When you get your caffeine fix do you feel jittery, on-edge, or maybe you just don’t get the ‘buzz’? The way that your body responds to the effects of caffeine might lie in your genetics. Knowing what’s in your DNA may help you decide whether to finish off your evening meal with a cappuccino or just an after-dinner mint …
For many of us, caffeine is our daily fuel. On average in the UK, we drink nearly 123 million cups of tea and 90 million cups of coffee per day. The morning brew is somewhat of an institution for us Brits – it wakes us up in the morning and keeps us alert throughout the day. The effects of caffeine can improve our focus and concentration so that we can be more productive and ready for the daily ‘grind!’
As well as tea and coffee, it’s particularly prevalent in popular fizzy drinks like cola, energy drinks and chocolate – so most of us will end up having some amount of caffeine each day. That caffeine ‘hit’ can be addictive, but the effects of caffeine can also leave us feeling less than perky so it's good to keep a check-up on your caffeine intake and understand how your body reacts to caffeine.
Caffeine addiction – how much is too much?
Do you find yourself regularly downing mugs of strong coffee? Maybe you prefer guzzling sugary energy drinks … Whatever your preferred caffeine source, how much you consume can be directly linked to your genetic makeup. In a large study into DNA and coffee drinking, people with a certain version of the CYPIA1 gene drank an extra 0.25 cups a day than the average.
What you especially need to keep an eye on is whether your DNA indicates a tendency to consume higher than average amounts of caffeine. If you’ve got the TT genotype, you’re likely to opt for a highly caffeinated drink more often than others. Watch out if you’re drinking more than four cups of caffeinated drinks per day, as this is found to raise your blood pressure – which isn’t great for your heart health.
Caffeine and your metabolism – why we have different reactions to the effects of caffeine
How your body breaks down caffeine determines your caffeine metabolism. When you have coffee, tea or an energy drink, the caffeine is processed by an enzyme in the liver. Variations in the CYP1A2 gene cause different levels of enzyme activity – but what are the consequences of having different metabolic speeds when it comes to caffeine?
Fast caffeine metabolism
If you’ve got the AA genotype, your body will likely metabolise caffeine faster than others. Fast metabolisers tend to be less sensitive to its typical effects – you might experience less caffeine-related sleep disruption, because the stimulant effects of caffeine may be shortened for you.
It’s important to understand whether you’re a fast metaboliser, as you may drink more and more caffeine in order to maintain that ‘coffee buzz’ over a long time. This could mean you’ll end up drinking more than is healthy for you.
Slow caffeine metabolism
Having either the AC or CC genotype means that you’ve probably got slow caffeine metabolism. The enzyme that metabolises caffeine doesn’t work properly in some people, so they’ll have to adapt their daily dose of coffee to ensure they don’t suffer from the negative effects of caffeine.
After drinking the exact same amount as others, slower metabolisers might get the jitters and feel anxious. It’s especially important for these people to monitor their caffeine intake, because they’ll suffer from more sleep disturbances like insomnia. In addition to this, the effects of caffeine for some people can be more serious – heavy coffee consumption has been linked to higher risk of heart attacks in slow metabolisers.
Don’t worry though – people with this genetic makeup can still enjoy caffeine, as long as they don’t have more than 200mg per day – around 2 cups of coffee.
Evergreen Life DNA testing kits
With an Evergreen Life DNA testing kit, you can find out whether your genes play a role in your caffeine consumption and caffeine sensitivity. By knowing your genetics, you can alter your daily caffeine intake to suit your own body and minimise the negative effects of caffeine. Our DNA Diet Test analyses your unique genes, so you can see whether substituting an espresso for decaf might be a healthier choice for you. Why not give it a ‘shot?’
Take control of your health, wellbeing and fitness today with an Evergreen Life DNA Test.
Amin N et al. (2011). “Genome-wide association analysis of coffee drinking suggests association with CYP1A1/CYP1A2 and NRCAM.” Mol Psychiatry. (11): 1116–1129.
Cornelis MC et al. (2006). “Coffee, CYP1A2 genotype, and risk of myocardial infarction.” JAMA 295(10): 1135-41.
Cornelis MC et al. (2007). “Coffee, Caffeine, and Coronary Heart Disease.” Current Opinion in Clinical Nutrition and Metabolic Care. 10, 745-51.
Djordjevic N et al. (2010). “Induction of CYP1A2 By Heavy Coffee Consumption is Associated with The CYP1A2 -163C>A Polymorphism.” European Journal of Clinical Pharmacology 66, 697-703.
Gunes A et al. (2008). “Variation in CYP1A2 Activity and its Clinical Implications: Influence of Environmental Factors and Genetic Polymorphisms.” Pharmacogenomics 9, 625-37.
Sachse C et al. (1999). “Functional Significance of a C--> A Polymorphism in Intron 1 of the Cytochrome P450 CYP1A2 Gene Tested with Caffeine.” British Journal of Clinical Pharmacology 47, 445-9.
Zhou SF et al. (2010). “Structure, Function, Regulation and Polymorphism and The Clinical Significance of Human Cytochrome P450 1A2.” Drug Metabolism Reviews 42, 268-354.