A groundbreaking international investigation led by researchers at the University of California San Diego has unveiled a compelling microbial factor that may be behind the worrisome surge in early-onset colorectal cancer. This elucidation centers on a bacterial toxin known as colibactin, produced by select strains of Escherichia coli residing in the human gut, particularly in the colon and rectum. Colibactin is not just any toxin—its remarkable ability to inflict DNA damage sets the stage for genetic mutations that may precipitate cancer development decades earlier than previously understood.
The study, published recently in the distinguished journal Nature, conducted a comprehensive genomic analysis of nearly a thousand colorectal cancer tumors collected globally from diverse populations spanning 11 countries. This extensive investigation revealed that the mutational footprints left behind by colibactin were significantly enriched in patients diagnosed with colorectal cancer before the age of 40. These genetic signatures were notably 3.3 times more prevalent in early-onset cases compared to those identified in patients over 70 years old, underscoring a potential age-related disparity in the molecular origins of colorectal cancer.
Professor Ludmil Alexandrov, the study’s senior author and a prominent bioengineering and molecular medicine expert at UC San Diego, explains that the mutational imprints found in these young patients’ DNA serve as “historical records,” chronicling early-life exposure to colibactin-producing bacteria. This molecular evidence not only links microbial factors to cancer etiology but also challenges the longstanding perception that colorectal cancer is primarily a disease afflicting older adults.
Prior research efforts had documented colibactin-associated mutations in colorectal cancer; however, these earlier studies either did not differentiate between early- and late-onset cases or predominantly focused on older patients. This new analysis conclusively demonstrates a strong enrichment of colibactin-induced DNA alterations specifically within younger patients, painting a more intricate picture of how this toxin acts as a potential accelerator of carcinogenesis in early life.
The epidemiological implications of this discovery are profound. Traditionally considered a cancer of aging populations, colorectal cancer is now exhibiting alarming incidence rates in adults under 50, with the disease doubling every decade over the last 20 years in at least 27 countries. Projections even suggest colorectal cancer could become the leading cause of cancer-related death in young adults as soon as 2030, a stark shift beckoning urgent scientific and public health attention.
One of the most perplexing aspects is that many affected young adults lack familial cancer history or classical risk factors such as obesity and hypertension. This pattern has fueled hypotheses that elusive environmental or microbial exposures may underlie the rise, a theory substantiated by the current study through direct molecular evidence implicating the bacterial toxin colibactin in early-onset colorectal cancer pathogenesis.
Marcos Díaz-Gay, the study’s first author and a former postdoctoral researcher at UC San Diego now heading his own lab at the Spanish National Cancer Research Center, reflects on the serendipity of their findings. The team initially intended to scrutinize geographic variations in colorectal cancer but found themselves captivated by the prevalence of colibactin-related mutations in younger patients, highlighting an unforeseen avenue of exploration.
An innovative aspect of the study involves molecular timing of mutational signatures, a technique that allows researchers to estimate when during tumor evolution these genetic lesions arise. Findings indicate that colibactin-associated mutations accumulate early, well within the first decade of life, implying that children may be silently harboring DNA alterations that predispose them to cancer many years later. Significantly, about 15% of APC driver mutations, key early genetic events in colorectal carcinogenesis, bear the hallmark of colibactin damage, reinforcing its potential role as a molecular instigator.
Alexandrov emphasizes the gravity of this insight: acquiring such driver mutations in childhood could precipitate cancer onset decades earlier than typical, transforming the disease landscape and urging a reevaluation of cancer prevention strategies focusing on early life exposures rather than solely adult risk factors.
The notion that the human microbiome, particularly colibactin-producing E. coli, could covertly influence cancer risk from childhood bestows a new dimension to cancer biology. These bacterial populations may act as insidious agents of genomic instability, modifying cellular DNA and setting a molecular clock ticking long before clinical manifestation emerges.
Nevertheless, Alexandrov stresses that correlation does not equal causation, and further rigorous investigation is necessary to definitively establish colibactin’s causal role in early-onset colorectal cancer. Still, this study significantly advances our understanding by applying mutational signature analysis as a forensic tool to trace the microbial origins of cancer.
This work builds on extensive previous research by Alexandrov and collaborators, who specialize in decoding environmental mutagenesis in cancer. Their methodological innovations include identifying unique “mutational signatures” linked to diverse carcinogens such as ultraviolet radiation, tobacco, and now, bacterial toxins like colibactin. This approach allows the dissection of complex cancer etiologies by recognizing DNA fingerprints left by specific mutagens.
Collaborating with premier institutions including the International Agency for Research on Cancer in France and the Wellcome Sanger Institute in the UK, under the funding aegis of Cancer Research UK’s Cancer Grand Challenges initiative, the research consortium known as Mutographs has systematically mapped mutational processes across cancer types worldwide. Their discoveries in esophageal, kidney, head and neck cancers previously unearthed environmental mutagenic contributors, and this new colorectal cancer insight broadens the global framework on cancer causation.
By analyzing thousands of genomes, the team aims to uncover hitherto unrecognized cancer triggers. Alexandrov notes that not every suspected environmental factor leaves clear genomic scars, yet colibactin’s distinctive mutational imprint stands out strongly in early-onset colorectal cancers, marking it as a critical biological player deserving intensive study.
Emerging questions from this research now drive the scientific agenda. The team is actively investigating routes of early colibactin exposure in children, potential dietary or lifestyle factors influencing bacterial toxin production, and strategies to reduce or neutralize bacterial carcinogens safely. One promising avenue involves probiotic interventions designed to displace harmful E. coli strains without disrupting beneficial microbiota.
Furthermore, efforts are underway to develop early detection methodologies capable of identifying colibactin-related mutations via non-invasive stool analyses. Such tools could revolutionize cancer screening by flagging at-risk individuals well before malignancy develops, enhancing preventive care especially for young populations.
Interestingly, the study also revealed geographical disparities, with countries including Argentina, Brazil, Colombia, Russia, and Thailand showing distinct mutational signatures alongside colibactin profiles. This suggests that localized environmental or microbial factors could influence colorectal cancer risk, highlighting the need for tailored, region-specific prevention strategies adaptable to varied global contexts.
In a broader conceptual shift, Alexandrov proposes that many cancers might originate from environmental or microbial insults incurred in early life instead of adulthood—a paradigm challenging conventional cancer biology. This perspective urges sustained investment in research focused on early-life exposures to transform cancer prevention and intervention.
He concludes eloquently, “Cancer might not merely be a culmination of adult exposures but could be intricately shaped by molecular events in the formative years of life. Understanding and intercepting these processes holds immense promise for preventing cancer before it takes hold.”
Subject of Research: Early-onset colorectal cancer and microbial mutational signatures
Article Title: Geographic and age variations in mutational processes in colorectal cancer
News Publication Date: 23-Apr-2025
Web References: http://dx.doi.org/10.1038/s41586-025-09025-8
Keywords: Early-onset colorectal cancer, colibactin, Escherichia coli, mutational signatures, DNA mutations, microbial toxins, cancer etiology, mutational timing, pediatric carcinogenesis, microbiome, cancer prevention, genomic imprint
Tags: age-related cancer disparitiescolibactin and colorectal cancerDNA damage and cancer progressionearly childhood bacterial toxin exposureearly-onset colorectal cancer ratesEscherichia coli and cancer riskgenetic mutations in young adultsgenomic analysis of cancer tumorsinternational colorectal cancer studymicrobial factors in cancer developmentmutational footprints in cancer patientsUC San Diego research on colorectal cancer