As more receptors are defined, researchers will further unlock the mechanics of taste. How the mind perceives these sensory signals is another matter.
Take a sip of milk, look in the mirror and stick out your tongue. The tiny pink bumps emerging from the creamy film coating your tongue are the mushroom-shaped, or fungiform, papillae that conceal many of your taste buds. These are the gateway to detecting the sweetness of a cake, the saltiness of a potato crisp, the meatiness of a steak, the bitterness of beer, and the sourness of a lemon.
The four types of papillae that speckle the tongue (see 'Taste discovery') give it a rough surface that helps move the food around as we chew. The filiform papillae simply detect texture, whereas the other three — fungiform, foliate and circumvallate — contain onion-shaped taste buds. Each taste bud is packed with taste cells, which are capped with sensors for the five basic tastes (although we may be able to detect other taste qualities too). Contrary to popular belief, every part of the tongue is sensitive to all five taste qualities — the once common 'tongue map' depicting specific regions for each taste was based on a misunderstanding in the early 1900s and is wrong.
In 1931, Arthur Fox, a chemist at US chemical giant DuPont, made a remarkable discoveryafter accidentally releasing a cloud of fine phenylthiocarbamide (PTC) crystals while transferring the powder to a bottle. A colleague commented that the compound tasted bitter, but Fox, in the midst of the powder cloud, tasted nothing. After testing friends, family and colleagues, Fox found that people are either 'tasters' or 'non-tasters' of PTC (ref. 1).Geneticist L. H. Snyder confirmed Fox's work and found that non-tasting is a recessive Mendelian trait. Later work uncovered a range of PTC sensitivity, suggesting the involvement of more than one gene in perceiving this bitter compound2.
It took almost seven decades to pinpoint the genes that encode taste receptors. It was widely believed that each taste cell carried sensors for several, if not all, of the five tastes, with the signals being decoded in the brain. But this made no sense to neuroscientist Charles Zuker, a Howard Hughes Medical Investigator now at Columbia University in New York. He couldn't understand why a cell could carry sensors for both sweet, signalling an energy-rich food, and bitter, which could warn of spoiled or toxic food — a mix-up could be lethal.
Zuker rejected this 'broad tuning' and assumed that the difference between a sweet and a bitter taste cell, for example, was the collection of receptors on its surface. He joined forces with geneticist Nicholas Ryba of the National Institute of Dental and Craniofacial Research in Bethesda, Maryland, and over the next 12 years they sought to discover the sensors for all five tastes (see 'Taste discovery').
In 2000, using the first draft of the human genome, Zuker and Ryba's team identified the first taste sensors: a family of G-protein-coupled receptors (GPCRs)3 on chromosome 5. These so-called Taste-2 receptors (T2Rs) can detect bitter tastes from a wide range of different chemical compounds, requiring a collection of sensors. Some T2Rs can detect only one bitter compound, but some can respond to more than 50 natural and synthetic bitter chemicals.
Each bitter taste cell carries from 4–11T2Rs — this variety, along with under-lying genetic variation, is thought to account for an individual's tolerance of bitter tastes. For example, variation in the gene encoding T2R38 modifies sensitivity to PTC, which correlates with sensitivity to bitter compounds in cabbage or Brussels sprouts4.
More than five teams were competing to find the sweet receptor.
The race was on to find the remaining taste receptors. In 2001, more than five teams were competing to find the sweet receptor and narrowed the candidates to a different family of GPCRs. These T1R receptors have a different structure from the T2Rs, including a bulky extracellular region that interacts with sweet molecules. Zuker and Ryba provided the decisive evidence by transforming a sweet-insensitive mouse into a sugar-loving one, showing that T1R2 and T1R3 combine to detect natural and artificial sweeteners5. Barely a year later, they also found that the combination of T1R1 and T1R3 receptors can detect all 20 amino acids found in nature6, sensing a taste described as umami or savoury (for example, in meat or cheese) that can be chemically distilled into the common food additive monosodium glutamate. The receptors for sweet, bitter and umami all use essentially the same signalling molecules to convey nutrient sensing to the brain.
In 2006, Zuker and Ryba discovered the PKD2L1 receptor7, which detects sourness — a high concentration of hydrogen ions, or acidity, found both unripe and spoiled foods. Sour taste cells also host the Car4 receptor8, which senses carbon dioxide — block this receptor and a carbonated beverage will taste flat (even though it might still feel bubbly). Finally, in 2010, Zuker and Ryba found that the epithelial sodium channel (ENaC) detects sodium salt9 (other salts, such as potassium chloride, probably have other receptors). Instead of GPCRs, salt and sour detection uses ion channels — proteins that shuttle sodium and hydrogen ions in and out of cells.
Five basic tastes are generally recognized but there may be others, and the hunt for receptors continues. In 2003, neuroscientist Robert Margolskee, then at the Mount Sinai School of Medicine in New York, showed that mice lacking the T1R3 receptor couldn't taste artificial sweeteners but still had an affinity for sugars, especially glucose, and could also perceive umami10. “It said very clearly to us there are two different sweet mechanisms,” he says.
But receptors don't tell the whole taste story. Zuker and Ryba are using the taste sensors already discovered to figure out, as Zuker says, “how the brain transforms detection into perception”.
Fox, A. L. Science 73, 14 (1931).
Snyder, L. H. Science 74, 151–152 (1931)
Chandrashekar, J. et al. Cell 100, 703–711 (2000).
Boyd, W. C. Science 112, 153 (1950).
Nelson, G. et al. Cell 106, 381–390 (2001).
Nelson G. et al. Nature 416, 199–202 (2002).
Huang, A. L. et al. Nature 442, 934–938 (2006).
Chandrashekar J. et al. Science 326, 443–445 (2009).
Chandrashekar, J. et al. Nature 464, 297–301 (2010).
Damak, S. et al. Science 301, 850–853 (2003).
Blakeslee, A. F. & A. L. Fox . J. Hered. 23, 97–107 (1932).
Fisher, R. A. et al. Nature 144, 750 (1939).
McLaughlin, S. K. et al. Nature 357, 563–569 (1992).
Wu, S. V. et al. Proc. Natl Acad. Sci. USA 99, 2392–2397 (2002).
Dyer, J. et al. Biochem. Soc. 33, 302–305 (2005).
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Cite this article
Trivedi, B. Gustatory system: The finer points of taste. Nature 486, S2–S3 (2012). https://doi.org/10.1038/486S2a
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