Secret Army: More Manoeuvres Revealed


I don’t know about you but I find it difficult to grasp the idea that there are more bugs in my body than there are ‘me’ cells. That is, microorganisms (mostly bacteria) outnumber the aggregate of liver, skin and what-have-you cells. They’re attracted, of course, to the warm, damp surfaces of the cavities in our bodies that are covered by a sticky, mucous membrane, e.g., the mouth, nose and especially the intestines (the gastrointestinal tract).

The story so far

Over the last few years it’s become clear that these co-residents — collectively called the microbiota — are not just free-loaders. They’re critical to our well-being in helping to fight infection by other microrganisms (as we noted in Our Inner Self), they influence our immune system and in the gut they extract the last scraps of nutrients from our diet. So maybe it makes them easier to live with if we keep in mind that we need them every bit as much as they depend on us.

We now know that there are about 2000 different species of bacteria in the human gut (yes, that really is 2,000 different types of bug) and, with all that diversity, it’s not surprising that the total number of genes they carry far exceeds our own complement (by several million to about 20,000). In it’s a small world we noted that obesity causes a switch in the proportions of two major sub-families of bacteria, resulting in a decrease in the number of bug genes. The flip side is that a more diverse bug population (microbiome) is associated with a healthy status. What’s more, shifts of this sort in the microbiota balance can influence cancer development. Even more remarkably, we saw in Hitchhiker Or Driver? That the microbiome may also play a role in the spread of tumours to secondary sites (metastasis).

Time for a deep breath

If all this is going on in the intestines you might well ask “What about the lungs?” — because, and if you didn’t know you might guess, their job of extracting oxygen from the air we inhale means that they are covered with the largest surface area of mucosal tissue in the body. They are literally an open invitation to passing microorganisms — as we all know from the ease with which we pick up infections.

In view of what we know about gut bugs a rather obvious question is “Could the bug community play a role in lung cancer?” It’s a particularly pressing question because not only is lung cancer the major global cause of cancer death but 70% lung cancer patients have bacterial infections and these markedly influence tumour development and patient survival. Tyler Jacks, Chengcheng Jin and colleagues at the Massachusetts Institute of Technology approached this using a mouse model for lung cancer (in which two mutated genes, Kras and P53 drive tumour formation).

In short they found that germ-free mice (or mice treated with antibiotics) were significantly protected from lung cancer in this model system.

How bacteria can drive lung cancer in mice. Left: scheme of a lung with low levels of bacteria and normal levels of immune system cells. Right: increased levels of bacteria accelerate tumour growth by stimulating the release of chemicals from blood cells that in turn activate cells of the immune system to release other effector molecules that promote tumour growth. The mice were genetically altered to promote lung tumour growth (by mutation of the Kras and P53 genes). In more detail the steps are that the bacteria cause macrophages to release interleukins (IL-1 & IL-23) that stick to a sub-set of T cells (γδ T cells): these in turn release factors that drive tumour cell proliferation, including IL-22. From Jin et al. 2019.

As lung tumours grow in this mouse model the total bacterial load increases. This abnormal regulation of the local bug community stimulates white blood cells (T cells present in the lung) to make and release small proteins (cytokines, in particular interleukin 17) that signal to neutrophils and tumour cells to promote growth.

This new finding reveals that cross-talk between the local microbiota and the immune system can drive lung tumour development. The extent of lung tumour growth correlated with the levels of bacteria in the airway but not with those in the intestinal tract — so this is an effect specific to the lung bugs.

Indeed, rather than the players prominent in the intestines (Bs & Fs) that we met in Hitchhiker Or Driver?, the most common members of the lung microbiome are Staphylococcus, Streptococcus and Lactobacillus.

In a final twist Jin & Co. took bacteria from late-stage tumours and inoculated them into the lungs of mice with early tumours that then grew faster.

These experiments have revealed a hitherto unknown role for bacteria in cancer and, of course, the molecular signals identified join the ever-expanding list of potential targets for drug intervention.


Jin, C. et al. (2019). Commensal Microbiota Promote Lung Cancer Development via γδ T Cells. Cell 176, 998-1013.e16.


The Shocking Effect of Boiled Bugs

There’s never a dull moment in science – well, not many – and at the moment no field is fizzing more than immunotherapy. Just the other day in Outsourcing the Immune Response we talked about the astonishing finding that cells from healthy people could be used to boost the immune response – a variant on the idea of taking from patients cells that attack cancers, growing them in the lab and using genetic engineering to increase potency (generally called adoptive cell therapy).

A general prod

Just when you thought that was as smart as it could get, along comes Angus Dalgleish and chums from various centres in the UK and Spain with yet another way to give the immune system a shock. They used microorganisms (i.e. bugs) as a tweaker. The idea is that bacteria (that have been heat-killed) are injected, they interact with the host’s immune system and, by altering the proteins expressed on immune cells (macrophages, natural killer cells and T cells) can boost the immune response. That in turn can act to kill tumour cells. It’s a general ‘immunomodulatory’ effect. Dalgleish describes it as “rather like depth-charging the immune system which has been sent to sleep”. Well, giving it a prod at least.


Inactivating bugs (bacteria) and waking up the immune system.

And a promising effect

The Anglo-Spanish effort used IMM-101 (a heat-killed suspension of a bacterium called Mycobacterium obuense) injected under the skin, which has no significant side-effects. The trial was carried out in patients with advanced pancreatic cancer, a disease with dismal prognosis, and IMM-101 immunotherapy was combined with the standard chemotherapy drug (gemcitabine). IMM-101increased survival from a median of 4.4 months to 7 months with some patients living for more than a year and one for nearly three years.

Although the trial numbers are small as yet, this is a very exciting advance because it looks as though immunotherapy may be able to control one of the most serious of cancers in which its incidence nearly matches its mortality.


Dalgleish, A. et al. (2016). Randomised, open-label, phase II study of gemcitabine with and without IMM-101 for advanced pancreatic cancer. British Journal of Cancer doi: 10.1038/bjc.2016.271.