Stanford Scientists Discover Surprising New Reason Why
By STANFORD UNIVERSITY
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While this discovery is preliminary and primarily observed in lab-grown cells and mice, it highlights a potentially significant pathway for genetic damage and calls for further investigation into the health implications of different cooking methods and food choices.
Scientists have recently uncovered a
surprising and potentially important reason why eating foods frequently cooked
at high temperatures, such as red meat and deep-fried fare, elevates cancer
risk. The suspected culprit: DNA within the food
that’s been damaged by the cooking process.
ACS Cent. Sci. 2023, 9, 6, 1170-1179
As shown for the first time known to the authors, the study led by Stanford scientists, in collaboration with their counterparts at the National Institute of Standards and Technology (NIST), the University of Maryland, and Colorado State University, demonstrates that components of DNA damaged by heat can be absorbed through digestion and subsequently incorporated into the DNA of the person consuming the food.
That uptake directly places damage in the
consumer’s DNA, potentially triggering genetic mutations that may eventually
lead to cancer and other diseases.
While it’s too soon to say this occurs in
humans – the study only observed heat-damaged DNA component uptake and
increased DNA injury in lab-grown cells and mice – the findings could have
important implications for dietary choices and public health.
“We have shown that cooking can damage DNA in
food, and have discovered that consumption of this DNA may be a source of
genetic risk,” said study senior author Eric Kool, the George A. and Hilda M.
Daubert Professor in Chemistry in the Stanford School of Humanities and
Sciences. “Building upon these findings could really change our perceptions of
food preparation and food choices.”
Yong Woong Jun, a former postdoctoral
research affiliate in chemistry at Stanford and now at the Korea Advanced
Institute of Science and Technology, is the lead author of the study, which was
published on June 1 in ACS Central Science.
Novel genetic hazard
Many studies link the consumption of charred
and fried foods to DNA damage and attribute the harm to certain small molecules
that form so-called reactive species in the
body. Of note, however, those small molecules produced in typical cooking
number many thousands of times less than the amount of DNA occurring naturally
in foods, Kool says.
For those reactive species to cause DNA
damage, they must physically encounter DNA in a cell to trigger a deleterious
chemical reaction – a rare event, in all likelihood. In contrast, key
components of DNA known as nucleotides that are made available through the
normal breakdown of biomolecules – for instance, during digestion – are readily
incorporated into the DNA of cells, suggesting a plausible and potentially
significant pathway for damaged food DNA to inflict damage on other DNA
downstream in consumers.
“We don’t doubt that the small molecules
identified in prior studies are indeed dangerous,” says Kool. “But what has
never been documented before our study is the potentially large quantities of
heat-damaged DNA available for uptake into a consumer’s own DNA.”
We are what we eat
Many people aren’t aware that foods we eat –
meat, fish, grains, veggies, fruit, mushrooms, you name it – include the
originating organisms’ DNA. The oversight is understandable, since DNA does not
appear on nutrition labels in the same manner as protein, carbohydrates, fat,
vitamins, and minerals.
Yet the amounts of devoured DNA are not
negligible. For example, a roughly 500-gram (16-ounce) beef steak contains over
a gram (0.04 ounce) of cow DNA, suggesting that human exposure to potentially
heat-damaged DNA is likewise not negligible.
Investigating the nitty-gritty of how complex
DNA molecules are repaired – both after unavoidable natural errors, as well as
damage induced by environmental exposures – is a chief aim of Kool’s lab at
Stanford. To this end, Kool’s lab and their collaborators have devised means of
inducing and measuring specific forms of damage to DNA.
While pursuing this line of research, Kool
began wondering about a hypothetical connection to foodborne DNA and the
well-known process of the body “salvaging” and reusing DNA scraps.
The researchers proceeded to cook foods –
namely, ground beef, ground pork, and potatoes – through either 15-minute boils
at 100 degrees Celsius (212 degrees Fahrenheit) or 20-minute mild roastings at 220 C (about 430
F). The Stanford researchers then extracted DNA from these foods and sent the
samples to collaborators at NIST.
The NIST team, led by Miral Dizdaroglu,
showed that all three foods exhibited DNA damage when boiled and roasted, and
higher temperatures increased DNA damage in nearly all instances.
Interestingly, even just boiling, a relatively low cooking temperature, still
resulted in some DNA damage. Other intriguing results emerged as well –
potatoes, for instance, incurred less DNA damage at higher temperatures than
meat for unknown reasons.
The two most common kinds of damage involved
a nucleotide component containing a compound called cytosine changing
chemically to a related compound called uracil and the addition of oxygen to
another compound called guanine. Both kinds of DNA damage are genotoxic, in
that they can ultimately impair gene functioning and foster mutations that
cause cells to replicate uncontrollably as cancer.
Next, Kool’s team exposed lab-grown cells and
fed mice a solution containing the heat-damaged DNA components in high
concentrations. The researchers used an innovative tool, created in-house in
Kool’s lab in previous work, that tags sites of damaged DNA with fluorescent
molecules, making the extent of the damage easy to measure.
Overall, the lab-grown cells showed
significant DNA damage resulting from taking up heat-damaged DNA components. As
for the mice, DNA damage appeared prominently in the cells lining the small
intestine, which makes sense because that’s where much of food digestion takes
place.
Meriting further investigation
The team now plans to delve deeper into these
eyebrow-raising, preliminary findings. One future avenue of research is testing
a broader variety of foods, following up on the idea that foods with high
levels of DNA content, such as animal products, could pose more of a potential
genetic menace than low-DNA-level sustenance such as potatoes and other plants.
The researchers also plan on examining cooking methods that simulate different
food preparations – for instance, cooking food for longer than just 20 minutes.
Importantly, the scope of research will need
to expand to the long-term, lower doses to heat-damaged DNA expected over
decades of consumption in typical human diets, versus the high doses
administered in the proof-of-concept study.
“Our study raises a lot of questions about an
entirely unexplored, yet possibly substantial chronic health risk from eating
foods that are grilled, fried, or otherwise prepared with high heat,” said
Kool. “We don’t yet know where these initial findings will lead, and we invite
the wider research community to build upon them.”
Reference: “Possible Genetic Risks from
Heat-Damaged DNA in Food” by Yong Woong Jun, Melis Kant, Erdem Coskun,
Takamitsu A. Kato, Pawel Jaruga, Elizabeth Palafox, Miral Dizdaroglu and Eric
T. Kool, 1 June 2023, ACS Central Science.
DOI: 10.1021/acscentsci.2c01247
The research was funded in part by the U.S.
National Cancer Institute and the American Cancer Society.
