Meet The Microbiologist - The Scientists Behind The Microbiology

In this podcast, I talk to Charles Bamforth of the University of California, Davis, about the surprisingly complex chemistry of beer, and the pivotal role microbes play in making it happen.

In this podcast I talk to Thomas Scott of the University of California, Davis, about dengue fever, a disease that's on the rise. Spread by mosquitoes, it can make you feel as if your bones are broken and leave you exhausted for months. In more serious cases, people suffer uncontrollable bleeding and sometimes die. Dengue is expanding its range, and is even making incursions into the United States. Scott and I talk about what scientists know and don't know yet about dengue, and what the best strategy will be to drive the virus down.

In this podcast I talk to Charles Ofria, a computer scientist at Michigan State University. Ofria and his colleagues have created a program called Avida in which digital organisms can multiply and evolve. They are studying many of evolution's deepest questions, such as how complexity evolves from simplicity and why individuals make sacrifices for each other. The evolution unfolding in Avida is also yielded new software that can run robots and sensors in the real world. Bonus Content includes: Avida Movie In this movie, we started with a normal Avida organism in the middle of the population and let it grow for a while before injecting a highly-virulent parasite into the middle.  The hosts are all colored with shades of blue and the parasites are shades of red.

In this podcast I spoke to David Baker, a professor of biochemistry at the University of Washington. Baker and his colleagues study how proteins fold, taking on the complex shapes that make our lives possible. It turns out that protein folding is a fiendishly hard problem to solve, and even the  most sophisticated computers do a poor job of solving it. So Baker and his colleagues have enlisted tens of thousands of people to play a protein-folding game called Foldit. I talked to David Baker about the discoveries they've made through crowdsourcing, and the challenges of getting 57,000 co-authors listed on a paper. Additional Resources: Rosetta@Home Foldit

It never occurred to me that the human body and a coral reef have a lot in common--until I spoke to Forest Rohwer for this podcast. Rohwer is a microbiologist at San Diego State University, and he studies how microbes make coral reefs both healthy and sick. Just as we are home to a vast number of microbes, coral reefs depend on their own invisible menagerie of algae and bacteria to get food, recycle waste, and fend off invaders. But as Rohwer writes in his new book, Coral Reefs in the Microbial Seas, we humans have thrown this delicate balance out of kilter, driving the spread of coral-killing microbes instead. Additional Reading: Viral communities associated with healthy and bleaching corals.The lagoon at Caroline/Millennium atoll, Republic of Kiribati: natural history of a nearly pristine ecosystem.Metagenomic analysis of stressed coral holobionts.

In this podcast, I talk to Susan Golden, the co-director of the Center for Chronobiology at the University of California at San Diego. We talked about Golden's research into time--in particular, how living things know what time it is. While you may have heard of our own "body clock" that tracks the 24-hour cycle of the day, it turns out that some bacteria can tell time, too. Golden has discovered how evolution has produced a molecular clock inside microbes far more elegant than any manmade timepiece. Additional Reading: Proteins Found in a CikA Interaction Assay Link the Circadian Clock, Metabolism, and Cell Division in Synechococcus elongatus Quinone sensign by the circadian input kinase of the cyanobacterial circadian clock

How many genes can a species lose and still stay alive? It turns out, bacteria can lose just about all of them! In this podcast, I talk to Nancy Moran of Yale University about her fascinating work on the microbes that live inside insects such as aphids and cicadas. After millions of years, they have become stripped down creatures that are revealing some profound lessons about how superfluous most genes are--at least if you live inside a host. Recent Publications: Bacterial genes in the aphid genome: absence of functional gene transfer from Buchnera to its host Symbiosis and insect diversification: an ancient symbiont of sap-feeding insects from the bacterial phylum Bacteroidetes

In this podcast I talk to Carl Bergstrom of the University of Washington about the mathematics of microbes. Bergstrom is a mathematical biologist who probes the abstract nature of life itself. We talk about how life uses information, and how information can evolve. But in Bergstrom's hands, these abstractions shed light on very real concerns in medicine, from the way that viruses jam our immune system's communication systems to to the best ways to fight antibiotic resistance. Publications: Mapping Change in Large Networks [html] [pdf] The transmission sense of information [pdf] Dealing with deception in biology [pdf]

In this podcast I talk to Bonnie Bassler, a professor at Princeton and the president-elect of the American Society for Microbiology. Bassler studies the conversations that bacteria have, using chemicals instead of words, Her research is not only helping to reveal how bacteria work together to make us sick, but also how we might interrupt their dialogue in order to cure infections. Related Projects: Measurement of the copy number of the master quorum-sensing regulator of a bacterial cell. Information processing and signal integration in bacterial quorum sensing.

In this podcast, I talk to Mitchell Sogin, the Director of the Josephine Bay Paul Center for Comparative Molecular Biology and Evolution at the Marine Biological Laboratory in Wood's Hole, Massachusetts. Dr. Sogin is one of the leaders of an ambitious project to survey the microbes of the ocean--which total over 36,000,000,000,000,000,000,000,000,000,000 cells. Using the latest DNA-sequencing technology, Dr. Sogin and his colleagues are cataloging microbes from all over the world, and are discovering a genetic diversity in the microbial world far exceeding anyone's expectations.  Dr. Sogin explained how most species they find only exist in small numbers, while a minority of species dominate their samples. Dr. Sogin is investigating how this "rare biosphere" changes the way we understand how the ocean's ecosystems work. Related Projects: International Census of Marine Microbes Woods Hole Center for Oceans and Human Health

In this podcast I talk to James Liao, a professor in the Department of Chemical and Biomolecular Engineering at UCLA. I spoke to Dr. Liao about his research into engineering microbes to make fuel. Today, we get most of the fuel for our cars out of the ground. It's a process fraught with dangerous consequences, from the oil spill in the Gulf of Mexico to the rise in global temperatures thanks to greenhouse gases. Dr. Liao is among a growing number of scientists who think that microbes can help us out of this predicament. We talked about the attraction of microbe-derived fuels, and the challenges of getting bacteria to turn air, water, and sun into something that can power your car. Selected Publications Atsumi, S.; T. Hanai and J.C. Liao (2008) Non-Fermentative Pathways for Synthesis of Branched-Chain Higher Alcohols as Biofuels, Nature, 451:86-89. Atsumi,S.; Higashide, W.; and Liao, J.C. (2009) Direct recycling of carbon dioxide to isobutyraldehyde using photosynthesis, Nat Biotechnol,

In this podcast, I talk to R. Ford Denison of the University of Minnesota. Denison is an evolutionary biologist who's interested in how to make agriculture better. The ways in which plants thrive or fail are shaped by their evolutionary history, as well as the evolution that unfolds every planting season. We're most familiar with the evolution of resistance to pesticides in insects and to herbicides in weeds. But evolution has many other effects on farms. For example, many important crop plants, like soybeans, cannot extract nitrogen from the atmosphere on their own. They depend instead on bacteria that live inside their roots. In exchange for fixed nitrogen, the bacteria get nutrients from the plants. It may seem like a happy case of cooperation, but the evolution of cooperation always runs the risk of cheating and deception. How plants and bacteria come to a compromise is a remarkable story that Denison and his colleagues are now documenting. Selected Publications Denison, R.F. 2010.

In this podcast, I talk with Irwin Sherman, professor emeritus at the University of California at Riverside, about the century-long quest for a vaccine against malaria. Scientists have been trying to make a vaccine for the disease almost since the discovery of the parasite that causes malaria. Yet decade after decade, they've encountered setbacks and failures. We talked about why it's so hard to make a malaria vaccine, and how likely it is that scientists will ever be able to do so in the future. If you want to find out more about this long-running saga, check out Sherman's new book, The Elusive Malaria Vaccine: Miracle or Mirage. About the Book Chronicling a 100-year quest, this book tells the fascinating story of the hunt for the still-elusive malaria vaccine. Its clear, engaging style makes the book accessible to a general audience and brings to life all the drama of the hunt, celebrating the triumphs and documenting the failures. The author captures the controversies, missteps, wars of

In this podcast I talk to Keith Klugman, William H. Foege Chair of Global Health at Emory University. Dr. Klugman studies the disease that is the number one killer of children worldwide. If you guessed malaria or AIDS, you’d be wrong. It’s pneumonia. Two million children under five die every year from it every year--one child every 15 seconds.   Dr. Klugman and I spoke about his research on how pneumonia causes so much devastation, its hidden role in the 50 million deaths in the 1918 flu pandemic, and how a new pneumonia vaccine can stop the disease in its tracks. For more information on pneumonia and how we can all help fight it, visit the World Pneumonia Day web site. Dr. Klugman's recent publications: A role for Streptococcus pneumoniaein virus-associated pneumonia (pdf) Levofloxacin-Resistant Invasive Streptococcus pneumoniae in the United States: Evidence for Clonal Spread and the Impact of Conjugate Pneumococcal Vaccine (pdf)  

Dr. Peter Daszak is a disease ecologist and President of the Wildlife Trust, an international organization of scientists dedicated to the conservation of biodiversity. He is a leader in the field of conservation medicine and is well known for uncovering the wildlife origin of the SARS virus. Dr. Daszak also identifed the first case of a species extinction caused by a disease and has demonstrated a link between global trade and disease emergence via a process called "pathogen pollution." In this interview I ask Dr. Daszak about the threat new pathogens pose to endangered species and go into detail about his discovery that chytridiomycosis, a fungal disease caused by the chytrid Batrachochytrium dendrobatidis, is responsible for global amphibian population declines. Dr. Daszack also discusses a unique study that exposes how the W.H.O. might better use their resources when faced with new pathogens such as the kind we've seen with the recent outbreak of the H1N1 virus. We also explore how pathogens

In this podcast I talk to Curtis Suttle, a professor and associate dean at the University of British Columbia.Suttle studies the diversity and population of viruses across the entire planet. He has helped show that viruses are by far the most common life forms on the planet. They also contain most of the genetic diversity of life, and they even control how much oxygen we have to breathe. I talked to Suttle about coming to terms with the fact that we live on a virus planet, and how hard it is to find a place on Earth that's virus-free--even two miles underground.  Links to Curtis Suttle and his work. Curtis Suttle's Labatory Website A detailed listing of Curtis Suttle's publications

In this podcast, I talk to James Collins, an investigator at the Howard Hughes Medical Institute and a professor at Boston University. Ten years ago Collins helped launch a new kind of science called synthetic biology. I talked to Collins about the achievements of synthetic biology over the past decade, such as engineering E. coli that can count, and about the future of synthetic biology--from using bacteria to make fuel to reprogramming the bacteria in our guts to improve our health.

In this episode, I talk to Michael Worobey, an associate professor at the University of Arizona. Worobey is virus detective, gathering clues about how some of the world's deadliest pathogens have emerged and spread across the globe. Worobey and I talked about the harrowing journeys he has made in search of the origin of HIV, as well as the round-the-clock data-processing he and his colleagues used to discover the hidden history of the new H1N1 flu strain.

In this episode, I speak to Rob Knight, an assistant professor in the Department of Chemistry and Biochemistry at the University of Colorado, Boulder. Knight studies our inner ecology: the 100 trillion microbes that grow in and on our bodies. Knight explained how hundreds of species can coexist on the palm of your hand, how bacteria manipulate your immune system and maybe even your brain, and how obesity and other health problems may come down to the wrong balance of microbes. Links to studies mentioned in this episode: Ruth Ley and Peter Turnbaugh's studies on obesity in Jeff Gordon's lab: Obesity alters gut microbial ecology. Microbial ecology: human gut microbes associated with obesity. An obesity-associated gut microbiome with increased capacity for energy harvest. A core gut microbiome in obese and lean twins. Julie Segre's studies of the skin: A diversity profile of the human skin microbiota. Topographical and temporal diversity of the human skin microbiome. Chris Lauber and Elizabeth Costello's s

In this episode I speak to Julian Davies, professor emeritus in the Department of Microbiology & Immunology at the University of British Columbia. Dr. Davies is one of the world's experts on antibiotics. I talked to Davies about how the discovery of antibiotics changed the course of modern medicine, and how we now face a growing threat from the evolution of antibiotic-resistant bacteria. We also talked about some enduring mysteries about antibiotics. Most of us think of antibiotics as a way to kill microbes. But the fact is that microbes make antibiotics naturally, and for them, these molecules may not be lethal weapons. They may actually be a way to talk to other microbes.