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1. Skin-penetrating nematodes exhibit life-stage-specific interactions with host-associated and environmental bacteria

Author

Chavez, Ivan N, Brown, Taylor M, Assié, Adrien, Bryant, Astra S, Samuel, Buck S, and Hallem, Elissa A

Subjects
Microbiology, Biological Sciences, Infectious Diseases, Aetiology, 2.2 Factors relating to the physical environment, Infection, Animals, Bacteria, Larva, Life Cycle Stages, Nematoda, Rats, Skin, Strongyloides ratti, Strongyloides stercoralis, Strongyloides, Parasitic nematode, Chemosensation, Sensory behavior, Developmental Biology, Biological sciences
Abstract

BackgroundSkin-penetrating nematodes of the genus Strongyloides infect over 600 million people, posing a major global health burden. Their life cycle includes both a parasitic and free-living generation. During the parasitic generation, infective third-stage larvae (iL3s) actively engage in host seeking. During the free-living generation, the nematodes develop and reproduce on host feces. At different points during their life cycle, Strongyloides species encounter a wide variety of host-associated and environmental bacteria. However, the microbiome associated with Strongyloides species, and the behavioral and physiological interactions between Strongyloides species and bacteria, remain unclear.ResultsWe first investigated the microbiome of the human parasite Strongyloides stercoralis using 16S-based amplicon sequencing. We found that S. stercoralis free-living adults have an associated microbiome consisting of specific fecal bacteria. We then investigated the behavioral responses of S. stercoralis and the closely related rat parasite Strongyloides ratti to an ecologically diverse panel of bacteria. We found that S. stercoralis and S. ratti showed similar responses to bacteria. The responses of both nematodes to bacteria varied dramatically across life stages: free-living adults were strongly attracted to most of the bacteria tested, while iL3s were attracted specifically to a narrow range of environmental bacteria. The behavioral responses to bacteria were dynamic, consisting of distinct short- and long-term behaviors. Finally, a comparison of the growth and reproduction of S. stercoralis free-living adults on different bacteria revealed that the bacterium Proteus mirabilis inhibits S. stercoralis egg hatching, and thereby greatly decreases parasite viability.ConclusionsSkin-penetrating nematodes encounter bacteria from various ecological niches throughout their life cycle. Our results demonstrate that bacteria function as key chemosensory cues for directing parasite movement in a life-stage-specific manner. Some bacterial genera may form essential associations with the nematodes, while others are detrimental and serve as a potential source of novel nematicides.

Published
2021

3. Chemosensory mechanisms of host seeking and infectivity in skin-penetrating nematodes

Author

Gang, Spencer S, Castelletto, Michelle L, Yang, Emily, Ruiz, Felicitas, Brown, Taylor M, Bryant, Astra S, Grant, Warwick N, and Hallem, Elissa A

Subjects
Veterinary Sciences, Agricultural, Veterinary and Food Sciences, Biomedical and Clinical Sciences, Biotechnology, Infectious Diseases, Aetiology, 2.1 Biological and endogenous factors, Animals, Behavior, Animal, Carbon Dioxide, Chemoreceptor Cells, Host-Parasite Interactions, Humans, Life Cycle Stages, Nematoda, Nematode Infections, Odorants, Olfactory Receptor Neurons, Skin, Strongyloides stercoralis, Temperature, parasitic helminth, parasitic nematode, host seeking, chemosensation
Abstract

Approximately 800 million people worldwide are infected with one or more species of skin-penetrating nematodes. These parasites persist in the environment as developmentally arrested third-stage infective larvae (iL3s) that navigate toward host-emitted cues, contact host skin, and penetrate the skin. iL3s then reinitiate development inside the host in response to sensory cues, a process called activation. Here, we investigate how chemosensation drives host seeking and activation in skin-penetrating nematodes. We show that the olfactory preferences of iL3s are categorically different from those of free-living adults, which may restrict host seeking to iL3s. The human-parasitic threadworm Strongyloides stercoralis and hookworm Ancylostoma ceylanicum have highly dissimilar olfactory preferences, suggesting that these two species may use distinct strategies to target humans. CRISPR/Cas9-mediated mutagenesis of the S. stercoralis tax-4 gene abolishes iL3 attraction to a host-emitted odorant and prevents activation. Our results suggest an important role for chemosensation in iL3 host seeking and infectivity and provide insight into the molecular mechanisms that underlie these processes.

Published
2020

5. Irruptive fall migrations are linked to elevated breeding abundance but are not associated with body condition or stopover duration in Northern Saw-whet Owls

Author

Craik, Shawn R, primary, Doucet, Amélie, additional, Manuel, Mathieu, additional, Roy, Chloé, additional, Brown, Taylor M, additional, Knighton, Emilie J, additional, Shutler, Dave, additional, Lauff, Randy F, additional, Ethier, Danielle, additional, Kouwenberg, Amy-Lee, additional, and Taylor, Philip D, additional

Published
2023
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6. Irruptive fall migrations are linked to elevated breeding abundance but are not associated with body condition or stopover duration in Northern Saw-whet Owls.

Author

Craik, Shawn R, Doucet, Amélie, Manuel, Mathieu, Roy, Chloé, Brown, Taylor M, Knighton, Emilie J, Shutler, Dave, Lauff, Randy F, Ethier, Danielle, Kouwenberg, Amy-Lee, and Taylor, Philip D

Subjects
BIRD breeding, NORTHERN saw-whet owl, BIRD migration, RADIO telemetry, STAGING areas (Birds)
Abstract

Bird species that undertake irruptive migrations are good candidates for assessing density-dependent effects on stopover ecology because the number of birds using stopover sites varies considerably from year to year. Using morphometric data from a 9-year banding program and radiotelemetry (n  = 25 females), we found that increases in the annual density of Northern Saw-whet Owls (NSWO; Aegolius acadicus) encountered at a fall stopover site in Nova Scotia, Canada, were not linked to female body condition or minimum stopover duration. Rather, most NSWO spent no more than 1 or 2 full days at the stopover site following radio-tagging and during their return visits to the site. Body condition indices were highest for NSWO captured near the end of the migration monitoring season, possibly reflecting birds that had recently established wintering ranges and were elevating energy stores. We used breeding abundance indices derived from Birds Canada's Atlantic Nocturnal Owl Survey to help test the hypothesis that irruptive fall migrations in NSWO were driven by elevated breeding productivity and dispersal of immature birds (breeding success hypothesis). Indeed, irruptive fall migrations were characterized by elevated densities of immatures, but not adults, and mean breeding abundance indices for the Maritime provinces during years with irruptive migrations were higher than those for non-irruptive years. We hypothesize that prey abundance during years with irruptive migrations was sufficient to enable high breeding densities and minimize effects of elevated fall densities of NSWO on rates of mass gain and stopover duration. [ABSTRACT FROM AUTHOR]

Published
2024
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7. Additional file 9 of Skin-penetrating nematodes exhibit life-stage-specific interactions with host-associated and environmental bacteria

Author

Chavez, Ivan N., Brown, Taylor M., Assié, Adrien, Bryant, Astra S., Samuel, Buck S., and Hallem, Elissa A.

Subjects
parasitic diseases
Abstract

Additional file 9.: Fig. S8. S. ratti and S. stercoralis respond similarly to the bacterial species tested. a. S. ratti free-living adults and S. stercoralis free-living adults displayed similar chemotaxis responses to the bacterial panel. No significant differences were detected (two-way ANOVA with Sidak’s post-test). n = 20-40 trials per condition, with 75-150 worms per trial. b. S. ratti iL3s and S. stercoralis iL3s displayed similar chemotaxis responses to the bacterial panel, with only a minor difference in the response to P. mirabilis. *p

Published
2021
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8. Additional file 10 of Skin-penetrating nematodes exhibit life-stage-specific interactions with host-associated and environmental bacteria

Author

Chavez, Ivan N., Brown, Taylor M., Assié, Adrien, Bryant, Astra S., Samuel, Buck S., and Hallem, Elissa A.

Abstract

Additional file 10: Fig. S9. Single-worm tracking assay design. Bacteria and unseeded LB media were plated on either side of a 5 cm diameter tracking arena (bolded inner circle) centered on a 10 cm 2% NGM plate (left). A single, older S. stercoralis free-living adult female was placed in the center of the arena and recorded for 20 min or until it left the tracking arena. Video analysis software and custom MATLAB code (see Materials and Methods) were used to produce and compile movement tracks (right). Pink and grey shaded circles indicate the location of the bacteria and LB media, respectively; red and grey circle outlines indicate the experimental region and the control region, respectively.

Published
2021
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9. Additional file 7 of Skin-penetrating nematodes exhibit life-stage-specific interactions with host-associated and environmental bacteria

Author

Chavez, Ivan N., Brown, Taylor M., Assié, Adrien, Bryant, Astra S., Samuel, Buck S., and Hallem, Elissa A.

Abstract

Additional file 7: Fig. S6. Bacteria chemotaxis assay design. a. Diagram of the bacterial chemotaxis assay. Following plating of bacteria and unseeded media on either side of the plate, a population of nematodes was placed along the center of a 10 cm 2% NGM plate and allowed to migrate for the duration of the assay. A chemotaxis index (CI) was then calculated after counting the number of nematodes in each region as: CI = (# worms in bacteria - # worms in control) / (# worms in bacteria + # worms in control). A positive CI indicates attraction to the bacteria, a negative CI indicates repulsion, and a CI near zero indicates a neutral response. b-e. Control chemotaxis assays with unseeded media on both sides of the plate. Each point in the graphs shows the CI of a single trial; medians (solid lines) and interquartile ranges (dashed lines) are also shown. LB = Luria broth; TS = tryptic soy media; RhiX = Rhizobium X media; BHIS = brain-heart infusion supplemented media. For each graph, no significant differences were detected comparing each condition to all other conditions, Kruskal-Wallis test with Dunn’s post-test (b and e) or Brown-Forsythe and Welch ANOVA with Dunnett’s T3 post-test (c-d). n = 20-32 trials per condition.

Published
2021
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10. Additional file 8 of Skin-penetrating nematodes exhibit life-stage-specific interactions with host-associated and environmental bacteria

Author

Chavez, Ivan N., Brown, Taylor M., Assié, Adrien, Bryant, Astra S., Samuel, Buck S., and Hallem, Elissa A.

Abstract

Additional file 8: Fig. S7. S. stercoralis free-living adults do not display strong preferences among fecal/gut bacteria. a. Diagram of the bacterial chemotaxis assay. For bacterial competition chemotaxis assays, different bacteria were plated on each side of the plate. A chemotaxis index (CI) was calculated after counting the number of nematodes in each region as: CI = (# worms in bacteria 1 region - # worms in bacteria 2 region) / (# worms in bacteria 1 region + # worms in bacteria 2 region). b. S. stercoralis free-living adults did not prefer E. coli or E. fergusonii over P. mirabilis. No significant differences were detected (Brown-Forsythe and Welch ANOVA). c. S. stercoralis free-living adults showed a slight preference for E. coli over E. fergusonii. **p

Published
2021
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11. Additional file 2 of Skin-penetrating nematodes exhibit life-stage-specific interactions with host-associated and environmental bacteria

Author

Chavez, Ivan N., Brown, Taylor M., Assié, Adrien, Bryant, Astra S., Samuel, Buck S., and Hallem, Elissa A.

Abstract

Additional file 2: Fig. S2. Heatmap summary of the genera abundance across samples for Experiment 1. Average relative abundance of different genera found in the different sample categories for Experiment 1. Sequencing samples were as described for Additional file 1: Fig. S1, in addition to an empty well negative control that was processed along with the other samples. ASVs were filtered to display only samples with an average relative abundance > 0.5%. Small columns within each category represent replicate samples.

Published
2021
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12. Additional file 6 of Skin-penetrating nematodes exhibit life-stage-specific interactions with host-associated and environmental bacteria

Author

Chavez, Ivan N., Brown, Taylor M., Assié, Adrien, Bryant, Astra S., Samuel, Buck S., and Hallem, Elissa A.

Subjects
ComputingMethodologies_PATTERNRECOGNITION, MathematicsofComputing_NUMERICALANALYSIS
Abstract

Additional file 6: Table S1. The bacterial panel selected. The table lists each bacterial species tested, its environment-type designation, the rationale for selecting it, and supporting references.

Published
2021
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13. Additional file 5 of Skin-penetrating nematodes exhibit life-stage-specific interactions with host-associated and environmental bacteria

Author

Chavez, Ivan N., Brown, Taylor M., Assié, Adrien, Bryant, Astra S., Samuel, Buck S., and Hallem, Elissa A.

Abstract

Additional file 5: Fig. S5. Heatmap summary of order abundance across samples for Experiment 2. Average relative abundance of different orders found in the different sample categories for Experiment 2, indicating the large abundance of Escherichia-Shigella, Lactobacillus, and Solibacillus ASVs in S. stercoralis free-living adults. Sequencing samples were as described for Additional file 1: Fig. S1, except that S. stercoralis iL3s were not included in this experiment. ASVs were filtered to display only samples with an average relative abundance > 0.5%. ASV identifiers in red are those that showed a significant enrichment in S. stercoralis free-living adults vs. controls in both sequencing experiments. Small columns within each category represent replicate samples.

Published
2021
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