Your search keyword '"Łukasik, Piotr"' showing total 11 results

1. Genome Comparison Reveals Inversions and Alternative Evolutionary History of Nutritional Endosymbionts in Planthoppers (Hemiptera: Fulgoromorpha).

Author

Deng, Junchen, Bennett, Gordon M, Franco, Diego C, Prus-Frankowska, Monika, Stroiński, Adam, Michalik, Anna, and Łukasik, Piotr

Subjects

PLANTHOPPERS, IMAGINARY histories, ESSENTIAL amino acids, BIOLOGICAL fitness, HOMOPTERA, INSECT diversity, GENOMES

Abstract

The evolutionary success of sap-feeding hemipteran insects in the suborder Auchenorrhyncha was enabled by nutritional contributions from their heritable endosymbiotic bacteria. However, the symbiont diversity, functions, and evolutionary origins in this large insect group have not been broadly characterized using genomic tools. In particular, the origins and relationships among ancient betaproteobacterial symbionts Vidania (in Fulgoromorpha) and Nasuia / Zinderia (in Cicadomorpha) are uncertain. Here, we characterized the genomes of Vidania and Sulcia from three Pyrops planthoppers (family Fulgoridae) to understand their metabolic functions and evolutionary histories. We find that, like in previously characterized planthoppers, these symbionts share nutritional responsibilities, with Vidania providing seven out of ten essential amino acids. Sulcia lineages across the Auchenorrhyncha have a highly conserved genome but with multiple independent rearrangements occurring in an early ancestor of Cicadomorpha or Fulgoromorpha and in a few succeeding lineages. Genomic synteny was also observed within each of the betaproteobacterial symbiont genera Nasuia , Zinderia, and Vidania , but not across them, which challenges the expectation of a shared ancestry for these symbionts. The further comparison of other biological traits strongly suggests an independent origin of Vidania early in the planthopper evolution and possibly of Nasuia and Zinderia in their respective host lineages. This hypothesis further links the potential acquisition of novel nutritional endosymbiont lineages with the emergence of auchenorrhynchan superfamilies. [ABSTRACT FROM AUTHOR]

Published

2023

2. No Transcriptional Compensation for Extreme Gene Dosage Imbalance in Fragmented Bacterial Endosymbionts of Cicadas.

Author

Spencer, Noah, Łukasik, Piotr, Meyer, Mariah, Veloso, Claudio, and McCutcheon, John P

Subjects

*CICADAS, *CYTOLOGY, *GENES, *DNA sequencing, *GENOMES

Abstract

Bacteria that form long-term intracellular associations with host cells lose many genes, a process that often results in tiny, gene-dense, and stable genomes. Paradoxically, the some of the same evolutionary processes that drive genome reduction and simplification may also cause genome expansion and complexification. A bacterial endosymbiont of cicadas, Hodgkinia cicadicola , exemplifies this paradox. In many cicada species, a single Hodgkinia lineage with a tiny, gene-dense genome has split into several interdependent cell and genome lineages. Each new Hodgkinia lineage encodes a unique subset of the ancestral unsplit genome in a complementary way, such that the collective gene contents of all lineages match the total found in the ancestral single genome. This splitting creates genetically distinct Hodgkinia cells that must function together to carry out basic cellular processes. It also creates a gene dosage problem where some genes are encoded by only a small fraction of cells while others are much more abundant. Here, by sequencing DNA and RNA of Hodgkinia from different cicada species with different amounts of splitting—along with its structurally stable, unsplit partner endosymbiont Sulcia muelleri— we show that Hodgkinia does not transcriptionally compensate to rescue the wildly unbalanced gene and genome ratios that result from lineage splitting. We also find that Hodgkinia has a reduced capacity for basic transcriptional control independent of the splitting process. Our findings reveal another layer of degeneration further pushing the limits of canonical molecular and cell biology in Hodgkinia and may partially explain its propensity to go extinct through symbiont replacement. [ABSTRACT FROM AUTHOR]

Published

2023

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

Author

Béchade, Benoît, Hu, Yi, Sanders, Jon G, Cabuslay, Christian S, Łukasik, Piotr, Williams, Bethany R, Fiers, Valerie J, Lu, Richard, Wertz, John T, and Russell, Jacob A

Subjects

ANTS, DIETARY fiber, ANT ecology, ANIMAL nutrition, TURTLES, GUT microbiome, PHYLOGENY, ANT colonies

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. [ABSTRACT FROM AUTHOR]

Published

2022

4. Off-target capture data, endosymbiont genes and morphology reveal a relict lineage that is sister to all other singing cicadas.

Author

Simon, Chris, Gordon, Eric R L, Moulds, M S, Cole, Jeffrey A, Haji, Diler, Lemmon, Alan R, Lemmon, Emily Moriarty, Kortyna, Michelle, Nazario, Katherine, Wade, Elizabeth J, Meister, Russell C, Goemans, Geert, Chiswell, Stephen M, Pessacq, Pablo, Veloso, Claudio, McCutcheon, John P, and Łukasik, Piotr

Subjects

CICADAS, HOMOPTERA, DATA distribution, ARID regions, MOLECULAR probes

Abstract

Phylogenetic asymmetry is common throughout the tree of life and results from contrasting patterns of speciation and extinction in the paired descendant lineages of ancestral nodes. On the depauperate side of a node, we find extant 'relict' taxa that sit atop long, unbranched lineages. Here, we show that a tiny, pale green, inconspicuous and poorly known cicada in the genus Derotettix , endemic to degraded salt-plain habitats in arid regions of central Argentina, is a relict lineage that is sister to all other modern cicadas. Nuclear and mitochondrial phylogenies of cicadas inferred from probe-based genomic hybrid capture data of both target and non-target loci and a morphological cladogram support this hypothesis. We strengthen this conclusion with genomic data from one of the cicada nutritional bacterial endosymbionts, Sulcia , an ancient and obligate endosymbiont of the larger plant-sucking bugs (Auchenorrhyncha) and an important source of maternally inherited phylogenetic data. We establish Derotettiginae subfam. nov. as a new, monogeneric, fifth cicada subfamily, and compile existing and new data on the distribution, ecology and diet of Derotettix. Our consideration of the palaeoenvironmental literature and host-plant phylogenetics allows us to predict what might have led to the relict status of Derotettix over 100 Myr of habitat change in South America. [ABSTRACT FROM AUTHOR]

Published

2019

5. One Hundred Mitochondrial Genomes of Cicadas.

Author

Łukasik, Piotr, Bublitz, De Anna C, Campbell, Matthew A, Meyer, Mariah C, Leuven, James T Van, McCutcheon, John P, Chong, Rebecca A, Nazario, Katherine, Simon, Chris, Matsuura, Yu, Pessacq, Pablo, and Veloso, Claudio

Subjects

*MITOCHONDRIA, *GENOMES, *BIOLOGY, *ORGANISMS, *CICADA (Genus), *PHYLOGENETIC models, *ECOLOGY

Abstract

Mitochondrial genomes can provide valuable information on the biology and evolutionary histories of their host organisms. Here, we present and characterize the complete coding regions of 107 mitochondrial genomes (mitogenomes) of cicadas (Insecta: Hemiptera: Auchenorrhyncha: Cicadoidea), representing 31 genera, 61 species, and 83 populations. We show that all cicada mitogenomes retain the organization and gene contents thought to be ancestral in insects, with some variability among cicada clades in the length of a region between the genes nad2 and cox1, which encodes 3 tRNAs. Phylogenetic analyses using these mitogenomes recapitulate a recent 5-gene classification of cicadas into families and subfamilies, but also identify a species that falls outside of the established taxonomic framework. While protein-coding genes are under strong purifying selection, tests of relative evolutionary rates reveal significant variation in evolutionary rates across taxa, highlighting the dynamic nature of mitochondrial genome evolution in cicadas. These data will serve as a useful reference for future research into the systematics, ecology, and evolution of the superfamily Cicadoidea. [ABSTRACT FROM AUTHOR]

Published

2019

6. 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

7. 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

8. Horizontal transfer of facultative endosymbionts is limited by host relatedness.

Author

Łukasik, Piotr, Guo, Huifang, Asch, Margriet, Henry, Lee M., Godfray, H. Charles J., and Ferrari, Julia

Subjects

*ENDOSYMBIOSIS, *ENTEROBACTERIACEAE, *BIOLOGICAL evolution, *GENOTYPES, *SITOBION avenae

Abstract

Heritable microbial symbionts can have important effects on many aspects of their hosts' biology. Acquisition of a novel symbiont strain can provide fitness benefits to the host, with significant ecological and evolutionary consequences. We measured barriers to horizontal transmission by artificially transferring facultative symbionts from the grain aphid, Sitobion avenae, and five other aphid species into two clonal genotypes of S. avenae. We found the symbiont Hamiltonella defensa establishes infections more easily following a transfer from the same host species and that such infections are more stable. Infection success was also higher when the introduced symbiont strain was more closely related to the strain that was originally present in the host (but which had previously been removed). There were no differences among successfully established symbiont strains in their effect on aphid fecundity. Hamiltonella defensa did not confer protection against parasitoids in our S. avenae clones, although it often does in other aphid hosts. However, strains of the symbiont Regiella insecticola originating from two host species protected grain aphids against the pathogenic fungus Pandora neoaphidis. This study helps describe the extent to which facultative symbionts can act as a pool of adaptations that can be sampled by their eukaryote hosts. [ABSTRACT FROM AUTHOR]

Published

2015

9. Trophic dimorphism in alternative male reproductive morphs of the acarid mite Sancassania berlesei.

Author

Łukasik, Piotr

Subjects

*CANNIBALISM, *ANIMAL behavior, *MITES, *DIMORPHISM in animals, *ANIMAL morphology, *SPECIES, *ANIMAL sexual behavior

Abstract

Presence of alternative male morphologies within a species has traditionally been related to different reproductive behaviors of morphs, and sexually selected weapons, that is, structures often present in a major male morph of a species, have been associated exclusively with competition between males over females. In this study, I show that alternative male phenotypes of the acarid mite Sancassania berlesei, one of the model male dimorphic species, differ in their foraging behaviors and diets. When food is deficient, aggressive “fighter” males use their weapons—thickened and sharply clawed third pair of legs, to kill conspecific juveniles and females, as well as individuals from at least one other species, which are subsequently consumed. Unarmed and benign “scrambler” males have no means of feeding in this way. The ecological importance and evolutionary consequences of this trophic dimorphism are unknown, but it might play an important role in fitness trade-offs between alternative male morphologies and, therefore, in evolution of conditional strategies. It might also increase the species’ potential for rapid diversification and speciation. [ABSTRACT FROM PUBLISHER]

Published

2010

10. STRUCTURAL COMPLEXITY OF THE ENVIRONMENT AFFECTS THE SURVIVAL OF ALTERNATIVE MALE REPRODUCTIVE TACTICS.

Author

Łukasik, Piotr, Radwan, Jacek, and Tomkins, Joseph L.

Subjects

*ANIMAL sexual behavior, *BIOLOGICAL evolution, *PHENOTYPES, *ANIMAL species, *MALES

Abstract

Alternative reproductive tactics in males are often associated with divergent phenotypes expressed as phenotypically plastic threshold traits. The evolution of threshold traits in these species has been modeled under the conditional evolutionarily stable strategy (ESS). Both strategic and genetic models predict that perturbations to the fitness trade-off between the male morphs will lead to a shift in the ESS switch point of the threshold. So far, demographic factors that influence the competitive ability of male morphs have been investigated and related to intraspecific population variation in male dimorphic thresholds. Here we reveal evidence for the theoretical prediction that abiotic features of the environment, in particular its structural complexity, are likely to influence the ESS threshold. In the male dimorphic mite Sancassania berlesei, we monitored the survival of aggressive fighter males and their benign scrambler counterparts in populations that differed in structural complexity. We found that, consistent with our prediction, the complex habitat favored fighter males, enabling them to kill a greater number of rival scramblers. We found no effect of habitat complexity on the survival of fighter males. These results demonstrate how abiotic as well as biotic aspects of the environment can be important in determining the frequencies of males adopting alternative tactics in different species or populations. [ABSTRACT FROM AUTHOR]

Published

2006

11. Corrigendum: Off-target capture data, endosymbiont genes and morphology reveal a relict lineage that is sister to all other singing cicadas.

Author

Simon, Chris, Gordon, Eric R L, Moulds, M S, Cole, Jeffrey A, Haji, Diler, Lemmon, Alan R, Lemmon, Emily Moriarty, Kortyna, Michelle, Nazario, Katherine, Wade, Elizabeth J, Meister, Russell C, Goemans, Geert, Chiswell, Stephen M, Pessacq, Pablo, Veloso, Claudio, McCutcheon, John P, and Łukasik, Piotr

Subjects

CICADAS, MORPHOLOGY, SISTERS, GENES

Published

2019