatively high rate of mutation and pseudogenization. Researchers use two synthetic substances,
phenylthiocarbamide (PTC) and
6-n-propylthiouracil (PROP) to study the
genetics of bitter perception. These two substances taste bitter to some people, but are virtually tasteless to others. Among the tasters, some are so-called "
supertasters" to whom PTC and PROP are extremely bitter. The variation in sensitivity is determined by two common alleles at the TAS2R38 locus. This genetic variation in the ability to taste a substance has been a source of great interest to those who study genetics. Gustducin is made of three subunits. When it is activated by the GPCR, its subunits break apart and activate
phosphodiesterase, a nearby enzyme, which in turn converts a precursor within the cell into a secondary messenger, which closes potassium ion channels. Also, this secondary messenger can stimulate the
endoplasmic reticulum to release Ca2+ which contributes to depolarization. This leads to a build-up of potassium ions in the cell, depolarization, and neurotransmitter release. It is also possible for some bitter tastants to interact directly with the G protein, because of a structural similarity to the relevant GPCR. The most bitter substance known –
oligoporin D – stimulates the bitter taste receptor type TAS2R46 at the lowest concentrations 100 n
M (0.1 micromolar, approx. 63 millionths of a gram/liter).
Savoriness Savoriness, or umami, is an
appetitive taste. which is similar to the word "savory" that comes from the French for "tasty". is considered fundamental to many
East Asian cuisines, such as
Japanese cuisine. and or in ancient China. Umami was first studied in 1907 by
Ikeda isolating
dashi taste, which he identified as the chemical
monosodium glutamate (MSG). MSG is a sodium salt that produces a strong savory taste, especially combined with foods rich in
nucleotides such as meats, fish, nuts, and mushrooms. Some savory taste buds respond specifically to glutamate in the same way that "sweet" ones respond to sugar. Glutamate binds to a variant of
G protein coupled glutamate receptors. L-glutamate may bond to a type of GPCR known as a metabotropic glutamate receptor (
mGluR4) which causes the G-protein complex to activate the sensation of umami. ==Measuring relative tastes==