Your search keyword '"Łukasik, Piotr"' showing total 12 results

1. Co-habiting ants and silverfish display a converging feeding ecology.

Author

Parmentier T, Molero-Baltanás R, Valdivia C, Gaju-Ricart M, Boeckx P, Łukasik P, and Wybouw N

Subjects

Animals, Phylogeny, Nitrogen Isotopes analysis, Carbon Isotopes analysis, Perciformes physiology, Perciformes microbiology, Ants physiology, Ants microbiology, Feeding Behavior physiology, Symbiosis

Abstract

Background: Various animal taxa have specialized to living with social hosts. Depending on their level of specialization, these symbiotic animals are characterized by distinct behavioural, chemical, and morphological traits that enable close heterospecific interactions. Despite its functional importance, our understanding of the feeding ecology of animals living with social hosts remains limited. We examined how host specialization of silverfish co-habiting with ants affects several components of their feeding ecology. We combined stable isotope profiling, feeding assays, phylogenetic reconstruction, and microbial community characterization of the Neoasterolepisma silverfish genus and a wider nicoletiid and lepismatid silverfish panel where divergent myrmecophilous lifestyles are observed., Results: Stable isotope profiling (δ 13 C and δ 15 N) showed that the isotopic niches of granivorous Messor ants and Messor-specialized Neoasterolepisma exhibit a remarkable overlap within an ant nest. Trophic experiments and gut dissections further supported that these specialized Neoasterolepisma silverfish transitioned to a diet that includes plant seeds. In contrast, the isotopic niches of generalist Neoasterolepisma silverfish and generalist nicoletiid silverfish were clearly different from their ant hosts within the shared nest environment. The impact of the myrmecophilous lifestyle on feeding ecology was also evident in the internal silverfish microbiome. Compared to generalists, Messor-specialists exhibited a higher bacterial density and a higher proportion of heterofermentative lactic acid bacteria. Moreover, the nest environment explained the infection profile (or the 16S rRNA genotypes) of Weissella bacteria in Messor-specialized silverfish and the ant hosts., Conclusions: Together, we show that social hosts are important determinants for the feeding ecology of symbiotic animals and can induce diet convergence., (© 2024. The Author(s).)

Published

2024

2. Microbial symbionts are shared between ants and their associated beetles.

Author

Valdivia C, Newton JA, von Beeren C, O'Donnell S, Kronauer DJC, Russell JA, and Łukasik P

Subjects

Animals, Phylogeny, RNA, Ribosomal, 16S genetics, Larva, Bacteria genetics, Symbiosis, Ants genetics, Ants microbiology, Coleoptera, Microbiota

Abstract

The transmission of microbial symbionts across animal species could strongly affect their biology and evolution, but our understanding of transmission patterns and dynamics is limited. Army ants (Formicidae: Dorylinae) and their hundreds of closely associated insect guest species (myrmecophiles) can provide unique insights into interspecific microbial symbiont sharing. Here, we compared the microbiota of workers and larvae of the army ant Eciton burchellii with those of 13 myrmecophile beetle species using 16S rRNA amplicon sequencing. We found that the previously characterized specialized bacterial symbionts of army ant workers were largely absent from ant larvae and myrmecophiles, whose microbial communities were usually dominated by Rickettsia, Wolbachia, Rickettsiella and/or Weissella. Strikingly, different species of myrmecophiles and ant larvae often shared identical 16S rRNA genotypes of these common bacteria. Protein-coding gene sequences confirmed the close relationship of Weissella strains colonizing army ant larvae, some workers and several myrmecophile species. Unexpectedly, these strains were also similar to strains infecting dissimilar animals inhabiting very different habitats: trout and whales. Together, our data show that closely interacting species can share much of their microbiota, and some versatile microbial species can inhabit and possibly transmit across a diverse range of hosts and environments., (© 2023 The Authors. Environmental Microbiology published by Applied Microbiology International and John Wiley & Sons Ltd.)

Published

2023

3. Turtle ants harbor metabolically versatile microbiomes with conserved functions across development and phylogeny.

Author

Béchade B, Hu Y, Sanders JG, Cabuslay CS, Łukasik P, Williams BR, Fiers VJ, Lu R, Wertz JT, and Russell JA

Subjects

Animals, Bacteria genetics, Dietary Fiber, Nitrogen, Phylogeny, Symbiosis, Ants, Gastrointestinal Microbiome

Abstract

Gut bacterial symbionts can support animal nutrition by facilitating digestion and providing valuable metabolites. However, changes in symbiotic roles between immature and adult stages are not well documented, especially in ants. Here, we explored the metabolic capabilities of microbiomes sampled from herbivorous turtle ant (Cephalotes sp.) larvae and adult workers through (meta)genomic screening and in vitro metabolic assays. We reveal that larval guts harbor bacterial symbionts with impressive metabolic capabilities, including catabolism of plant and fungal recalcitrant dietary fibers and energy-generating fermentation. Additionally, several members of the specialized adult gut microbiome, sampled downstream of an anatomical barrier that dams large food particles, show a conserved potential to depolymerize many dietary fibers. Symbionts from both life stages have the genomic capacity to recycle nitrogen and synthesize amino acids and B-vitamins. With help of their gut symbionts, including several bacteria likely acquired from the environment, turtle ant larvae may aid colony digestion and contribute to colony-wide nitrogen, B-vitamin and energy budgets. In addition, the conserved nature of the digestive capacities among adult-associated symbionts suggests that nutritional ecology of turtle ant colonies has long been shaped by specialized, behaviorally-transferred gut bacteria with over 45 million years of residency., (© The Author(s) 2022. Published by Oxford University Press on behalf of FEMS.)

Published

2022

4. Herbivorous turtle ants obtain essential nutrients from a conserved nitrogen-recycling gut microbiome.

Author

Hu Y, Sanders JG, Łukasik P, D'Amelio CL, Millar JS, Vann DR, Lan Y, Newton JA, Schotanus M, Kronauer DJC, Pierce NE, Moreau CS, Wertz JT, Engel P, and Russell JA

Subjects

Amino Acids metabolism, Ammonia metabolism, Animals, Diet, Geography, Metagenome, Metagenomics, Nitrogen Fixation genetics, Nitrogen Isotopes, Symbiosis, Urea metabolism, Urease metabolism, Uric Acid metabolism, Ants microbiology, Ants physiology, Gastrointestinal Microbiome genetics, Herbivory physiology, Nitrogen metabolism

Abstract

Nitrogen acquisition is a major challenge for herbivorous animals, and the repeated origins of herbivory across the ants have raised expectations that nutritional symbionts have shaped their diversification. Direct evidence for N provisioning by internally housed symbionts is rare in animals; among the ants, it has been documented for just one lineage. In this study we dissect functional contributions by bacteria from a conserved, multi-partite gut symbiosis in herbivorous Cephalotes ants through in vivo experiments, metagenomics, and in vitro assays. Gut bacteria recycle urea, and likely uric acid, using recycled N to synthesize essential amino acids that are acquired by hosts in substantial quantities. Specialized core symbionts of 17 studied Cephalotes species encode the pathways directing these activities, and several recycle N in vitro. These findings point to a highly efficient N economy, and a nutritional mutualism preserved for millions of years through the derived behaviors and gut anatomy of Cephalotes ants.

Published

2018

5. The structured diversity of specialized gut symbionts of the New World army ants.

Author

Łukasik P, Newton JA, Sanders JG, Hu Y, Moreau CS, Kronauer DJC, O'Donnell S, Koga R, and Russell JA

Subjects

Animals, Phylogeny, Phylogeography, RNA, Ribosomal, 16S genetics, Ants microbiology, Bacteria classification, Gastrointestinal Tract microbiology, Microbiota, Symbiosis

Abstract

Symbiotic bacteria play important roles in the biology of their arthropod hosts. Yet the microbiota of many diverse and influential groups remain understudied, resulting in a paucity of information on the fidelities and histories of these associations. Motivated by prior findings from a smaller scale, 16S rRNA-based study, we conducted a broad phylogenetic and geographic survey of microbial communities in the ecologically dominant New World army ants (Formicidae: Dorylinae). Amplicon sequencing of the 16S rRNA gene across 28 species spanning the five New World genera showed that the microbial communities of army ants consist of very few common and abundant bacterial species. The two most abundant microbes, referred to as Unclassified Firmicutes and Unclassified Entomoplasmatales, appear to be specialized army ant associates that dominate microbial communities in the gut lumen of three host genera, Eciton, Labidus and Nomamyrmex. Both are present in other army ant genera, including those from the Old World, suggesting that army ant symbioses date back to the Cretaceous. Extensive sequencing of bacterial protein-coding genes revealed multiple strains of these symbionts coexisting within colonies, but seldom within the same individual ant. Bacterial strains formed multiple host species-specific lineages on phylogenies, which often grouped strains from distant geographic locations. These patterns deviate from those seen in other social insects and raise intriguing questions about the influence of army ant colony swarm-founding and within-colony genetic diversity on strain coexistence, and the effects of hosting a diverse suite of symbiont strains on colony ecology., (© 2017 John Wiley & Sons Ltd.)

Published

2017

6. By their own devices: invasive Argentine ants have shifted diet without clear aid from symbiotic microbes.

Author

Hu Y, Holway DA, Łukasik P, Chau L, Kay AD, LeBrun EG, Miller KA, Sanders JG, Suarez AV, and Russell JA

Subjects

Animals, Ants physiology, Argentina, Feeding Behavior, Introduced Species, RNA, Ribosomal, 16S genetics, Ants microbiology, Bacteria classification, Diet, Symbiosis

Abstract

The functions and compositions of symbiotic bacterial communities often correlate with host ecology. Yet cause-effect relationships and the order of symbiont vs. host change remain unclear in the face of ancient symbioses and conserved host ecology. Several groups of ants exemplify this challenge, as their low-nitrogen diets and specialized symbioses appear conserved and ancient. To address whether nitrogen-provisioning symbionts might be important in the early stages of ant trophic shifts, we studied bacteria from the Argentine ant, Linepithema humile - an invasive species that has transitioned towards greater consumption of sugar-rich, nitrogen-poor foods in parts of its introduced range. Bacteria were present at low densities in most L. humile workers, and among those yielding quality 16S rRNA amplicon sequencing data, we found just three symbionts to be common and dominant. Two, a Lactobacillus and an Acetobacteraceae species, were shared between native and introduced populations. The other, a Rickettsia, was found only in two introduced supercolonies. Across an eight-year period of trophic reduction in one introduced population, we found no change in symbionts, arguing against a relationship between natural dietary change and microbiome composition. Overall, our findings thus argue against major changes in symbiotic bacteria in association with the invasion and trophic shift of L. humile. In addition, genome content from close relatives of the identified symbionts suggests that just one can synthesize most essential amino acids; this bacterium was only modestly abundant in introduced populations, providing little support for a major role of nitrogen-provisioning symbioses in Argentine ant's dietary shift., (© 2016 John Wiley & Sons Ltd.)

Published

2017

7. Correlates of gut community composition across an ant species (Cephalotes varians) elucidate causes and consequences of symbiotic variability.

Author

Hu Y, Łukasik P, Moreau CS, and Russell JA

Subjects

Animals, Bacteria genetics, DNA, Bacterial genetics, Diet, Environment, Florida, Genotype, Molecular Sequence Data, Phylogeny, Polymorphism, Restriction Fragment Length, RNA, Ribosomal, 16S genetics, Sequence Analysis, DNA, Ants microbiology, Bacteria classification, Digestive System microbiology, Symbiosis

Abstract

Insect guts are often colonized by multispecies microbial communities that play integral roles in nutrition, digestion and defence. Community composition can differ across host species with increasing dietary and genetic divergence, yet gut microbiota can also vary between conspecific hosts and across an individual's lifespan. Through exploration of such intraspecific variation and its correlates, molecular profiling of microbial communities can generate and test hypotheses on the causes and consequences of symbioses. In this study, we used 454 pyrosequencing and TRFLP to achieve these goals in an herbivorous ant, Cephalotes varians, exploring variation in bacterial communities across colonies, populations and workers reared on different diets. C. varians bacterial communities were dominated by 16 core species present in over two-thirds of the sampled colonies. Core species comprised multiple genotypes, or strains and hailed from ant-specific clades containing relatives from other Cephalotes species. Yet three were detected in environmental samples, suggesting the potential for environmental acquisition. In spite of their prevalence and long-standing relationships with Cephalotes ants, the relative abundance and genotypic composition of core species varied across colonies. Diet-induced plasticity is a likely cause, but only pollen-based diets had consistent effects, altering the abundance of two types of bacteria. Additional factors, such as host age, genetics, chance or natural selection, must therefore shape natural variation. Future studies on these possibilities and on bacterial contributions to the use of pollen, a widespread food source across Cephalotes, will be important steps in developing C. varians as a model for studying widespread social insect-bacteria symbioses., (© 2013 John Wiley & Sons Ltd.)

Published

2014

8. Partner fidelity and environmental filtering preserve stage‐specific turtle ant gut symbioses for over 40 million years.

Author

Hu, Yi, D'Amelio, Catherine L., Béchade, Benoît, Cabuslay, Christian S., Łukasik, Piotr, Sanders, Jon G., Price, Shauna, Fanwick, Emily, Powell, Scott, Moreau, Corrie S., and Russell, Jacob A.

Subjects

INSECT societies, SYMBIOSIS, LACTIC acid bacteria, ANTS, QUEEN honeybees, INSECTS, ACTINOBACTERIA

Abstract

Sustaining beneficial gut symbioses presents a major challenge for animals, including holometabolous insects. Social insects may meet such challenges through partner fidelity, aided by behavioral symbiont transfer and transgenerational inheritance through colony founders. We address such potential through colony‐wide explorations across 13 eusocial, holometabolous insect species in the ant genus Cephalotes. Through amplicon sequencing, we show that previously characterized worker microbiomes are conserved in soldier castes, that adult microbiomes exhibit trends of phylosymbiosis, and that Cephalotes cospeciate with their most abundant adult‐enriched symbiont. We find, also, that winged queens harbor worker‐like microbiomes prior to colony founding, suggesting vertical inheritance as a means of partner fidelity. Whereas some adult‐abundant symbionts colonize larvae, larval gut microbiomes are uniquely characterized by environmental bacteria from the Enterobacteriales, Lactobacillales, and Actinobacteria. Distributions across Cephalotes larvae suggest more than 40 million years of conserved environmental filtering and, thus, a second sustaining mechanism behind an ancient, developmentally partitioned symbiosis. [ABSTRACT FROM AUTHOR]

Published

2023

9. Genome Evolution of Bartonellaceae Symbionts of Ants at the Opposite Ends of the Trophic Scale.

Author

Bisch, Gaelle, Neuvonen, Minna-Maria, Pierce, Naomi E, Russell, Jacob A, Koga, Ryuichi, Sanders, Jon G, Łukasik, Piotr, and Andersson, Siv G E

Subjects

BARTONELLACEAE, ANTS, INSECT genomes, INSECT genetics, MOLECULAR evolution

Abstract

Many insects rely on bacterial symbionts to supply essential amino acids and vitamins that are deficient in their diets, but metabolic comparisons of closely related gut bacteria in insects with different dietary preferences have not been performed. Here, we demonstrate that herbivorous ants of the genus Dolichoderus from the Peruvian Amazon host bacteria of the family Bartonellaceae, known for establishing chronic or pathogenic infections in mammals. We detected these bacteria in all studied Dolichoderus species, and found that they reside in the midgut wall, that is, the same location as many previously described nutritional endosymbionts of insects. The genomic analysis of four divergent strains infecting different Dolichoderus species revealed genes encoding pathways for nitrogen recycling and biosynthesis of several vitamins and all essential amino acids. In contrast, several biosynthetic pathways have been lost, whereas genes for the import and conversion of histidine and arginine to glutamine have been retained in the genome of a closely related gut bacterium of the carnivorous ant Harpegnathos saltator. The broad biosynthetic repertoire in Bartonellaceae of herbivorous ants resembled that of gut bacteria of honeybees that likewise feed on carbohydrate-rich diets. Taken together, the broad distribution of Bartonellaceae across Dolichoderus ants, their small genome sizes, the specific location within hosts, and the broad biosynthetic capability suggest that these bacteria are nutritional symbionts in herbivorous ants. The results highlight the important role of the host nutritional biology for the genomic evolution of the gut microbiota—and conversely, the importance of the microbiota for the nutrition of hosts. [ABSTRACT FROM AUTHOR]

Published

2018

10. Herbivorous turtle ants obtain essential nutrients from a conserved nitrogen-recycling gut microbiome.

Author

Yi Hu, Sanders, Jon G., Łukasik, Piotr, D'Amelio, Catherine L., Millar, John S., Vann, David R., Yemin Lan, Newton, Justin A., Schotanus, Mark, Kronauer, Daniel J. C., Pierce, Naomi E., Moreau, Corrie S., Wertz, John T., Engel, Philipp, and Russell, Jacob A.

Subjects

GUT microbiome, MUTUALISM (Biology), ESSENTIAL nutrients, ANTS, ESSENTIAL amino acids, HERBIVORES

Abstract

Nitrogen acquisition is a major challenge for herbivorous animals, and the repeated origins of herbivory across the ants have raised expectations that nutritional symbionts have shaped their diversification. Direct evidence for N provisioning by internally housed symbionts is rare in animals; among the ants, it has been documented for just one lineage. In this study we dissect functional contributions by bacteria from a conserved, multi-partite gut symbiosis in herbivorous Cephalotes ants through in vivo experiments, metagenomics, and in vitro assays. Gut bacteria recycle urea, and likely uric acid, using recycled N to synthesize essential amino acids that are acquired by hosts in substantial quantities. Specialized core symbionts of 17 studied Cephalotes species encode the pathways directing these activities, and several recycle N in vitro. These findings point to a highly efficient N economy, and a nutritional mutualism preserved for millions of years through the derived behaviors and gut anatomy of Cephalotes ants. [ABSTRACT FROM AUTHOR]

Published

2018

11. Dramatic Differences in Gut Bacterial Densities Correlate with Diet and Habitat in Rainforest Ants.

Author

Sanders, Jon G., Łukasik, Piotr, Frederickson, Megan E., Russell, Jacob A., Ryuichi Koga, Knight, Rob, and Pierce, Naomi E.

Subjects

*BACTERIAL communities, *ANTS, *HABITATS, *FLUORESCENCE microscopy, *MICROBIAL diversity

Abstract

Abundance is a key parameter in microbial ecology, and important to estimates of potential metabolite flux, impacts of dispersal, and sensitivity of samples to technical biases such as laboratory contamination. However, modern amplicon-based sequencing techniques by themselves typically provide no information about the absolute abundance of microbes. Here, we use fluorescence microscopy and quantitative polymerase chain reaction as independent estimates of microbial abundance to test the hypothesis that microbial symbionts have enabled ants to dominate tropical rainforest canopies by facilitating herbivorous diets, and compare these methods to microbial diversity profiles from 16S rRNA amplicon sequencing. Through a systematic survey of ants from a lowland tropical forest, we show that the density of gut microbiota varies across several orders of magnitude among ant lineages, with median individuals from many genera only marginally above detection limits. Supporting the hypothesis that microbial symbiosis is important to dominance in the canopy, we find that the abundance of gut bacteria is positively correlated with stable isotope proxies of herbivory among canopy-dwelling ants, but not among ground-dwelling ants. Notably, these broad findings are much more evident in the quantitative data than in the 16S rRNA sequencing data. Our results provide quantitative context to the potential role of bacteria in facilitating the ants' dominance of the tropical rainforest canopy, and have broad implications for the interpretation of sequence-based surveys of microbial diversity. [ABSTRACT FROM AUTHOR]

Published

2017

12. Author Correction: Herbivorous turtle ants obtain essential nutrients from a conserved nitrogenrecycling gut microbiome.

Author

Yi Hu, Sanders, Jon G., Łukasik, Piotr, D’Amelio, Catherine L., Millar, John S., Vann, David R., Lan, Yemin, Newton, Justin A., Schotanus, Mark, Kronauer, Daniel J. C., Pierce, Naomi E., Moreau, Corrie S., Wertz, John T., Engel, Philipp, and Russell, Jacob A.

Subjects

GUT microbiome, ESSENTIAL nutrients, ANTS, TURTLES, LOGGERHEAD turtle, SEA turtles, HYMENOPTERA

Published

2018