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1. House sparrows ( Passer domesticus ) adjusted hypothalamic‐pituitary‐adrenal axis negative feedback and perch hopping activities in response to a single repeated stimulus

   https://doi.org/10.1002/jez.2229  

   Gormally, Brenna M. G.; Romero, L. Michael (September 2018, Journal of Experimental Zoology Part A: Ecological and Integrative Physiology)

   Abstract Chronic stress has been extensively studied in both laboratory and field settings; however, a conclusive and consistent phenotype has not been reached. Several studies have reported attenuation of the hypothalamic–pituitary–adrenal axis during experiments intended to cause chronic stress. We sought to determine whether this attenuation could be indicative of habituation. Importantly, we were not investigating habituation to a specific stimulus—as many stress physiology studies do—but rather we assessed how the underlying physiology and behavior changed in response to repeated stressor presentation. We exposed house sparrows (Passer domesticus) to a single stimulus twice per day at random times for 8 consecutive days. We predicted that this period of time would be long enough for the birds to determine that these acute stressors were not, in fact, dangerous and they would, therefore, acclimate. A second control group remained undisturbed for the same period of time. We measured baseline, stress‐induced, negative feedback strength, and maximum production of corticosterone as well as neophobic behavior before, during, and after this 8‐day experiment. When birds experienced a stimulus for 4 days, their negative feedback strength was significantly diminished, but recovered after the second 4 days. Additionally, perch hopping decreased and recovered in this same time frame. These data suggest that distinct physiological and behavioral responses arise when house sparrows are exposed to the same stressor for several consecutive days as opposed to many stressors layered on top of one another. Furthermore, they indicate that habituation—as with chronic stress—can appear differently depending on the metric being examined. 

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2. Continuous, long-term crawling behavior characterized by a robotic transport system

   https://doi.org/10.7554/eLife.86585  

   Yu, James; Dancausse, Stephanie; Paz, Maria; Faderin, Tolu; Gaviria, Melissa; Shomar, Joseph W; Zucker, Dave; Venkatachalam, Vivek; Klein, Mason (August 2023, eLife)

   Detailed descriptions of behavior provide critical insight into the structure and function of nervous systems. InDrosophilalarvae and many other systems, short behavioral experiments have been successful in characterizing rapid responses to a range of stimuli at the population level. However, the lack of long-term continuous observation makes it difficult to dissect comprehensive behavioral dynamics of individual animals and how behavior (and therefore the nervous system) develops over time. To allow for long-term continuous observations in individual fly larvae, we have engineered a robotic instrument that automatically tracks and transports larvae throughout an arena. The flexibility and reliability of its design enables controlled stimulus delivery and continuous measurement over developmental time scales, yielding an unprecedented level of detailed locomotion data. We utilize the new system’s capabilities to perform continuous observation of exploratory search behavior over a duration of 6 hr with and without a thermal gradient present, and in a single larva for over 30 hr. Long-term free-roaming behavior and analogous short-term experiments show similar dynamics that take place at the beginning of each experiment. Finally, characterization of larval thermotaxis in individuals reveals a bimodal distribution in navigation efficiency, identifying distinct phenotypes that are obfuscated when only analyzing population averages. 

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3. Chronic stress reverses enhanced neophobia following an acute stressor in European starlings

   https://doi.org/10.1002/jez.2431  

   de Bruijn, Robert; Romero, L. Michael (November 2020, Journal of Experimental Zoology Part A: Ecological and Integrative Physiology)

   Abstract Neophobia is an animal's avoidance of novelty. Animals tend to respond to novel objects by increasing their latency to approach the objects, and they eventually habituate after repeated exposure by attenuating this increased approach latency. Interestingly, the physiological stress response does not appear to have a causal link to neophobia, although acute stress can prevent animals from habituating to novel objects, possibly through a permissive effect. Chronic stress can induce an anxiety‐like state in animals, while often disrupting the ability to respond to acute stress. We thus hypothesized that chronic stress may increase neophobia and tested this by inducing chronic stress in wild‐caught European starlings (Sturnus vulgaris). Four distinct anthropogenic stressors were administered daily for 30 min each in a randomized order for 21 days. We then evaluated whether exposure to chronic stress altered the latency to approach a novel object placed on or near a food dish presented after overnight fasting. Chronically stressed birds and nonstressed controls exhibited similar initial neophobic responses to novel objects and showed similar habituation in response to repeated exposure. However, when birds were exposed to 15 min of restraint before repeated exposure to the same object, habituation was eliminated in control birds (i.e., they continued to respond with neophobia), whereas chronically stressed birds continued to show habituation as measured by attenuated approach latencies. These results demonstrate that an acute stress response (restraint) has a different impact on neophobia depending upon whether the bird is or is not concurrently exposed to chronic stress. 

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4. Prior restraint stress inhibits habituation to novel objects in the European starlings ( Sturnus vulgaris )

   https://doi.org/10.1002/jez.2327  

   de Bruijn, Robert; Romero, L. Michael (October 2019, Journal of Experimental Zoology Part A: Ecological and Integrative Physiology)

   Abstract Animals often avoid novel objects, a behavior known as neophobia. We examined behavioral responses of captive European starlings to novel objects placed at their food dishes. Exposure occurred concurrently to food reintroduction following overnight fasting. Behavior was analyzed for 10 min via video recording. We expected an increase in avoidance behavior compared with trials in which food was reintroduced without a novel object. Seven of 10 novel objects increased latency to approach the dish. In contrast to our expectations, neither prior restraint nor exogenous corticosterone changed the neophobic response to novel objects. While exposure to a novel object increased approach latency, there was no additional effect of restraining animals in a cloth bag for 15 min before food reintroduction. Furthermore, the subcutaneous injection of corticosterone did not affect approach latency by itself, nor did it affect the response to a novel object. Finally, we expected repeated exposure to the same object to extinguishing the neophobic response, and that restraint stress would prevent habituation. Our results show that European starlings habituate rapidly to exposure to a novel object, as approach latency returned to baseline within three repeated exposures to the same object. When the repeated presentation of the object was combined with prior restraint, however, the latency to approach never returned to baseline. These results reveal that neophobia in starlings is object‐specific and that, while neither acute stress nor corticosterone directly affects the behavioral response to a novel object, acute stress appears to have a permissive effect on neophobia by inhibiting habituation. 

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5. The AMsh glia of C. elegans modulates the duration of touch-induced escape responses

   https://doi.org/10.1101/2023.12.13.571291  

   Awe, Temitope; Akinosho, Aalimah; Niha, Shifat; Kelly, Laura; Adams, Jessica; Stein, Wolfgang; Vidal-Gadea, Andrés (December 2023, bioRxiv)

   Abstract Once considered mere structural support cells in the nervous system, glia have recently been demonstrated to play pivotal roles in sensorimotor processing and to directly respond to sensory stimuli. However, their response properties and contributions to sensory-induced behaviors remain little understood. InCaenorhabditis elegans, the amphid sheath glia (AMsh) directly respond to aversive odorants and mechanical stimuli, but their precise transduction machinery and their behavioral relevance remain unclear. We investigated the role of AMsh in mechanosensation and their impact on escape behaviors inC. elegans. We found that nose touch stimuli in immobilized animals induced a slow calcium wave in AMsh, which coincided with the termination of escape reversal behaviors. Genetic ablation of AMsh resulted in prolonged reversal durations in response to nose touch, but not to harsh anterior touch, highlighting the specificity of AMsh’s role in distinct escape behaviors. Mechanotransduction in AMsh requires the α-tubulin MEC-12 and the ion channels ITR-1 and OSM-9, indicating a unique mechanosensory pathway that is distinct from the neighboring ASH neurons. We find that GABAergic signaling mediated by the GABA-A receptor orthologs LGC-37/8 and UNC-49 play a crucial role in modulating the duration of nose touch-induced reversals. We conclude that in addition to aversive odorant detection, AMsh mediate mechanosensation, play a pivotal role in terminating escape responses to nose touch, and provide a mechanism to maintain high sensitivity to polymodal sensory stimuli. SignificancePolymodal nociceptive sensory neurons have the challenge of multitasking across sensory modalities. They must respond to dangerous stimuli of one modality, but also adapt to repeated nonthreatening stimuli without compromising sensitivity to harmful stimuli from different modalities. Here we show that a pair of glia in the nematodeC. elegansmodulate the duration of nose-touch induced escape responses. We identify several molecules involved in the transduction of mechanical stimuli in these cells and show that they use the signaling molecule GABA to modulate neural function. We propose a mechanism through which these glia might function to maintain this polysensory neuron responsive to dangerous stimuli across different modalities. 

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