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    Watch: Jumping ants duel with antennae after the queen dies

    "Despite prolonged social upheaval in ant colonies following the loss of the queen, the winners of these dueling tournaments are rapidly determined," says Claude Desplan. (Credit: IOC Young Reporters/Flickr)

    Changes in behavior and gene expression show which worker will come out on top in the first days of a month-long battle between worker ants to establish new leadership after their queen dies, researchers report.

    “Despite prolonged social upheaval in ant colonies following the loss of the queen, the winners of these dueling tournaments are rapidly determined,” says Claude Desplan, a professor of biology at New York University.

    “Our findings may provide clues on adaptability in reproduction and aging, given that the workers who win the duel, or ‘pseudoqueens,’ gain the ability to lay eggs and live much longer than the average worker ant. This suggests that changes in the environment are able to dramatically affect the structure of a society.”

    The caste system in social insects creates a division of labor, with insects specialized to perform particular tasks. The queen is responsible for reproduction, while workers maintain the colony—caring for the young, foraging and hunting for food, cleaning, and defending the nest.

    In many insect societies, when the queen dies, the entire colony dies along with her due to the lack of reproduction. However, in Indian jumping ants (Harpegnathos saltator), “caste switching” occurs after the queen’s death. While the queen is alive, she secretes pheromones that prevent female worker ants from laying eggs, but when she dies, the workers sense the lack of pheromones and begin fighting each other to take on the top role.

    The ants engage in dueling tournaments, striking each other with their antennae in matches that can last more than a month. While most ants quickly return to their usual work during the tournament, the winners become pseudoqueens—also known as gamergates—and acquire new behaviors and roles. Through this transition, their life expectancy dramatically increases (from seven months to four years) and they begin laying eggs, allowing the colony to survive.

    In their study, the researchers explored changes in the Indian jumping ants’ social behavior and accompanying changes in gene expression during the early stages of the worker-to-pseudoqueen transition.

    They found that, as early as after three days of dueling, the winners can be accurately predicted solely based on the dueling behavior. The workers who triumphed and became pseudoqueens had much higher levels of dueling—sparring roughly twice as much in the first five days—while the others who remained workers dueled less and went back to performing other tasks such as cleaning and hunting.

    “Despite the fact that dueling tournaments last for several weeks, we were able to anticipate which ants would become pseudoqueens in only three days,” says Comzit Opachaloemphan, a doctoral student in the Department of Biochemistry and Molecular Pharmacology at NYU Grossman School of Medicine and one of the study’s lead authors.

    Comparing biological samples and gene expression from dueling versus non-dueling ants, the researchers then determined the changes associated with the worker-to-pseudoqueen transition. Molecular analyses revealed that the brain may be driving the dueling and early caste determination in the ants, with other tissues taking cues from the brain.

    The researchers found that the first genes to respond to the loss of the queen were in the brain, suggesting that the lack of queen pheromones perceived by the olfactory system affects brain neurohormonal factors. These changes in the brain then lead to altered social behavior and hormone-mediated physiological changes in other parts of the body, including the ovaries.

    “Both behavioral and molecular data—especially changes in gene expression in the brain—show us that new pseudoqueens are quickly determined after a colony’s social structure has been disrupted by the loss of the queen,” says study author Danny Reinberg, a professor in the biochemistry and molecular pharmacology department at the Grossman School of Medicine, as well as an investigator for the Howard Hughes Medical Institute.

    The research appears in the journal Genes & Development.

    Support for the research came from a Howard Hughes Medical Institute Collaborative Innovation Award, the National Institutes of Health, EMBO, and the Human Frontier Science Program.

    Source: New York University

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    Infected ‘zombie ants’ shuffle through colony undetected

    Carpenter ants don’t attack or isolate their nest mates infected with a specialized parasitic fungus, and instead continue to share the colony’s food resources until the infected ants leave the nest for the last time to die, according to a new study.

    The findings suggest that, although the fungus is deadly to infected individuals, it is only a chronic condition for the colony—one that does not induce the kind of strong defensive measures thought to be common in social insect societies, the researchers say.

    A dead ant manipulated by a species of so-called “zombie ant fungus” clings to a twig in a South Carolina forest. (Credit: Hughs Lab/Penn State)

    Studies have shown that fungal pathogens from the genus Ophiocordyceps—known as “zombie ant fungus”—control the behavior of carpenter ant workers, compelling them to climb vegetation and bite the veins or margins on the underside of leaves. The infected ants die, remaining attached to the vegetation postmortem. There, the fungus grows and releases spores onto the forest floor below, where they can infect other foraging ants.

    Social security

    “Previous work suggested that insect societies protect the colony through social immunity,” says lead author Emilia Solá Gracia, postdoctoral scholar in biology at Penn State. “It was thought that during social interaction, ant workers detect infections in their peers and display aggression toward them or remove them from the nest.

    “…the parasite is able to fly under the radar of the colony’s defenses.”

    “This fungus, which coevolved with its host, takes 14 to 21 days to develop in infected individuals before compelling them to leave the nest and perform their last act. The question is, during this development, does the pathogen change how infected ants interact with others or alter the chemical cues they emit, which allows nest mates to detect the infection? Such detection would be optimal for the colony since infected workers die near foraging trails where the fungus releases spores that infect other members of the colony.”

    To test the hypothesis that healthy colony members recognize infected individuals, the research team looked at whether nest mates attack infected ant workers, whether they spend more or less time in trophallaxis—socially exchanging food, and whether they are spatially separated from other colony members inside the nest.

    The researchers collected ants from forested areas in South Carolina and established three colonies in a laboratory, each colony consisting of three groups of worker ants. Researchers left one of the three groups untreated—healthy, injected the second with a growth medium containing the parasitic fungus, and gave a third the growth medium alone. The ants were marked with unique dot patterns on their head, thorax, and gaster so individuals could be followed over time.

    They affixed a modified GoPro camera fitted with both an infrared lens and a macro lens on top of the colonies to capture recorded video virtually 24 hours daily.

    Dodging colony defenses

    While observing the 1,240 hours of video footage, the researchers, who report their findings in PLOS ONE, saw no attacks toward individuals injected with the fungus and found no significant difference in food sharing between infected and uninfected individuals.

    The team did find that infected individuals spent considerably more time inside near the nest entrance and spent more time outside the nest than healthy workers.

    “It could be that spending more time outside the nest is an early signal of fungal manipulation, which ultimately requires its host to leave the nest for fungal reproduction to occur,” Solá Gracia says. “But the most significant finding is that this coevolved parasite doesn’t seem to directly affect social dynamics within the colony.”

    Mysterious ‘lazy’ ants have jobs after all

    Taken together, these results suggest healthy individuals do not detect the parasite inside their nest mates, according to senior author David Hughes, associate professor of entomology and biology.

    “The colony’s inability to detect infected individuals allows the fungus to develop within the colony, while receiving food and protection from natural enemies that could damage or kill its ant host before the parasite has completed its development,” he says.

    “Based on our observations and the biology of the fungus, we suggest that the pathogen is a chronic parasite of the colony that is able to survive without triggering strong behavioral defenses in the society—in short, the parasite is able to fly under the radar of the colony’s defenses.”

    Other researchers on the project are from Penn State and the University of Central Florida. The National Science Foundation supported this work.

    Source: Penn State