Genes Strengthen the Protective Effects of Fruit and Fiber
With data from 大象tv CPS-II and 44 other studies, scientists found genetic markers that interact with dietary fiber and fruit to reduce colorectal cancer risk.
The Challenge
Diets high in whole grains, fruits, vegetables, and dietary fiber?have been linked with lowering the risk of developing colorectal cancer. But how they work is not fully known.?
Scientists think genetic variants/markers in people are likely the factor that modifies the way specific foods contribute to cancer prevention. The most common type of variants in the human genome are single nucleotide polymorphisms (SNPs). SNPs serve as genetic markers to help scientists locate the specific genes associated with a specific disease.
Researchers?are still at the early stages of exploring gene-diet interactions, which are a specific type of gene-environment (GxE) study. Until recently, only one significant interaction had been found—between eating processed meat and the SNP rs4143094 near the gene GATA3, which increased the risk of developing colorectal cancer.
One of the main limiting factors for discovering other gene-diet interactions in previous studies has been small numbers of study participants.?
Putting It All Together?
Each chromosome contains 100s or 1,000s of individual genes. A genetic marker is a gene sequence at a known, distinctive location on a chromosome. That location is called the locus. A SNP (single nucleotide polymorphism) is a variation in DNA sequence and is also called a single locus marker. A GWAS (genome-wide association study) rapidly scans many people’s DNA to find small genetic variations/SNPs. These SNPs may contribute to certain diseases, like cancer. Some GWAS look at gene-environment (GxE) interactions (for instance, a gene interacting with a drug or food) to see if SNPs strengthen or weaken the way something in the body’s environment works.
See the Glossary for Nonscientists for definitions of the bold?terms, and more.
The Research
A recent study in , (part of The Lancet Discovery Science) aimed to clarify whether eating fruits, vegetables, or foods rich in dietary fiber influence the risk of developing colorectal cancer and also to identify the specific genetic markers/SNPs involved.
In this largest genome-wide study involving nearly 70,000 participants, our research group identified two genetic loci that influence how dietary fiber and fruit intake affect colorectal cancer risk. Our findings suggest that higher dietary fiber and fruit intake reduce the risk of developing colorectal cancer, enhancing our understanding of the interplay between diet and genetics in colorectal cancer development. Further research is needed to validate these results and explore the underlying mechanisms."
Compared to people without cancer (the control group), the group with colorectal cancer (the case group) tended to:
- Be older.
- Have a higher body mass index (BMI) and consume more calories.
- Be more likely to have a family history of colorectal cancer.
- Have a higher prevalence of type 2 diabetes.
- Be more likely to have a history of smoking tobacco.
- Eat less dietary fiber, fruit, and vegetables.
Discovery of an SNP that Strengthens the Protective Effects of Fiber
One of the two significant interaction SNPs the researchers found in this G x fiber interaction with colorectal cancer was?rs4730274 (close to the SLC26A3 gene).
This SNP showed the most significant interaction effect. It's been linked with:
- Inflammatory bowel disease (IBD). Current evidence suggests that people with IBD in remission who eat dietary?fiber are more likely to stay in remission compared with those who don’t eat it. It’s also well documented that people with IBD have a higher risk for developing colorectal cancer.?
- Ulcerative colitis (UC). People with UC in remission who eat a high-fiber diet have decreased signs of inflammation. Chronic inflammation increases the risk of colorectal cancer.
Based on their own test results and current knowledge about how fiber operates in the body, the authors concluded that?SLC26A3, the gene near the?rs4730274?SNP, “probably functions as a tumor suppressor."?
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Discovery of an SNP that Strengthens the Beneficial Effects of Fruit?
The second significant interaction SNP identified by the researchers was found to interact with fruit:?rs1620977?in the?NEGR1?gene.
The NEGR1 gene is linked with the regulation of body weight. The researchers suggest that this gene, similar to?SLC26A3, may also play a role in tumor suppression.
How the Study Was Done
The?researchers analyzed a large-scale dataset of 69,734 participants (with European ancestry) from 45 studies from 3 genetic consortia that focus on genetics and colorectal cancer. (Consortia are a group of scientists from multiple institutions who collaborate on projects and pool resources.)
- A genome-wide interaction scan (GWAS) to look for recurring SNPs that might be associated with the prevention of colorectal cancer.
- A gene-environment (GxE) analysis (a specific type of GWAS) to see if the SNP was modified by any 1 of the 3 food types being studied to increase the preventative factor for colorectal cancer. This study was the largest GxE study to date.
- A more advanced and powerful test called a 3-DF joint test, which increases the ability to detect interacting?disease susceptibility?loci—specific points/locations on the?gene—which helps with further evaluations.
Several American Cancer Society (大象tv) researchers participated in this study: Christina Newton, MSPH; Anita Peoples, PhD, MPH, and Caroline Um, PhD, MPH, RD. Data from the 大象tv Cancer Prevention Study-II was part of the data pool. Andrew T. Chan, MD, MPH, with Massachusetts General Hospital in Boston and an 大象tv Professor was also one of the study's authors.
Why It Matters
The results of this study add to the existing evidence that genetic markers/SNPs can identify genes that are associated with the risk of developing colorectal cancer.
Specifically, they found supportive evidence that the SNP rs4730274 and the gene close to it, SLC26A3, have interactions with fiber consumption, chronic inflammatory disorders, and overall gut function that modify the strength of fiber's protective effect related to the risk of developing colorectal cancer.
They also found a second significant interaction SNP (rs1620977 in the NEGR1 gene) that modified the strength of fruit’s protective effect for the development of colorectal cancer.
This analysis was limited to individuals of European ancestry and captured food intake at only one point in time, so future studies will need to replicate these findings in people with European ancestry as well as demonstrate them with other ethnicities and races.
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