Dr. Elizabeth Dinsdale, Matthew Flinders Fellow in Marine Biology in the College of Science and Engineering at Flinders University in Adelaide, Australia, uses genomic techniques to investigate the biodiversity of microbial communities in distinct ecological niches, including coral reefs, kelp forest and shark epidermis. She discusses how shotgun metagenomics is being used to characterize the architecture of microbial communities living in the thin layer of underlying mucus on shark’s skin, and how understanding the function of these microbes is providing clues to important host-microbe interactions, including heavy metal tolerance. Ashley’s Biggest Takeaways: Sharks belong to a subclass of cartilaginous fish called elasmobranchs and are unique in that their epidermises are covered in dermal denticles—overlapping tooth-like structures that reduce drag and turbulence, helping the shark to move quickly and quietly through the water. These dermal denticles are sharp (if you’re going to pet a shark, make sure you go from the head to the tail to avoid getting cut!), and depending on the species of shark, may be more or less spread out across the epidermis. Where do microbes enter the story? Dermal denticles overlay a thin layer of mucus, which provides a distinctive environment for microbial life. Collecting microbial samples from underneath a shark’s dermal denticles is quite difficult, and the technique varies by shark species (shark size, water depth and ability to bite all factor into the equation). Liz’s team uses a specially designed tool that the group affectionately calls a “supersucker,” to create and capture a slurry of microbes and water for analysis. The team then uses shotgun metagenomics to identify and characterize the microbes in their collected samples. Sequencing has revealed biogeographical difference, as well as similarities in microbial architecture of whale sharks across the globe. There are 2 populations of whale sharks—one in the Atlantic Ocean and the other in the Indian Pacific Ocean. Samples collected from both populations have revealed that each individual whale shark, from within each aggregation, shares many of the same microbes. In fact, unlike algae which may share 1 to 2 microbial species, whale sharks share about 80% of microbes across every individual. Since many of the sharks don’t cross aggregations, Liz’s team is investigating the possibility of coevolution between microbes and hosts. Metagenomic sequencing also provides information about the function of the sequenced microbes. High presence of heavy metal-tolerant microbes has been found in the epidermis of all shark species that the team has analyzed. Sharks are known to carry high levels of heavy metals in their skin, muscle and even blood. However, muscle tissue samples contain lower concentrations than skin, indicating that there may be a density gradient in place, and raising questions about how microbes might be involved in this regulation. Is there a pathway by which the microbes metabolize and help to remove concentrations of heavy metals across the epidermis? Liz and her team are hoping to find out. Links: Elizabeth Dinsdale https://www.flinders.edu.au/people/elizabeth.dinsdale Tracking Pathogens via Next Generation Sequencing (NGS) https://asm.org/Magazine/2021/Spring/Tracking-Pathogens-via-Next-Generation-Sequencing Microbial Ecology of Four Coral Atolls in the Northern Line Islands https://journals.plos.org/plosone/article?id=10.1371/journal.pone.0001584 Coral Research https://coralandphage.org/research_coral.php Metagenomic analysis of stressed coral holobionts https://pubmed.ncbi.nlm.nih.gov/19397678/ Metagenomic analysis of the microbial community associated with the coral Porites astreoides https://pubmed.ncbi.nlm.nih.gov/17922755/
Dr. Mallory Choudoir, microbial ecologist and evolutionary biologist at the University of Massachusetts Amherst shares how she leverages microbial culture collections to infer ecological and evolutionary responses to warming soil temperatures. She discusses complexities of the soil microbiome and microbial dispersal dynamics, and introduces fundamental concepts about the intersection between microbes and social equity. Ashley’s Biggest Takeaways: Microbial culture collections are fundamental resources, serving as libraries where diverse species of microbes are identified, characterized and preserved in pure, viable form. Culture collections ensure conservation of species diversity and sustainable use of the collected microbes. For soil microbiologists, like Mallory Choudoir, culture collections provide the opportunity to connect patterns of genomic variation and microbial physiology to the conditions under which a particular microbe was isolated. Soil is a complex environment from the perspective of a microbe. In order to coexist in such a biologically diverse environment, which consists of spatial heterogeneity, as well as heterogeneity in access to moisture and nutrients, microbes must evolve different strategies to survive as part of a stable community. Choudoir’s field site is based in the Harvard Forest Long Term Ecological Research Program's field site, where coils are buried and have been heating the forest soil to 5 degrees above ambient temperatures for nearly 30 years. The study allows Choudoir and colleagues to observe and evaluate long-term responses to chronic soil warming stress. This research is important because microbes function as resources to the health and well-being of ourselves and our planet. Understanding how microbes adapt to biotic and abiotic stresses can help inform future conservation strategies, biotechnological approaches and applications and equitable allocation of microbial resources. Visit https://asm.org/mtm for links mentioned
Peter Hotez talks about the global impact and historical context of neglected tropical diseases. He also highlights important developments in mass drug administration and vaccine research and shares why he chose to publish the thirdedition ofForgotten People, Forgotten Diseasesduring the COVID-19 pandemic. Ashley's Biggest Takeaways Neglected Tropical Diseases (NTDs) are chronic and debilitating conditions that disproportionately impact people in low- and middle-income countries (LMICs). Many of these diseases are parasitic, such as hookworm infection, schistosomiasis and chagas disease; however, in recent years, several non-parasitic infections caused by bacteria, fungi and viruses, as well as a few conditions that are not infections, including snake bite and scabies (an ectoparasitic infestation), have been added to the original NTD framework (established in the early 2000s). What do most NTDs have in common? High prevalence. High mortality; low morbidity. Disabling. Interfere with people’s ability to work productively. Impact child development and/or the health of girls and women. Occur in a setting of poverty and actually cause poverty because of chronic and debilitating effects. Hotez and his colleagues recognized that there is a uniqueness to the NTDs ecosystem, and they began putting together a package of medicines that could be given on a yearly or twice per year basis, using a strategy called Mass Drug Administration (MDA). This involved the identification of medicines that were being used on an annual basis in vertical control programs and combining those medications in a package of interventions that costs about $0.50 per person per year. “Throw in an extra 50 cents per person and we could double or triple the impact of public health interventions,” he explained. Emerging diseases, such as SARS-CoV-2, capture the attention of the public for obvious reasons. They pose an imminent threat to mankind. NTDs are not emerging infections, but they are ancient afflictions that have plagued humankind for centuries and, as a consequence, have had a huge impact on ancient and modern history. One of the reasons we have mainland China and Taiwan today may have been, in part, due to a parasitic infection, Schistosomiasis. Hotez and colleagues at the Texas Children’s Center for Vaccine Development have developed a COVID-19 vaccine, based on simple technology, similar to what is used for the Hepatitis B vaccine. They hope to release the vaccine for emergency use in resource poor countries like India and Indonesia. When asked about the timing of the publication of his book, the thirdedition of Forgotten People, Forgotten Diseases, Hotez acknowledged the difficulty of helping countries understand that NTDs have not gone away. COVID-19 is superimposed on top of them, and the pandemic has done a lot of damage in terms of NTD control. Although social disruption has interfered with the ability to deliver mass treatments, Hotez said that it has been gratifying to see that the USAID and their contractors have responded by putting out guidelines about how to deliver mass treatments with safe social distancing. “As a global society, we have to figure out how to walk and chew gum at the same time,” he said. “We’ve got to take care of COVID, but we really must not lose the momentum we’ve had for NTDs because the prevalence is starting to decline and we’re really starting to make an impact.”
Rita Colwell has made major advances in basic and applied microbiology, largely focused on Vibrio cholerae. She describes several lines of evidence for the environmental niche of the bacterium, as well as her work to predict and prepare for cholera outbreaks. Colwell closes with her thoughts on why it’s a great time to be a microbiologist.
Denise Akob discusses her studies of microbial communities of contaminated and pristine environments using life science and earth science techniques. She discusses how to figure out “who’s there,” how to optimize select natural microbial activities, and her career path into government research. Julie’s Biggest Takeaways: Biogeomicrobiology straddles the life science and earth science fields. This is a growing area of research in the academic setting as well as in the private sector, where one can contribute to hydrogeology or bioremediation efforts. What happens on the surface when extracting resources like natural gases? Wastewater from hydraulic shale fracking, or fracking, can contaminate microbes. Preliminary data suggests that microbes that thrive in that wastewater can be a fingerprint for surface contamination, and this is one of the areas of active research in Akob’s lab. Additionally, microbes can respond to contaminants to remove that risk and remediate the spills. On...
How does tick biology influence their ability to transmit disease? Marshall Bloom explains the role of the tick salivary glands in Powassan virus transmission and the experiments that led to this discovery. He also provides a historical background for the Rocky Mountain Labs in Hamilton, Montana, and talks about the 3 elements to consider when working with potentially harmful biological agents. Subscribe (free) on Apple Podcasts, Google Podcasts, Android, RSS or by email. Julie’s Biggest Takeaways There are 3 elements to consider when working with potentially harmful biological agents: Biosafety: protecting the laboratory workers from the infectious agents in the lab. Biocontainment: protecting the community by keeping the infectious agent contained within the facility. Bioassurity: protecting the individual by ensuring those working with infectious agents are capable to do so. You need 4 bites of an APPLE for full lab safety, for work in labs from high school level through biosafe...
What kinds of microorganisms can degrade oil? How do scientists prioritize ecosystems for bioremediation after an oil spill? Joel Kostka discusses his research and the lessons from the Deepwater Horizon oil spill that will help scientists be better prepared for oil spills of the future. Links for this Episode: Joel Kostka Lab Website Kostka J. et al. Hydrocarbon-Degrading Bacteria and the Bacterial Community Response in Gulf of Mexico Beach Sands Impacted by the Deepwater Horizon Oil Spill. Applied and Environmental Microbiology. 2011. Shin B. et al. Succession of Microbial Populations and Nitroget-Fixation Associated With the Biodegradation of Sediment-Oil-Agglomerates Buried in a Florida Sandy Beach. Scientific Reports. 2019. Bociu I. Decomposition of Sediment-Oil-Agglomerates in a Gulf of Mexico Sandy Beach. Scientific Reports. 2019. Overhold W.A. et al. Draft Genome Sequences for Oil-Degrading Bacterial Strains from Beach Sands Impacted by the Deepwater Horizon Oil Spill. Genome...
How do arboviruses evolve as they pass between different hosts? Greg Ebel discusses his research on West Nile virus evolution and what it means for viral diversity. He also talks about using mosquitos’ most recent blood meal to survey human health in a process called xenosurveillance. Julie’s Biggest Takeaways: Mosquitoes and other arthropods have limited means of immune defense against infection. One major defense mechanism is RNA interference (RNAi). RNAi uses pieces of the West Nile viral genome to select against the viral genome, which helps select for broadly diverse viral sequences. The more rare a viral genotype, the more likely it is to escape negative selection inside the mosquito host, allowing this viral sequence to increase in frequency. West Nile virus passes largely between birds and mosquitos. Culex mosquitos tend to prefer birds, and this leads to an enzootic cycle for the virus passing between birds and mosquitos. The viral life cycle inside the mosquito has sever...
How can the intricate relationship between soil microbiota and plants be managed for improved plant health? Linda Kinkel discusses new insights into the plant rhizosphere and the ways that some Streptomyces isolates can protect agricultural crops against bacterial, fungal, oomycete, and nematode infections. Julie’s Biggest Takeaways: The soil microbiome is extremely dynamic, with boom-and-bust cycles driven by nutrient fluxes, microbial interactions, plant-driven microbial interactions, and signaling interactions. Finding the source of these boom-and-bust cycles can help people to manage the microbiome communities and produce plant-beneficial communities for agricultural purposes. Rhizosphere soil is soil closely associated with the root and is distinct from rhizoplane soil that directly touches the root. The endophytic rhizosphere are those microbes that get inside the root. Many scientists view these communities as a continuum rather than sharply delineated. Plants provide necess...
Pathogenic E. coli are different than lab-grown or commensal E. coli found in the gut microbiome. Alfredo Torres describes the difference between these, the method his lab is using the develop vaccines against pathogenic E. coli, and how this same method can be used to develop vaccines against Burkholderia infections. Julie’s Biggest Takeaways: coli plays many roles inside and outside the scientific laboratory: Laboratory E. coli strains used by scientists to study molecular biology. Commensal E. coli strains contribute to digestion and health as part of the intestinal microbiome. Pathogenic E. coli strains have acquired factors that allow them to cause disease in people The pathogenic E. coli associated with diarrheal disease are the ones named for their O-antigen and flagellar H-antigen, such as O157:H7. There are about 30 E. coli strains with various combinations of O-H factors known to cause diarrheal disease in people. The E. coli Shiga toxin (though not the bacterium itself) ...