429 - Springtails Smell, Spread Streptomyces

Springtail Folsomia candida
By Andy Murray
CC BY-SA 2.0

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

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Show notes:
Microbe of the episode: Blotched snakehead virus

News item

Takeaways

Soil, especially after a rain, often has a characteristic "earthy" smell. This soil smell is actually the result of certain bacteria producing a volatile chemical called geosmin. Many geosmin producers are in the Streptomyces genus, which produces a large variety of interesting chemicals, but geosmin is one of the few that is nearly universal in the genus.

This study found that insect-like arthropods called springtails are attracted to geosmin. These animals usually feed on fungi, but they will also eat bacteria when available. Despite this result, the bacteria continue to produce the chemical, which is linked to their sporulation cycle. The study found that springtails carry intact bacterial spores to new places stuck to the insides and outsides of the animal, and this enhances the dispersal ability of the bacteria.

Journal Paper:
Becher PG, Verschut V, Bibb MJ, Bush MJ, Molnár BP, Barane E, Al-Bassam MM, Chandra G, Song L, Challis GL, Buttner MJ, Flärdh K. 2020. Developmentally regulated volatiles geosmin and 2-methylisoborneol attract a soil arthropod to Streptomyces bacteria promoting spore dispersal. 6. Nat Microbiol 5:821–829.

Other interesting stories:

• Silicon nanowires help bacteria harvest light to fix carbon dioxide
• Bacterium produces membrane balls containing enzymes to help digest lignin

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

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428 - Microbes May Manage Mysteries

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


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Show notes:
Microbe of the episode: Actinobacillus lignieresii

Takeaways

The microbial communities in and on our bodies are highly complex and highly varied between people; this complexity has raised the question of whether the microbes that people transfer onto things they touch could be used in forensics, to track their movement and activity, like fingerprints or DNA evidence. One difficulty with this approach is that microbe communities are constantly changing as conditions change or other microbes are introduced.

This study simulated such microbial tracking in a couple of scenarios, such as touching door handles in an office building and touching various surfaces in a home in a mock burglary. Tracking a person on door handles worked fairly well for up to an hour after the contact, even if other people had also touched the same door handles. However, the accuracy of identifying the "burglar" in a home was not very high, but modifying the analysis from looking at the community as a whole to only rare microbes relatively unique to an individual improved the results.

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.

Other interesting stories:

• Using slime molds to model the gravity-based web of gas and dark matter between galaxies
• Using bacteria to produce antibody-like molecules (paper)

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

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427 - Simple Cells Stay Strong

Fluorescent SimCells
By Fan et al. 2020,
PNAS 117(12):6752
CC BY 4.0

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


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Show notes:
Microbe of the episode: Rosavirus A

Takeaways

Microbes have amazing biochemical transformation abilities, creating and breaking down many compounds and proteins. This makes them great candidates for many purposes, in medicine, industry, and environmental remediation. In some of these purposes, though, there are risks associated with adding foreign microbes, especially engineered ones, that can replicate themselves and possibly persist, into new places.

To avoid this risk, this study turns intact bacteria into SimCells, simplified entities with most of their genetic material removed, leaving only the proteins and other components and just enough DNA to accomplish desired tasks. These SimCells were able to continue performing tasks for around 10 days before running out of the cellular resources needed to keep going. One of these tasks was producing a compound that damaged cancer cells in a dish but left non-cancerous cells unharmed.

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.

Other interesting stories:

• Biofuel-producing bacteria can generate electricity at the same time (paper)
• Using dried microbial biomass as fertilizer works pretty well (paper)

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

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426 - Sensory Cilia Supply Susceptibility

C. elegans roundworm
By Bob Goldstein, UNC Chapel Hill
CC BY-SA 3.0

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


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Show notes:
Microbe of the episode: Bat associated cyclovirus 9

Takeaways

Not all predators are fast or agile; some are sneaky, or good trap builders, or just good chemists. The predator club includes animals but also plants and even fungi. For example, the oyster mushroom fungus can paralyze roundworms in the soil that touch its filaments, then degrade their bodies and consume their nutrients.

The mechanism of this paralysis has been a mystery, but it's one step closer to being solved. This study found that intact sensory cilia, little hairs on the worm's head that help it sense its surroundings, are required for the paralysis to work. Worms with mutations in the structure of their cilia were protected from paralysis. How exactly the fungus acts on these cilia and the neurons they connect to, though, is still unknown.

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.

Other interesting stories:

• Bread waste could be good food for useful fermentations
• Symbiotic bacteria in beetle picked up gene that helps defend beetle eggs from fungus

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

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425 - Paired Predators Prevent Pathogen Persistence

Haloed plaques, Bdellovibrio,
and bacteriophage
By Hobley et al. 2020,
J Bacteriol 202(6), CC BY 4.0

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

Thanks to Laura Hobley, J. Kimberley Summers, and Jan-Ulrich Kreft for their contributions!

Also a note: I will be taking a short break from podcasts while I rebuild my collection of awesome microbiology stories to talk about.


Download Episode (6.8 MB, 9.9 minutes)

Show notes:
Microbe of the episode: Blackbird associated gemycircularvirus 1

Takeaways

Bacteriophages and bacterial predators that prey on other bacteria are both very good at killing large numbers of bacteria. But bacteria as a whole are also very good at surviving being killed in large numbers; there are almost always a few that have the right genes to overcome whatever is doing the killing. This is what makes the threat of antibiotic resistance so scary, and why phage therapy is both very promising and very limited.

In this study, however, a combination of phages and the bacterial predator Bdellovibrio bacteriovorans is able to completely eradicate a population of bacteria, or at least reduce their numbers below a detectable level. A mathematical model based on these data predicts that despite the two killers working independently, they can effectively eliminate all the individual prey organisms that would otherwise be able to resist killing by either one alone.

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.

Other interesting stories:

• Combination of beneficial bacteria could substitute for fertilizer somewhat (paper)
• Gut bacteria turn broccoli molecules into potentially healthy compounds

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

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424 - Stranger Cells Switch Stable States

Lactobacillus bacteria

Pelzer et al. 2012, PLOS One e49965

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

Thanks to Dr. Daniel Amor for his contribution!


Download Episode (6.3 MB, 9.2 minutes)

Show notes:
Microbe of the episode: Gadgets Gully virus

News item

Takeaways

Microbial communities show more than just competition between species. Stable assemblies of many species can exist for long periods in places like the human gut, despite constant minor shifts in conditions. More major shifts, or invaders like pathogens coming in and taking over, can cause big disruptions in the community and lead to long-term gut dysbiosis, which can be, interestingly, also a stable community. 

This study shows that invaders into a community, even if they don't persist for very long, can cause a shift from one stable state to another, by favoring the dominance of a species or group that was not dominant before, for example by changing the pH of the environment. So competition is always present. This could be helpful to know for efforts to intentionally shift community structures.

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.

Other interesting stories:

• Symbiotic bacteria engineered to protect honeybees from pathogens
• Mouse diet differences in fiber show much more effect on microbiome than differences in fat (paper)

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

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423 - Roundworm Riders Route Rootworm Resistance

Western corn rootworm adult

By Siga, CC BY-SA 4.0

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

Interactions between species and even kingdoms in nature can be complex and multilayered. This means that when we want to intervene to cause a particular outcome, there may be multiple points at which we can act, but the consequences may be hard to predict.

In this study, action was taken to counteract the damage the Western corn rootworm causes to corn crops, using a tiny roundworm that attacks the insect pest with deadly bacteria. The rootworm defends itself by accumulating plant-produced toxins that inhibit the bacteria. Directed evolution was used to make the bacteria more resistant, and this led to more effective killing of the pest.

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.

Other interesting stories:

• Altering pathogenic bacteria to reduce disease with genome-integrating phage (paper)
• Bacteria could inhibit fungus that causes deadly disease of bananas (paper)

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.