Microbiomes play critical roles in our lives. They play an important role in global ecosystems, and also in agriculture, where they provide plants with essential nutrients and even enzymes. But, we know very little about them. A group of 48 biologists and physical scientists from 50 institutions is aiming to change that. In the October 28, 2015, issue of the Science, they called for an ambitious research effort to understand and harness microbiomes. Such research could lead to advances in fields as diverse as medicine, child development, agricultural productivity, and climate modeling.
Now, in a far-ranging round table discussion, three of the paper's co-authors explain to The Kavli Foundation why this is the time to launch a major national effort - the Unified Microbiome Initiative - to study the planet's least understood ecosystems.
Janet Jansson. Jansson is Chief Scientist of Biology in the Earth and Biological Sciences Directorate at Pacific Northwest National Laboratory (PNNL) and sector lead for PNNL research in the Department of Energy's Biological Systems Science Division, said, "In the past, we did not fully understand the complexity and richness of microbiomes, and we were limited because we could not grow the majority of bacteria in a lab, and so they were hard to study."
Rob Knight, founder of the American Gut Project and holds joint appointments at the University of California, San Diego, School of Medicine and Department of Computer Science and Engineering, said, "New genomic tools have vastly expanded our understanding of the role microbiomes play in our lives. Remember, 10 years ago, microbes hadn't been linked to any of the things we now know they're involved in, such as obesity, allergies, depression and brain development. While the links between the microbiome and metabolism have certainly been very surprising, what surprised me the most has been the links between the microbiome and behavior. This was not even on the radar 10 years ago."
The Unified Microbiome Initiative calls for developing a new generation of scientific instruments that would let researchers study how microorganisms within a community interact with one another and their environment. This knowledge would make it possible to manipulate microbiomes to improve healthcare, agriculture and the environment.
The impact of microbiome research on human health alone could be profound. Over the past 10 years, researchers have discovered that the composition of the gut microbiome - which contains 10 times more cells and 100 times more genetic information than the human body - can determine how medicines are metabolized.
And physicians have demonstrated that transplanting healthy microbiomes into patients afflicted with colitis, an inflammation of the lining of the colon, caused by Clostridium difficile is three to four times more effective than antibiotics.
Jeff Miller, lead author of the Science paper, who is director of the California NanoSystems Institute, and holds the Fred Kavli Chair in NanoSystems Sciences, and is also a professor of Microbiology, Immunology & Molecular Genetics at University of California, Los Angeles, said, "This is actually the first proof of principle that we can manipulate microbiomes in a very deliberate way to treat a serious human disease."
Jansson studies how microbiomes behave as Arctic permafrost thaws. She hopes to learn how this will affect the metabolism of microbiomes that cycle carbon so scientists can model the impact on climate change.
However, the ability to engineer microbiomes also raises some flags. Miller said, "Whenever we manipulate something in an animal or a human being, we need to consider the ethical issues. But the idea of potentially engineering Earth's microbial ecosystems raises very legitimate questions."