For decades, cancer research concentrated on understanding genetic alterations, characterizing tumor behavior, and advancing treatment modalities like radiation therapy, chemotherapy and, more recently, immunotherapy. But science is now uncovering a surprising player in cancer development and treatment response: the microbiome, the vast community of microorganisms (bacteria, fungi, viruses) that live inside and on our bodies[1].
The three-way relationship between the microbiome, the immune system, and cancer is often called the microbiome–immune–cancer triangle. It describes how these systems continuously interact with one another, sometimes helping the body fight cancer, and other times unintentionally helping cancer grow[2].
Understanding this triangle is bringing new hope to patients by opening doors to improved treatment responses and new therapeutic strategies.
A Critical but overlooked player: The Lung Microbiome
An important but often underappreciated part of the microbiome–immune–cancer triangle is the lung microbiome. Whereas healthy lungs were long thought to be sterile organs (free from the presence of viable microorganisms), new molecular methods have uncovered that lungs host their own distinct and complex microbiome community. These microorganisms play an essential role in shaping local immune activity and inflammation.
When this delicate ecosystem becomes unbalanced, it has been linked to chronic lung diseases and even the development and progression of lung cancer. Similar to the gut, microbes in the airways influence immune surveillance and the tumor microenvironment through pattern-recognition signaling, metabolic activity, and cytokine modulation. Emerging evidence suggests that modifying the lung microbiome may support lung cancer prevention and potentially improve responses to immunotherapy, particularly for diseases like non-small cell lung cancer.
Understanding this unique microbial niche widens the scope of microbiome-based cancer strategies, showing that precision oncology must consider not only gut health but lung-specific ecosystems as well[3].
The Microbiome Shapes Immunity
The immune system does not work alone. It relies heavily on support from the microbiome. Research shows that microbial communities influence how immune cells develop, mature, and respond to threats. When the microbiome is healthy and balanced, it supports strong immune surveillance, the body’s ability to detect and destroy abnormal cells before they become harmful. However, when the microbiome becomes disturbed (a state called dysbiosis), immune regulation weakens. This imbalance can trigger chronic inflammation, reduce the power of protective immune cells, and create an environment that allows tumors to grow more easily[1].
Put simply, your microbial community helps train your immune system every day — and its balance matters.
How the Microbiome Influences Cancer Risk
Scientists are increasingly discovering that certain microbes can protect against cancer, while others may promote tumor formation. Dysbiosis can shift the immune system into an inflammatory state that supports tumor development and progression.
Chronic inflammation can damage DNA, fuel rapid cell growth, and weaken immune cells that would normally keep cancer cells in check.
Some microbes produce helpful metabolites like short-chain fatty acids that reduce inflammation. Others may produce toxins that damage cells or interfere with the immune response. This means cancer risk is partly shaped by the microscopic world living inside us[4]. In lung cancer, shifts in the biomass, distribution, and composition of the lung microbiome have been associated with tumor initiation and progression, suggesting that local microbial communities can directly shape carcinogenic risk in the airways. Disturbances along the gut–lung axis further illustrate how dysbiosis in the gut may reverberate to the lungs, altering systemic and mucosal immunity in ways that can promote or restrain lung tumor development.
The Microbiome Shapes Response to Cancer Treatment
One of the most significant insights from recent scientific research is that the microbiome strongly affects how well patients respond to immunotherapy.
Microbiome influences both innate and adaptive immunity, altering how T cells and other key immune cells behave during cancer therapy.
Studies show that patients with a diverse, balanced gut microbiome respond better to immune checkpoint inhibitors, a class of immunotherapy drugs. Certain bacterial species can enhance T-cell activation, boost antigen presentation, and improve the overall anti-tumor response.
On the other hand, dysbiosis is linked to poorer response rates, treatment resistance, and more severe side effects in some patients.
This finding is so compelling that researchers are exploring whether modifying the microbiome could improve cancer treatment outcomes with immunotherapy[5].
Immune Cells, Microbes, and Tumors: A Three-Way Conversation
The triangle concept illustrates that cancer is not just a disease of malignant cells, but a disease of ecosystems. Immune cells, microbes, and tumor cells constantly interact through chemical signals, inflammatory mediators, and metabolic products.
Rather than a single fixed state, a “healthy” microbiome in cancer care is best thought of as a diverse, resilient community with a beneficial composition of microbes and metabolites that supports balanced immune responses. In NSCLC and other cancers, specific patterns of microbial diversity and composition, rather than the mere presence of bacteria, have been linked to stronger and more durable responses to immunotherapy.
Some microbes can even affect how tumors behave by altering the acidity of tissues, modifying metabolic pathways, or influencing immune checkpoints.
This interconnected network goes some way to explain why cancer can behave so differently from person to person[4, 5].
Can We Use the Microbiome to Fight Cancer?
This question is now at the center of cutting-edge research. Scientists are exploring several exciting strategies:
1. Microbiome-based biomarkers
Certain microbial patterns can predict how well a patient might respond to therapy. For example, specific gut bacteria have been associated with better immunotherapy outcomes[6]. In NSCLC, for example, patterns in the lung tissue microbiome can help distinguish adenocarcinoma from squamous cell carcinoma, highlighting how microbial signatures within the tumor microenvironment may serve as non‑traditional biomarkers for diagnosis and precision treatment planning.
2. Probiotics and diet-based modulation
Researchers are investigating whether foods, probiotics, or prebiotics can strengthen the microbiome enough to improve immune function[4].
3. Fecal microbiota transplantation (FMT)
Some clinical trials are assessing whether transferring microbiome material from a patient who responds well to immunotherapy can boost the response in a patient who does not[7].
4. Targeted microbial therapies
Future treatments may involve engineered bacteria that deliver drugs, modulate immune cells, or change local tissue environments.
We are entering a new era in cancer care where treatment may not only target the tumor, but also the ecosystem surrounding it.
The Future of Cancer Care Through the Microbiome Lens
As research expands, the microbiome–immune–cancer triangle is becoming a powerful framework for understanding why cancers behave the way they do and how treatments can be improved. It shines a light on the importance of whole-body health and the role that unseen microscopic partners play in shaping immunity. It also offers hope that by restoring balance to the microbiome, we may boost the effectiveness of modern therapies and improve long-term outcomes.
This growing body of research highlights one core principle: cancer cannot be understood in isolation, and at Helix BioPharma, we remain closely attuned to the scientific advances that reinforce this view. Microbial metabolites and immune-modulating signals influence systemic inflammation, cytokine profiles and immune cell activation. These systemic effects can ultimately alter how immune cells behave once they enter the tumor microenvironment (TME), affecting everything from immune surveillance to treatment responsiveness. In other words, the microbiome acts upstream, shaping the body’s immune tone and metabolic state, whereas the TME represents the downstream arena where these influences play out. The more we understand these upstream and downstream influences, the closer we move to pushing the boundaries of what cancer treatment can achieve.
References:
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