Lifespan behavioural and neural resilience in a social insect

Giraldo, Ysabel Milton; Kamhi, J. Frances; Fourcassié, Vincent; Moreau, Mathieu; Robson, Simon K. A.; Rusakov, Adina; Wimberly, Lindsey; Diloreto, Alexandria; Kordek, Adrianna; Traniello, James F. A.

doi:10.1098/rspb.2015.2603

Cited by 25 publications

(32 citation statements)

References 76 publications

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“…It is notable that in our experimental study reducing the size of a minute brain by 25%, while causing significant changes in trail following ability, did not significantly compromise worker performance in other task assays, including our comprehensive assessment of the ability of workers to forage for and tend to larvae. Adult neurogenesis, which could compensate for neuron loss, is not thought to occur in adult hymenopterans [Fahrbach et al, 1995;Gronenberg et al, 1996;Cayre et al, 2002], but the brains of P. dentata workers nevertheless remain functionally robust following antennal lesioning as well as throughout much of the minor worker lifespan [Giraldo et al, 2016]. The maintenance of MB architecture, as we demonstrated, may allow workers to remain adept at task performance.…”

Section: Neural and Behavioral Robustness And Brain Modularitymentioning

confidence: 58%

“…It is of interest that this module is robust to injury, enabling social functions to be maintained following a substantial reduction in sensory input. Giraldo et al [2016] hypothesized that P. dentata worker brains allocate energy savings toward neuromolecular mechanisms that decrease apoptosis, increase brain monoamine levels, and thus prevent behavioral senescence. Our present finding of increased synapsin immunoreactivity after lesioning could be in part associated with accommodation in sensorimotor function.…”

Section: Neural and Behavioral Robustness And Brain Modularitymentioning

confidence: 99%

“…To quantify MG in worker MB, brains were processed as described by Giraldo et al [2016]. Brains were dissected in cold HEPES-buffered saline and fixed overnight in 4% paraformaldehyde.…”

Section: Measurements Of the Mb-c Mg Numbermentioning

confidence: 99%

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Behavioral Performance and Neural Systems Are Robust to Sensory Injury in Workers of the Ant Pheidole dentata

2017

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Miniaturized nervous systems have been thought to limit behavioral ability, and animals with miniaturized brains may be less flexible when challenged by injuries resulting in sensory deficits that impact the development, maintenance, and plasticity of small-scale neural networks. We experimentally examined how injuries to sensory structures critical for olfactory ability affect behavioral performance in workers of the ant Pheidole dentata, which have minute brains (0.01 mm³) and primarily rely on the perception and processing of chemical signals and cues to direct their social behavior. We employed unilateral antennal denervation to decrease the olfactory perception ability of workers and quantified consequential neuroanatomical and behavioral performance effects. Postablation neuroanatomical metrics revealed a 25% reduction in the volume of the antennal lobe ipsilateral to the antennal lesion relative to the contralateral lobe, indicating atrophy of the input-deprived tissue. However, antennectomy did not affect the volumes of the mushroom body or its subcompartments or the number of mushroom body synaptic complexes (microglomeruli) in either brain hemisphere. Synapsin immunoreactivity, however, was significantly higher in the ipsilateral mushroom body calyces, which could reflect presynaptic potentiation and homeostatic compensation in higher-order olfactory regions. Despite tissue loss caused by antennal lesioning and resulting unilateral sensory deprivation, the ability of workers to perform behaviors that encompass the breadth of their task repertoire and meet demands for colony labor remained largely intact. The few behavioral deficits recorded were restricted to pheromone trail-following ability, a result that was expected due to the need for bilateral olfactory input to process spatial odor information. Our macroscopic and cellular neuroanatomical measurements and assessments of task performance demonstrate that the miniaturized brains of P. dentata workers and their sensorimotor functions are remarkably robust to injury-related size reduction and remain capable of generating behaviors required to respond appropriately to chemical social signals and effectively nurse immatures, as well as participate in coordinated foraging.

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Section: Neural and Behavioral Robustness And Brain Modularitymentioning

confidence: 58%

Section: Neural and Behavioral Robustness And Brain Modularitymentioning

confidence: 99%

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Behavioral Performance and Neural Systems Are Robust to Sensory Injury in Workers of the Ant Pheidole dentata

2017

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“…or on tasks performed by foragers (Schmid-Hempel and Schmid-Hempel 1984; Burd 1996; Wolf 2008; Grüter et al 2011; Arnan et al 2011). Few studies have considered worker aging and long-term patterns of task performance across the worker lifespan in ants (Lenoir 1979; Mersch et al 2013; Giraldo and Traniello 2014; Giraldo et al 2016). Furthermore, the regulation of task performance involves mechanisms of neural organization that may vary with worker age (Muscedere et al 2011; Stieb et al 2012; Giraldo et al 2013) and be controlled by biogenic amines (Schulz and Robinson 2001; Seid and Traniello 2005; Jones et al 2009; Muscedere and Traniello 2012; Muscedere et al 2013, 2016; Kamhi and Traniello 2013; Smith et al 2013; Kamhi et al 2015).…”

Section: Introductionmentioning

confidence: 99%

Age, worksite location, neuromodulators, and task performance in the ant Pheidole dentata

Giraldo

Rusakov

Diloreto

et al. 2016

Behav Ecol Sociobiol

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Social insect workers modify task performance according to age-related schedules of behavioral development, and/or changing colony labor requirements based on flexible responses that may be independent of age. Using known-age minor workers of the ant Pheidole dentata throughout 68% of their 140-day laboratory lifespan, we asked whether workers found inside or outside the nest differed in task performance and if behaviors were correlated with and/or causally linked to changes in brain serotonin (5HT) and dopamine (DA). Our results suggest that task performance patterns of individually assayed minors collected at these two spatially different worksites were independent of age. Outside-nest minors displayed significantly higher levels of predatory behavior and greater activity than inside-nest minors, but these groups did not differ in brood care or phototaxis. We examined the relationship of 5HT and DA to these behaviors in known-age minors by quantifying individual brain titers. Both monoamines did not increase significantly from 20 to 95 days of age. DA did not appear to directly regulate worksite location, although titers were significantly higher in outside-nest than inside-nest workers. Pharmacological depletion of 5HT did not affect nursing, predation, phototaxis or activity. Our results suggest that worker task capabilities are independent of age beyond 20 days, and only predatory behavior can be consistently predicted by spatial location. This could reflect worker flexibility or variability in the behavior of individuals collected at each location, which could be influenced by complex interactions between age, worksite location, social interactions, neuromodulators, and other environmental and internal regulators of behavior.

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“…Moreover, a vast number of genetic techniques and tools are available that allow precise spatial and temporal control of genetic perturbations [38, 129]. Other invertebrate species, such as ants and bees, show promise for future studies in aging and cognition, but in the present review, the focus will be on more commonly used, genetically tractable organisms [4, 8, 36, 37, 66]. Though these features make invertebrate models attractive in the study of aging, there are some obvious caveats when working in such a simple system.…”

Section: Model Systems and Assays Of Cognitive Functionmentioning

confidence: 99%

Conserved regulators of cognitive aging: From worms to humans

Arey

Murphy

2017

Behavioural Brain Research

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Cognitive decline is a major deficit that arises with age in humans. While some research on the underlying causes of these problems can be done in humans, harnessing the strengths of small model systems, particularly those with well-studied longevity mutants, such as the nematode C. elegans, will accelerate progress. Here we review the approaches being used to study cognitive decline in model organisms and show how simple model systems allow the rapid discovery of conserved molecular mechanisms, which will eventually enable the development of therapeutics to slow cognitive aging.

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Lifespan behavioural and neural resilience in a social insect

Cited by 25 publications

References 76 publications

Behavioral Performance and Neural Systems Are Robust to Sensory Injury in Workers of the Ant Pheidole dentata

Behavioral Performance and Neural Systems Are Robust to Sensory Injury in Workers of the Ant Pheidole dentata

Age, worksite location, neuromodulators, and task performance in the ant Pheidole dentata

Conserved regulators of cognitive aging: From worms to humans

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