Our Moods, Our Foods

Have you ever wondered why you sometimes have good days and bad days, or are in good or bad mood? Can there be a connection between the food you eat and how you feel afterwards?

You don’t need a study to tell you the obvious: we see a lot of people all around us who just aren't feeling the love. Such people could be our coworkers, the impatient people in the supermarket, and aggressive and vindictive drivers. In the United States, it is estimated that nearly 21 million adults suffer from mood disorders and about 40 million people have anxiety disorders. Stop for a moment and reflect on how food affects your mood [1].
Do you sometimes feel fuzzy-headed and sleepy after lunch? This is due to the increase in blood sugar level which suppresses orexin; a neuropeptide linked to alertness [1]. On the contrary, when your blood sugar level is low due to hunger, more primitive brain regions take charge and you are more likely to be impatient and easily irritated [2].

Source:  http://bit.ly/1OvEDhe

Eating specific foods affects brain chemicals and eating patterns also affect blood sugar levels, both of which play a role in mood. However, the connection between food and mood not only depends on blood sugar fluctuations, but also on the quality and quantity of nutrients in the diet [1,3]. Our mood is just like our bodies: better enhanced with fresh, whole foods containing proteins, vitamins and minerals. Everything we eat affects the synthesis of neurotransmitters and hormones and the quality of our synaptic connections. These together go a long way to influence how we respond to stress and the demands of daily life [3].

Eating Yourself Happier
Making certain changes in one's diet may help to improve mood: Eating regular meals, especially breakfast and choosing positive mood foods containing tryptophan (essential for the synthesis of serotonin, a neurotransmitter important for a positive affect) can influence one’s mood positively. In addition to eating tryptophan-containing foods, the intake of carbohydrates, vitamins, and minerals which help the uptake of serotonin is also highly recommended. A late night snack can actually help you fall asleep!

WHAT YOU EAT DEFINES YOUR MOOD

 
A study conducted at the University of Otago, Dunedin, New Zealand, shows that fruit and vegetable consumption may contribute to a well-being state and hence positive affect. They reported that there is a correlation between eating more fruits and vegetables to the state of well-being, curiosity, and creativity [3]. One possible biological mechanism underlying the relation between the intake of fruits and vegetables to a greater positive affect and well-being is the fact that vitamins B and C are cofactors for the synthesis of dopamine; a neurotransmitter responsible for motivation and greater engagement. In addition, the antioxidants found in fruits and vegetables are known to lower inflammatory responses. A lower inflammation leads to lower levels of depression and promotes positive affect [4,5].

Happy Fats
Who said all fats are bad? Are you constantly getting rid of fat from your meal? Then stop and think again. Omega-3 fatty acids, although not technically neurotransmitters, are essential for normal brain function and mood regulation. The brain is composed of 70% fat and therefore needs fat for maintaining normal balanced moods throughout life and for moderating aggressive behavior. Omega-3 fatty acids improve the activity of neurotransmitters by assisting the communication between brain cells and thus enhancing plasticity and reducing inflammation which can damage brain cells [6]. By completely eliminating one thing from your diet, even fat, it can have negative consequences on your mood.

Bad Mood Foods
I guess we all want to be in a positive mood most of the time. There are various foods that put us in a bad mood. For example studies show that depression is a symptom of gluten intolerance. Individuals with gluten intolerance have lower levels of serotonin [7,8].
Other examples include soy because it contains proteins that the body finds difficult to digest. The stress on the digestive tract in digesting this protein can equally put us in a state of stress and discomfort. Refined white flour, sugars, vegetable oils can also affect our mood depending on their quantity [9]. Therefore go ahead, eliminate the sad mood foods and eat yourself happier.

[1] http://bit.ly/1U1JOth
[2] http://bit.ly/1DIut7g
[3] http://bit.ly/1IABMp9
[4] Wurtman et al, Am J Clin Nutr, 2003
[5] Girbe et al, Neuroreport, 1994
[6] Appleton et al, Am J Clin Nutr, 2006
[7] Coleman NS et al., Clin Gastroenterol Hepatol, 2006
[8]  http://bit.ly/1H1YizV
[9] http://bit.ly/1fz7OVa 

by Priscilla Koduah, PhD Student AG Meisel
This article originally appeared 2015 in CNS Volume 8, Issue 3, Food for Thought.

Can You Be Addicted to Food?

Clearly, food is something that most people really cannot go without. For some, it is the casual craving for carbohydrate-rich food after a long, frustrating day, while others just enjoy Schnitzel too much. But in recent years, a growing controversy has developed from the question of whether there is a darker, more sinister side to the pleasure of eating. As an old Jewish proverb has it, "worries go down better with soup". But can drowning your sorrows in soup become a problem someday?

The concept of “food addiction” has been around for significantly longer than current debates may make you believe (nearly 60 years, to be precise) [1]. Conceptually, its location on the etiological food chain ranks it somewhere between substance (e.g. alcohol) and behavioral addictions (e.g. gambling). One reason why food addiction offers such an intuitive appeal is its seamless correlation with the global rise in obesity levels. Additionally, it offers a psychological remedy (a sugar-coating, if you excuse the pun) that relieves the consumer from the responsibility to choose: who could be blamed for overeating if all those companies sell food that has been carefully developed to maximize palatability and reward? However, the story may not be that straightforward.

Source: Bay Hippisley

As always when in doubt, a look at animal models proves instructive. And indeed, there is a plethora of studies indicating that animals often fall prey to developing addiction-like behavioral phenotypes when offered access to food. However, not all foods are created equal. More specifically, it has been shown that highly palatable foodstuff (so, the goodies that you should be careful with... you know, the ones with health warnings on them) including a high proportion of processed sugar, fat or salt, are especially attractive.

While it is generally appreciated that eating highly toothsome food activates reward areas and neurochemical paths that are notorious for their implication in addiction, it has remained significantly less clear whether this follows the act of eating per se, or depends on food content (i.e. certain ingredients). For instance, while there is evidence to suggest that lab rodents may show withdrawal-like symptoms when going cold turkey on sugar [2], such behaviors have generally not been described in humans (except in a single case study) [3]. For fat and salt, results have even been less clear.

Fast food is equivalent to pornography

Besides, there are some semantic problems that the term “food addiction” has difficulties digesting. Essentially, while no one debates the existence of problematic eating behavior, for instance, during binge eating attacks, the concept of addiction implies that there is something in the food that gets people hooked. However, humans who overeat tend not to be picky about a particular nutrient, but rather binge on a wide range of available toothsome foodstuff. And normally, there is very little evidence to suggest that humans ingest specific food to satisfy their craving for specific ingredients, like sugar or fat, or that these chemicals are consumed in isolation [4].

Eating addiction may be more appropriate than food addiction

From this perspective, ”addictive eating behavior” may be a better term. What is more, at this point, it has become challenging to tell apart people with increased appetite/reduced satiety from people with real “eating addiction” [4]. Overeating may, therefore, be something that is the consequence of high and readily availability of food paired with a certain vulnerability, such as negative effect, emotion dysregulation, and stress susceptibility [5]. To satisfy criteria for an addiction, rather than a maladaptive, potentially harmful behavior per se, science still has to carry forward the necessary proof. In any case, medicalizing such behavior may have its benefits, as has been the case for smoking, which today receives undivided medical/therapeutic attention. 

And while “food addicts” have been able to exchange their experiences among peers in Food Addicts Anonymous since 1987, they might have been the victims of a simple misnomer. For all those in doubt, better try the quiz at http://www.foodaddicts.org/am-i-a-food-addict.


[1] Randolph, Q J Stud Alcohol, 1956
[2] Colantuoni et al, Obes Res, 2002
[3] Thornley and McRobbie, N Z Med J, 2009
[4] Hebebrand et al, Neurosci Biobehav Rev, 2014
[5] Gearhardt et al, J Law Med Ethics, 2013

By Helge Hasselmann, PhD Student AG Otte

This article originally appeared September 2015 in Volume 08 Issue 02 "Food for Thought"

Are Oreos the New Cocaine?

We have all found ourselves reaching for that second delicious, crunchy Oreo (or maybe the German variant, Neo) after we finished the first one all too soon. But just because we do not stop with one cookie, does this mean we are addicted to them? Can Oreos be compared to drugs of abuse? Maybe. At least in rats.  

Source

Researchers at the University of Connecticut made headlines with their discovery that rats spent as much time in a chamber where they got Oreos as in one where they got a shot of cocaine or morphine. In other words, when rats had to pick between two chambers – one with a boring, bland, rice cake and one with an Oreo cookie – they preferred the Oreo chamber. And when given the choice between a shot of saline and a shot of morphine, they picked the morphine chamber. The researchers also found that eating cookies activated more neurons in the brain's nucleus accumbens than exposure to drugs of abuse [1]. 

EATING AN OREO GIVES US PLEASURE

Can we conclude that Oreos are as addictive as drugs of abuse? No! Here is a fatal flaw in the experiment: the researchers never directly compared Oreos to cocaine. They performed two independent experiments in two different groups of animals comparing rice cakes to Oreos and cocaine to saline. What the study does show is that eating an Oreo produces pleasure. But this is nothing new! In order to really find out if Oreos are as addictive as cocaine, we have to compare how hard a rat will work (for example, how often they press a lever) to get either an Oreo or a dose of cocaine [2]. Junk foods can create addictive-like tendencies [4] – this idea is neither new nor wrong. But the conclusions of this particular study certainly are [3].

How addictive are high fat/high sugar foods? Read the upcoming article to find the answer before checking into the treatment center for your addiction just yet!

[1] http://bit.ly/1KrTRTG
[2] http://bit.ly/1er5Fdp
[3] http://bit.ly/1MuWaIS
[4] Avena et al., Method Mol Biol, 2012


by Apoorva Rajiv Madipakkam
This article originally appeared 2015 in CNS Volume 8, Issue 3, Food for Thought.

A New Experience for the Adventurous Neuroscientist

In anticipation of Halloween, today's article is about an unusual type of meal.

When I heard that the MedNeuro newsletter was doing an issue on food and the brain, I naturally jumped at the chance to write an article. The excitement! The fun! The opportunity to explore a new frontier… in culinary arts. Yes, dear reader, this is an article all about cooking and eating brains.

But Are Brains Edible?
The short answer is “of course”! Like almost every other part of the body, the brain and spinal cord may be used from an animal to prepare various dishes. In fact, brain consumption in one form or another is practiced by groups worldwide. In Western Europe and North America, brain consumption is decreasing, as more desirable cuts of meat become more widespread and affordable. While you may not be able to find brain at the local Lidl or Netto, specialty butchers in Berlin will occasionally have calf brains for sale. Elsewhere in the world, brain still forms an important part of a traditional diet. For example, in Mexico, one can sometimes find “tacos de sesos”, while in parts of Indonesia, “gulai otak” (beef brain curry) is very popular.

Photo Giddy, "Brain Candy"

But Are Brains Safe to Eat?
In addition to changing demand for more “user-friendly” types of meat, brain consumption has decreased to concerns about its safety. Most readers are probably familiar with the string of deaths linked to Mad Cow (aka Creutzfeld-Jakob) Disease in the mid-1990s. This condition is still poorly understood, but is believed to stem from proliferation of prions in the brains and spinal cords of cattle that were fed remnants of other animals who died of the disease [1]. Humans who also ate meat from these animals became ill with neurological symptoms, and then swiftly died of generalized brain atrophy. Since the time of the first outbreak, most governments have taken aggressive steps to curtail the use of cattle byproducts as livestock feed, but cases still occasionally pop up every few years.

Consider yourself warned

 By and large, consumption of brain in Europe and North America should be relatively safe.
Another question of brain safety is worth mentioning, though is quite unlikely to apply to most would-be brain consumers: In the 1950s, a strange neurological disease was first noticed among the Fore region of Papua New Guinea. Eventually, the disease later christened “Kuru” was traced to practices of mortuary cannibalism, where family members of a recently deceased person would consume their remains in a gesture of respect. It was later determined to be another form of prion spongiform encephalopathy, much like Creutzfeld-Jakob [1]. These days, outbreaks are much more rare, but due to a long incubation period (2-20 years), cases still pop up [2]. So in case you are considering trying out human brain, consider yourself warned…

But Are They Good for You?
Ironically, brains are probably most dangerous in terms of their nutritional content. As any good neuroscientist knows, a good deal of the brain is formed by fatty myelin-covered axons. Thus, with small differences across species and methods of brain preparation, brain is extremely high in fat and cholesterol! For example, a serving of “pork brains in milk gravy” contains an estimated 1170% of daily-recommended cholesterol intake [3]! On the other hand, brains are also rich in omega fatty acids such as DHA [4]. All of this really takes “brain food” (see"The ABCs of Brain Foods - How to Eat Smart") to a whole new level.

Brain is extremely high in fat

But Are They Tasty?
The most important question of all! Although I’ve eaten some pretty “interesting” dishes in my life, I can’t say that I’ve ever (knowingly) tried brain. I’m a vegetarian, but I’m also quite curious. Hmmm… Perhaps the best thing to do is leave this here for exploratory purposes:

Swabian Brain Soup (Schwaebische Hirnsuppe)

  (adapted from http://eatsmarter.de/rezepte/schwaebische-hirnsuppe)

Please note: The editors of the MedNeuro newsletter hold no responsibility for the safety, nutritional value, or tastiness of the following recipe suggestion!

Ingredients:

• 1 onion
• 2 tbs butter
• 2 tbs flour
• 750 ml water or beef stock
• 1 tsp salt
• 0.5 tsp grated nutmeg
• 125 ml milk or cream
• 2 tbs chopped parsley or chives
• 1 egg yolk
• 1 veal brain

Instructions:

1. Rinse brain with hot water to remove blood and other connective tissue. Chop into small cubes.
2. Peel and chop the onion. Saute with butter until golden-brown in a large pot and stir in flour. Pour in water/stock and simmer for 40 minutes. Add salt, nutmeg, and brain, and simmer for a further 10 minutes.
3. Finally, add milk/cream, parsley/chives, and stir in the egg yolk. Serve soup hot with crusty bread.

Guten Appetit, and let us know how it goes!

[1] Wadsworth et al, PNAS, 2008
[2] Collinge et al, Philos Trans R Soc Lond B Biol Sci, 2008
[3] http://bit.ly/1g5qTPN
[4] http://bit.ly/1CVhbcw

by Constance Holman, PhD student AG Schmitz

This article originally appeared 2015 in CNS Volume 8, Issue 3, Food for Thought. 

The ABCs of Brain Foods - How to Eat Smart

Planning a picnic during the long weekend, but not sure what to put in picnic basket? Here is a list of healthy foods with lots of benefits for your brain.

A: Amino acids:
Your body cannot synthesise all of the 20 amino acids. Nine of them can only be obtained through food, including tryptophan and phenylalanine. These two amino acids, along with tyrosine, are the biosynthetic precursors for the neurotransmitters serotonin, dopamine, and norepinephrine. The amino acids glutamate and aspartate are themselves neurotransmitters as well. However, they are not taken up into the brain from the diet. Regular meals containing aspartate and glutamate have no effect on the levels of these neurotransmitters in the brain. The brain is only affected when glutamate is administered alone in extremely large doses [1]. Meat, fish, eggs, dairy products and legumes are rich in protein and thus, amino acids.

B: B complex vitamins
A typical component of dietary supplements for the brain are vitamin B complexes, which include Vitamin B6, B12 and folic acid. Vitamin B6 is a cofactor in the production of cysteine and vitamin B12 is a cofactor needed in folic acid metabolism. Folate promotes the regeneration of methionine from homocysteine. They all work by reducing levels of homocysteine and their deficiency leads to hyperhomocysteinemia. This can lead to DNA damage, increase the generation of reactive oxygen species, contribute to excitotoxicity and cause mitochondrial dysfunction which may lead to apoptosis [2]. Further, vitamin B12 deficiency and high levels of homocysteine double your risk for brain atrophy and cognitive decline [3, 4]. Taking vitamin B6, B12, and folic acid can reduce brain atrophy and improve brain function [5]. Vitamin B6 can be found in dairy products, meat and fish, but also in cabbage, beans, whole meal products, nuts, yeast, avocados and bananas. Foods with high folate content are dark green leafy vegetables like spinach, avocado, liver, asparagus, brussel sprouts, nuts, beans, dairy products and eggs. Animal products are the best source of vitamin B12; you find it especially in liver, but also in eggs and dairy products. For vegans it is difficult to get enough B12. A recent study suggests that dried purple laver (Nori) could be a good source of B12 for vegans and vegetarians [6].

Brainfoods by Claudia Willmes

C: Calcium
This is one of the most important messengers in neurons. Indeed, only a few neuronal functions are immune to the influence of calcium! A transient rise in cytoplasmic calcium concentration allows activation of a large number of Ca²⁺-binding proteins that start signalling cascades. As calcium participates in the transmission of the depolarizing signal and contributes to synaptic activity, calcium deficiency impairs many neurological functions. Milk and dairy products as well as green vegetables, sesame seeds and nuts are an excellent source of calcium.

C: Chromium
Chromium is a trace mineral found in many nutritional supplements, especially in weight-loss and muscle-building pills. The use of chromium-containing dietary supplements is controversial, owing to the absence of any verified biological beneficial effect on healthy people [7]. However, eating some chromium should not hurt. Food sources of chromium are broccoli, grapes, whole-wheat products and potatoes.

F: Fat
Many people avoid eating fat because they are afraid of gaining weight, but never underestimate their necessity for a functioning brain! Fatty acids are structural components of myelin. Both prenatal and postnatal fatty acid deficiency in rodents reduces the amount and alters the composition of myelin [8]. Avocado, olives and coconut oil are an excellent source of essential fatty acids. Very often, omega 3 fatty acids are found in dietary supplements. There are two main omega-3 fatty acids, eicosapentaenoic acid (EPA) and docosahexaenoic acid (DHA). The latter shields against age-related mental decline and improves both learning and memory in older adults [9]. People with low DHA levels actually have smaller brains and exhibit more cognitive impairment than those with adequate levels [10]! The best sources of omega-3 are animal products: cold-water fish such as salmon, as well as dairy products from animals on a grass-fed diet. Plants only contain the fatty acid precursor alpha-linolenic acid (ALA), of which a tiny amount eventually gets converted to EPA and DHA in the body. If you are vegan, eat pumpkin seeds, walnuts, soy beans and seaweed.

G: Glucose
This is the second important addition in neuro-drinks and the brain's primary energy source. Blood glucose levels influence mood and attention span. Glucose administration also improves performance in cognitively demanding tasks [11]. The brain cannot store glucose and needs a steady supply, but this does not mean you should constantly be sipping soda! To ensure a constant glucose supply to your brain, eat food with high fiber carbohydrates such as carrots, beets, potatoes or dark fiber-rich whole wheat bread.

I: Iodine
The body cannot produce iodine, so it is an essential part of your diet. This trace element is required for producing thyroid hormones [12] which, in turn are required for brain development. Iodine deficiency in utero or during early postnatal development results in impaired cognitive and motor development [12]. Pregnancy, smoking and increased alcohol intake are risk factors for iodine deficiency. Great sources for iodine are saltwater fish and seafood, milk and dairy products, and, of course, iodized salt.

I: Iron
Iron is an important mineral for neurodevelopment and neuronal function. It plays a fundamental role in neurotransmitter synthesis, myelination and ensures oxygenation and energy production in the brain. Iron deficiency appears to alter the metabolism of the monoamines dopamine and norepinephrine [13] and decreased iron intake is associated with reduced myelination [14]. Iron deficiency is linked to attention-deficit/hyperactivity disorder and abnormal development of cognitive functions. Iron deficiency is particularly common in women and is associated with depression [15]. Rich sources of dietary iron include red meat, fish, legumes such as lentils and chickpeas, leafy vegetables and whole-grain products.

M: Magnesium
Magnesium is often listed as a supplement in brain-boosting drugs or drinks. It is involved in all the major metabolic pathways such as oxidation-reduction and ionic regulation. It also blocks the NMDA receptor, thereby preventing glutamate excitotoxicity. In magnesium deficiency, NMDA receptors become hyperexcitable, leading to excessive intracellular calcium. This can cause production of toxic reactive oxygen species and eventually lead to neuronal cell death. People with low magnesium are more susceptible to migraine attacks [16]. Parkinson's patients have low magnesium levels in the brain and rats with chronic low magnesium rapidly lose dopaminergic neurons [16]. Supplementary magnesium may thus be beneficial to prevent Parkinson's disease. Increased magnesium intake can also lead to improvement in patients with mania and depression [16]. The exact benefit of magnesium supplementation however is not yet definitive. Although whole grains contain magnesium, phytic acid in grains can inhibit its absorption. Therefore, the best sources of magnesium are dairy products, beans, leafy green veggies, and nuts.

V: Vitamin C:
This is an important antioxidant, serving as an electron donor in biological reactions. The brain has higher concentrations of Vitamin C compared to other organs [17]. It participates in neuronal maturation and myelin formation and supplies electrons for dopamine-β-hydroxylase, catalyzes the formation of norepinephrine from dopamine and is involved in presynaptic re-uptake of glutamate. Thus, it modulates the cholinergic, catecholinergic, and glutamergic systems [17]. Studies show that vitamin C levels are low in patients with dementia while research with animal models show that vitamin C supplementation can reduce cognitive decline [18]. Foods rich in vitamin C are citrus fruits, berries, bell peppers and sea buckthorn.

V: Vitamin D:
Although it's difficult to obtain from food, one thing you should definitely not get too little of is vitamin D. The best food source by far is cod liver oil (yuck!). Luckily, vitamin D is created when our skin is exposed to sunlight. Vitamin D has profound effects on the brain during all stages of life. Continuing to get adequate vitamin D throughout adult life can ward off cognitive decline, dementia, and Alzheimer’s disease [19, 20].

W: Water:
Obviously the most important thing for your brain is water. It helps the blood flow and consequently the oxygen supply of the brain. Thus, our advice: Try to drink 2 liters of water per day.

Z: Zinc:
The organ containing the highest amount of zinc is the brain, especially the hippocampus and cerebral cortex. Zinc acts as an antagonist of the NMDA receptor, induces BDNF gene expression and is a cofactor in the conversion of homocysteine to cysteine. Early postnatal zinc deficiency impairs neurogenesis, leading to learning and memory deficits persisting into adulthood [21]. Studies with rodent depression models and clinical studies have demonstrated the benefit of zinc supplementation in antidepressant therapy [22]. In animal models of depression, zinc treatment has antidepressant-like effects and dietary zinc insufficiency induces depressive behaviors [23].  Even though zinc has been associated with many psychological disorders, the nature of this relationship remains unclear. Seafood, beef, lamb, "variety meats" such as liver or brain, and some cheeses such as Emmental, Edam and Gouda are excellent sources of zinc. Plants provide us with zinc as well, but with lower bioavailability. Vegetarians and vegans should consume seeds, nuts, spinach, cocoa and beans to get enough zinc.

Our advice: Add these smart foods to your shopping list and go out for a picnic in the sun!

[1] Fernstrom, J Am Diet Assoc, 1994
[2] Kronenberg, Curr Mol Med, 2009
[3] de Jager, Neurobiol Aging, 2014
[4] Tangney et al, Neurology, 2011
[5] Douaud et al, PNAS, 2013
[6] Watanabe et al, Nutrients, 2014
[7] EFSA Panel, EFSA Journal, 2014
[8] Salvati et al, Dev Neurosci, 2000
[9] Yurko-Mauro et al, Alzheimers, 2010
[10] Tan et al, Neurology, 2012
[11] Brandt et al, Behav Neurosci, 2013
[12] Delange, Proc Nutr Soc, 2000
[13] Burhans et al, Nutr Neurosci, 2005
[14] Todorich et al, Glia, 2009
[15] Lozoff et al, Semin Pediatr Neurol, 2006
[16] de Baaij et al, Physiol rev, 2015
 [17] Normann Hansen et al, Nutrients, 2014
[18] Harrison et al, Nutrients, 2014
[19] Lee et al, J Neurol Neurosurg Psychiatry, 2009
[20] Anastasiou et al, J Alzheimers Dis, 2014
[21] Chowanadisai, J Neurochem, 2005
[22] Nowak et al, Pharmacol Rep, 2005
[23] Swardfager et al, Neurosci Biobehav Rev, 2013

by Claudia Willmes, PhD Student AG Eickholt / AG Schmitz
This article originally appeared 2015 in CNS Volume 8, Issue 3, Food for Thought.

From Molecules to Mouthwatering - An Overview of Taste Physiology

By now the stores are overloaded with easter-candies and it gets harder and harder to steer clear of the tempting sweets. Ever wondered why so many people have a sweet tooth? Or how we can taste the wide range of flavors that span all the different types of global cuisine? 

Our sense of taste is important for both of the above. Taste is a chemical sensation critical for survival because it allows us to detect nutrients and toxins in the foods we eat. Although it works in conjunction with the olfactory system [1], it can be considered the final step in consumption at which we accept or reject food. Chemoreceptors on the tongue detect five different fundamental tastes: salty, sweet, sour, bitter, and umami (glutamate) [1]. 

WE HAVE 1000 ODOR RECEPTORS AND 50 TASTE RECEPTORS

Taste buds consist of 50-100 taste receptor cells with a central taste pore, and are located all over the surface of the tongue and soft palate. The taste buds line small projections on the surface of the tongue called papillae and project to dendrites from the cranial nerves 7, 9, and 10, which are responsible for conveying taste information from various regions of the tongue and palate. At the ganglion level, most neurons receive input from exactly one taste modality, but there are also neurons that respond to combinations of taste-receptors such as bitter-sour, sweet-umami or sweet-salty [2].

Taste vs. Smell
The senses of taste and olfaction work closely together to create our perception of flavor. There are as many as 1000 odor receptors in the olfactory bulb, but only 50 different taste receptors – the less precise taste receptor system recognizes fewer different chemical cues, and multiple ligands can bind to the same taste receptor. In fact, some very distinctive flavors cannot be detected without the aid of olfaction, such as coffee or chocolate [1].

An Evolutionary Function
Let's think about each of the five fundamental tastes in terms of its survival-relevant function for the organism. A family of specialized taste receptor proteins (TR) detect the different tastes. The T1R family of receptors detects sugars and amino acids. These receptors have a relatively low affinity, which allows them to detect only the foods that are rich in these tastes (i.e. that have a lot of sugars or amino acids). Bitter taste is mediated by the T2Rs, which have a relatively higher sensitivity. This is helpful because bitter tastes are often associated with compounds that are poisonous. Salty taste is mediated by the detection of sodium chloride and is mediated by ENaC’s – epithelial sodium channels [1]. Sour taste, however, is a mechanism for the detection of low pH, or acidic substances, found in spoiled or unripe foods [3]. 

Species and Individual Differences 
The sequence of these receptors is very important for determining the specific chemical signals that are recognized by a given receptor. For example, humans are able to detect the chemical aspartame as sweet, while rodents cannot detect it at all. In fact, if transgenic rodents express the human sequence of T1R receptor, they gain the ability to taste aspartame. Cats, on the other hand, lack the functional T1R receptor for sweetness and therefore cannot detect sweet tastes.

CATS CAN'T TASTE SWEETS

The same precise structure-function relationship exists for amino acids as well. For example, the human TR for amino acids can recognize glutamate with a 10-fold higher affinity than other amino acids while the same receptor for rodents is a general amino acid receptor, which recognizes all amino acids relatively equally [1].
Going one step further: The sequence of the genes for the taste receptors gives rise to threshold differences and the ability to detect different tastes between individuals. For example, about 75% of people detect the compound phenylthiocarbamide (PTC) as sharply bitter, while 25% cannot taste it. The ability to (or not to) taste PTC depends on two major variations in the sequence for the bitter taste receptor gene. There is one primary allele that allows for tasting and one that does not. Individuals who have inherited two non-tasting alleles cannot detect the compound, those who have inherited only one “tasting” allele can detect it, and those who have two of the “tasting” alleles are super-tasters, detecting PTC at even lower concentrations [1].

Taste Map Debunked
While the sequence of a person’s individual taste receptors is very important for their ability to perceive tastes, the location of the taste on their tongue is not. In spite of the commonly taught “taste map” in which different tastes are said to be detected on different regions of the tongue, recent work suggests that the taste buds in all regions of the tongue contain a variety of different types of receptors. Although the distribution is not necessarily uniform, the differences in the relative sensitivities of tongue regions are likely to contribute only subtly to the distinct perceptions of taste [1]. 

[1] Squire, Fundamental Neuroscience, 2008
[2] Barretto et al, Nature, 2015
[3] Huang et al, Nature, 2006

by Lauren Mamer, PhD Student AG Rosenmund
This article originally appeared September 2015 in CNS Volume 8, Issue 3, Food for Thought.