Gut microbes play a variety of roles in health and disease, but there has been a dearth of tools to investigate the relationship between microbial activity and host physiology. Two new studies in mice have now overcome this hurdle, making it possible to simultaneously visualize multiple bacterial strains in the gut by making them express unique combinations of fluorescent proteins.
The approach allowed the researchers to pinpoint location of the bacteria in the gut based on the rainbow of colors they emitted. Additionally, these tools also allowed precise control of the activity of bacterial genes in real time and in specific locations.
“We found that tools from synthetic biology can allow us to ask new questions about the gut microbiota. We also imagine these strategies may provide a starting point for on-demand delivery of therapeutics or other molecules from the microbiota,”
Advances in sequencing technology have enabled in-depth characterization of bacterial species found in the gut, but tools to manipulate the gut microbiome have lagged far behind. Although tools have been developed for model organisms such as Escherichia coli, these systems do not work in Bacteroides, the most abundant genus within the guts of people in the United States.
In one of the studies, Justin Sonnenburg of the Stanford University School of Medicine and his team developed a way to engineer Bacteroides, making it possible to simultaneously track multiple bacterial strains in the gut. These tools included a panel of synthetic promoters — DNA sequences that initiate transcription of particular genes.
Using this panel of promoters, the researchers genetically engineered six different Bacteroides species to produce unique combinations of a red fluorescent protein (RFP) called mCherry and green fluorescent protein (GFP). They introduced the engineered species into mice that had been raised in a germ-free environment, and after two weeks, they analyzed sections of colon tissue using a fluorescence microscope to pinpoint the location of the bacteria in different parts of the gut.
In a separate experiment, Sonnenburg and his team genetically engineered two Bacteroides strains to produce either GFP or RFP. They then introduced the RFP-expressing strain into the mouse gut, followed by the GFP-expressing strain one week later.
It was clear that the RFP-expressing strain successfully colonized the colon and outcompeted the GFP-expressing strain, especially in tube-like glands called crypts. The findings demonstrate that colonization of these specific intestinal structures is a key step that allows longer-term gut residents to outcompete invading species.
In future research, Sonnenburg and his team will continue to develop these tools to engineer bacteria to produce proteins at a precise time or location.
“On the commercial side, the expression tools may allow us to deliver therapeutic proteins to the gut by producing them in the microbes that live inside of us. The use of bacterial cells for drug delivery opens the door to smart therapeutics that are produced at the right time and location,”
says Weston Whitaker, lead author of the Stanford study.
Synthetic Promoter Panel
In the other study, Yale’s Andrew Goodman and his team also developed a panel of synthetic promoters enabling the fine-tuned control of gene activity in diverse Bacteroides species. The researchers integrated these promoters into the Bacteroides genome and modulated gene activity using a tetracycline-regulated system, which allows transcription to reversibly turn on or off depending on the presence of a synthetic compound called anhydrotetracycline.
Luminal and crypt bacteria from co-colonized mouse proximal colon. Credit: Whitaker et al.
In the OFF state, gene activity controlled by the synthetic promoters was completely shut off, but in the presence of anhydrotetracycline, gene activity rapidly increased by a factor of 9,000. The researchers next introduced the engineered bacteria into mice and confirmed that their tools allow gene activity in gut bacteria to be tightly controlled, simply by adding different amounts of anhydrotetracycline to the drinking water of mice.
If extended to humans, this approach could potentially enable on-demand delivery of therapeutic compounds.
Moreover, precise control of bacterial gene activity in specific locations in the gastrointestinal tract could be achieved by administering anhydrotetracycline through different routes, for example, via time- or pH-dependent delayed release capsules or surgically through catheterization. In future studies, Goodman and his team will apply their system to other microbes and other types of interactions between gut microbes and their hosts.
“These tools open the door to new types of studies to better understand our microbiota and to define how gut commensal bacteria can be engineered for therapeutic purposes,” Sonnenburg says. “However, before gut commensals can be engineered for therapeutics, it will be important to develop methods of safely and reliably colonizing the human gut, which will require more research.”