Similar but Different: Dynamic Social Network Analysis Highlights Fundamental Differences between the Fission-Fusion Societies of Two Equid Species,the Onager and Grevy’s Zebra

Understanding why animal societies take on the form that they do has benefited from insights gained by applying social network analysis to patterns of individual associations. Such analyses typically aggregate data over long time periods even though most selective forces that shape sociality have strong temporal elements. By explicitly incorporating the temporal signal in social interaction data we re-examine the network dynamics of the social systems of the evolutionarily closely-related Grevy’s zebras and wild asses that show broadly similar social organizations. By identifying dynamic communities, previously hidden differences emerge: Grevy’s zebras show more modularity than wild asses and in wild asses most communities consist of solitary individuals; and in Grevy’s zebras, lactating females show a greater propensity to switch communities than non-lactating females and males. Both patterns were missed by static network analyses and in general, adding a temporal dimension provides insights into differences associated with the size and persistence of communities as well as the frequency and synchrony of their formation. Dynamic network analysis provides insights into the functional significance of these social differences and highlights the way dynamic community analysis can be applied to other species.     

Infestation by a Common Parasite is Correlated with Ant Symbiont Identity in a Plant‐Ant Mutualism

In East Africa, up to four symbiotic ant species associate with the obligate myrmecophyte Acacia drepanolobium. These ant species differ in the extent to which they defend their host trees from both vertebrate and invertebrate herbivores, but other potential roles of ants in tree defense have not been studied. We investigate the distribution of a new species of parasitic midge targeting A. drepanolobium in a region where A. drepanolobium is inhabited almost exclusively by two ant species—Crematogaster nigriceps and C. mimosae. We find that the frequency of infestation correlates strongly with the identity of the ant occupant: trees inhabited by C. nigriceps are significantly less likely to be infested with parasitic midges. Although the two ant species responded similarly to simulated large herbivore disturbances, trees inhabited by C. nigriceps also had a lower invertebrate load than trees inhabited by C. mimosae. We suggest that differences in defensive behavior towards invertebrates could be one explanation of the observed differences in infestation of A. drepanolobium by parasitic midges.