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Nutrigenomics of Vitamins + SNPs, Food Sources

Written by Ana Aleksic, MSc (Pharmacy) | Last updated:
Nattha Wannissorn
Puya Yazdi
Medically reviewed by
Nattha Wannissorn, PhD, Puya Yazdi, MD | Written by Ana Aleksic, MSc (Pharmacy) | Last updated:

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nutrients

Recent research suggests that genetics can influence nutrient and vitamin levels–and that nutrients can also affect gene expression. Enter nutrigenomics and nutrigenetics: new sciences exploring the interplay between each person’s unique genetic makeup and their nutritional status. Read on to understand how vitamin intake may be adapted to DNA.

What Is Nutrigenomics?

The term nutrigenomics was first coined less than 10 years ago.

The terms nutrigenomics and nutrigenetics are often used interchangeably, although they don’t mean quite the same thing.

The Difference Between Nutrigenetics and Nutrigenomics

Nutrigenetics is how your genes affect your nutritional status

Recently, scientists have started pointing out that genetics may have a profound influence on the way our bodies use nutrients [1].

Genes can impact how nutrients are absorbed, transported, activated, and eliminated in the body.

Nutrigenetics is the science of how genetic variations influence a person’s nutritional status.

To make a rough scheme, this sums up nutrigenetics:

Genetic variations ———–> Nutritional status (vitamin and mineral levels)

It’s directly tied to how a person’s DNA influences their vitamin and mineral levels risk for deficiencies. It may imply an increased need for certain foods (or supplements) to achieve optimal nutrient levels.

Recommended daily allowances you see on most supplements and foods are not adapted to individual genetic variations.

For example, limited research suggests that genetics can play a role in low B12, folate, iron, or vitamin C absorption. Nutrigenetics aims to match the nutrients people consume to their genetic makeup to establish a healthy balance in the body [1].

Nutrigenomics is how the nutrients you eat impact your genes

Nutrigenomics focuses on how nutrients and food can impact gene expression.

It zooms in on the interactions between nutrients and genes, especially when it has to do with disease prevention [2].

For example, nutrients such as vitamins or minerals from foods can activate or deactivate genes linked to risk for Alzheimer’s disease, heart disease, or other health issues.

To mirror the rough scheme from above, nutrigenomics could be represented as:

Nutrients (vitamins and minerals) ———–> Gene expression/activity

Any kind of malnutrition – a nutrient deficiency or excess in your diet – might affect gene expression [2].

These effects on gene expression are known as epigenetic influences. Each environmental factor that can turn our genes “on” or “off” is considered epigenetic. Epi means “on top of,” describing an influence “on top of genetics” [1].

For example, methylation affects the activity of various genes. A deficiency in methyl donors (such as folate, vitamin B12, choline, and methionine) can hinder the methylation process. Nutrigenomics deals with these and other epigenetic influences of diet and nutrients [1].

The End Goal: DNA-Targeted Nutrition & Optimal Health

Although these terms are different, one can’t do without the other.

Nutrigenetics <———–> Nutrigenomics

The goal of both nutrigenetics and nutrigenomics is to match each person’s genetic makeup to optimal diet and nutrient recommendations and lowest overall disease risk. Researchers have yet a long way to go, but the existing findings are encouraging.

How Can SNPs Influence Nutrients?

Single nucleotide polymorphisms (SNPs) are the most common type of variation in our DNA. They affect just one single letter in a gene that may be thousands of letters long. Over 10 million SNPs are currently known.

However small these “single-letter variations” may seem, some SNPs may have a big influence on the activity of a gene.

For example, if a SNP reduces the activity of a gene that makes a vitamin A-activating enzyme, then people with this variation in their DNA may be at risk for low vitamin A levels. This remains a hypothesis until proven in proper human studies.

Research Limitations

Remember, the SNPs mentioned below have only been found to be associated with nutrient deficiencies. However, more research will be needed to know what role, if any, these variants play in actually causing specific nutrient deficiencies.

Additionally, many different factors, including diet, other genetic and environmental factors, can influence the risk of nutrient deficiencies.

Vitamins

Small Nutrients with Large Impact

There are 13 known vitamin groups. Vitamins are small nutrients that broadly influence overall health, brain function, heart health, blood glucose levels, and energy production. The largest vitamin group is the vitamin B family, which consists of 8 subtypes.

Individual genetic variations may influence the effect of vitamins on the body. Genes affect how vitamins are taken up, used, and eliminated. Certain SNPs have been linked with decreased vitamin availability, and in some cases, deficiency [3, 4].

Precautions

Our body can create some vitamins, such as vitamin D and K2. But we have to rely on our diet to obtain most other vitamins.

However, vitamin supplements have not been approved by the FDA for medical use. Supplements generally lack solid clinical research. Regulations set manufacturing standards for them but don’t guarantee that they’re safe or effective.

Concerns have been raised about associations between high doses of certain antioxidant vitamins and health risks. Beta-carotene supplementation has been linked with lung cancer in smokers, vitamin E with prostate cancer, and vitamin A with a higher risk of dying [5, 6].

Additionally, vitamin supplements may interact with some medicines. Supplement-drug interactions can be dangerous and, in rare cases, even life-threatening.

Always consult your doctor before supplementing or making major changes to your diet and let them know about all drugs and supplements you are using or considering.

Vitamin A

Vitamin A refers to retinol (active vitamin A), retinal, retinoic acid, and provitamin A (carotenoids). Vitamin A is required a healthy brain, immune system, skin, teeth, eyes, bones, and the production of hormones [7].

This vitamin plays a diverse role, about which you can read in detail here. To summarize, vitamin A is important for the following [7, 8, 9]:

Vitamin A deficiency is the most common cause of preventable blindness in children globally. Additionally, vitamin A deficiency has been linked to [8, 10, 11]:

  • Reduced immune system function and increased risk of infections
  • Diarrhea
  • Increased risk of complications in pregnant women
  • A buildup of glucose in the blood and possibly weight gain.

On the other hand, too much Vitamin A may reduce bone density because it competes with the uptake of other vitamins such as vitamin D and K2 [12].

Nutrigenetics

A vast number of proteins are involved in making and using vitamin A. Among others, proteins that break down and take up vitamin A in the gut can influence the amount of available vitamin A in the body [13].

Beta-carotene is the main source of vitamin A in plants. It is converted in the body into the active form of vitamin A, which is affected by the activity of the BCO1 gene. Scientists think that SNPs in BCO1 might impact how a person uses vitamin A from plant-based sources [14].

The following are a few SNPs associated with decreased BCO1 activity, potentially resulting in lower levels of available vitamin A in the body [14, 15]:

B Vitamins

8 water-soluble vitamins make up the B-vitamin group. These vitamins play a role in the body’s energy system and are important for brain function. They are needed for [16]:

  • Cognitive Function
  • Memory
  • Mood
  • The production of neurotransmitters
  • Maintaining energy levels
  • Protein functioning and repair

Limited clinical studies explored the mechanisms and benefits of vitamins B9 and vitamin B12, especially when it comes to MTHFR mutations [16].

Vitamin B9 (Folate)

Vitamin B9 is commonly known as folate. It is inactive before the body converts it into methyl-folate. Vitamin B9 helps produce and repair DNA and amino acids, ensuring cellular proteins are working at full capacity. Scientists think that it also enables cells to recover from damage. All in all, folate is thought to be beneficial for [17]:

  • Fetal health in pregnant women
  • Red blood cell production
  • Brain health, mood, and cognitive function
  • Antioxidant and immune defense

Folate deficiency has been linked to anemia and neural tube defects in babies. However, supplementing folate may mask a vitamin B12 deficiency. To avoid a B12 deficiency, keep your doctor in the loop about any supplements you choose to take [17, 18].

You can read more about the health benefits of folate in detail here.

Nutrigenetics

Folate needs to be activated to l-methylfolate by a number of proteins to achieve its health benefits. Enzymes and proteins that play a role in this process include MTHFR and MTHFD1.

Variations in the MTHFR gene may reduce the activity of the MTHFR enzyme, and in turn, decrease the amount of available l-methylfolate. These variations or SNPs are:

To take a deeper dive, take a look at your genotype for rs1801133:

  • MTHFR CC677 (rs1801133) or GG is normal
  • MTHFR C677T (rs1801133) or AG may reduce MTHFR function by 30% maximum
  • MTHFR 677TT (rs1801133) or AA may reduce MTHFR function by up to 70% maximum

If you see “AA” in your file, this means your MTHFR enzyme activity is more likely not to function as well. AG means it may have reduced function, but the chances are lower. And finally, GG is the normal version.

Next, take a look at rs1801131. This SNP has less of an effect on MTHFR function, but might still be worth looking into. For this SNP:

  • MTHFR AA1298 (rs1801131) or TT is normal
  • MTHFR A1298C (rs1801131) or GT may slightly reduce MTHFR activity
  • MTHFR 1298CC (rs1801131) or GG may reduce MTHFR activity more

To get a complete picture, look at your genotype for these SNPs together. If you have the “bad” genotype for both, your MTHFR enzyme is less likely to work well – hypothetically speaking.

Vitamin B12

Vitamin B12, also known as cobalamin, helps the body make energy, DNA, red blood cells, and the insulation of brain cells. Vitamin B12 may have benefits for [19, 16]:

  • Brain and nerve health and cognitive function
  • Low mood
  • Preventing a type of anemia called megaloblastic anemia
  • Improving sleeping patterns
  • Skin health
  • Reducing inflammation
  • Pain relief (insufficient evidence)

Vitamin B12 deficiency may cause [19]:

  • Fatigue
  • Lethargy
  • Depression
  • Poor memory
  • Headaches

You can read about vitamin B12 in detail here.

Nutrigenetics

Vitamin B12 absorption depends on enzymes and good bacteria in the gut. Scientists discovered that a protein called FUT2 increases in the presence of healthy gut bacteria. They suspect FUT2 might help gut bacteria with vitamin B12 absorption. The following SNPs have been associated with increased absorption of vitamin B12 [20, 21, 22]:

Vitamin K

The term vitamin K refers to a group of fat-soluble vitamins that are found in two forms: phylloquinone, commonly known as vitamin K1, and menaquinone, also known as vitamin K2 [23, 24].

Our diet usually contains much more Vitamin K1, which is estimated to make up 75% of vitamin K consumed by most people [24].

Vitamin K1 is found in plants, such as green leafy vegetables. Vitamin K2 is produced by our gut bacteria from vitamin K1. Plants can’t make vitamin K2, so the main dietary sources are animal-based (such as meat, butter, lard, and egg yolk) [24].

Vitamin K1 helps with blood clotting, whereas vitamin K2 may also affect blood vessels, bone health, and cognition [25, 24].

To sum it up, vitamins K1 and K2 may help [25, 24, 23, 26]:

  • Prevent bleeding disorders (particularly in newborns)
  • Support bone health and calcium absorption
  • Act together with vitamin D
  • Promote brain and heart health
  • Support energy production and mitochondrial health

Vitamin K deficiency has been linked to osteoporosis and an increased risk of bone fractures. Also, vitamin K deficiency may result in increased blood clotting time, putting people at higher risk of bleeding [23, 25].

Read more about vitamin K here or specifically about vitamin K2 here.

Nutrigenetics

Vitamin K plays a critical role in blood clotting and many proteins can influence how well it functions. For blood clotting to start, vitamin K must be activated by an enzyme called VKORC1. The following SNPs have been linked to decreased levels of vitamin K in the body [27, 28]:

Side Effects & Safety of Vitamin Supplements

Safety

Generally, the regular consumption of vitamins A, B9, B12, and K within the generally-recommended dosage is considered safe and poses a low risk of harm. High doses of these vitamins can have adverse effects [17, 18, 23].

High doses (above 3 mg) of active vitamin A (retinol) pose a risk of a condition known as hypervitaminosis A, which may result in [29]:

  • Dizziness
  • Nausea
  • Headaches
  • Skin irritation
  • Coma, and even death

However, high doses of vitamin B9 (folate) have been linked to neurological defects in people with megaloblastic anemia, which is caused by vitamin B12 deficiency [17].

Other side effects are possible. Contact your doctor or pharmacist for medical advice about side effects.

Additionally, there is conflicting evidence about the effects of individual and multivitamin supplements.

The long-term effects of using multivitamin supplements are unknown. In general, we recommend getting your vitamins from a balanced diet rather than from supplements, if possible, and discussing your health goals with your healthcare provider.

Possible Drug-Vitamin Interactions

Keep in mind that the drug interactions of many vitamins are relatively unknown, given the lack of well-designed clinical studies. The list below is not a definite one. Always consult your doctor before supplementing and let them know about all drugs and supplements you are using or considering.

Vitamin A (retinol) may interact with [8]:

  • Orlistat (Alli)
  • Psoriasis medication acitretin
  • Anti-cancer drug bexarotene

Vitamin B9 (folate) may possibly interact with [17]:

  • Rheumatoid arthritis medication sulfasalazine
  • Chemotherapy drug methotrexate
  • Anti-seizure drugs, such as phenytoin, carbamazepine, valproate

Vitamin B12 may interact with [19]:

  • Antibiotic chloramphenicol
  • Antacids, which reduce vitamin B12 absorption by lowering stomach acid; these include:
  • The anti-diabetes drug metformin

Vitamin K may increase or decrease the effects of a number of substances. The following interactions may either reduce the activity of the drug or the absorption of vitamin K [30, 23]:

  • May reduce the blood-thinning effects of warfarin
  • Orlistat (Alli) is an obesity medication. Taking Alli may reduce vitamin K absorption in the gut.
  • Antibiotic use may reduce vitamin K levels
  • Low-fat diets
  • Cholesterol-lowering drugs

Natural Sources of Vitamins

Although genetic variations might influence a person’s vitamin levels, the healthiest way to boost vitamin status is to ensure regular vitamin intake through a balanced, healthy diet and lifestyle.

Take a look at some of our suggestions below, read more about each vitamin and its food sources, and take it from there (but don’t make any major changes to your diet without seeing a doctor)!

Food Sources of Vitamin A (retinol) and provitamin A (carotenoids)

Foods rich in active vitamin A (retinol) [31]:

Provitamin A (carotenoids) can be found in plant sources [9].

  • Mangoes
  • Papayas
  • Carrots
  • Dark leafy greens (spinach)

Food Sources of B Vitamins

Vitamin B9 (folate) [32, 33]:

  • Broccoli
  • Liver
  • Okra
  • Spinach
  • Poultry
  • Eggs

Vitamin B12 [34, 19]:

  • Fish
  • Meat
  • Poultry
  • Eggs

Food Sources of Vitamin K1 and K2

Vitamin K1 (phylloquinone) [24]:

  • Spinach
  • Broccoli
  • Iceberg lettuce
  • Vegetable oils

Vitamin K2 (menaquinones) [24]:

  • Meat
  • Eggs

About the Author

Ana Aleksic

Ana Aleksic

MSc (Pharmacy)
Ana received her MS in Pharmacy from the University of Belgrade.
Ana has many years of experience in clinical research and health advising. She loves communicating science and empowering people to achieve their optimal health. Ana spent years working with patients who suffer from various mental health issues and chronic health problems. She is a strong advocate of integrating scientific knowledge and holistic medicine.

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