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Salt taste is surprisingly mysterious

Too much sodium is bad, but so is too little — no wonder the body has two sensing mechanisms
Amber Dance
By Amber Dance
Dec. 10, 2023

We’ve all heard of the five tastes our tongues can detect — sweet, sour, bitter, savory-umami and salty. But the real number is actually six, because we have two separate salt-taste systems. One of them detects the attractive, relatively low levels of salt that make potato chips taste delicious. The other one registers high levels of salt — enough to make overly salted food offensive and deter overconsumption.

Exactly how our taste buds sense the two kinds of saltiness is a mystery that’s taken some 40 years of scientific inquiry to unravel, and researchers haven’t solved all the details yet. In fact, the more they look at salt sensation, the weirder it gets.

Many other have been worked out over the past 25 years. For sweet, bitter and umami, it’s known that molecular receptors on certain taste bud cells recognize the food molecules and, when activated, kick off a series of events that ultimately sends signals to the brain.

Sour is slightly different: It is , researchers recently learned.

In the case of salt, scientists understand many details about the low-salt receptor, but a complete description of the high-salt receptor has lagged, as has an understanding of which taste bud cells host each detector.

“There are a lot of gaps still in our knowledge — especially salt taste. I would call it one of the biggest gaps,” says Maik Behrens, a taste researcher at the Leibniz Institute for Food Systems Biology in Freising, Germany. “There are always missing pieces in the puzzle.”

A fine balance

Our dual perception of saltiness helps us to walk a tightrope between the two faces of sodium, an element that’s crucial for the function of muscles and nerves but dangerous in high quantities. To tightly control salt levels, the body manages the amount of sodium it lets out in urine, and controls how much comes in through the mouth.

“It’s the Goldilocks principle,” says Stephen Roper, a neuroscientist at the University of Miami Miller School of Medicine in Florida. “You don’t want too much; you don’t want too little; you want just the right amount.”

Our bodies need sodium to survive and function. The good-salt taste detects moderate levels of sodium and signals the brain that this is desirable. The second, bad-salt taste, which detects potentially harmful salt levels, works differently — perhaps by detecting sodium’s molecular partner, chloride.
Our bodies need sodium to survive and function. The good-salt taste detects moderate levels of sodium and signals the brain that this is desirable. The second, bad-salt taste, which detects potentially harmful salt levels, works differently — perhaps by detecting sodium’s molecular partner, chloride.

If an animal takes in too much salt, the body tries to compensate, holding on to water so the blood won’t be overly salty. In many people, that extra fluid volume raises blood pressure. The excess fluid puts strain on the arteries; over time, it can damage them and create the conditions for heart disease or stroke.

But some salt is necessary for body systems, for example to transmit electrical signals that underlie thoughts and sensations. Consequences of too little salt include muscle cramps and nausea — that’s why athletes chug Gatorade to replace the salt lost in sweat — and, if enough time passes, shock or death.

Scientists in search of salt taste receptors already knew that our bodies have special proteins that act as channels to allow sodium to cross nerve membranes for the purpose of sending nerve impulses. But the cells in our mouth, they reasoned, must have some additional, special way to respond to sodium in food.

A key clue to the mechanism came in the 1980s, when scientists experimented with a drug that prevents sodium from entering kidney cells. This drug, when applied to rats’ tongues, . Kidney cells, it turns out, use a molecule called ENaC (pronounced “ee-nack”) to suck extra sodium from blood and help maintain proper blood salt levels. The finding suggested that salt-sensing taste bud cells used ENaC too.

To prove it, scientists engineered mice to lack the ENaC channel in their taste buds. These mice for mildly salty solutions, the scientists reported in 2010 — confirming that ENaC was, indeed, the good-salt receptor.

Researchers measure a mouse’s taste preference for salt by recording how often it chooses to lick from a bottle containing a salty solution versus a bottle with plain water. At left, normal mice strongly favor salty water if the salt concentration is relatively low, while mice missing ENaC, the molecule that acts as a good-salt sensor, do not. At right, normal mice lose their preference for salty water when the salt concentration gets too high — but mice that lack bitter and sour taste systems (implicated in high-salt taste) keep consuming even the saltiest liquid.
Researchers measure a mouse’s taste preference for salt by recording how often it chooses to lick from a bottle containing a salty solution versus a bottle with plain water. At left, normal mice strongly favor salty water if the salt concentration is relatively low, while mice missing ENaC, the molecule that acts as a good-salt sensor, do not. At right, normal mice lose their preference for salty water when the salt concentration gets too high — but mice that lack bitter and sour taste systems (implicated in high-salt taste) keep consuming even the saltiest liquid.

So far, so good. But to truly understand how the good-salt taste worked, scientists would also need to know how the entry of sodium into taste buds is translated into a “Yum, salty!” sensation. “It’s what gets sent to the brain that’s important,” says Nick Ryba, a neuroscientist at the National Institute of Dental and Craniofacial Research in Bethesda, Maryland, who was involved in linking ENaC to salt taste.

And to understand that signal transmission, scientists needed to find where in the mouth the signal started.

The answer might seem obvious: The signal would start from the specific set of taste bud cells that contain ENaC and that are sensitive to tasty levels of sodium. But those cells didn’t prove simple to find. ENaC, it turns out, is made up of three different pieces, and although individual pieces are scientists had a hard time finding cells containing all three.

In 2020, a team led by physiologist Akiyuki Taruno at the Kyoto Prefectural University of Medicine in Japan reported that they had at last. The researchers started with the assumption that sodium-sensing cells would spark an electrical signal when salt was present, but not if the EnaC blocker was there too. They found just such a population of cells inside taste buds isolated from the middle of mouse tongues, and these turned out to make all three components of the ENaC sodium channel.

Scientists can thus now describe where and how animals perceive desirable levels of salt. When there are enough sodium ions outside those key taste bud cells in the mid-tongue area, the ions can enter these cells using the three-part ENaC gateway. This rebalances the sodium concentrations inside and outside the cells. But it also redistributes the levels of positive and negative charges across the cell’s membrane. This change activates an electrical signal inside the cell. The taste bud cell then sends the “Mmmm, salty!” message onward to the brain.

The pleasantly salty taste sensation is detected by sodium-sensing cells within taste buds on the tongue. Sodium ions enter these cells through a special sodium channel, a molecule called ENaC. The influx of positively charged sodium ions causes the taste cell to fire (or depolarize), sending a nerve signal to the brain.
The pleasantly salty taste sensation is detected by sodium-sensing cells within taste buds on the tongue. Sodium ions enter these cells through a special sodium channel, a molecule called ENaC. The influx of positively charged sodium ions causes the taste cell to fire (or depolarize), sending a nerve signal to the brain.

Too salty!

But this system doesn’t explain the “Blech, too much salt!” signal that people also can get, usually when we taste something that’s more than twice as salty as our blood. Here, the story is less clear.

The other component of salt — chloride — , some studies suggest. Recall that salt’s chemical structure is sodium chloride, though when dissolved in water it separates into positively charged sodium ions and negatively charged chloride ions. Sodium chloride creates the saltiest high-salt sensation, while sodium paired with larger, multi-atom partners tastes less salty. This suggests that sodium’s partner might be an important contributor to the high-salt sensation, with some partners tasting saltier than others. But as to exactly how chloride might cause high-salt taste, “Nobody has a clue,” says Roper.

One hint came from work by Ryba and colleagues with an ingredient of mustard oil: In 2013, they reported that this component in mouse tongues. Weirdly, the same mustard-oil compound also nearly eliminated the tongue’s response to bitter taste, as if the high-salt-sensing system was piggybacking onto the bitter-tasting system.

And it got odder still: Sour-taste cells seemed to respond to high salt levels, too. Mice lacking one or the other of the bitter- or sour-taste systems were less put off by extremely salty water, while those lacking both happily slurped down the salty stuff.

Not all scientists are convinced, but the findings, if confirmed, raise an interesting question: Why don’t super-salty things taste bitter and sour too? It could be because the too-salty taste is the sum of multiple signals, not just one input, says Michael Gordon, a neuroscientist at the University of British Columbia in Vancouver, who coauthored, with Taruno, a discussion of the in the 2023 Annual Review of Physiology.

Despite the mustard oil lead, attempts to find the receptor molecule responsible for the high-salt taste sensation have so far been inconclusive. In 2021, a Japanese team reported that cells containing TMC4 — a molecular channel that lets chloride ions into cells — in lab dishes. But when the researchers engineered mice without the TMC4 channel anywhere in their bodies, it didn’t make much difference to their aversion to extremely salty water. “There’s no definitive answer at this point,” Gordon says.

As a further complication, there’s no way to be sure that mice perceive salty tastes in exactly the same way that people do. “Our knowledge of salt taste in humans is actually quite limited,” says Gordon. People can certainly distinguish desirable, lower-salt levels from the foul, high-salt sensation, and the same ENaC receptor used by mice . But studies with the ENaC sodium channel blocker in people , sometimes seeming to diminish salt taste but other times to enhance it.

A possible explanation is the fact that people have a fourth, extra piece of ENaC, called the delta subunit, that rodents lack. It can take the place of one of the other pieces, perhaps making a version of the channel that is .

Forty years into investigations of salt taste, researchers are still left with questions about how people’s tongues perceive salt and how the brain sorts those sensations into “just right” versus “too much” amounts. At stake is more than just satisfying a scientific curiosity: Given the cardiovascular risks that a high-salt diet poses to some of us, it’s important to understand the process.

Researchers even dream of developing better salt alternatives or enhancers that would create the “yum” without the health risks. But it’s clear they have more work to do before they invent something we can sprinkle on our dinner plates with abandon, free of health worries.

This article originally appeared in , an independent journalistic endeavor from Annual Reviews.

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Amber Dance
Amber Dance

Amber Dance has been working from home since 2008.

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