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1. A comparison of cannabinoid receptor 1-immunoreactive axon density in the amygdala among nine primate species

   Jones, DN (January 2022, Abstracts Society for Neuroscience)

   The amygdala is a sensory integration center that plays an important role in emotional learning, behavior, and motivation. Cannabinoid signaling in the amygdala modulates aspects of anxiety, aggression, and fear in rodents via cannabinoid receptor 1, however little is known about cannabinoid signaling in the amygdala of humans and nonhuman primates. Primates are behaviorally diverse, with closely related species often displaying distinct social styles characterized by varying degrees of social tolerance and agonistic tendencies. Such behavioral differences are thought to be associated with neurochemical differences among species. Given what is known about the functional role of cannabinoid signaling in the amygdala, we tested whether relatively tolerant species, such as humans, bonobos, and marmosets, possess relatively higher cannabinoid receptor 1-immunoreactive (CB1R-ir) axon density in the basolateral amygdala. We used immunohistochemistry and stereological methods to compare CB1R-ir axon density among 47 primates representing nine species: humans (n=5), chimpanzees (n=6), bonobos (n=2), baboons (n=6), rhesus macaques (n=5), Japanese macaques (n=6), pigtail macaques (n=6), marmosets (n=5), and capuchins (n=6). The basolateral amygdala is comprised of the lateral, basal, and accessory basal nuclei. Stereological data for each nucleus was collected separately. After ruling out sex differences within each species, we used repeated measures ANOVA to evaluate species differences. The interaction (F16,76 = 5.061, p<.001) and main effects of species (F8,38 = 8.007, p<.001) and area (F2,76 = 59.616, p<.001) were all significant. However, the observedspecies differences did not support our hypothesis related to social tolerance nor did the data conform to a phylogenetic pattern. Instead, we found that while some closely related species differed from each other in a nucleus-dependent manner, some distantly related species shared unexpected similarities. Our results highlight the need for additional comparative work on the cannabinoid system from a molecular and genetic perspective. We discuss the implications of our observations with special focus on primate brain evolution and its connection to primate social style. 

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2. A comparison of cell density and serotonergic innervation of the amygdala among four macaque species

   https://doi.org/10.1002/cne.25048  

   Jones, Danielle N.; Erwin, Joseph M.; Sherwood, Chet C.; Hof, Patrick R.; Raghanti, Mary Ann (October 2020, Journal of Comparative Neurology)

   Abstract The genusMacacais an ideal model for investigating the biological basis of primate social behavior from an evolutionary perspective. A significant amount of behavioral diversity has been reported among the macaque species, but little is known about the neural substrates that support this variation. The present study compared neural cell density and serotonergic innervation of the amygdala among four macaque species using histological and immunohistochemical methods. The species examined included rhesus (Macaca mulatta), Japanese (M. fuscata), pigtailed (M. nemestrina), and moor macaques (M. maura). We anticipated that the more aggressive rhesus and Japanese macaques would have lower serotonergic innervation within the amygdala compared to the more affiliative pigtailed and moor macaques. In contrast to our prediction, pigtailed macaques had higher serotonergic innervation than Japanese and moor macaques in the basal and central amygdala nuclei when controlling for neuron density. Our analysis of neural cell populations revealed that Japanese macaques possess significantly higher neuron and glia densities relative to the other three species, however we observed no glia‐to‐neuron ratio differences among species. The results of this study revealed serotonergic innervation and cell density differences among closely related macaque species, which may play a role in modulating subtle differences in emotional processing and species‐typical social styles. 

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3. Tolerant and despotic macaques show divergent temperament but similar theory of mind

   https://doi.org/10.1098/rstb.2024.0121  

   Schwob, Natalie; Bettle, Rosemary; Mulhinch, Megan; Machanda, Zarin P; Rosati, Alexandra G (June 2025, Philosophical Transactions of the Royal Society B: Biological Sciences)

   The social intelligence hypothesis proposes that the demands of social life shape the evolution of cognition, but different aspects of social interactions may be relevant. To test how competitive versus cooperative interactions shape social cognition, we assessed multiple metrics of social cognition in Barbary macaques (Macaca sylvanus,n= 40) and rhesus macaques (Macaca mulatta,n= 60). These closely related species have similar social organization, but diverge in social styles: Barbary macaques are more tolerant, whereas rhesus macaques are more despotic. Monkeys completed a battery of experimental tasks measuringgaze-following(co-orienting with others),knowledge attribution(representing others’ underlying knowledge states),goal attribution(interpreting others’ actions in terms of underlying intentional goals) andtemperament(boldness in response to exploring novelty). While the rhesus macaques were more willing to approach a novel object than were Barbary macaques, both species showed similar success in each social task. However, individual Barbary macaques were more likely to show greater overall proficiency across all social measures combined than were individual rhesus monkeys. Overall, these results indicate that similar social cognitive capacities may evolve in distinct social contexts, and suggest socio-cognitive skills may be relevant for both competitive and cooperative interactions in primates. This article is part of the Theo Murphy meeting issue ‘Selection shapes diverse animal minds’. 

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4. Comparative analysis reveals distinctive epigenetic features of the human cerebellum

   https://doi.org/10.1371/journal.pgen.1009506  

   Guevara, Elaine E.; Hopkins, William D.; Hof, Patrick R.; Ely, John J.; Bradley, Brenda J.; Sherwood, Chet C. (May 2021, PLOS Genetics)

   Gojobori, Takashi (Ed.)

   Identifying the molecular underpinnings of the neural specializations that underlie human cognitive and behavioral traits has long been of considerable interest. Much research on human-specific changes in gene expression and epigenetic marks has focused on the prefrontal cortex, a brain structure distinguished by its role in executive functions. The cerebellum shows expansion in great apes and is gaining increasing attention for its role in motor skills and cognitive processing, including language. However, relatively few molecular studies of the cerebellum in a comparative evolutionary context have been conducted. Here, we identify human-specific methylation in the lateral cerebellum relative to the dorsolateral prefrontal cortex, in a comparative study with chimpanzees ( Pan troglodytes ) and rhesus macaques ( Macaca mulatta ). Specifically, we profiled genome-wide methylation levels in the three species for each of the two brain structures and identified human-specific differentially methylated genomic regions unique to each structure. We further identified which differentially methylated regions (DMRs) overlap likely regulatory elements and determined whether associated genes show corresponding species differences in gene expression. We found greater human-specific methylation in the cerebellum than the dorsolateral prefrontal cortex, with differentially methylated regions overlapping genes involved in several conditions or processes relevant to human neurobiology, including synaptic plasticity, lipid metabolism, neuroinflammation and neurodegeneration, and neurodevelopment, including developmental disorders. Moreover, our results show some overlap with those of previous studies focused on the neocortex, indicating that such results may be common to multiple brain structures. These findings further our understanding of the cerebellum in human brain evolution. 

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5. Planum Temporale Asymmetries in Primates: A Comparative Study in Great Apes and Monkeys

   https://doi.org/10.1002/ajpa.25060  

   Achorn, Angela_M; Mulholland, Michele_M; Cox, Chelsea_M; Phillips, Kimberley_A; Bennett, Allyson_J; Pierre, Peter_J; Sherwood, Chet_C; Schapiro, Steven_J; Hopkins, William_D (January 2025, American Journal of Biological Anthropology)

   ABSTRACT ObjectivesMost human brains exhibit left hemisphere asymmetry for planum temporale (PT) surface area and gray matter volume, which is interpreted as cerebral lateralization for language. Once considered a uniquely human feature, PT asymmetries have now been documented in chimpanzees and olive baboons. The goal of the current study was to further investigate the evolution of PT asymmetries in nonhuman primates. Materials and MethodsWe measured PT surface area in chimpanzees (Pan troglodytes,n = 90), bonobos (Pan paniscus,n = 21), gorillas (Gorilla gorilla,n = 34), orangutans (Pongospp.,n = 33), olive baboons (Papio anubis,n = 105), rhesus macaques (Macaca mulatta,n = 144), and tufted capuchins (Sapajus apella,n = 29) from magnetic resonance imaging scans. ResultsOur findings reveal significant leftward biases in PT surface area among chimpanzees, gorillas, olive baboons, rhesus macaques, and capuchins. We did not find significant population‐level asymmetries among orangutans and bonobos, which could be due, in part, to small sample sizes. We also detected significant age effects for rhesus macaques only, and no significant sex effects for any species. DiscussionThe observation of a population‐level leftward bias for PT surface area among not only hominids (chimpanzees and gorillas), but also two cercopithecoids (olive baboons and rhesus macaques) and one platyrrhine (tufted capuchins) suggests that PT lateralization was likely present in some early anthropoid primate ancestors and relatives. This provides further evidence that human brains have since undergone changes to the size and connectivity of the PT in response to selection for the cognitive processes needed to support the evolution of language and speech. 

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