This episode: How family members share gut microbes across multiple generations!

Download Episode (7.3 MB, 10.7 minutes) Show notes: Microbe of the episode: Dyozetapapillomavirus 1

This episode: Bacteriophages can hitch a ride on bacteria they don't infect to travel through soil on fungal filaments, potentially helping their carriers by infecting and killing their competitors!

Download Episode (7.1 MB, 10.3 minutes) Show notes: Microbe of the episode: Epinotia aporema granulovirus

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This episode: Beetles inoculate bamboo with a fungus that consumes the bamboo sugars to feed the beetle larvae!

Download Episode (7.7 MB, 11.2 minutes) Show notes: Microbe of the episode: Saccharomyces cerevisiae virus L-BC (La)

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Video: Lizard beetle laying its egg

This episode: New techniques allow specific modifications in certain members of a complex community of microbes, without isolating them in pure culture first!

Download Episode (11.5 MB, 16.7 minutes) Show notes: Microbe of the episode: Tomato golden mosaic virus

12-crispring-microbiome-corner.html">News item

This episode: Predatory bacteria could protect lobster farms from disease-causing bacteria!

Download Episode (4.8 MB, 7 minutes) Show notes: Microbe of the episode: Gordonia rubripertincta

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This episode: A bacteriophage that overcomes the bacterial CRISPR/Cas immune system by interrupting the CRISPR DNA with its own genome!

Download Episode (6.8 MB, 10 minutes) Show notes: Microbe of the episode: Wenzhou mammarenavirus

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This episode: Bacteria can use blobs of disordered proteins to quickly adapt to new conditions!

Download Episode (10.9 MB, 15.9 minutes) Show notes: Microbe of the episode: Drosophila melanogaster Micropia virus

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This episode: A phage both kills bacterial pathogens and selects for reduced virulence!

Download Episode (6.3 MB, 9.9 minutes) Show notes: Microbe of the episode: Helminthosporium victoriae 145S virus

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This episode: Tiny bacteria that live on larger bacteria reduce the inflammation and gum disease the bigger microbes cause in the mouths of mice!

Download Episode (6.3 MB, 9.2 minutes) Show notes: Microbe of the episode: Actinomadura viridilutea

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This episode: A virus lurking in a bacterial genome protects its host population from infection with other phages, by killing off infected cells!

Download Episode (7.6 MB, 11.0 minutes) Show notes: Microbe of the episode: Olive latent ringspot virus

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This episode: Harmless gut microbes resist cholera with good defense or better offense!

Download Episode (5.8 MB, 8.4 minutes) Show notes: Microbe of the episode: Streptomyces corchorusii

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This episode: Prions in yeast can allow better adaptation to changing conditions!

Download Episode (9.5 MB, 13.9 minutes) Show notes: Microbe of the episode: Hepatovirus F

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This episode: Bacteria are able to extract metals from rocks for industrial use, even in microgravity!

Download Episode (6.2 MB, 9.0 minutes) Show notes: Microbe of the episode: Decapod ambidensovirus 1

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This episode: Bacteria living inside soil fungus produce toxins that can protect their host from tiny predators!

Download Episode (7.7 MB, 11.2 minutes) Show notes: Microbe of the episode: Mycobacterium virus DLane

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This episode: Certain nectar-dwelling bacteria can induce pollen to germinate to access their tasty proteins!

Download Episode (6.0 MB, 8.8 minutes) Show notes: Microbe of the episode: Clostridium oceanicum

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This episode: Bacteria produce a compound that causes a phage lurking in the genome of a competing species to wake up and start killing that competitor!

Download Episode (8.2 MB, 12.0 minutes) Show notes: Microbe of the episode: Zaire ebolavirus

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This episode: A eukaryote has symbionts living in it: green algae and also purple bacteria, a combo never seen before!

Download Episode (6.1 MB, 8.8 minutes) Show notes: Microbe of the episode: Staphylococcus virus phiETA

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This episode: Training a phage strain on bacteria can increase its ability to control those bacteria for much longer than an untrained phage!

Download Episode (5.7 MB, 8.3 minutes) Show notes: Microbe of the episode: Pepper yellow leaf curl Indonesia virus

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This episode: A bacterial communication signal makes algae stop growing, which helps them survive virus attacks!

Download Episode (5.3 MB, 7.7 minutes) Show notes: Microbe of the episode: Veillonella parvula

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This episode: Transplanting microbes from some corals to others could help the corals survive high temperatures!

Download Episode (5.7 MB, 8.3 minutes) Show notes: Microbe of the episode: Streptomyces olivaceoviridis

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This episode: Bacteria can resist the force of gravity in liquid culture by covering themselves with goopy sugar polymers like parachutes!

Download Episode (10.4 MB, 15.2 minutes) Show notes: Microbe of the episode: Brevicoryne brassicae virus

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This episode: Newspapers report on scientific studies about microbiomes a fair amount, but certain kinds of studies are more likely than others to show up in the news!

Download Episode (5.7 MB, 8.3 minutes) Show notes: Microbe of the episode: Cafeteriavirus-dependent mavirus

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This episode: A virus of archaea stops cells from dividing, so they just keep getting bigger and releasing more viruses!

Download Episode (6.9 MB, 10.1 minutes) Show notes: Microbe of the episode: Streptomyces caelestis

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This episode, in honor of World Ocean Day: Bacteria that may move between high and low pressure areas in the ocean use a particular molecule to protect their cells from being crushed!

Download Episode (6.6 MB, 9.5 minutes) Show notes: Microbe of the episode: Rickettsia rickettsii

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This episode: Spores of some bacteria latch onto the tails of other bacteria and ride along as they move around in the soil!

Download Episode (5.5 MB, 8.0 minutes) Show notes: Microbe of the episode: Bohle iridovirus

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This episode: Some bacteria produce antibiotics that can also help them gather more nutrients!

Download Episode (5.0 MB, 7.3 minutes) Show notes: Microbe of the episode: Diadromus pulchellus toursvirus

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This episode: Single-celled eukaryotes can thrive without oxygen with the help of bacterial endosymbionts that respire nitrate the way our mitochondria respire oxygen!

Download Episode (12.4 MB, 18.1 minutes) Show notes: Microbe of the episode: Brenneria salicis

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This episode: Despite being photosynthetic, some kinds of algae engage in predatory behavior, hunting and consuming live bacteria!

Download Episode (4.9 MB, 7.1 minutes) Show notes: Microbe of the episode: Paramecium bursaria Chlorella virus 1

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This episode: Lighting in caves open to tourists supports the growth of unwanted photosynthetic bacteria!

Download Episode (6.6 MB, 9.5 minutes) Show notes: Microbe of the episode: Dill cryptic virus 2

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This episode: Deep-sea bacteria can detoxify cadmium and convert it to light-capturing particles!

Download Episode (5.8 MB, 8.4 minutes) Show notes: Microbe of the episode: Arthrobacter virus Sonny

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Finally found some good stories, so we're back! This episode: How slime molds encode and use memories built into their own bodies!

Download Episode (4.6 MB, 6.7 minutes) Show notes: Microbe of the episode: Aeromonas salmoncida

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This episode: Giant bacteria with many chromosomes in each cell carry extra genes to help them live in many different environments!

Download Episode (8.7 MB, 12.7 minutes) Show notes: Microbe of the episode: Propionibacterium virus SKKY

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This episode: The biofilm that probiotic bacteria can leave behind on a titanium implant seems to help it integrate better with the existing skeleton, with less inflammation and risk of infection!

Download Episode (5.5 MB, 7.9 minutes) Show notes: Microbe of the episode: Methylobacterium organophilum

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This episode: Engineered bacteria encapsulated in little beads sense chemicals from landmines and give off light!

Download Episode (6.4 MB, 9.3 minutes) Show notes: Microbe of the episode: Bifidobacterium pullorum

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This episode: An interesting bacterial genetic element protects against viruses in a unique way!

Download Episode (7.1 MB, 10.3 minutes) Show notes: Microbe of the episode: Mongoose associated gemykibivirus 1

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This episode: Certain gut microbes protect mice from harmful effects of high-energy radiation!

Download Episode (7.3 MB, 10.6 minutes) Show notes: Microbe of the episode: Solenopsis invicta virus-1

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This episode: Algae surviving impact that killed the dinosaurs seem to have consumed other organisms to make it through the dark times!

Download Episode (7.1 MB, 10.3 minutes) Show notes: Microbe of the episode: Chaetoceros tenuissimus RNA virus 01

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This episode: A fungus-infecting virus transforms the fungal foe into a friend of its host plant!

Download Episode (6.1 MB, 8.9 minutes) Show notes: Microbe of the episode: Hepacivirus J

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This episode: Bacteria pay for the privilege of cruising around soil on fungus filaments!

Download Episode (7.7 MB, 11.2 minutes) Show notes: Microbe of the episode: Clostridium acetobutylicum

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This episode: Bacteria protect farmed mushrooms from damage by other bacteria by breaking down their toxins!

Download Episode (4.9 MB, 7.1 minutes) Show notes: Microbe of the episode: Tomato mosaic virus

Takeaways

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This episode: Actinomycete bacteria are often helpful to insects, but some can be deadly yet still attractive!

Download Episode (5.7 MB, 8.3 minutes) Show notes: Microbe of the episode: Streptomyces corchorusii

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This episode: Warmth helps mice build stronger bones, mediated by bacteria producing certain compounds!

Download Episode (6.8 MB, 9.9 minutes) Show notes: Microbe of the episode: Aquaspirillum serpens

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This episode: Copper electrodes, rather than killing bacteria in microbial fuel cells, allow them to generate higher densities of electric current!

Download Episode (5.0 MB, 7.2 minutes) Show notes: Microbe of the episode: Xipapillomavirus 2

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This episode: Combining Salmonella with something called photoimmunotherapy to attack tumors in multiple ways!

Download Episode (8.2 MB, 11.9 minutes) Show notes: Microbe of the episode: Shimwellia blattae

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This episode: Large phage discovered that contains a compact version of the CRISPR/Cas defense/gene editing system!

Download Episode (5.9 MB, 8.6 minutes) Show notes: Microbe of the episode: Stenotrophomonas virus IME13

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This episode: A probiotic can protect intestine-like cell growths from destruction by pathogens, but it can also be infected by a virus that makes it more harmful to intestinal cells!

Download Episode (6.9 MB, 10.1 minutes) Show notes: Microbe of the episode: Euphorbia yellow mosaic virus

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This episode: Bacteria living in the driest place on earth have ways to extract water from the mineral structures of rocks!

Download Episode (3.7 MB, 5.4 minutes) Show notes: Microbe of the episode: Irkut lyssavirus

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This episode: Cable bacteria around rice roots transport electrons and help prevent formation of methane!

Download Episode (5.7 MB, 8.3 minutes) Show notes: Microbe of the episode: Vibrio alginolyticus

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This episode: Bacteria that can store sugar as glycogen have multiple advantages when food is only available sporadically!

Download Episode (7.2 MB, 10.4 minutes) Show notes: Microbe of the episode: Carnivore bocaparvovirus 3 Takeaways

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This episode: Bacteria in soil produce smells to attract arthropods that eat them but also spread their spores!

Download Episode (6.2 MB, 9.0 minutes) Show notes: Microbe of the episode: Blotched snakehead virus

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This episode: The skin microbes that people leave behind may be used to identify them, even after other people have touched the same surface!

Download Episode (5.4 MB, 7.9 minutes) Show notes: Microbe of the episode: Actinobacillus lignieresii Takeaways

Journal Paper: Hampton-Marcell JT, Larsen P, Anton T, Cralle L, Sangwan N, Lax S, Gottel N, Salas-Garcia M, Young C, Duncan G, Lopez JV, Gilbert JA. 2020. Detecting personal microbiota signatures at artificial crime scenes. Forensic Sci Int 313:110351.

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This episode: Bacterial cells with their genomes removed can still be active and useful!

Download Episode (10.2 MB, 14.9 minutes) Show notes: Microbe of the episode: Rosavirus A Takeaways

Journal Paper: Fan C, Davison PA, Habgood R, Zeng H, Decker CM, Salazar MG, Lueangwattanapong K, Townley HE, Yang A, Thompson IP, Ye H, Cui Z, Schmidt F, Hunter CN, Huang WE. 2020. Chromosome-free bacterial cells are safe and programmable platforms for synthetic biology. Proc Natl Acad Sci 117:6752–6761.

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This episode: A fungus paralyzes its tiny worm prey by acting on the worm's own sensory hairs!

Download Episode (6.0 MB, 8.7 minutes) Show notes: Microbe of the episode: Bat associated cyclovirus 9 Takeaways

Journal Paper: Lee C-H, Chang H-W, Yang C-T, Wali N, Shie J-J, Hsueh Y-P. 2020. Sensory cilia as the Achilles heel of nematodes when attacked by carnivorous mushrooms. Proc Natl Acad Sci 117:6014–6022.

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This episode: This episode: A bacteriophage and bacterial predator can wipe out a population of bacteria that could develop resistance to each individually!

Download Episode (6.8 MB, 9.9 minutes) Show notes: Microbe of the episode: Blackbird associated gemycircularvirus 1 Takeaways

Journal Paper: Hobley L, Summers JK, Till R, Milner DS, Atterbury RJ, Stroud A, Capeness MJ, Gray S, Leidenroth A, Lambert C, Connerton I, Twycross J, Baker M, Tyson J, Kreft J-U, Sockett RE. 2020. Dual Predation by Bacteriophage and Bdellovibrio bacteriovorus Can Eradicate Escherichia coli Prey in Situations where Single Predation Cannot. J Bacteriol 202.

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This episode: Certain bacteria can greatly affect the makeup of a microbial community, even if they quickly disappear!

Download Episode (6.3 MB, 9.2 minutes) Show notes: Microbe of the episode: Gadgets Gully virus 02-microbes-environment-dying.html">News item Takeaways

Journal Paper: Amor DR, Ratzke C, Gore J. 2020. Transient invaders can induce shifts between alternative stable states of microbial communities. Sci Adv 6:eaay8676.

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This episode: Helping insect-killing bacterial symbionts of nematodes evolve resistance to chemicals that major corn pests use to defend themselves!

Download Episode (10.0 MB, 14.0 minutes) Show notes: Microbe of the episode: Listeria virus PSA Takeaways

Journal Paper: Machado RAR, Thönen L, Arce CCM, Theepan V, Prada F, Wüthrich D, Robert CAM, Vogiatzaki E, Shi Y-M, Schaeren OP, Notter M, Bruggmann R, Hapfelmeier S, Bode HB, Erb M. 2020. Engineering bacterial symbionts of nematodes improves their biocontrol potential to counter the western corn rootworm. 5. Nat Biotechnol 38:600–608.

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This episode: Producing both biodiesel and bioethanol fuels from cold-loving Arctic algae!

Download Episode (8.7 MB, 12.6 minutes) Show notes: Microbe of the episode: Royal Farm virus Takeaways

Journal Paper:

Kim EJ, Kim S, Choi H-G, Han SJ. 2020. Co-production of biodiesel and bioethanol using psychrophilic microalga Chlamydomonas sp. KNM0029C isolated from Arctic sea ice. Biotechnol Biofuel 13:20.

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This episode: Using phages to target gold nanoparticles to infecting bacteria, then using light to heat the nanoparticles just enough to kill the bacteria! Thanks to Raymond Borg and Huan Peng for contributing!

Download Episode (10.6 MB, 15.4 minutes) Show notes: Microbe of the episode: Pantoea agglomerans News item Takeaways Viruses that infect bacteria, bacteriophages, are often very good at overcoming bacterial defenses and killing them. This raises the possibility, and many times actuality, of using phages to treat bacterial infections that are no longer treatable with antibiotics. But bacteria can evolve resistances to viruses as well as drugs, and using multiplying, evolving entities as treatments in people raises questions about the safety and consistency of the treatment. This study circumvents these questions by using phages for delivery and targeting of bacteria rather than the therapeutic agent itself. The actual treatment is done with tiny rods of gold, gold nanorods, bound to the phage surface. When a certain wavelength of light hits these nanorods, they vibrate enough to generate enough heat in their immediate surroundings to render nearby bacteria nonviable. Thus the infection is treated in a very localized, targeted way that doesn't leave any active bacteria or phages behind. The authors have plans to study this approach as a topical treatment of wounds. Journal Paper: Peng H, Borg RE, Dow LP, Pruitt BL, Chen IA. 2020. Controlled phage therapy by photothermal ablation of specific bacterial species using gold nanorods targeted by chimeric phages. Proc Natl Acad Sci 117:1951–1961.

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This episode: Simplified gut communities growing in bioreactors grow and metabolize reproducibly, with only moderate variations, even when individual members of the community are absent!

Download Episode (8.2 MB, 11.9 minutes) Show notes: Microbe of the episode: Citrobacter virus Merlin Takeaways The community of microbes in our guts is highly complex, with thousands of species all interacting with each other, with our own cells, and with the contents of our diet. Each region of the gut has a different collection of microbes as well. Many questions remain to be answered about the functions and fluctuations of these communities. How can we study such a complex system? Which species, if any, are most important for its continued function? In this study, a simplified community of only 14 species is grown repeatedly in bioreactors, and one species at a time is left out of the community to see what will change in its absence. This reveals effects different species have on the overall growth, carbon source consumption, and production of various metabolites relevant to gut health. Some microbes have large effects, but none of them appears to be crucial for the overall function and stability of the community. Journal Paper: Gutiérrez N, Garrido D. 2019. Species Deletions from Microbiome Consortia Reveal Key Metabolic Interactions between Gut Microbes. mSystems 4:e00185-19.

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BacterioFiles is back! This episode: Measuring how quickly marine methane-consuming microbes become active when new methane enters an area!

Download Episode (9.0 MB, 13.0 minutes) Show notes: Microbe of the episode: Torque teno midi virus 6 Takeaways Oceans and the organisms living in them have a large effect on the planet, in terms of climate and gases they absorb from or release into the atmosphere. They are a source of much of a potent greenhouse gas, methane, but microbes living in ocean sediments also consume large amounts of methane. These anaerobic methanotrophic archaea generate energy for themselves by transforming methane and sulfate into carbonate and sulfide. In this study, however, methane-consuming microbes were only found active at sites of methane seepage. Even in sites where methane had previously been present, only few of these microbes were present and active. After enriching samples of these sediments for up to 8 months, still the only activity that was seen was from actively methane-consuming communities. So once dispersed, such communities seem slow to regenerate as the locations of methane seepage shift. Journal Paper: Klasek S, Torres ME, Bartlett DH, Tyler M, Hong W-L, Colwell F. 2020. Microbial communities from Arctic marine sediments respond slowly to methane addition during ex situ enrichments. Environ Microbiol 22:1829–1846.

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This episode: A newly discovered species of bacteria consumes other bacteria as prey by engulfing them!

Download Episode (8.7 MB, 12.6 minutes) Show notes: Microbe of the episode: SARS-CoV-2! This is the coronavirus responsible for COVID-19, the current pandemic. For more up-to-date information, please refer to the American Society for Microbiology, This Week in Virology, and other reputable sources. Stay healthy! Takeaways There are bacteria living almost every different lifestyle you can think of, including predatory, preying on other bacteria. Since bacterial cells are usually quite rigid, bacterial predators usually consume others either by burrowing inside them or digesting them from outside, rather than engulfing prey like eukaryotes often do. The study here discovers a new kind of bacteria, in the group called Planctomycetes, known for having unusually flexible cells and internal compartments like eukaryotes. This new species does engulf its prey, including bacteria and even tiny algae, and digests them inside itself. It possesses multiple adaptations that suit it for this lifestyle. Journal Paper: Shiratori T, Suzuki S, Kakizawa Y, Ishida K. 2019. Phagocytosis-like cell engulfment by a planctomycete bacterium. Nat Commun 10:1–11.

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This episode: A phage defends its genome against bacterial host defenses by building a wall to keep them out!

Download Episode (7.0 MB, 10.2 minutes) Show notes: Microbe of the episode: Myroides odoratus and M. odoratimimus 12-crispr-resistant-viruses-safe-rooms-shield.html">News item Takeaways Parasites and their hosts are constantly in arms races with each other, each thriving best when it acquires new and more effective methods of attack, defenses, defenses against defenses, and so on. Bacterial defenses against viruses that infect them mostly involve cutting up viral genomes, either by the indiscriminate specific-cutting restriction enzymes, or by adaptive, sequence-sensing CRISPR/Cas systems. Bacteriophages have proteins that can defend against the CRISPR/Cas system, but they mostly require the sacrifice of multiple failed infections before the proteins build up enough to defeat the defense. In this study, a phage is discovered that can immediately defend against all DNA-cutting systems, by constructing a nucleus-like protective compartment inside the host. Journal Paper: Mendoza SD, Nieweglowska ES, Govindarajan S, Leon LM, Berry JD, Tiwari A, Chaikeeratisak V, Pogliano J, Agard DA, Bondy-Denomy J. 2020. A bacteriophage nucleus-like compartment shields DNA from CRISPR nucleases. Nature 577:244–248.

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This episode: Earth's iron deposits could have been created by anaerobic light-harvesting microbes instead of those that make oxygen!

Download Episode (9.3 MB, 13.5 minutes) Show notes: Microbe of the episode: Streptomyces avidinii News item Takeaways In the ancient earth, the sun was dimmer, the world was colder, and oxygen was rare because photosynthesis had not yet evolved. Without oxygen to oxidize it, iron remained in its soluble, more accessible form, and many organisms took advantage of it for anaerobic metabolism. But was it photosynthesis and the oxygen it created that transformed most of the planet's iron into its insoluble form, creating large iron deposits in the ground? This study explores the possibility that it was another form of light-harvesting metabolism, called photoferrotrophy, that uses light and the transformation of iron to generate energy. This hypothesis is found to be consistent with the evidence we have about what the early earth was like. Journal Paper: Thompson KJ, Kenward PA, Bauer KW, Warchola T, Gauger T, Martinez R, Simister RL, Michiels CC, Llirós M, Reinhard CT, Kappler A, Konhauser KO, Crowe SA. 2019. Photoferrotrophy, deposition of banded iron formations, and methane production in Archean oceans. Sci Adv 5:eaav2869.

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This episode: A global estimate of plants and their root fungi shows how agriculture may have greatly affected soil carbon storage over time!

Download Episode (5.7 MB, 8.3 minutes) Show notes: Microbe of the episode: Rhizobium virus RHEph4 News item Takeaways Even small organisms can have a big effect on the climate of the planet if there are enough of them. This includes trees, which are small relative to the planet, and also includes the fungi that attach to the roots of trees and other plants. These mycorrhizal fungi thread subtly through the soil, some occasionally popping up mushrooms, and transfer valuable nutrients they gather to the trees in exchange for carbon fixed from the air. Knowing how big an effect a given kind of organism has requires knowing how much of it is around. This study collates data from various surveys of global plant populations and the fungi that interact with their roots, to estimate a global picture of the fungi below our feet. It estimates that a kind of fungus that stores more carbon in the soil may have been replaced in many areas with fungi that store less, or no fungi at all, due to the transformation of land from wild areas to farmland. Journal Paper: Soudzilovskaia NA, van Bodegom PM, Terrer C, Zelfde M van’t, McCallum I, Luke McCormack M, Fisher JB, Brundrett MC, de Sá NC, Tedersoo L. 2019. Global mycorrhizal plant distribution linked to terrestrial carbon stocks. Nat Commun 10:1–10.

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This episode: Microalgae can produce hydrogen, but other metabolic pathways take priority, except when special engineered hydrogenase enzymes can overcome this limitation!

Download Episode (8.4 MB, 12.2 minutes) Show notes: Microbe of the episode: Alphapapillomavirus 11 Takeaways There are many options being explored as ways to replace fossil fuels. Electricity and batteries are good, but they have their limitations, especially for long-distance high-energy travel such as airplanes. Hydrogen is one good option: high energy density, clean-burning, simple to produce. Microbes can produce hydrogen through various metabolic pathways, including fermentation, nitrogen fixation byproduct, and photosynthesis. However, competing metabolic pathways make microbial hydrogen production less efficient. In this study, scientists engineer a hydrogenase enzyme for hydrogen production in microalgae that can compete better with carbon fixation as a destination for the electrons and protons that hydrogen production requires. This engineered enzyme allowed the algae to produce hydrogen continuously, even during photosynthesis. Journal Paper: Ben-Zvi O, Dafni E, Feldman Y, Yacoby I. 2019. Re-routing photosynthetic energy for continuous hydrogen production in vivo. Biotechnol Biofuels 12:266.

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This episode: Some fungi only form fruiting bodies after forest fires; where do they hide the rest of the time? At least for some of them, the answer is: inside mosses! Thanks to Daniel Raudabaugh for his contribution!

Download Episode (6.2 MB, 9.0 minutes) Show notes: Microbe of the episode: Nocardia brevicatena News item Takeaways Forest fires can do a lot of damage, but life grows back quickly. Certain kinds of plant seed actually only germinate after a fire, and a similar thing is true of certain kinds of fungi: they only form fruiting bodies (like mushrooms, for spreading spores) after a fire. For plants, the advantage may come from increased access to light with some or all of the canopy burned away, and fungi may benefit from less competition on the ground. But in between burn events, these fire-loving (pyrophilous) fungi seem to disappear. Where do they go? The study here sought an answer, suspecting an association with some mosses that reappeared soon after a forest fire in North Carolina in 2016. They looked for fungi lurking as endophytes inside moss and other samples, both by growing them on agar and by DNA sequencing, and they found a number of different known pyrophilous fungi. Some of these were in soil, or samples from outside the burned area, but the majority were inside mosses growing in the recently burned zone. Journal Paper: Raudabaugh DB, Matheny PB, Hughes KW, Iturriaga T, Sargent M, Miller AN. 2020. Where are they hiding? Testing the body snatchers hypothesis in pyrophilous fungi. Fungal Ecol 43:100870.

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This episode: Looking at the effects of almost doubling CO₂ concentrations on the interaction between wheat varieties and beneficial fungi!

Download Episode (8.1 MB, 11.8 minutes) Show notes: Microbe of the episode: Lato River virus News item Takeaways As the world's population grows, feeding everyone will grow more challenging. Advances in technology in the past have made today's population possible, but future advances may be needed, especially in the face of an increasing concentration of carbon dioxide in the atmosphere. Soil microbes that partner with crop plants for the benefit of each may be part of the solution. One option to explore is a group called mycorrhizal fungi, which associate with plant roots to extend their nutrient-gathering ability, in exchange for carbon compounds produced by photosynthesis. This study examined the influence of increased carbon dioxide in the atmosphere on the interaction of several varieties of wheat with these fungi. Journal Paper: Thirkell TJ, Pastok D, Field KJ. Carbon for nutrient exchange between arbuscular mycorrhizal fungi and wheat varies according to cultivar and changes in atmospheric carbon dioxide concentration. Glob Change Biol.

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This episode: Giant virus in newly discovered microscopic marine predator encodes several light-harvesting proteins!

Download Episode (7.8 MB, 11.4 minutes) Show notes: Microbe of the episode: Dolphin mastadenovirus A News item Takeaways Giant viruses are distinct in many ways from other viruses, even aside from their size. One way is the large number and variety of genes they carry in their genome. Though many of their genes are unknown in origin and function, many others appear to take the place of essential reproductive functions, such as translation and protein synthesis. This allows them to assume more control of their host's metabolism and control its resources more optimally. In this study, the sequence of a giant virus was discovered seemingly infecting a newly discovered microscopic marine predator. The eukaryotic cell feeds on smaller microbes such as bacteria, but strangely, the virus carries genes for several light-harvesting proteins, possibly converting a heterotrophic predator into a partial phototroph. Journal Paper: Needham DM, Yoshizawa S, Hosaka T, Poirier C, Choi CJ, Hehenberger E, Irwin NAT, Wilken S, Yung C-M, Bachy C, Kurihara R, Nakajima Y, Kojima K, Kimura-Someya T, Leonard G, Malmstrom RR, Mende DR, Olson DK, Sudo Y, Sudek S, Richards TA, DeLong EF, Keeling PJ, Santoro AE, Shirouzu M, Iwasaki W, Worden AZ. 2019. A distinct lineage of giant viruses brings a rhodopsin photosystem to unicellular marine predators. Proc Natl Acad Sci 116:20574–20583.

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This episode: Mice that got a microbe transplant from humans with higher physical function performed better in certain ways than mice receiving microbes from humans with lower physical function!

Download Episode (6.7 MB, 9.8 minutes) Show notes: Microbe of the episode: Stenotrophomonas maltophila News item Takeaways Our bodies and our microbe communities are closely interconnected, with effects going both ways. Studies had previously shown that making changes to the microbe communities of mice could even affect the physical function and body composition of the mice. This study aimed at addressing the same question in humans. There were certain consistent differences in microbial communities between elderly people with high ability to function physically, compared with low functioning people. These differences carried over in transplants of microbes from people to mice, and mice receiving microbes from high-functioning humans did better in tests of grip strength than mice receiving microbes from low-functioning people. Journal Paper: Fielding RA, Reeves AR, Jasuja R, Liu C, Barrett BB, Lustgarten MS. 2019. Muscle strength is increased in mice that are colonized with microbiota from high-functioning older adults. Exp Gerontol 127:110722.

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This episode: Microbes in low-oxygen zones in the ocean consume significant amounts of methane anaerobically!

Download Episode (5.2 MB, 7.6 minutes) Show notes: Microbe of the episode: Mojiang henipavirus News item Takeaways Methane is a much more potent greenhouse gas than carbon dioxide. Fortunately there's not as much of it in the atmosphere, but even smaller amounts can have significant effects on the climate. One source of methane is low-oxygen zones in the ocean, where certain kinds of archaea make methane as part of their energy metabolism. This study found that other anaerobic microbes in the same areas consume much of this methane, preventing it from reaching the atmosphere. Journal Paper: Thamdrup B, Steinsdóttir HGR, Bertagnolli AD, Padilla CC, Patin NV, Garcia‐Robledo E, Bristow LA, Stewart FJ. 2019. Anaerobic methane oxidation is an important sink for methane in the ocean’s largest oxygen minimum zone. Limnol Oceanogr 64:2569–2585.

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This episode: Ocean bacteria brought up from the sea floor into the air can help create clouds!

Download Episode (6.1 MB, 8.9 minutes) Show notes: Microbe of the episode: Streptomyces thermodiastaticus News item Takeaways The ocean is an important player affecting the climate of the planet, in many ways. Its effects on clouds influence the amount of solar radiation reflected back into space or trapped as heat, and microbes play a role in this effect. Certain microbes make particles that form the nucleus of water droplets or ice crystals that make up clouds, and other microbes can perform this nucleation themselves. In this study, an unusual combination of a phytoplankton bloom and strong winds and currents, all in the right places, led to a large number of ice-nucleating bacteria being fed and then brought up from the sea floor and launched into the air, possibly affecting weather patterns in the Arctic. Journal Paper: Creamean JM, Cross JN, Pickart R, McRaven L, Lin P, Pacini A, Hanlon R, Schmale DG, Ceniceros J, Aydell T, Colombi N, Bolger E, DeMott PJ. 2019. Ice Nucleating Particles Carried From Below a Phytoplankton Bloom to the Arctic Atmosphere. Geophys Res Lett 46:8572–8581.

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Probably the last episode of the year. See you in the next! This episode: Fungus living inside plants helps them form partnerships with nitrogen-fixing bacteria!

Download Episode (5.9 MB, 8.5 minutes) Show notes: Microbe of the episode: Prevotella intermedia Takeaways Plants are very good at acquiring carbon, but they can often use some help with other nutrients. Many form partnerships with microbes such as nitrogen-fixing bacteria or mycorrhizal fungi that can help gather nutrients from the soil better than the plants' own roots. In this study, legume plants could form a partnership with nitrogen-fixing bacteria in its roots, but a fungus living inside the plant could enhance this partnership even more, increasing the amount of nitrogen acquired and influencing the community of microbes around the plant roots in ways favorable to all partners. Journal Paper: Xie X-G, Zhang F-M, Yang T, Chen Y, Li X-G, Dai C-C. 2019. Endophytic Fungus Drives Nodulation and N₂ Fixation Attributable to Specific Root Exudates. mBio 10:e00728-19, /mbio/10/4/mBio.00728-19.atom.

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This episode: DNA from related species can kill certain pathogens when they incorporate it into their genome!

Download Episode (7.9 MB, 11.5 minutes) Show notes: Microbe of the episode: Ungulate tetraparvovirus 3 Paper summary (paywall) Takeaways Neisseria gonorrhoeae, the bacteria that cause gonorrhea, have the unusual ability of taking up DNA from their surroundings at any time and making use of it in their own genome. This helps them acquire useful traits that help them survive better, such as antibiotic resistance. But it turns out that the ability is also a secret weakness! This study showed that when N. gonorrhoeae takes up DNA from harmless, commensal species of Neisseria in the body, the DNA is similar enough to be incorporated into the genome but different enough that it kills the pathogen. This effect also occurs with a serious pathogen in the same genus, N. meningitidis. Journal Paper: Kim WJ, Higashi D, Goytia M, Rendón MA, Pilligua-Lucas M, Bronnimann M, McLean JA, Duncan J, Trees D, Jerse AE, So M. 2019. Commensal Neisseria Kill Neisseria gonorrhoeae through a DNA-Dependent Mechanism. Cell Host Microbe 26:228-239.e8.

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This episode: Coating metal surfaces with artificial biofilms could help keep the surfaces corrosion-free even in the ocean!

Download Episode (6.3 MB, 9.1 minutes) Show notes: Microbe of the episode: Hymenopteran ambidensovirus 1 Takeaways The ocean can be a harsh place for metal surfaces. Between the water, the salt, and oxygen (near the surface), corrosion is a common reality. Microbes in the ocean can contribute to this too, degrading metal structures to obtain energy for their metabolism. They colonize surfaces in biofilms that can be difficult to remove, a process called biofouling. In this study, instead of trying to remove or prevent biofilms on surfaces, artificial biofilms were created by coating the surfaces and specially selected bacterial cells with polymers. This approach did not prevent colonization by other organisms in the sea, but preliminary results suggested that the community that did take up residence was not as corrosive as the communities found on uncoated steel. Journal Paper: Rijavec T, Zrimec J, Spanning R van, Lapanje A. 2019. Natural Microbial Communities Can Be Manipulated by Artificially Constructed Biofilms. Adv Sci 6:1901408.

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This episode: Another climate-related story: Cyanobacteria infected by viruses continue taking up nutrients from their environment, using it to make more viruses than would otherwise be possible!

Download Episode (6.3 MB, 9.2 minutes) Show notes: Microbe of the episode: Microcystis virus Ma-LMM01 07-viruses-affect-climate-probes-effects.html">News item Takeaways Though global warming is a global problem, accurate models for predicting where things are headed need to incorporate the activity of even the smallest organisms, if they're numerous enough. Photosynthesis and other activities of microbes in the oceans are a big sink for carbon, but cycles of other nutrients and also viruses can affect the carbon cycle. In this study, phages infecting photosynthetic ocean bacteria were able to continue their host's uptake of nitrogen from the environment even after mostly shutting down the host's own protein production and growth. This has implications for how viruses affect carbon cycling by cyanobacteria and how quickly populations of these bacteria may grow or die off. Journal Paper: Waldbauer JR, Coleman ML, Rizzo AI, Campbell KL, Lotus J, Zhang L. 2019. Nitrogen sourcing during viral infection of marine cyanobacteria. Proc Natl Acad Sci 116:15590–15595.

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This episode: First episode of a climate-related arc! Considering microorganisms is important when predicting the amount of carbon coming from soil as temperature increases!

Download Episode (4.7 MB, 6.75 minutes) Show notes: Microbe of the episode: Streptomyces virus Zemlya 07-microbes-soil-respiration.html">News item Takeaways Soil as a whole has a big influence on the climate of the planet, by enabling the communities of organisms that live in it to interact and grow, taking up gases from the atmosphere and putting others back in. Even aside from plants that grow in it, the other organisms in soil can respire and break down compounds to produce CO2, adding to what's in the atmosphere already. There has long been observed a relationship between ambient temperatures and this respiration in soil, such that more heat means more activity and more gases released from the soil, but today's study found that the microbial biomass in a given piece of land can have a big effect on the temperature/respiration relationship. Journal Paper: Čapek P, Starke R, Hofmockel KS, Bond-Lamberty B, Hess N. 2019. Apparent temperature sensitivity of soil respiration can result from temperature driven changes in microbial biomass. Soil Biol Biochem 135:286–293.

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This episode: Gut microbes can stimulate immune cells in mouse brains to fight off viral infections!

Download Episode (9.0 MB, 13.0 minutes) Show notes: Microbe of the episode: Streptoverticillium mobaraense News item Takeaways The central nervous system, including the brain, is a protected area of the body. Pathogens that get in can do a lot of damage, including memory loss, paralysis, and death, so there's a strict barrier in healthy people that keeps most things out of this area: the blood-brain barrier. The immune system is also kept separate, so special cells called microglia do the patrolling and protection of the brain. Nevertheless, microbes in the gut can influence the function of the immune system in the brain, even from a distance. In this study, mice lacking gut microbes did not have as effective an immune response to a virus infecting the brain, and it was found that molecules from bacterial outer membranes were sensed by microglia to activate their defensive response. Journal Paper: Brown DG, Soto R, Yandamuri S, Stone C, Dickey L, Gomes-Neto JC, Pastuzyn ED, Bell R, Petersen C, Buhrke K, Fujinami RS, O’Connell RM, Stephens WZ, Shepherd JD, Lane TE, Round JL. 2019. The microbiota protects from viral-induced neurologic damage through microglia-intrinsic TLR signaling. eLife 8:e47117.

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This episode: In this partnership between fungus and algae, the algae eventually take up residence inside their partner!

Download Episode (8.4 MB, 12.1 minutes) Show notes: Microbe of the episode: Erwinia tracheiphila News item/Summary article Takeaways Partnerships and cooperation between otherwise free-living organisms is common in the natural world. Partnering with a photosynthetic organism is a smart approach, allowing the partner to get its energy from the sun and making gathering nutrients easier for the phototroph, and possibly offering protection as well. But in most partnerships, each partner stays separated by its own cell membrane. In this study, a fungus and an alga grow well together, exchanging carbon for nitrogen, similar to how lichens operate. But after a month or so of co-culture, the algae apparently enter the cells of the fungus somehow and live inside it, happily growing and dividing, turning the fungus green. Journal Paper: Du Z-Y, Zienkiewicz K, Vande Pol N, Ostrom NE, Benning C, Bonito GM. 2019. Algal-fungal symbiosis leads to photosynthetic mycelium. eLife 8:e47815.

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This episode: Figuring out how gut communities change with changes in diet!

Download Episode (6.1 MB, 8.8 minutes) Show notes: Microbe of the episode: Hepacivirus A News item Takeaways Diet can play a big role in our health. It's not a magic pill that can cure or prevent anything, but a good diet can significantly reduce many health risks for the average person, compared with a bad diet. Diet also has a big effect on the community of microbes in our gut, and this may play a role in the health effects we see from diet, so understanding how food and microbes interact is important. This study looked at the diet quality of participants in several food categories, and correlated this with various kinds of microbes found inside them. Journal Paper: Liu Y, Ajami NJ, El-Serag HB, Hair C, Graham DY, White DL, Chen L, Wang Z, Plew S, Kramer J, Cole R, Hernaez R, Hou J, Husain N, Jarbrink-Sehgal ME, Kanwal F, Ketwaroo G, Natarajan Y, Shah R, Velez M, Mallepally N, Petrosino JF, Jiao L. 2019. Dietary quality and the colonic mucosa–associated gut microbiome in humans. Am J Clin Nutr 110:701–712.

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This episode: Bacteria can aide the production of the useful material graphene, using their ability to add electrons to external surfaces!

Download Episode (7.7 MB, 11.3 minutes) Show notes: Microbe of the episode: Brevibacterium frigoritolerans News item Takeaways Advanced materials often take advanced techniques to create, but they offer numerous benefits: increased strength and flexibility, smaller size, more options. One such material is graphene, which is basically a sheet of carbon atoms linked together like chainmail. It is only a single atom thick but is amazingly strong, mostly transparent, and good at conducting heat and electricity. The trick is, it's hard to make in large quantities cheaply and easily. Sheets of carbons can be obtained from blocks of graphite, but these sheets are graphene oxide, which lack the desirable properties of graphene. Chemical methods can be used to remove the oxidation, but they are harsh and difficult. Luckily, bacteria are great at microscopic remodeling. In this study, electron-transferring bacteria are able to reduce the graphene oxide to graphene with properties almost as good as are achieved by chemical reduction. Journal Paper: Lehner BAE, Janssen VAEC, Spiesz EM, Benz D, Brouns SJJ, Meyer AS, van der Zant HSJ. 2019. Creation of Conductive Graphene Materials by Bacterial Reduction Using Shewanella oneidensis. ChemistryOpen 8:888–895.

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This episode: Bacteria found in the guts of serious athletes help mice exercise longer by transforming their metabolic waste!

Download Episode (7.3 MB, 10.6 minutes) Show notes: Microbe of the episode: Aggregatibacter (Actinobacillus) actinomycetemcomitans News item Takeaways Our gut microbes affect many aspects of health, and many aspects of how we live affect our microbes. One such aspect is physical exertion, which has been associated with enrichment of various microbes in the guts of athletes. This observation led to the question: are these microbes just benefiting from the high levels of exertion, or are they able to contribute also? This study found that certain such bacteria, when given to mice, enabled the mice to run for a longer period on a treadmill. These microbes break down lactic acid, which is generated in our bodies when we push our physical limits, but the study provided evidence that the longer run times were due not to removal of this waste product, but to the propionate compound produced by its degradation. Journal Paper: Scheiman J, Luber JM, Chavkin TA, MacDonald T, Tung A, Pham L-D, Wibowo MC, Wurth RC, Punthambaker S, Tierney BT, Yang Z, Hattab MW, Avila-Pacheco J, Clish CB, Lessard S, Church GM, Kostic AD. 2019. Meta-omics analysis of elite athletes identifies a performance-enhancing microbe that functions via lactate metabolism. Nat Med 25:1104–1109.

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This episode: Plants stimulate their root bacteria to compete better, and these bacteria help the plants resist disease!

Download Episode (7.3 MB, 10.6 minutes) Show notes: Microbe of the episode: Bacillus circulans Takeaways In some ways, plants' roots are like our gut. They both absorb nutrients, and they both have complex communities of microbes living alongside the host cells. These microbes can assist their hosts in various ways, and get fed in return. In this study, one species of root bacterium is able to compete against others by producing an antimicrobial compound. The plant stimulates this production with chemical signals, and benefits from its symbionts' increased competitiveness because the bacterium helps the plant resist infection. Journal Paper: Ogran A, Yardeni EH, Keren-Paz A, Bucher T, Jain R, Gilhar O, Kolodkin-Gal I. 2019. The Plant Host Induces Antibiotic Production To Select the Most-Beneficial Colonizers. Appl Environ Microbiol 85:e00512-19.

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This episode: Bacterial enzymes could convert donated blood to be compatible with more people in need!

Download Episode (8.0 MB, 11.7 minutes) Show notes: Microbe of the episode: Cucumber leaf spot virus 06-enzymes-blood-human-gut-biome.html">News item Takeaways Blood transfusions using donated blood save many lives. Unfortunately, most donations can't be given to just anyone that needs blood; there must be a match in blood type between donor and recipient, or else a life-threatening reaction could occur in the recipient's body. So type A can't donate to type B, or vice versa, but type O is compatible with the other types. In this study, bacterial enzymes found in human gut microbes have the ability to cleave off the unique type A and B sugars on the surface of red blood cells. This could allow the conversion of all donated blood to type O, greatly increasing the blood bank supply, but more testing is needed to develop the process. Journal Paper: Rahfeld P, Sim L, Moon H, Constantinescu I, Morgan-Lang C, Hallam SJ, Kizhakkedathu JN, Withers SG. 2019. An enzymatic pathway in the human gut microbiome that converts A to universal O type blood. Nat Microbiol 4:1475–1485.

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This episode: Five different ways of thinking about our relationship with our microbes!

Download Episode (20.4 MB, 29.8 minutes) Show notes: Microbe of the episode: Tuhoko rubulavirus 3 News item Takeaways The microbiome by itself is an amazingly complicated community of many different species, with different lifestyles and metabolisms, all living together in competition and cooperation. On top of that, interactions between the microbiome and our body and our lifestyle multiply the complexity even more. This article explores five different views of the microbiome and how it fits into our body (or how the body fits in with the microbiome). From the organ view to the ecosystem view, each is a different way of looking at the different functions, dynamic patterns, and integration of the microbiome in its host, and each provides guidance for how to approach treatment of disease and maintenance of health. Journal Paper: Morar N, Bohannan BJM. 2019. The Conceptual Ecology of the Human Microbiome. The Quarterly Review of Biology 94:149–175.

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This episode: Not as simple as it sounds—how rod-shaped bacteria maintain their shape! Thanks to Dr. Ethan Garner for his contribution!

Download Episode (6.3 MB, 9.2 minutes) Show notes: Microbe of the episode: Erwinia virus M7 News item Takeaways Microbes seem like they should be a lot simpler than large multicellular organisms, but even what seems like it should be a simple system in microbes can be surprisingly complex. In this case, the system bacteria maintaining their particular cell shape. Spherical cells have it easier: just add more cell material at every point. But for rods, they must make the cell longer without making it wider. How do they accomplish this? Two groups of proteins work together to help rod-shaped species grow, but how they work wasn't specifically known. In this study, it was found that one group of proteins adds more cell material as it moves around the circumference, while the other adds structure to the cell that allows it to maintain shape. The more of these structural proteins present, the thinner the cell can stay. Journal Paper: Dion MF, Kapoor M, Sun Y, Wilson S, Ryan J, Vigouroux A, van Teeffelen S, Oldenbourg R, Garner EC. 2019. Bacillus subtilis cell diameter is determined by the opposing actions of two distinct cell wall synthetic systems. Nat Microbiol 4:1294–1305.

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This episode: Bacterial symbionts of amoebas help them survive bacterial infection, and prevent pathogens from spreading to others as much!

Download Episode (7.5 MB, 8.1 minutes) Show notes: Microbe of the episode: Eubacterium dolichum 05-symbionts-lifesavers.html">News item Takeaways Amoebas are free-living, single-celled organisms, but they have some things in common with some cells of our immune system (macrophages). For example, certain bacterial pathogens can infect both in similar ways. So it can be useful to study the interactions of amoebas and bacteria to learn about our own immune defenses. In this study, the amoeba Acanthamoeba castellanii has another bacterial symbiont that helps it resist killing by the bacterial pathogen Legionella pneumophila. Once the amoebas recovered from the infection, they were more resistant to future challenges. Even better, the symbiont prevented the pathogen from transforming into a more spreadable form like it does when infecting amoebas alone. Journal Paper: König L, Wentrup C, Schulz F, Wascher F, Escola S, Swanson MS, Buchrieser C, Horn M. 2019. Symbiont-Mediated Defense against Legionella pneumophila in Amoebae. mBio 10:e00333-19.

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This episode: A marine protist can orient itself along magnetic fields thanks to bacterial symbionts on its surface that make magnetic nanoparticles!

Download Episode (7.2 MB, 7.9 minutes) Show notes: Microbe of the episode: Chlorocebus pygerythrus polyomavirus 3 Takeaways Various kinds of bacteria can orient their movement along a magnetic field. These are called magnetotactic, and they use this ability to swim toward or away from the surface of their aquatic habitat, to adjust their oxygen exposure according to their preference. No eukaryotic microbes have yet been discovered that can sense and react to magnetic fields like these prokaryotes. In this study, however, a protist was discovered that can do it via its partnership with ectosymbionts, or bacteria attached to its surface, that sense magnetism and orient their host's movement. In return, factors of the host's metabolism may feed its symbionts. Journal Paper: Monteil CL, Vallenet D, Menguy N, Benzerara K, Barbe V, Fouteau S, Cruaud C, Floriani M, Viollier E, Adryanczyk G, Leonhardt N, Faivre D, Pignol D, López-García P, Weld RJ, Lefevre CT. 2019. Ectosymbiotic bacteria at the origin of magnetoreception in a marine protist. Nat Microbiol 4:1088–1095.

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This episode: Slime molds can learn to get used to salt and hold on to that memory even after a period of dormancy!

Download Episode (8.9 MB, 9.7 minutes) Show notes: Microbe of the episode: Nocardia transvalensis 04-slime-mold-absorbs-substances.html">News item Takeaways Slime mold Physarum polycephalum has many surprisingly intelligent abilities, despite being only a single cell. Studying how these abilities work in the cell can teach us new ways that life can do things. The ability of interest here is habituation, or learning not to avoid a chemical that seems unpleasant to the cell but is not necessarily harmful, especially with a food reward. The slime mold can become habituated to salt, in this case, learning to tolerate it enough to pass through a gradient of increasing concentration to get to some food as quickly as it crosses the same distance with no salt present. The scientists here learned that the cell takes up sodium into itself as it habituates, and holds onto both sodium and its memory through a period of hibernation. Journal Paper: Boussard A., Delescluse J., Pérez-Escudero A., Dussutour A. 2019. Memory inception and preservation in slime moulds: the quest for a common mechanism. Phil Trans R Soc B 374:20180368.

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This episode: Bacteria carry deadly phages and use them against rival strains!

Download Episode (9.4 MB, 10.2 minutes) Show notes: Microbe of the episode: Bifidobacterium bifidum 04-bacteria-harness-viruses-distinguish-friend.html">News item Takeaways Bacteria such as Escherichia coli live in environments such as the gut with many other types of microbes, and often develop communities of microbes cooperating and/or competing with each other for resources. But in order to cooperate or compete, bacteria must first be able to identify and discriminate between themselves and others. Sometimes microbes do this by exchanging membrane molecules, or secreting chemical signals that only partners can detect, or transferring plasmids or producing antimicrobial compounds that kill competitors. In the current study, scientists discovered a strain of E. coli that carries around phages that help them distinguish other strains and compete with them. When this strain encounters another, the phages it carries attack and destroy cells of the other strain, while leaving the carrier strain mostly unharmed. This strategy is not without cost, though; the viral proteins take resources to produce, and when there's no competing strains around, the virus can attack its carrier to some extent. Journal Paper: Song S, Guo Y, Kim J-S, Wang X, Wood TK. 2019. Phages Mediate Bacterial Self-Recognition. Cell Reports 27:737-749.e4.

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This episode: Engineered bacteria could help people digest an essential nutrient when they can't digest it themselves!

Download Episode (8.5 MB, 9.3 minutes) Show notes: Microbe of the episode: Kadipiro virus News item (paywall) Science-Based Medicine blog article about phenylketonuria, Synlogic, and engineering bacteria to treat this disorder, with lots of good detail Takeaways Treating genetic disorders can be very difficult. Sometimes they can be managed, with lifestyle, diet, or medication, but cure has almost always been out of the picture. With a disorder such as phenylketonuria (PKU), for example, in which the body is unable to fully metabolize the amino acid phenylalanine, diet and medication may work to some extent. In an effort to provide better options for PKU, scientists at Synlogic, Inc have created a strain of Escherichia coli that produces phenylalanine-degrading enzymes in the gut. The hope is that ingesting this bacterium could allow PKU patients to be less restrictive with their diet. Journal Paper: Isabella VM, Ha BN, Castillo MJ, Lubkowicz DJ, Rowe SE, Millet YA, Anderson CL, Li N, Fisher AB, West KA, Reeder PJ, Momin MM, Bergeron CG, Guilmain SE, Miller PF, Kurtz CB, Falb D. 2018. Development of a synthetic live bacterial therapeutic for the human metabolic disease phenylketonuria. Nat Biotechnol 36:857–864.

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This episode: Microbes in household dust help degrade potentially harmful plasticizer chemicals! Thanks to Ashleigh Bope for her contribution!

Download Episode (6.7 MB, 7.3 minutes) Show notes: Microbe of the episode: Rosa rugosa leaf distortion virus News item Takeaways Modern life and technology comes with modern challenges, including exposure to chemicals in building materials and such that humans didn't encounter much before the last few generations. Phthalate esters, found in PVC and other materials, can accumulate in homes and cause some problems, especially in children. Modern life is also new to microbes, but they are very adaptable and versatile. In this study, microbes in household dust show some ability to break down the phthalates over time. Whether this activity is significant and beneficial to residents remains to be discovered. Journal Paper: Bope A, Haines SR, Hegarty B, Weschler CJ, Peccia J, Dannemiller KC. Degradation of phthalate esters in floor dust at elevated relative humidity. Environ Sci: Processes Impacts.

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This episode: Bacteria strengthen concrete while helping to prevent damage from road salts!

Download Episode (6.8 MB, 7.4 minutes) Show notes: Microbe of the episode: Azospirillum brasilense News item Takeaways Winter is a bad time for concrete outside. Water seeps into cracks and freezes, causing bigger cracks that widen into potholes. Even the road salts used to keep water from freezing can react with compounds in the cement to break down the structure of the concrete. This study looks to bacteria for a solution for protecting concrete from these reactions. Sporosarcina pasteurii, given the right nutrients, can take the harmful salt compounds and turn them into minerals that strengthen the concrete instead of weakening it. Journal Paper: Ksara M, Newkirk R, Langroodi SK, Althoey F, Sales CM, Schauer CL, Farnam Y. 2019. Microbial damage mitigation strategy in cementitious materials exposed to calcium chloride. Construction and Building Materials 195:1–9.

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This episode: Bacteria help gently clean residue off artworks painted on stone!

Download Episode (5.6 MB, 6.1 minutes) Show notes: Microbe of the episode: Cellulophaga virus Cba171 Takeaways More and more cleaning products these days contain an ingredient called "enzymes." These are proteins that break down contaminants biologically instead of just removing them chemically, in a targeted manner. In a similar approach, this study explores applying bacteria directly to classic artwork painted directly on stone, to clean up residues on the surface. These bacteria can produce enzymes on site and degrade the contaminants while leaving the underlying paint intact. Journal Paper: Ranalli G, Zanardini E, Rampazzi L, Corti C, Andreotti A, Colombini MP, Bosch‐Roig P, Lustrato G, Giantomassi C, Zari D, Virilli P. 2019. Onsite advanced biocleaning system on historical wall paintings using new agar-gauze bacteria gel. J Appl Microbiol 126:1785–1796.

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This episode: Bacteria produce antifungal compounds that can protect paper from fungal deterioration!

Download Episode (6.8 MB, 7.4 minutes) Show notes: Microbe of the episode: Acetobacter aceti Takeaways Paper is a very useful information storage medium, but it is also somewhat delicious for microbes that can break it down as food, degrade the quality, and cause indelible stains and discoloration under the right conditions. Preventing this usually requires careful control, such as keeping humidity low, for storing paper for long periods. In this study, scientists tested the ability of the bacterium Lysobacter enzymogenes to protect paper via the antifungal compounds it produces. This first required filtering out the pigments that the bacteria produced, to prevent them from discoloring the paper. Once a method for this filtering was in place, they found the bacterial culture supernatant could significantly reduce fungal growth on various kinds of paper, and protect the paper from staining and degradation. Journal Paper: Chen Z, Zou J, Chen B, Du L, Wang M. 2019. Protecting books from mold damage by decreasing paper bioreceptivity to fungal attack using de-coloured cell-free supernatant of Lysobacter enzymogenes C3. J Appl Microbiol 126:1772–1784.

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This episode: Contact with soil materials and moss causes significant, though short-term, changes in the skin microbiota! Thanks to Dr. Mira Grönroos for her contribution!

Download Episode (7.1 MB, 7.75 minutes) Show notes: Microbe of the episode: Leonurus mosaic virus Takeaways Exposure to microbes throughout life is thought to help calibrate the immune system to some extent, reducing the risk of allergies and asthma without losing defense against pathogens. In this study, rubbing soil or packets of moss on the skin changed the composition of the skin microbiota temporarily, so this may be a way to help with this important type of exposure, but it is not yet known how to achieve optimal long-term effects. Journal Paper: Grönroos M, Parajuli A, Laitinen OH, Roslund MI, Vari HK, Hyöty H, Puhakka R, Sinkkonen A. 2019. Short-term direct contact with soil and plant materials leads to an immediate increase in diversity of skin microbiota. MicrobiologyOpen 8:e00645.

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I'm back! This episode: Looking at how people in different villages share microbes!

Download Episode (6.5 MB, 7.0 minutes) Show notes: Microbe of the episode: Cristispira pectinis Takeaways Our microbiota, the communities of microbes living in and on our bodies, are incredibly diverse and varied. Each person's is different, and they can change drastically over time with changes in location, diet, lifestyle, and other factors. Learning how our microbiota forms and changes and functions is important, because it can affect many aspects of health. In this study, villagers in the islands of Fiji share microbes with others in the same and other villages, but not always in patterns that might be expected. Journal Paper: Brito IL, Gurry T, Zhao S, Huang K, Young SK, Shea TP, Naisilisili W, Jenkins AP, Jupiter SD, Gevers D, Alm EJ. Transmission of human-associated microbiota along family and social networks. Nat Microbiol.

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This episode: Fungus-hunting amoebas have different strategies for detecting and preying on single-celled and filamentous fungi! Also, a personal note: I'm going to be taking a few weeks off the podcast to be able to take full advantage of spring, but I'll be back as soon as the weather gets too hot.

Download Episode (7.5 MB, 8.2 minutes) Show notes: Microbe of the episode: Chondromyces catenulatus Takeaways Amoebas in the microbial world are like powerful predators, going around gobbling up whatever they find that's small enough, by a process called phagocytosis, in which they surround their prey with their cell membrane and engulf it. It's similar to macrophages or white blood cells as part of our immune system in our bodies. The prey of amoebas includes bacteria, large viruses, and single-celled fungi called yeasts. In this study, scientists showed that some yeasts make great food sources for a certain kind of amoeba called Protostelium aurantium, while others either lack nutritional value or hide from the predators by covering up certain recognition molecules on their cell wall. They found that the amoebas could also consume the spores of filamentous fungi, and could even attack the filaments, or hyphae. In this latter case, instead of engulfing the large filaments, they pierced the cells and extracted their contents, an approach named ruphocytosis, from the Greek for suck or slurp. Journal Paper: Radosa S, Ferling I, Sprague JL, Westermann M, Hillmann F. The different morphologies of yeast and filamentous fungi trigger distinct killing and feeding mechanisms in a fungivorous amoeba. Environ Microbiol.

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This episode: Pigmented bacteria can be used in a cancer imaging technique that combines light and sound!

Download Episode (8.9 MB, 9.75 minutes) Show notes: Microbe of the episode: Streptomyces bellus Takeaways Because "cancer" is a general term that describes many different forms of disease affecting different cells in different parts of the body, effective cancer treatment relies on understanding the location and physiology of the cancer in a given patient. New imaging technologies for diagnosis and analysis of cancer and for cancer research can be very valuable, especially if they don't require big investments of money and space. One promising imaging technology is called multispectral optoacoustic imaging, or MSOT. This uses pulses of light to create vibrations as pigments in tissues absorb the light and undergo thermal expansion; these vibrations are then detected by ultrasound technology. This approach allows good resolution and depth of imaging without large equipment like MRI machines, but the best results require adding pigments into the body. In this study, scientists showed that the photosynthetic pigments of purple non-sulfur bacteria can be useful in this optoacoustic imaging, providing a somewhat long-term, nontoxic approach. It proved especially interesting when they discovered that the wavelength spectrum changing over time was an indication of macrophage activity in the tumors. Journal Paper: Peters L, Weidenfeld I, Klemm U, Loeschcke A, Weihmann R, Jaeger K-E, Drepper T, Ntziachristos V, Stiel AC. 2019. Phototrophic purple bacteria as optoacoustic in vivo reporters of macrophage activity. Nat Commun 10:1191.

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This episode: A microbe that boosts plant growth needs to make storage polymers for both itself and the plant's sake!

Download Episode (7.1 MB, 7.75 minutes) Show notes: Microbe of the episode: Suid gammaherpesvirus 3 Takeaways Bacteria that promote plant growth are fascinating and not too hard to find. Plants and microbes make good partners by each contributing something the other needs. Plants make sugars via photosynthesis that microbes can use as food, and microbes can gather nutrients that plants can't make, can drive off pathogens, and can contribute to plant growth in other ways. However, plants aren't making sugars all the time, because the sun goes down every day. So what do partner microbes do at these times? In this study, a beneficial microbe Herbaspirillum seropedicae was found to produce a storage compound called polyhydroxyalkanoate, or PHA, that it could use to store food for times of scarcity. Mutants of this microbe that could not make the storage compound weren't very beneficial for their plant partners. Journal Paper: Alves LPS, Amaral FP do, Kim D, Bom MT, Gavídia MP, Teixeira CS, Holthman F, Pedrosa F de O, Souza EM de, Chubatsu LS, Müller-Santos M, Stacey G. 2019. Importance of Poly-3-Hydroxybutyrate Metabolism to the Ability of Herbaspirillum seropedicae To Promote Plant Growth. Appl Environ Microbiol 85:e02586-18.

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This episode: Light increases the growth even of some bacteria that don't harvest its energy!

Download Episode (9.0 MB, 9.75 minutes) Show notes: Microbe of the episode: Methylococcus thermophilus News item Takeaways Light from the sun is one of the fundamental sources of energy for life on this planet. Plants and other phototrophs—photosynthetic organisms that get their energy mainly from light—form the foundation of the food web, and organisms that feed on them or that feed on organisms that feed on them are all dependent on the ability to capture the sun's rays. There are other ways to benefit directly from the sun's energy, besides photosynthesis—some microbes have enzymes that use light energy to repair damage to DNA (the same damage that is caused by ultraviolet light), and we use sunlight to synthesize vitamin D. In this study, however, microbes are discovered to grow faster in the presence of light despite not being phototrophs or producing any light-harvesting proteins. The scientists discover some possible light-sensing proteins, though, that could regulate these microbes' behavior, allowing them to synchronize their growth cycles to phototroph partners in aquatic environments.

Journal Paper: Maresca JA, Keffer JL, Hempel P, Polson SW, Shevchenko O, Bhavsar J, Powell D, Miller KJ, Singh A, Hahn MW. Light modulates the physiology of non-phototrophic Actinobacteria. J Bacteriol JB.00740-18.

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