442 - Fossil Phototroph Phagocytosis

Fossilized coccolithophores
By Gibbs et al. 2020
Sci Adv 6:eabc9123
CC BY-NC 4.0

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

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Show notes:
Microbe of the episode: Chaetoceros tenuissimus RNA virus 01

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Takeaways

Being able to look through time and learn about what might have happened to creatures throughout Earth's history is what makes paleontology great. Everyone knows about dinosaurs and what happened to them at the end of the Cretaceous period thanks to science. But what we can learn is not limited just to large organisms; there are ways to learn about microorganisms of the past as well, including by looking at fossils!

In this study, fossils of hard-shelled algae from around the end of the dinosaurs show that many of these microbes in the oceans went extinct at the same time due to the massive space impact. Debris blocked out sunlight for years, making it difficult for photosynthetic organisms to survive. So some of these algae appear to have survived by preying on smaller organisms, pulling them in through a hole in their shell.

Journal Paper:
Gibbs SJ, Bown PR, Ward BA, Alvarez SA, Kim H, Archontikis OA, Sauterey B, Poulton AJ, Wilson J, Ridgwell A. 2020. Algal plankton turn to hunting to survive and recover from end-Cretaceous impact darkness. Sci Adv 6:eabc9123.
Other interesting stories:

• Phages could help treat diabetic wound infections without harming microbiota (paper)

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441 - Hyphal Hijacker Helps Harvests

Fungus growing in root
By Zhang et al. 2020
Molec Plant 13:1420-1433
CC BY-NC-ND 4.0

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

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Show notes:
Microbe of the episode: Hepacivirus J

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Takeaways

Viruses can be useful for treating various diseases, especially bacterial infections and cancer. Their ability to target certain cell types specifically makes them great at hunting down and killing disease-causing cells without harming the body's healthy tissue. And just as bacteriophages can work to treat bacterial disease in us, fungal viruses could help to treat serious fungal infections in crop plants.

In this study, a fungus-infecting virus goes beyond treating a deadly fungal disease in rapeseed plants. Fungus infected with this virus no longer causes disease, but lives in harmony with the host plant, protects it from other fungal diseases, and even helps it to grow better.

Journal Paper:
Zhang H, Xie J, Fu Y, Cheng J, Qu Z, Zhao Z, Cheng S, Chen T, Li B, Wang Q, Liu X, Tian B, Collinge DB, Jiang D. 2020. A 2-kb Mycovirus Converts a Pathogenic Fungus into a Beneficial Endophyte for Brassica Protection and Yield Enhancement. Mol Plant 13:1420–1433.

Other interesting stories:

• Engineering E. coli to turn carbon dioxide into biomass
• Radiation super-resistant bacteria survive 1 year exposed to low Earth orbit

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440 - Prokaryotes Pay for Passage

Bacteria along fungal hyphae
By Abeysinghe et al. 2020,
Life Sci Alliance 3:e202000878
CC BY 4.0

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

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Show notes:
Microbe of the episode: Clostridium acetobutylicum

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Takeaways

In the complex environment of soil, many different kinds of organisms coexist. Some compete with each other, while others cooperate in fascinating interactions. One example is how bacteria can swim through a film of water surrounding the filaments of fungi, allowing them to traverse more quickly and reach new locations.

In this study, an interaction between fungus and bacterium is discovered in which the bacteria benefit from the fungus in enhanced ability to travel, and the fungus benefits by absorbing vitamins that the bacteria produce.

Journal Paper:
Abeysinghe G, Kuchira M, Kudo G, Masuo S, Ninomiya A, Takahashi K, Utada AS, Hagiwara D, Nomura N, Takaya N, Obana N, Takeshita N. 2020. Fungal mycelia and bacterial thiamine establish a mutualistic growth mechanism. Life Sci Alliance 3(12):202000878.

Other interesting stories:

• Honeybee gut microbes help them define their social groupings
• Smells that cheese fungi make help cheese microbe community develop

Post questions or comments here or email to bacteriofiles@gmail.com. Thanks for listening!

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439 - Microbes Mitigate Mushroom Morbidity

Button mushrooms
By chris_73, CC BY-SA 3.0

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

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Show notes:
Microbe of the episode: Tomato mosaic virus

Takeaways

Almost all organisms are vulnerable to pathogenic microbes that make them sick or cause damage. Most also have other microbes that help them grow better or protect them from pathogens. This includes animals, plants, and also fungi.

In this study, bacterial pathogens produce a toxin that causes button mushrooms to turn brown and rot. However, other bacteria can degrade this toxin and protect the fungus, and can also degrade molecules the pathogens produce to help them swarm to new places, restricting their movement.

Journal Paper:
Hermenau R, Kugel S, Komor AJ, Hertweck C. 2020. Helper bacteria halt and disarm mushroom pathogens by linearizing structurally diverse cyclolipopeptides. Proc Natl Acad Sci 117:23802–23806.

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438 - Bacteria Bait Bug Babies

Drosophila fruit fly
By André Karwath
CC BY-SA 2.5

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

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Show notes:
Microbe of the episode: Streptomyces corchorusii

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Takeaways

Actinomycete bacteria do a lot of interesting things. They grow like fungi, with mycelia and spores, and produce many interesting compounds, including antibiotics and other useful pharmaceuticals. They often team up with insects, producing such compounds to assist them in competing with other organisms or resisting disease.

But such amazingly helpful powers of chemistry can also be amazingly harmful. In this study, multiple strains of these bacteria were able to kill fruit fly larvae that ingested their spores. The toxin the bacteria produced was a chemical that interferes with cells' DNA-protein interactions. The bacteria also produced an odor that, in certain concentrations, lured the larvae to their doom.

Journal Paper:
Ho LK, Daniel-Ivad M, Jeedigunta SP, Li J, Iliadi KG, Boulianne GL, Hurd TR, Smibert CA, Nodwell JR. 2020. Chemical entrapment and killing of insects by bacteria. Nat Commun 11:4608.

Other interesting stories:

• Eukaryotes borrowed viperin genes for proteins that prokaryotes use to fight viruses (paper)
• Bacteria can break down plastic even faster with newly discovered enzyme

Also news, Feedspot ranked BacterioFiles in the top 5 virology podcasts! Check out the list for other good shows about viruses.

Post questions or comments here or email to bacteriofiles@gmail.com. Thanks for listening!

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437 - Balmy Bacteria Build Bone

Porous interior of bone
By Daniel Ullrich Threedots
CC BY-SA 3.0

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

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Show notes:
Microbe of the episode: Aquaspirillum serpens

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Takeaways

Bones aren't just solid, structural supports for the body's tissues. They're active and alive, housing important components of the immune system, and also capable of being broken down and built up in response to changes in the body's interactions with the environment. Various things can affect bone mass and health, including nutrition, temperature, age, and even the body's microbes.

In this study, two of these effects are found to interact. Warmth leads to increased bone density in mice, and this effect can be attributed to the microbes in the mice, and transmitted from one mouse to another just by transplanting microbes adapted to warmth. Even the particular chemicals the microbes produce that mediate this effect are discovered.

Journal Paper:
Chevalier C, Kieser S, Çolakoğlu M, Hadadi N, Brun J, Rigo D, Suárez-Zamorano N, Spiljar M, Fabbiano S, Busse B, Ivanišević J, Macpherson A, Bonnet N, Trajkovski M. 2020. Warmth Prevents Bone Loss Through the Gut Microbiota. Cell Metab 32:575-590.e7.

Other interesting stories:

• Salt-tolerant bacteria could help plants grow in coastal areas (paper)
• Fire ants like to nest near potentially antifungal bacteria

Post questions or comments here or email to bacteriofiles@gmail.com. Thanks for listening!

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436 - Copper Concentrates Culture Current

Geobacter sulferreducens
By Mantapia11147,
CC BY-SA 4.0

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

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Show notes:
Microbe of the episode: Xipapillomavirus 2

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Takeaways

Copper is widely used as a way to make surfaces and materials antimicrobial, to cut down on the spread of pathogens in hospitals and other environments. Among other mechanisms, it reacts with oxygen to form reactive oxygen species that are very harsh on microbial proteins. But copper is also a good electrical conductor, which would be useful to use in microbial fuel cells, which exploit bacterial metabolism to generate electricity. Microbes form biofilms on an electrode and transfer electrons to it as a way for them to generate energy. Most such fuel cells have used graphite electrodes to avoid toxicity.

In this study, fuel cell bacteria grew well on a copper electrode in an oxygen-free environment. The copper actually allowed them to increase the amount of current they produced per unit of area, as ionic copper diffused through the biofilm and allowed electrons to flow through the biofilm to the electrode from layers farther from the electrode that otherwise would not have access. Even graphite electrodes could be improved by adding these copper ions to the biofilm directly.

Journal Paper:
Beuth L, Pfeiffer CP, Schröder U. 2020. Copper-bottomed: electrochemically active bacteria exploit conductive sulphide networks for enhanced electrogeneity. Energy Environ Sci 13:3102–3109.

Other interesting stories:

• Lizard gut microbes are affected by temperature, and may affect lizard heat tolerance (paper)
• Phages in ice show evidence of trading genes easily to adapt to new environments

Post questions or comments here or email to bacteriofiles@gmail.com. Thanks for listening!

Subscribe: Apple Podcasts, Google Podcasts, Android, or RSS. Support the show at Patreon, or check out the show at Twitter or Facebook.