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1. Selection on heritable social network positions is context-dependent in Drosophila melanogaster

   https://doi.org/10.1038/s41467-021-23672-1  

   Wice, Eric Wesley; Saltz, Julia Barbara (June 2021, Nature Communications)

   Abstract Social group structure is highly variable and can be important for nearly every aspect of behavior and its fitness consequences. Group structure can be modeled using social network analysis, but we know little about the evolutionary factors shaping and maintaining variation in how individuals are embedded within their networks (i.e., network position). While network position is a pervasive target of selection, it remains unclear whether network position is heritable and can respond to selection. Furthermore, it is unclear how environmental factors interact with genotypic effects on network positions, or how environmental factors shape selection on heritable network structure. Here we show multiple measures of social network position are heritable, using replicate genotypes and replicate social groups ofDrosophila melanogasterflies. Our results indicate genotypic differences in network position are largely robust to changes in the environment flies experience, though some measures of network position do vary across environments. We also show selection on multiple network position metrics depends on the environmental context they are expressed in, laying the groundwork for better understanding how spatio-temporal variation in selection contributes to the evolution of variable social group structure. 

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2. Genetic Variation in Male Aggression Is Influenced by Genotype of Prior Social Partners in Drosophila melanogaster

   https://doi.org/10.1086/729463  

   Hutchins, Marina; Douglas, Tracy; Pollack, Lea; Saltz, Julia B. (March 2024, The American Naturalist)

   Social behaviors can be influenced by the genotypes of interacting individuals through indirect genetic effects (IGEs) and can also display developmental plasticity. We investigated how develop- mental IGEs, which describe the effects of a prior social partner’s geno- type on later behavior, can influence aggression in male Drosophila melanogaster. We predicted that developmental IGEs cannot be esti- mated by simply extending the effects of contextual IGEs over time and instead have their own unique effects on behavior. On day 1 of the ex- periment, we measured aggressive behavior in 15 genotypic pairings (n p 600 males). On day 2, each of the males was paired with a new opponent, and aggressive behavior was again measured. We found con- textual IGEs on day 1 of the experiment and developmental IGEs on day 2 of the experiment: the influence of the day 1 partner’s genotype on the focal individual’s day 2 behavior depended on the genotypic iden- tity of both the day 1 partner and the focal male. Importantly, the devel- opmental IGEs in our system produced fundamentally different dynam- ics than the contextual IGEs, as the presence of IGEs was altered over time. These findings represent some of the first empirical evidence dem- onstrating developmental IGEs, a first step toward incorporating de- velopmental IGEs into our understanding of behavioral evolution. 

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3. Cascading indirect genetic effects in a clonal vertebrate

   https://doi.org/10.1098/rspb.2022.0731  

   Makowicz, Amber M.; Bierbach, David; Richardson, Christian; Hughes, Kimberly A. (July 2022, Proceedings of the Royal Society B: Biological Sciences)

   Understanding how individual differences arise and how their effects propagate through groups are fundamental issues in biology. Individual differences can arise from indirect genetic effects (IGE): genetically based variation in the conspecifics with which an individual interacts. Using a clonal species, the Amazon molly ( Poecilia formosa ), we test the hypothesis that IGE can propagate to influence phenotypes of the individuals that do not experience them firsthand. We tested this by exposing genetically identical Amazon mollies to conspecific social partners of different clonal lineages, and then moving these focal individuals to new social groups in which they were the only member to have experienced the IGE. We found that genetically different social environments resulted in the focal animals experiencing different levels of aggression, and that these IGE carried over into new social groups to influence the behaviour of naive individuals. These data reveal that IGE can cascade beyond the individuals that experience them. Opportunity for cascading IGE is ubiquitous, especially in species with long-distance dispersal or fission–fusion group dynamics. Cascades could amplify (or mitigate) the effects of IGE on trait variation and on evolutionary trajectories. Expansion of the IGE framework to include cascading and other types of carry-over effects will therefore improve understanding of individual variation and social evolution and allow more accurate prediction of population response to changing environments. 

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4. Visual Influence Networks in Walking Crowds

   https://doi.org/10.1101/2025.01.29.635594  

   Yoshida, Kei; di_Bernardo, Mario; Warren, William H (January 2025, bioRxiv)

   Collective motion in human crowds has been understood as a self-organizing phenomenon that is generated from local visual interactions between neighboring pedestrians. To analyze these interactions, we introduce an approach that estimates local influences in observational data on moving human crowds and represents them as spatially-embedded dynamic networks (visual influence networks). We analyzed data from a human “swarm” experiment (N= 10, 16, 20) in which participants were instructed to walk about the tracking area while staying together as a group. We reconstructed the network every 0.5 seconds using Time-Dependent Delayed Correlation (TDDC). Using novel network measures of local and global leadership ('direct influence' and 'branching influence'), we find that both measures strongly depend on an individual’s spatial position within the group, yielding similar but distinctive leadership gradients from the front to the back. There was also a strong linear relationship between individual influence and front-back position in the crowd. The results reveal that influence is concentrated in specific positions in a crowd, a fact that could be exploited by individuals seeking to lead collective crowd motion. 

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5. Collective behavior emerges from genetically controlled simple behavioral motifs in zebrafish

   https://doi.org/10.1126/sciadv.abi7460  

   Harpaz, Roy; Aspiras, Ariel C.; Chambule, Sydney; Tseng, Sierra; Bind, Marie-Abèle; Engert, Florian; Fishman, Mark C.; Bahl, Armin (October 2021, Science Advances)

   It is not understood how changes in the genetic makeup of individuals alter the behavior of groups of animals. Here, we find that, even at early larval stages, zebrafish regulate their proximity and alignment with each other. Two simple visual responses, one that measures relative visual field occupancy and one that accounts for global visual motion, suffice to account for the group behavior that emerges. Mutations in genes known to affect social behavior in humans perturb these simple reflexes in individual larval zebrafish and change their emergent collective behaviors in the predicted fashion. Model simulations show that changes in these two responses in individual mutant animals predict well the distinctive collective patterns that emerge in a group. Hence, group behaviors reflect in part genetically defined primitive sensorimotor “motifs,” which are evident even in young larvae. 

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