Your search keyword '"Joanito Liberti"' showing total 27 results

1. Fecal transplant allows transmission of the gut microbiota in honey bees

Author

Amélie Cabirol, Audam Chhun, Joanito Liberti, Lucie Kesner, Nicolas Neuschwander, Yolanda Schaerli, and Philipp Engel

Subjects

host-microbe interactions, microbiome, 16S rRNA gene, social insects, Apis mellifera, Microbiology, QR1-502

Abstract

ABSTRACT The study of the fecal microbiota is crucial for unraveling the pathways through which gut symbionts are acquired and transmitted. While stable gut microbial communities are essential for honey bee health, their modes of acquisition and transmission are yet to be confirmed. The gut of honey bees is colonized by symbiotic bacteria within 5 days after emergence from their wax cells as adults. Few studies have suggested that bees could be colonized in part via contact with fecal matter in the hive. However, the composition of the fecal microbiota is still unknown. It is particularly unclear whether all bacterial species can be found viable in the feces and can therefore be transmitted to newborn nestmates. Using 16S rRNA gene amplicon sequencing, we revealed that the composition of the honey bee fecal microbiota is strikingly similar to the microbiota of entire guts. We found that fecal transplantation resulted in gut microbial communities similar to those obtained from feeding gut homogenates. Our study shows that fecal sampling and transplantation are viable tools for the non-invasive analysis of bacterial community composition and host-microbe interactions. It also implies that contact of young bees with fecal matter in the hive is a plausible route for gut microbiota acquisition.IMPORTANCEHoney bees are crucial pollinators for many crops and wildflowers. They are also powerful models for studying microbiome-host interactions. However, current methods rely on gut tissue disruption to analyze microbiota composition and use gut homogenates to inoculate microbiota-deprived bees. Here, we provide two new and non-invasive approaches that will open doors to longitudinal studies: fecal sampling and transplantation. Furthermore, our findings provide insights into gut microbiota transmission in social insects by showing that ingestion of fecal matter can result in gut microbiota acquisition.

Published

2024

2. Gut microbiota influences onset of foraging-related behavior but not physiological hallmarks of division of labor in honeybees

Author

Joanito Liberti, Erik T. Frank, Tomas Kay, Lucie Kesner, Maverick Monié--Ibanes, Andrew Quinn, Thomas Schmitt, Laurent Keller, and Philipp Engel

Subjects

Apis mellifera, behavioral maturation, social behavior, behavioral development, microorganisms, symbiosis, Microbiology, QR1-502

Abstract

ABSTRACT Gut microbes can impact cognition and behavior, but whether they regulate the division of labor in animal societies is unknown. We addressed this question using honeybees since they exhibit division of labor between nurses and foragers and because their gut microbiota can be manipulated. Using automated behavioral tracking and controlling for co-housing effects, we show that gut microbes influence the age at which bees start expressing foraging-like behaviors in the laboratory but have no effects on the time spent in a foraging arena and number of foraging trips. Moreover, the gut microbiota did not influence hallmarks of behavioral maturation such as body weight, cuticular hydrocarbon profile, hypopharyngeal gland size, gene expression, and the proportion of bees maturing into foragers. Overall, this study shows that the honeybee gut microbiota plays a role in controlling the onset of foraging-related behavior without permanent consequences on colony-level division of labor and several physiological hallmarks of behavioral maturation.IMPORTANCEThe honeybee is emerging as a model system for studying gut microbiota-host interactions. Previous studies reported gut microbiota effects on multiple worker bee phenotypes, all of which change during behavioral maturation—the transition from nursing to foraging. We tested whether the documented effects may stem from an effect of the microbiota on behavioral maturation. The gut microbiota only subtly affected maturation: it accelerated the onset of foraging without affecting the overall proportion of foragers or their average output. We also found no effect of the microbiota on host weight, cuticular hydrocarbon (CHC) profile, hypopharyngeal gland size, and the expression of behavioral maturation-related genes. These results are inconsistent with previous studies reporting effects of the gut microbiota on bee weight and CHC profile. Our experiments revealed that co-housed bees tend to converge in behavior and physiology, suggesting that spurious associations may emerge when rearing environments are not replicated sufficiently or accounted for analytically.

Published

2024

3. Targeted treatment of injured nestmates with antimicrobial compounds in an ant society

Author

Erik. T. Frank, Lucie Kesner, Joanito Liberti, Quentin Helleu, Adria C. LeBoeuf, Andrei Dascalu, Douglas B. Sponsler, Fumika Azuma, Evan P. Economo, Patrice Waridel, Philipp Engel, Thomas Schmitt, and Laurent Keller

Subjects

Science

Abstract

Abstract Infected wounds pose a major mortality risk in animals. Injuries are common in the ant Megaponera analis, which raids pugnacious prey. Here we show that M. analis can determine when wounds are infected and treat them accordingly. By applying a variety of antimicrobial compounds and proteins secreted from the metapleural gland to infected wounds, workers reduce the mortality of infected individuals by 90%. Chemical analyses showed that wound infection is associated with specific changes in the cuticular hydrocarbon profile, thereby likely allowing nestmates to diagnose the infection state of injured individuals and apply the appropriate antimicrobial treatment. This study demonstrates that M. analis ant societies use antimicrobial compounds produced in the metapleural glands to treat infected wounds and reduce nestmate mortality.

Published

2023

4. Deep Divergence and Genomic Diversification of Gut Symbionts of Neotropical Stingless Bees

Author

Garance Sarton-Lohéac, Carlos Gustavo Nunes da Silva, Florent Mazel, Gilles Baud, Vincent de Bakker, Sudip Das, Yassine El Chazli, Kirsten Ellegaard, Marc Garcia-Garcera, Natasha Glover, Joanito Liberti, Lorena Nacif Marçal, Aiswarya Prasad, Vincent Somerville, Germán Bonilla-Rosso, and Philipp Engel

Subjects

bacteria, diversification, genome, gut microbiome, insects, phylogeny, Microbiology, QR1-502

Abstract

ABSTRACT Social bees harbor conserved gut microbiotas that may have been acquired in a common ancestor of social bees and subsequently codiversified with their hosts. However, most of this knowledge is based on studies on the gut microbiotas of honey bees and bumblebees. Much less is known about the gut microbiotas of the third and most diverse group of social bees, the stingless bees. Specifically, the absence of genomic data from their microbiotas presents an important knowledge gap in understanding the evolution and functional diversity of the social bee microbiota. Here, we combined community profiling with culturing and genome sequencing of gut bacteria from six neotropical stingless bee species from Brazil. Phylogenomic analyses show that most stingless bee gut isolates form deep-branching sister clades of core members of the honey bee and bumblebee gut microbiota with conserved functional capabilities, confirming the common ancestry and ecology of their microbiota. However, our bacterial phylogenies were not congruent with those of the host, indicating that the evolution of the social bee gut microbiota was not driven by strict codiversification but included host switches and independent symbiont gain and losses. Finally, as reported for the honey bee and bumblebee microbiotas, we found substantial genomic divergence among strains of stingless bee gut bacteria, suggesting adaptation to different host species and glycan niches. Our study offers first insights into the genomic diversity of the stingless bee microbiota and highlights the need for broader samplings to understand the evolution of the social bee gut microbiota. IMPORTANCE Stingless bees are the most diverse group of the corbiculate bees and represent important pollinator species throughout the tropics and subtropics. They harbor specialized microbial communities in their gut that are related to those found in honey bees and bumblebees and that are likely important for bee health. Few bacteria have been cultured from the gut of stingless bees, which has prevented characterization of their genomic diversity and functional potential. Here, we established cultures of major members of the gut microbiotas of six stingless bee species and sequenced their genomes. We found that most stingless bee isolates belong to novel bacterial species distantly related to those found in honey bees and bumblebees and encoding similar functional capabilities. Our study offers a new perspective on the evolution of the social bee gut microbiota and presents a basis for characterizing the symbiotic relationships between gut bacteria and stingless bees.

Published

2023

5. Mild chronic exposure to pesticides alters physiological markers of honey bee health without perturbing the core gut microbiota

Author

Hanine Almasri, Joanito Liberti, Jean-Luc Brunet, Philipp Engel, and Luc P. Belzunces

Subjects

Medicine, Science

Abstract

Abstract Recent studies highlighted that exposure to glyphosate can affect specific members of the core gut microbiota of honey bee workers. However, in this study, bees were exposed to relatively high glyphosate concentrations. Here, we chronically exposed newly emerged honey bees to imidacloprid, glyphosate and difenoconazole, individually and in a ternary mixture, at an environmental concentration of 0.1 µg/L. We studied the effects of these exposures on the establishment of the gut microbiota, the physiological status, the longevity, and food consumption of the host. The core bacterial species were not affected by the exposure to the three pesticides. Negative effects were observed but they were restricted to few transient non-core bacterial species. However, in the absence of the core microbiota, the pesticides induced physiological disruption by directly altering the detoxification system, the antioxidant defenses, and the metabolism of the host. Our study indicates that even mild exposure to pesticides can directly alter the physiological homeostasis of newly emerged honey bees and particularly if the individuals exhibit a dysbiosis (i.e. mostly lack the core microbiota). This highlights the importance of an early establishment of a healthy gut bacterial community to strengthen the natural defenses of the honey bee against xenobiotic stressors.

Published

2022

6. Rival seminal fluid induces enhanced sperm motility in a polyandrous ant

Author

Joanito Liberti, Boris Baer, and Jacobus J. Boomsma

Subjects

Social insects, Sexual selection, Sperm competition, Sperm motility, Sexual conflicts, Evolution, QH359-425

Abstract

Abstract Background Promiscuous mating and sperm competition often induce arms races between the sexes with detrimental outcomes for females. However, ants with multiply-inseminated queens have only a single time-window for sperm competition and queens are predicted to gain control over the outcome of sperm storage quickly. The seminal fluid of Acromyrmex leaf-cutting ants reduces the viability of rival sperm, but how confrontations between unrelated ejaculates affect sperm storage remains unknown. Results We investigated the effects of ejaculate admixture on sperm motility in A. echinatior and found that the proportion of motile spermatozoa, sperm swimming speed, and linearity of sperm movement increased when rival ejaculates were mixed in vitro. Major effects induced by the seminal fluid of rival males were of similar magnitude to those generated by queen reproductive tract secretions, whereas own seminal fluid induced lower sperm activation levels. Conclusions Our results suggest that ant sperm respond via a self–non-self recognition mechanism to similar or shared molecules expressed in the reproductive secretions of both sexes. Lower sperm motility in the presence of own seminal fluid indicates that enhanced motility is costly and may trade-off with sperm viability during sperm storage, consistent with studies in vertebrates. Our results imply that ant spermatozoa have evolved to adjust their energetic expenditure during insemination depending on the perceived level of sperm competition.

Published

2018

7. Seminal fluid compromises visual perception in honeybee queens reducing their survival during additional mating flights

Author

Joanito Liberti, Julia Görner, Mat Welch, Ryan Dosselli, Morten Schiøtt, Yuri Ogawa, Ian Castleden, Jan M Hemmi, Barbara Baer-Imhoof, Jacobus J Boomsma, and Boris Baer

Subjects

social insects, sexual conflict, RNA-sequencing, neurotranscriptomics, artificial insemination, Apis mellifera, Medicine, Science, Biology (General), QH301-705.5

Abstract

Queens of social insects make all mate-choice decisions on a single day, except in honeybees whose queens can conduct mating flights for several days even when already inseminated by a number of drones. Honeybees therefore appear to have a unique, evolutionarily derived form of sexual conflict: a queen’s decision to pursue risky additional mating flights is driven by later-life fitness gains from genetically more diverse worker-offspring but reduces paternity shares of the drones she already mated with. We used artificial insemination, RNA-sequencing and electroretinography to show that seminal fluid induces a decline in queen vision by perturbing the phototransduction pathway within 24–48 hr. Follow up field trials revealed that queens receiving seminal fluid flew two days earlier than sister queens inseminated with saline, and failed more often to return. These findings are consistent with seminal fluid components manipulating queen eyesight to reduce queen promiscuity across mating flights.

Published

2019

8. Impact of Chronic Exposure to Sublethal Doses of Glyphosate on Honey Bee Immunity, Gut Microbiota and Infection by Pathogens

Author

Loreley Castelli, Sofía Balbuena, Belén Branchiccela, Pablo Zunino, Joanito Liberti, Philipp Engel, and Karina Antúnez

Subjects

glyphosate, pesticides, honey bee gut microbiota, honey bee immune response, Nosema ceranae, deformed wing virus, Biology (General), QH301-705.5

Abstract

Glyphosate is the most used pesticide around the world. Although different studies have evidenced its negative effect on honey bees, including detrimental impacts on behavior, cognitive, sensory and developmental abilities, its use continues to grow. Recent studies have shown that it also alters the composition of the honey bee gut microbiota. In this study we explored the impact of chronic exposure to sublethal doses of glyphosate on the honey bee gut microbiota and its effects on the immune response, infection by Nosema ceranae and Deformed wing virus (DWV) and honey bee survival. Glyphosate combined with N. ceranae infection altered the structure and composition of the honey bee gut microbiota, for example by decreasing the relative abundance of the core members Snodgrassella alvi and Lactobacillus apis. Glyphosate increased the expression of some immune genes, possibly representing a physiological response to mitigate its negative effects. However, this response was not sufficient to maintain honey bee health, as glyphosate promoted the replication of DWV and decreased the expression of vitellogenin, which were accompanied by a reduced life span. Infection by N. ceranae also alters honey bee immunity although no synergistic effect with glyphosate was observed. These results corroborate previous findings suggesting deleterious effects of widespread use of glyphosate on honey bee health, and they contribute to elucidate the physiological mechanisms underlying a global decline of pollination services.

Published

2021

9. Differences in forage-acquisition and fungal enzyme activity contribute to niche segregation in Panamanian leaf-cutting ants.

Author

Pepijn W Kooij, Joanito Liberti, Konstantinos Giampoudakis, Morten Schiøtt, and Jacobus J Boomsma

Subjects

Medicine, Science

Abstract

The genera Atta and Acromyrmex are often grouped as leaf-cutting ants for pest management assessments and ecological surveys, although their mature colony sizes and foraging niches may differ substantially. Few studies have addressed such interspecific differences at the same site, which prompted us to conduct a comparative study across six sympatric leaf-cutting ant species in Central Panama. We show that foraging rates during the transition between dry and wet season differ about 60 fold between genera, but are relatively constant across species within genera. These differences appear to match overall differences in colony size, especially when Atta workers that return to their nests without leaves are assumed to carry liquid food. We confirm that Panamanian Atta specialize primarily on tree-leaves whereas Acromyrmex focus on collecting flowers and herbal leaves and that species within genera are similar in these overall foraging strategies. Species within genera tended to be spaced out over the three habitat categories that we distinguished (forest, forest edge, open grassland), but each of these habitats normally had only a single predominant Atta and Acromyrmex species. We measured activities of twelve fungus garden decomposition enzymes, belonging to the amylases, cellulases, hemicellulases, pectinases and proteinases, and show that average enzyme activity per unit of fungal mass in Atta gardens is lower than in Acromyrmex gardens. Expression profiles of fungal enzymes in Atta also appeared to be more specialized than in Acromyrmex, possibly reflecting variation in forage material. Our results suggest that species- and genus-level identities of leaf-cutting ants and habitat-specific foraging profiles may give predictable differences in the expression of fungal genes coding for decomposition enzymes.

Published

2014

10. A defined community of core gut microbiota members promotes cognitive performance in honey bees

Author

Amélie Cabirol, Julie Schafer, Nicolas Neuschwander, Lucie Kesner, Joanito Liberti, and Philipp Engel

Abstract

The composition of the gut microbiota has recently been identified as a cause of cognitive variability in humans and animals. Germ-free individuals and individuals exposed to an antibiotic treatment show severe alteration of their learning and memory performance measured in various cognitive tasks. While different species of bacteria are known to interact in the gut, their cumulative or synergistic effects on cognitive performance remain elusive. Here we established a defined bacterial community - composed of core members of the corbiculate bee microbiota - which enhances honey bees’ cognitive capacities. Honey bees colonized with this reconstituted community discriminated better two odours based on the presence or absence of a sucrose reward compared to germ-free individuals. They also memorized better these odour-food associations in the short-term. These cognitive improvements seem to constitute an emergent property of the community, because they could not be recapitulated by any of the community members when mono-associated in gnotobiotic bees and they were not explained by the total biomass in the gut. The identification of this community and its effect on bees open new avenues of research in neuroscience, microbiology, and ecology. Future research should help understanding how interactions between bacterial species in the community promote the host’s associative learning and memory performance.

Published

2023

11. Antimicrobial wound care in an ant society

Author

Erik. T. Frank, Lucie Kesner, Joanito Liberti, Quentin Helleu, Adria C. LeBoeuf, Andrei Dascalu, Douglas B. Sponsler, Fumika Azuma, Evan P. Economo, Patrice Waridel, Philipp Engel, Thomas Schmitt, and Laurent Keller

Abstract

Infected wounds pose a major mortality risk in animals1,2. Injuries are common in the antMegaponera analis, which raids pugnacious prey3,4. Here we show thatM. analiscan determine when wounds are infected and treat them accordingly. By applying a variety of antimicrobial compounds and proteins secreted from the metapleural gland to infected wounds, workers reduce the mortality of infected individuals by 90%. Chemical analyses showed that wound infection is associated with specific changes in the cuticular hydrocarbon profile, thereby likely allowing nestmates to diagnose the infection state of injured individuals and apply the appropriate antimicrobial treatment. This study demonstrates that the targeted use of antimicrobials to treat infected wounds, previously thought to be a uniquely human behavior, has evolved in insect societies as well.

Published

2022

12. The gut microbiota affects the social network of honeybees

Author

Joanito Liberti, Tomas Kay, Andrew Quinn, Lucie Kesner, Erik T. Frank, Amélie Cabirol, Thomas O. Richardson, Philipp Engel, and Laurent Keller

Subjects

Ecology, Microbiota, Animals, Amino Acids, Bees, digestive system, Ecology, Evolution, Behavior and Systematics, Chromatin, Gastrointestinal Microbiome, Social Networking

Abstract

The gut microbiota influences animal neurodevelopment and behaviour but has not previously been documented to affect group-level properties of social organisms. Here, we use honeybees to probe the effect of the gut microbiota on host social behaviour. We found that the microbiota increased the rate and specialization of head-to-head interactions between bees. Microbiota colonization was associated with higher abundances of one-third of the metabolites detected in the brain, including amino acids with roles in synaptic transmission and brain energetic function. Some of these metabolites were significant predictors of the number of social interactions. Microbiota colonization also affected brain transcriptional processes related to amino acid metabolism and epigenetic modifications in a brain region involved in sensory perception. These results demonstrate that the gut microbiota modulates the emergent colony social network of honeybees and suggest changes in chromatin accessibility and amino acid biosynthesis as underlying processes.

Published

2022

13. Gut microbiota structure differs between honeybees in winter and summer

Author

Lucie Kešnerová, Berra Erkosar, Michaël Troilo, Philipp Engel, Olivier Emery, and Joanito Liberti

Subjects

Foraging, Zoology, Gut flora, digestive system, complex mixtures, Microbiology, Article, Microbial ecology, Low complexity, 03 medical and health sciences, Commensalibacter, Symbiosis, Animals, Microbiome, Ecology, Evolution, Behavior and Systematics, 030304 developmental biology, 0303 health sciences, Bacteria, biology, 030306 microbiology, fungi, Bees, biology.organism_classification, Gastrointestinal Microbiome, Gastrointestinal Tract, Community composition, Seasons

Abstract

Adult honeybees harbor a specialized gut microbiota of relatively low complexity. While seasonal differences in community composition have been reported, previous studies have focused on compositional changes rather than differences in absolute bacterial loads. Moreover, little is known about the gut microbiota of winter bees, which live much longer than bees during the foraging season, and which are critical for colony survival. We quantified seven core members of the bee gut microbiota in a single colony over 2 years and characterized the community composition in 14 colonies during summer and winter. Our data show that total bacterial loads substantially differ between foragers, nurses, and winter bees. Long-lived winter bees had the highest bacterial loads and the lowest community α-diversity, with a characteristic shift toward high levels of Bartonella and Commensalibacter, and a reduction of opportunistic colonizers. Using gnotobiotic bee experiments, we show that diet is a major contributor to the observed differences in bacterial loads. Overall, our study reveals that the gut microbiota of winter bees is remarkably different from foragers and nurses. Considering the importance of winter bees for colony survival, future work should focus on the role of the gut microbiota in winter bee health and disease.

Published

2019

14. Impact of chronic exposure to sublethal doses of glyphosate on honey bee immunity, gut microbiota and infection by pathogens

Author

Pablo Zunino, Belén Branchiccela, Philipp Engel, Sofía Balbuena, Karina Antúnez, Loreley Castelli, and Joanito Liberti

Subjects

0106 biological sciences, 0301 basic medicine, Microbiology (medical), NOSEMA CERANAE, animal structures, Pollination, APICULTURA, ABEJAS, honey bee immune response, GLYPHOSATE, honey bee gut microbiota, Nosema ceranae, Gut flora, 01 natural sciences, Microbiology, Article, 03 medical and health sciences, Vitellogenin, Immune system, glyphosate, PESTICIDES, Immunity, Virology, Deformed wing virus, lcsh:QH301-705.5, biology, deformed wing virus, HONEY BEE IMMUNE RESPONSE, digestive, oral, and skin physiology, fungi, food and beverages, pesticides, Honey bee, biology.organism_classification, 010602 entomology, 030104 developmental biology, lcsh:Biology (General), behavior and behavior mechanisms, biology.protein, HONEY BEE HEALTH, HONEY BEE GUT MICROBIOTA, DEFORMED WING VIRUS, honey bee health

Abstract

Glyphosate is the most used pesticide around the world. Although different studies have evidenced its negative effect on honey bees, including detrimental impacts on behavior, cognitive, sensory and developmental abilities, its use continues to grow. Recent studies have shown that it also alters the composition of the honey bee gut microbiota. In this study we explored the impact of chronic exposure to sublethal doses of glyphosate on the honey bee gut microbiota and its effects on the immune response, infection by Nosema ceranae and Deformed wing virus (DWV) and honey bee survival. Glyphosate combined with N. ceranae infection altered the structure and composition of the honey bee gut microbiota, for example by decreasing the relative abundance of the core members Snodgrassella alvi and Lactobacillus apis. Glyphosate increased the expression of some immune genes, possibly representing a physiological response to mitigate its negative effects. However, this response was not sufficient to maintain honey bee health, as glyphosate promoted the replication of DWV and decreased the expression of vitellogenin, which were accompanied by a reduced life span. Infection by N. ceranae also alters honey bee immunity although no synergistic effect with glyphosate was observed. These results corroborate previous findings suggesting deleterious effects of widespread use of glyphosate on honey bee health, and they contribute to elucidate the physiological mechanisms underlying a global decline of pollination services.

Published

2021

15. Author response: Seminal fluid compromises visual perception in honeybee queens reducing their survival during additional mating flights

Author

Jacobus J. Boomsma, Mat Welch, Yuri Ogawa, Ryan Dosselli, Ian Castleden, Jan M. Hemmi, Boris Baer, Joanito Liberti, Morten Schiøtt, Barbara Baer-Imhoof, and Julia Görner

Subjects

Communication, Visual perception, business.industry, Mating, Biology, business

Published

2019

16. Gut microbiota structure differs between honey bees in winter and summer

Author

Lucie Kešnerová, Olivier Emery, Michaël Troilo, Joanito Liberti, Berra Erkosar, and Philipp Engel

Subjects

biology, fungi, Zoology, Gut flora, medicine.disease_cause, biology.organism_classification, digestive system, complex mixtures, Worker bee, Honey Bees, Bartonella apis, Lactobacillus, behavior and behavior mechanisms, medicine, Nectar

Abstract

Adult honey bees harbor a specialized gut microbiota of relatively low complexity. While seasonal differences in community composition have been reported, previous studies have focused on compositional changes rather than differences in absolute bacterial loads. Moreover, little is known about the gut microbiota of winter bees, which live much longer than bees during the foraging season, and which are critical for colony survival. We quantified seven core members of the bee gut microbiota in a single colony over two years and characterized the community composition in 14 colonies during summer and winter. Our data shows that total bacterial loads substantially differ between foragers, nurses, and winter bees. Long-lived winter bees had the highest bacterial loads and the lowest community α-diversity, with a characteristic shift towards high levels of Bartonella and Commensalibacter, and a reduction of opportunistic colonizers. Using gnotobiotic bee experiments, we show that diet is a major contributor to the observed differences in bacterial loads. Overall, our study reveals that the gut microbiota of winter bees is remarkably different from foragers and nurses. Considering the importance of winter bees for colony survival, future work should focus on the role of the gut microbiota in winter bee health and disease.

Published

2019

17. Seminal fluid compromises visual perception in honeybee queens reducing their survival during additional mating flights

Author

Ian Castleden, Julia Görner, Boris Baer, Morten Schiøtt, Barbara Baer-Imhoof, Joanito Liberti, Mat Welch, Jacobus J. Boomsma, Ryan Dosselli, Yuri Ogawa, and Jan M. Hemmi

Subjects

0106 biological sciences, 0301 basic medicine, Survival, Vision, medicine.medical_treatment, Arms race, 01 natural sciences, Sexual conflict, Sexual Behavior, Animal, Biological Factors, Mating, Biology (General), reproductive and urinary physiology, Ecology, General Neuroscience, artificial insemination, General Medicine, Bees, Flight, behavior and behavior mechanisms, Medicine, Apis mellifera, ecology, Sequence Analysis, Research Article, Offspring, QH301-705.5, Science, Sexual Behavior, education, RNA-sequencing, Zoology, Biology, Insemination, 010603 evolutionary biology, General Biochemistry, Genetics and Molecular Biology, 03 medical and health sciences, Semen, Ocular, medicine, Electroretinography, Animals, Vision, Ocular, neurotranscriptomics, Evolutionary Biology, social insects, General Immunology and Microbiology, Sequence Analysis, RNA, Animal, Artificial insemination, evolutionary biology, Deteriorating vision, 030104 developmental biology, sexual conflict, Flight, Animal, RNA, Other, Biochemistry and Cell Biology

Abstract

Queens of social insects make all mate-choice decisions on a single day, except in honeybees whose queens can conduct mating flights for several days even when already inseminated by a number of drones. Honeybees therefore appear to have a unique, evolutionarily derived form of sexual conflict: a queen’s decision to pursue risky additional mating flights is driven by later-life fitness gains from genetically more diverse worker-offspring but reduces paternity shares of the drones she already mated with. We used artificial insemination, RNA-sequencing and electroretinography to show that seminal fluid induces a decline in queen vision by perturbing the phototransduction pathway within 24–48 hr. Follow up field trials revealed that queens receiving seminal fluid flew two days earlier than sister queens inseminated with saline, and failed more often to return. These findings are consistent with seminal fluid components manipulating queen eyesight to reduce queen promiscuity across mating flights., eLife digest For social insects like honeybees it is beneficial if their queens mate with many males, because genetic diversity can protect the hive against parasites. Early in life, a honeybee queen has a short period of time in which she can fly out to mate with males before returning to the hive with all the sperm needed to last for a lifetime. Queens that have mated on their first flight may embark on additional mating flights over a few consecutive days to further increase genetic variability in their offspring. This is problematic for a male that has already mated because the more males that inseminate the queen the fewer offspring will carry on his specific genes. This results in sexual conflict between males and queens over the number of mating flights. In many animals, males manipulate females using molecules in seminal fluid to reduce the chances of the female mating again and honeybee males may use a similar strategy. Previous studies revealed that insemination alters the activity of genes related to vision in a honeybee queen’s brain. This could be one way for the males to prevent queens from embarking on additional mating flights. Now, Liberti et al. find support for this idea by showing that seminal fluid can indeed trigger changes in the activity of vision-related genes in the brains of honeybee queens, which in turn reduce a queen’s opportunity to complete additional mating flights. Queens inseminated with seminal fluid were less responsive to light compared to queens that were exposed to saline instead. Electronic tracking devices affixed to queens showed that the seminal fluid-exposed queens left for mating flights sooner but were more likely to get lost and to not return to their hives compared to the saline-exposed queens. The experiments support the idea of a sexual arms race in honeybees. Males use seminal fluid to cause rapid deteriorating vision in queens, thus reducing their likelihood of leaving the hive to mate again and to find males when they do fly again. The queens try to counteract these effects by leaving for mating flights sooner, thereby increasing offspring genetic diversity and the success of their colonies. Further studies will be needed to find out how the honeybee sexual arms race varies across seasons, bee races, and geographic ranges. Such information will be useful for honeybee breeding programs, which rely on queen mating success and hive genetic diversity to ensure hive health.

Published

2019

18. Rival seminal fluid induces enhanced sperm motility in a polyandrous ant

Author

Boris Baer, Jacobus J. Boomsma, and Joanito Liberti

Subjects

Male, 0106 biological sciences, 0301 basic medicine, endocrine system, Evolution, Sexual Behavior, media_common.quotation_subject, Motility, Semen, Social insects, Biology, Insemination, 010603 evolutionary biology, 01 natural sciences, Andrology, Sexual Behavior, Animal, 03 medical and health sciences, QH359-425, Genetics, Animals, Sexual conflicts, Mating, Sperm competition, reproductive and urinary physiology, Ecology, Evolution, Behavior and Systematics, Sperm motility, media_common, Evolutionary Biology, Animal, Ants, urogenital system, Contraception/Reproduction, Reproduction, Spermatozoa, Sperm, 030104 developmental biology, Sexual selection, Female, Research Article

Abstract

Background Promiscuous mating and sperm competition often induce arms races between the sexes with detrimental outcomes for females. However, ants with multiply-inseminated queens have only a single time-window for sperm competition and queens are predicted to gain control over the outcome of sperm storage quickly. The seminal fluid of Acromyrmex leaf-cutting ants reduces the viability of rival sperm, but how confrontations between unrelated ejaculates affect sperm storage remains unknown. Results We investigated the effects of ejaculate admixture on sperm motility in A. echinatior and found that the proportion of motile spermatozoa, sperm swimming speed, and linearity of sperm movement increased when rival ejaculates were mixed in vitro. Major effects induced by the seminal fluid of rival males were of similar magnitude to those generated by queen reproductive tract secretions, whereas own seminal fluid induced lower sperm activation levels. Conclusions Our results suggest that ant sperm respond via a self–non-self recognition mechanism to similar or shared molecules expressed in the reproductive secretions of both sexes. Lower sperm motility in the presence of own seminal fluid indicates that enhanced motility is costly and may trade-off with sperm viability during sperm storage, consistent with studies in vertebrates. Our results imply that ant spermatozoa have evolved to adjust their energetic expenditure during insemination depending on the perceived level of sperm competition. Electronic supplementary material The online version of this article (10.1186/s12862-018-1144-y) contains supplementary material, which is available to authorized users.

Published

2018

19. Additional file 1: of Rival seminal fluid induces enhanced sperm motility in a polyandrous ant

Author

Joanito Liberti, Baer, Boris, and Boomsma, Jacobus

Abstract

Tables S1-S9. Full legends are contained within the file. (DOCX 69 kb)

Published

2018

20. Bacterial symbiont sharing in M egalomyrmex social parasites and their fungus‐growing ant hosts

Author

Joanito Liberti, Rachelle M. M. Adams, Panagiotis Sapountzis, Lars Hestbjerg Hansen, Søren J. Sørensen, Jacobus J. Boomsma, Centre for Social Evolution (CSE), Department of Plant and Environmental Sciences [Copenhagen], Faculty of Science [Copenhagen], University of Copenhagen = Københavns Universitet (KU)-University of Copenhagen = Københavns Universitet (KU)-Faculty of Science [Copenhagen], University of Copenhagen = Københavns Universitet (KU)-University of Copenhagen = Københavns Universitet (KU)-Department of Biology [Copenhagen], and University of Copenhagen = Københavns Universitet (KU)-University of Copenhagen = Københavns Universitet (KU)

Subjects

DNA, Bacterial, Bartonellaceae, Genotype, Cyphomyrmex, Megalomyrmex symmetochus, Zoology, Ecological Interactions, 03 medical and health sciences, social parasites, Entomoplasmatales, Species Specificity, Nest, RNA, Ribosomal, 16S, Actinomycetales, Genetics, Animals, Megalomyrmex, 16S rRNA pyrosequencing, Symbiosis, Phylogeny, Ecology, Evolution, Behavior and Systematics, ComputingMilieux_MISCELLANEOUS, 030304 developmental biology, 0303 health sciences, Acinetobacter, biology, Ants, 030306 microbiology, Ecology, Host (biology), Microbiota, fungi, Fungi, food and beverages, Sequence Analysis, DNA, biochemical phenomena, metabolism, and nutrition, biology.organism_classification, symbiosis, Social parasites, Original Article, Wolbachia, ORIGINAL ARTICLES, [SDE.BE]Environmental Sciences/Biodiversity and Ecology, Trophallaxis

Abstract

Bacterial symbionts are important fitness determinants of insects. Some hosts have independently acquired taxonomically related microbes to meet similar challenges, but whether distantly related hosts that live in tight symbiosis can maintain similar microbial communities has not been investigated. Varying degrees of nest sharing between Megalomyrmex social parasites (Solenopsidini) and their fungus‐growing ant hosts (Attini) from the genera Cyphomyrmex, Trachymyrmex and Sericomyrmex allowed us to address this question, as both ant lineages rely on the same fungal diet, interact in varying intensities and are distantly related. We used tag‐encoded FLX 454 pyrosequencing and diagnostic PCR to map bacterial symbiont diversity across the Megalomyrmex phylogenetic tree, which also contains free‐living generalist predators. We show that social parasites and hosts share a subset of bacterial symbionts, primarily consisting of Entomoplasmatales, Bartonellaceae, Acinetobacter, Wolbachia and Pseudonocardia and that Entomoplasmatales and Bartonellaceae can co‐infect specifically associated combinations of hosts and social parasites with identical 16S rRNA genotypes. We reconstructed in more detail the population‐level infection dynamics for Entomoplasmatales and Bartonellaceae in Megalomyrmex symmetochus guest ants and their Sericomyrmex amabilis hosts. We further assessed the stability of the bacterial communities through a diet manipulation experiment and evaluated possible transmission modes in shared nests such as consumption of the same fungus garden food, eating of host brood by social parasites, trophallaxis and grooming interactions between the ants, or parallel acquisition from the same nest environment. Our results imply that cohabiting ant social parasites and hosts may obtain functional benefits from bacterial symbiont transfer even when they are not closely related.

Published

2015

21. Chemically armed mercenary ants protect fungus-farming societies

Author

Anders A. Illum, Jacobus J. Boomsma, David R. Nash, Joanito Liberti, Rachelle M. M. Adams, and Tappey H. Jones

Subjects

0106 biological sciences, Parasitism, macromolecular substances, 010603 evolutionary biology, 01 natural sciences, Host-Parasite Interactions, 03 medical and health sciences, Animals, Megalomyrmex, Symbiosis, Phylogeny, 030304 developmental biology, Mutualism (biology), 0303 health sciences, Volatile Organic Compounds, Multidisciplinary, biology, Ecology, business.industry, Ants, fungi, Caste, Sericomyrmex, Fungi, food and beverages, biochemical phenomena, metabolism, and nutrition, Ant colony, Biological Sciences, biology.organism_classification, 3. Good health, Agriculture, Predatory Behavior, behavior and behavior mechanisms, Solenopsidini, business

Abstract

The ants are extraordinary in having evolved many lineages that exploit closely related ant societies as social parasites, but social parasitism by distantly related ants is rare. Here we document the interaction dynamics among a Sericomyrmex fungus-growing ant host, a permanently associated parasitic guest ant of the genus Megalomyrmex, and a raiding agro-predator of the genus Gnamptogenys. We show experimentally that the guest ants protect their host colonies against agro-predator raids using alkaloid venom that is much more potent than the biting defenses of the host ants. Relatively few guest ants are sufficient to kill raiders that invariably exterminate host nests without a cohabiting guest ant colony. We also show that the odor of guest ants discourages raider scouts from recruiting nestmates to host colonies. Our results imply that Sericomyrmex fungus-growers obtain a net benefit from their costly guest ants behaving as a functional soldier caste to meet lethal threats from agro-predator raiders. The fundamentally different life histories of the agro-predators and guest ants appear to facilitate their coexistence in a negative frequency-dependent manner. Because a guest ant colony is committed for life to a single host colony, the guests would harm their own interests by not defending the host that they continue to exploit. This conditional mutualism is analogous to chronic sickle cell anemia enhancing the resistance to malaria and to episodes in human history when mercenary city defenders offered either net benefits or imposed net costs, depending on the level of threat from invading armies.

Published

2013

22. Queen reproductive tract secretions enhance sperm motility in ants

Author

Jacobus J. Boomsma, Boris Baer, and Joanito Liberti

Subjects

Male, 0106 biological sciences, 0301 basic medicine, endocrine system, cryptic female choice, Zoology, Reproductive health and childbirth, In Vitro Techniques, 010603 evolutionary biology, 01 natural sciences, sperm competition, 03 medical and health sciences, Animals, sexual selection, Genitalia, Mating, Sperm competition, reproductive and urinary physiology, Sperm motility, Evolutionary Biology, social insects, biology, Reproductive success, urogenital system, Ants, Ecology, Contraception/Reproduction, Genitalia, Female, Biological Sciences, Polyspermy, biology.organism_classification, Spermatozoa, Agricultural and Biological Sciences (miscellaneous), Sperm, 030104 developmental biology, Female sperm storage, Sperm Motility, Female, Acromyrmex echinatior, General Agricultural and Biological Sciences

Abstract

Queens of Acromyrmex leaf-cutting ants store sperm of multiple males after a single mating flight, and never remate even though they may live for decades and lay tens of thousands of eggs. Sperm of different males are initially transferred to the bursa copulatrix and compete for access to the long-term storage organ of queens, but the factors determining storage success or failure have never been studied. We used in vitro experiments to show that reproductive tract secretions of Acromyrmex echinatior queens increase sperm swimming performance by at least 50% without discriminating between sperm of brothers and unrelated males. Indiscriminate female-induced sperm chemokinesis makes the likelihood of storage directly dependent on initial sperm viability and thus provides a simple mechanism to secure maximal possible reproductive success of queens, provided that initial sperm motility is an accurate predictor of viability during later egg fertilization.

Published

2016

23. Differences in Forage-Acquisition and Fungal Enzyme Activity Contribute to Niche Segregation in Panamanian Leaf-Cutting Ants

Author

Joanito Liberti, Pepijn W. Kooij, Morten Schiøtt, Jacobus J. Boomsma, and Konstantinos Giampoudakis

Subjects

0106 biological sciences, Atta, lcsh:Medicine, Acromyrmex, Biochemistry, 01 natural sciences, Behavioral Ecology, Faculty of Science, lcsh:Science, Enzyme Chemistry, Phylogeny, Principal Component Analysis, 0303 health sciences, Multidisciplinary, Ecology, Animal Behavior, biology, food and beverages, Niche segregation, Enzymes, Community Ecology, Research Article, Panama, Foraging, Flowers, 010603 evolutionary biology, Niche Construction, foraging, Enzyme Regulation, 03 medical and health sciences, habitats, Animals, Herbivory, 030304 developmental biology, forests, Ecological niche, Evolutionary Biology, Herbivore, species diversity, Ants, lcsh:R, Ecology and Environmental Sciences, fungi, Fungi, Biology and Life Sciences, Species diversity, Interspecific competition, 15. Life on land, biology.organism_classification, Plant Leaves, Evolutionary Ecology, Enzymology, lcsh:Q, Zoology, Entomology

Abstract

The genera Atta and Acromyrmex are often grouped as leaf-cutting ants for pest management assessments and ecological surveys, although their mature colony sizes and foraging niches may differ substantially. Few studies have addressed such interspecific differences at the same site, which prompted us to conduct a comparative study across six sympatric leaf- cutting ant species in Central Panama. We show that foraging rates during the transition between dry and wet season differ about 60 fold between genera, but are relatively constant across species within genera. These differences appear to match overall differences in colony size, especially when Atta workers that return to their nests without leaves are assumed to carry liquid food. We confirm that Panamanian Atta specialize primarily on tree-leaves whereas Acromyrmex focus on collecting flowers and herbal leaves and that species within genera are similar in these overall foraging strategies. Species within genera tended to be spaced out over the three habitat categories that we distinguished (forest, forest edge, open grassland), but each of these habitats normally had only a single predominant Atta and Acromyrmex species. We measured activities of twelve fungus garden decomposition enzymes, belonging to the amylases, cellulases, hemicellulases, pectinases and proteinases, and show that average enzyme activity per unit of fungal mass in Atta gardens is lower than in Acromyrmex gardens. Expression profiles of fungal enzymes in Atta also appeared to be more specialized than in Acromyrmex, possibly reflecting variation in forage material. Our results suggest that species- and genus-level identities of leaf-cutting ants and habitat-specific foraging profiles may give predictable differences in the expression of fungal genes coding for decomposition enzymes.

Published

2014

24. The gut microbiota — brain axis of insects

Author

Philipp Engel and Joanito Liberti

Subjects

0106 biological sciences, 0301 basic medicine, Behavioral phenotypes, Insecta, Neurophysiology, Biology, Gut flora, Insect behavior, 010603 evolutionary biology, 01 natural sciences, digestive system, 03 medical and health sciences, Human health, Animals, Symbiosis, Ecology, Evolution, Behavior and Systematics, Behavior, Host Microbial Interactions, Mental Disorders, Gastrointestinal Microbiome, fungi, Brain, Honey bee, Bees, Integrated approach, biology.organism_classification, Disease Models, Animal, 030104 developmental biology, Evolutionary biology, Insect Science, Hypocreales, Drosophila, Wolbachia

Abstract

Research on the connections between gut microbes and the neurophysiology and behavior of their animal hosts has grown exponentially in just a few years. Most studies have focused on mammalian models as their relevance to human health is widely established. However, evidence is accumulating that insect behavior may be governed by molecular mechanisms that are partly homologous to those of mammals, and therefore relevant for the understanding of their behavioral dysfunctions. Social insects in particular may provide experimentally amenable models to disentangle the contributions of individual bacterial symbionts to the gut microbiota — brain axis. In this review, we summarize findings from recent research on the neurological and behavioral effects of the gut microbiota of insects and propose an integrated approach to unravel the extended behavioral phenotypes of gut microbes in the honey bee.

25. Mild chronic exposure to pesticides alters physiological markers of honey bee health without perturbing the core gut microbiota

Author

Hanine, Almasri, Joanito, Liberti, Jean-Luc, Brunet, Philipp, Engel, Luc P, Belzunces, Abeilles et Environnement (AE), Institut National de Recherche pour l’Agriculture, l’Alimentation et l’Environnement (INRAE), Université de Lausanne = University of Lausanne (UNIL), ANR-15-CE34-0004,MIXTRESS,Interactions entre les pathogènes et les mélanges de pesticides chez l'abeille(2015), and European Project

Subjects

Bacteria, [SDE.MCG]Environmental Sciences/Global Changes, Longevity, fungi, behavior and behavior mechanisms, Animals, food and beverages, Bees, Pesticides, Gastrointestinal Microbiome

Abstract

International audience; Recent studies highlighted that exposure to glyphosate can affect specific members of the core gut microbiota of honey bee workers. However, in this study, bees were exposed to relatively high glyphosate concentrations. Here, we chronically exposed newly emerged honey bees to imidacloprid, glyphosate and difenoconazole, individually and in a ternary mixture, at an environmental concentration of 0.1 µg/L. We studied the effects of these exposures on the establishment of the gut microbiota, the physiological status, the longevity, and food consumption of the host. The core bacterial species were not affected by the exposure to the three pesticides. Negative effects were observed but they were restricted to few transient non-core bacterial species. However, in the absence of the core microbiota, the pesticides induced physiological disruption by directly altering the detoxification system, the antioxidant defenses, and the metabolism of the host. Our study indicates that even mild exposure to pesticides can directly alter the physiological homeostasis of newly emerged honey bees and particularly if the individuals exhibit a dysbiosis (i.e. mostly lack the core microbiota). This highlights the importance of an early establishment of a healthy gut bacterial community to strengthen the natural defenses of the honey bee against xenobiotic stressors.

26. Extended methods and results from Queen reproductive tract secretions enhance sperm motility in ants

Author

Joanito Liberti, Baer, Boris, and Boomsma, Jacobus J.

Subjects

Quantitative Biology::Subcellular Processes, endocrine system, Physics::Biological Physics, urogenital system, Quantitative Biology::Tissues and Organs, reproductive and urinary physiology, Quantitative Biology::Cell Behavior, 3. Good health

Abstract

Additional information on the procedures employed to measure sperm motility parameters and extended statistical results.

27. Extended methods and results from Queen reproductive tract secretions enhance sperm motility in ants

Author

Joanito Liberti, Baer, Boris, and Boomsma, Jacobus J.

Subjects

Quantitative Biology::Subcellular Processes, endocrine system, Physics::Biological Physics, urogenital system, Quantitative Biology::Tissues and Organs, reproductive and urinary physiology, Quantitative Biology::Cell Behavior, 3. Good health

Abstract

Additional information on the procedures employed to measure sperm motility parameters and extended statistical results.