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1. Social dominance has limited effects on spatial cognition in a wild food-caching bird

   https://doi.org/10.1098/rspb.2021.1784  

   Heinen, Virginia K.; Benedict, Lauren M.; Pitera, Angela M.; Sonnenberg, Benjamin R.; Bridge, Eli S.; Pravosudov, Vladimir V. (November 2021, Proceedings of the Royal Society B: Biological Sciences)

   Social dominance has long been used as a model to investigate social stress. However, many studies using such comparisons have been performed in captive environments. These environments may produce unnaturally high antagonistic interactions, exaggerating the stress of social subordination and any associated adverse consequences. One such adverse effect concerns impaired cognitive ability, often thought to be associated with social subordination. Here, we tested whether social dominance rank is associated with differences in spatial learning and memory, and in reversal spatial learning (flexibility) abilities in wild food-caching mountain chickadees at different montane elevations. Higher dominance rank was associated with higher spatial cognitive flexibility in harsh environments at higher elevations, but not at lower, milder elevations. By contrast, there were no consistent differences in spatial learning and memory ability associated with dominance rank. Our results suggest that spatial learning and memory ability in specialized food-caching species is a stable trait resilient to social influences. Spatial cognitive flexibility, on the other hand, appears to be more sensitive to environmental influences, including social dominance. These findings contradict those from laboratory studies and suggest that it is critical to investigate the biological consequences of social dominance under natural conditions. 

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2. The importance of scale in comparative microbiome research: New insights from the gut and glands of captive and wild lemurs

   https://doi.org/10.1002/ajp.22974  

   Greene, Lydia K.; Bornbusch, Sally L.; McKenney, Erin A.; Harris, Rachel L.; Gorvetzian, Sarah R.; Yoder, Anne D.; Drea, Christine M. (April 2019, American Journal of Primatology)

   Abstract Research on animal microbiomes is increasingly aimed at determining the evolutionary and ecological factors that govern host–microbiome dynamics, which are invariably intertwined and potentially synergistic. We present three empirical studies related to this topic, each of which relies on the diversity of Malagasy lemurs (representing a total of 19 species) and the comparative approach applied across scales of analysis. In Study 1, we compare gut microbial membership across 14 species in the wild to test the relative importance of host phylogeny and feeding strategy in mediating microbiome structure. Whereas host phylogeny strongly predicted community composition, the same feeding strategies shared by distant relatives did not produce convergent microbial consortia, but rather shaped microbiomes in host lineage‐specific ways, particularly in folivores. In Study 2, we compare 14 species of wild and captive folivores, frugivores, and omnivores, to highlight the importance of captive populations for advancing gut microbiome research. We show that the perturbational effect of captivity is mediated by host feeding strategy and can be mitigated, in part, by modified animal management. In Study 3, we examine various scent‐gland microbiomes across three species in the wild or captivity and show them to vary by host species, sex, body site, and a proxy of social status. These rare data provide support for the bacterial fermentation hypothesis in olfactory signal production and implicate steroid hormones as mediators of microbial community structure. We conclude by discussing the role of scale in comparative microbial studies, the links between feeding strategy and host–microbiome coadaptation, the underappreciated benefits of captive populations for advancing conservation research, and the need to consider the entirety of an animal's microbiota. Ultimately, these studies will help move the field from exploratory to hypothesis‐driven research. 

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3. Investigating the perception of risks during arboreal locomotion in wild and captive primates

   Schapker, Nicole M; Myers, Lydia C; Janisch, Judith; Matar, Ahmad; Pham, Julie; Miller, Aidan; Boghdady, Abdelrahman; Shapiro, Liza J; Young, Jesse W (March 2025, American Journal of Biological Anthropology)

   Much research on primate locomotor performance in arboreal settings focuses on how primate morphology allows them to navigate substrates that vary in diameter, orientation, and compliance. However, little prior research has considered how these and other environmental factors - such as substrate height and light availability - may also affect locomotor behavior by altering how risky a given substrate is perceived to be. To investigate the relationship between risk perception and locomotor performance, we video-recorded four species of wild lemur (Ranomafana National Park), three species of wild cercopithecoid monkeys (Kibale National Park), and four species of captive lemur (Duke Lemur Center). We test the general hypothesis that primates should change their gaits and engage in exploratory behaviors – using touch and sight as guides – to increase stability in precarious settings. Augmenting our prior study showing that some lemurs change their locomotion when moving high in the canopy, we present new data showing that wild lemurs and monkeys frequently cross gaps between substrates and transition between locomotor modes without pause. In the investigation on captive lemurs, we examine whether variations in branch diameter, compliance, orientation, and light availability influence the paths lemurs choose to take. Preliminary results suggest that lemurs tend to avoid the most precarious substrates (i.e., the most narrow and compliant) regardless of lighting conditions. Overall, this research indicates that primates are able to make quick and accurate judgements about locomotor safety in the context of ongoing arboreal locomotion. 

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4. Effect of captivity on the vertebral bone microstructure of xenarthran mammals

   https://doi.org/10.1002/ar.24817  

   Zack, Ellianna H.; Smith, Stephanie M.; Angielczyk, Kenneth D. (November 2021, The Anatomical Record)

   null (Ed.)

   Captive specimens in museum collections facilitate study of rare taxa, but the lifestyles, diets, and lifespans of captive animals differ from their wild counterparts. Trabecular bone architecture adapts to in vivo forces, and may reflect interspecific variation in ecology and behavior as well as intraspecific variation between captive and wild specimens. We compared trunk vertebrae bone microstructure in captive and wild xenarthran mammals to test the effects of ecology and captivity. We collected μCT scans of the last six presacral vertebrae in 13 fossorial, terrestrial, and suspensorial xenarthran species (body mass: 120 g to 35 kg). For each vertebra, we measured centrum length; bone volume fraction (BV.TV); trabecular number and mean thickness (Tb.Th); global compactness (GC); cross-sectional area; mean intercept length; star length distribution; and connectivity and connectivity density. Wild specimens have more robust trabeculae, but this varies with species, ecology, and pathology. Wild specimens of fossorial taxa (Dasypus) have more robust trabeculae than captives, but there is no clear difference in bone microstructure between wild and captive specimens of suspensorial taxa (Bradypus, Choloepus), suggesting that locomotor ecology influences the degree to which captivity affects bone microstructure. Captive Tamandua and Myrmecophaga have higher BV.TV, Tb.Th, and GC than their wild counterparts due to captivity-caused bone pathologies. Our results add to the understanding of variation in mammalian bone microstructure, suggest caution when including captive specimens in bone microstructure research, and indicate the need to better replicate the habitats, diets, and behavior of animals in captivity. 

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5. Scraping Network Analysis: A Method to Explore Complex White-tailed Deer Mating Systems

   Hearst, Scoty; Streeter, Sharron; Justin Hannah, Justin; Taylor, George; Shepherd, Sylmia; Winn, Bryce; Mao, Jinghe (January 2021, Southeastern naturalist)

   Applegate, Roger (Ed.)

   Abstract - Odocoileus virginianus (White-tailed Deer) are social animals that thrive in rural and urban settings. Scraping behavior is an olfactory reproductive communication used by White-tailed Deer to establish breeding networks. Male scraping is a complex scent-marking behavior which advertises sociosexual status and location to potential females as well as to competing males. Female scraping behavior is thought to be an estrus signal alerting males during times of optimal fertility. This study describes a new method to examine White-tailed Deer mating systems using social network analyses of scraping behavior using an urban population of White-tailed Deer as a model. First, we validated the scraping behavior at our study site in Tougaloo, MS, during the 2019–2020 breeding season. Using remote monitoring, we continuously documented scraping behaviors over 8 different scrape-site locations and found similar behavioral, temporal, and spatial patterns in our urban breeding network as reported in rural and captive deer studies. Next, we describe methods detailing how social network analyses can reveal sociality, dominance, importance, and social structure within male scraping networks. Using centrality measures, we were able to rank dominant male influencers, anticipate social conflict among rivals, and made predictions regarding the spread of communicable diseases through a male scraping network. We also detail network analyses combining both male and female scraping behavior to reveal a glimpse into the complexity of breeding networks. Using network measures, we were able to rank males based on competitiveness and female preference. Lastly, we generated a theoretical breeding network to explore female sociability, competitiveness, preference, and mate choice. Taken together, this work describes a new method using scraping network analysis to investigate the complexity of White-tailed Deer breeding networks. This work also demonstrates the future applications of this method for predicting the spread of communicable diseases and for predicting mate selection within White-tailed Deer mating systems. 

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