In recent years, the trillions of bacteria living in
our guts have risen from obscurity to stardom. Hyped press releases claim that probiotics and faecal transplants might one day treat almost everything, from bowel inflictions to obesity. These studies often involve mice, but are these rodents really a suitable model for microbiome research?
The gut microbiome has been associated with an
ever-growing list of diseases, including obesity, diabetes and even mental
disorders such as anxiety and autism. Much like the Human Genome Project around
15 years ago, the booming microbiome research field has promised to deliver new
revolutionary treatments, some as simple as eating a yogurt. Perhaps inevitably
though, history repeats itself. After a few years of frantic microbiome sequencing and many new biotech start-ups,
microbiome researchers are now having to face the hard questions: are the
changes in the gut microbiome associated with certain diseases a cause, or a
consequence, of the disease? How on earth can bacteria in the gut affect other
parts of the body, such as the brain? What are the molecular mechanisms behind all
this?
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| E. coli bacteria thrive in the gut. |
Studies in humans can at most reveal correlations
between the microbiome composition and a given disease. For example: Bob is obese
and happens to have a microbiome with lots of bacteria X, but John, who is
slim, doesn’t. This suggests that bacteria X cause obesity, yet, there’s also a
good chance that in fact it’s the other way round: obesity might somehow
promote growth of bacteria X. Or maybe this type of bacteria thrives on Bob’s
diet, or it simply prefers the unique environment of his gut.
It is virtually impossible, and unethical, to perform
experiments in humans to explore causal hypotheses (does bacteria X cause
obesity?) and control for confounding factors like diet and genetic background.
Microbiome researchers have to use the next best thing: mice. There are,
however, growing concerns within the scientific community that more often than
not, data from mouse can’t be extrapolated to humans for clinical purposes. Or
at least, not easily.
In a new study, Jeroen Raes and colleagues at the KULeuven
University, in Belgium, carefully compared the human and mouse gut microbiomes to
assess the strengths and pitfalls of this model system for studying microbiome-related
diseases.
“Microbiome research, notably its association to
inflammatory diseases, relies heavily on mouse models […]. It is essential to
know the qualities and limitations of each model to choose the correct one to
test specific hypotheses”, says Sara Vieira-Silva, one of the authors conducting
the study.
Can mice recapitulate the human gut microbiome?
Mice are great for biomedical research. They share most
of our genes, and have similar anatomy and physiology. With the many available
genetic tools, scientists can easily and quickly discover the function of
literally any gene in the mouse genome, and recapitulate human disease in a
controlled experimental set up. So where’s the catch? The problem is that although
mice and humans share many similarities, there are also many differences.
Human and mouse guts
have predominantly two ‘families’ of bacteria—Bacteroidetes and Firmicutes—but
within these groups, 85% of bacteria species found in mice are not present in
humans. And the bacteria found in both? It appears their abundance in the gut
also varies between mice and humans; when you’ve got a lot of a certain
bacteria in mouse, you may find very little of it in humans, and vice versa.
The authors stress that many of these differences could simply be a result of
technical limitations, like methodology or interference from external factors
(diet, age, etc).
Mouse models of disease
There are over 60 mouse models of Inflammatory Bowel
Disease (IBD), but none fully recapitulates the disease. Even so, the changes
in the gut microbiome of patients with IBD (when compared to healthy people)
are similar to those observed in IBD mouse models. For example, there is a significant
reduction in bacterial diversity in both IBD patients and IBD mouse models. However,
some specific bacteria species will be more (or less) abundant in mouse but not
in IBD patients. The same goes for obesity models. Overall, mice fed on
high-fat diet, and also leptin-deficient mice, which cannot control their appetite,
recapitulate the microbiome changes observed in obese people. But there are
many discrepancies in the data, again likely due to external factors that are
difficult to control, at least in human studies.
The conclusion? Well, mice are not people. Raes and
colleagues warn microbiome researchers that extreme care should be taken when
trying to extrapolate findings in mouse to humans. They should also make bigger
efforts to standardise their protocols for animal handling and data analysis, and
to share mouse models to eliminate any genetic variability that might skew the
data.
“Most limitations of murine [mouse] models for
fundamental microbiome research can be overcome by methodical study design and
statistical testing: either eliminating or keeping track of possible
confounders (e.g. diet variation, genetic background) and testing for their
influence on the results”, says Vieira-Silva.
Nevertheless, the authors conclude, when it comes to
understanding the causes and molecular mechanisms behind human disease, mouse
models seem to fit the bill. “Although the mouse microbiota composition is not
identical to the human's, most mechanisms of microbiota-host interaction will
be shared between mice and humans” concludes Vieira-Silva. “Mice models allow
us to study these mechanisms with direct controlled experiments, towards the
ultimate aim of providing therapeutic solutions.”
Nguyen T.L.A., A. Liston & J. Raes (2015). How informative is the mouse for human gut microbiota research?, Disease Models , 8 (1) 1-16. DOI: http://dx.doi.org/10.1242/dmm.017400
And edited version of this article was published in Lab Times on the 24-02-2015. You can read it here.
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