Wasp Waist and Flight: Convergent Evolution in Wasps Reveals a Link between Wings and Body Shapes

Species morphospace boundary revisited through wing phenotypic variations of Antodynerus species (Hymenoptera: Vespidae: Eumeninae) from the Indian subcontinent

The main objective of this study was to investigate the taxonomic significance of wing phenotypic variations (size and shape) for classifying potter wasps. This is the first study investigating the wing size and shape variations, as well as wing asymmetry, sexual dimorphism, wing integration, and phylogenetic signal analysis of all known Antodynerus species from the Indian subcontinent: A. flavescens, A. limbatus, and A. punctatipennis. We used forewings and hindwings for geometric morphometric analysis, and we proved that each species’ wing had unique size and shape variations, as well as significant right–left wing asymmetry and sexual dimorphism across the Antodynerus species, as verified by discriminant function analysis. Wings of Vespidae are longitudinally folded; based on that, we tested two alternative wing modular hypotheses for evaluating the wing integration, using two subsets organization, such as anterior–posterior (AP) and proximal-distal (PD) wing modular organization. We proved that Antodynerus species wings are highly integrated units (RV > 0.5), and we rejected our hypothesis at p < 0.05. The morphospace distribution analysis revealed that each species has its unique morphospace boundary, although they share some level of homoplasy, which suggests to us that we can use wing morphometric traits for Antodynerus species delimitation. In addition, we revealed the phylogenetic signal of Antodynerus species. Surprisingly, we found a shape-related phylogenetic signal in the forewing, and there is no significant (p > 0.05) phylogenetic signal in forewing size, hindwing shape, and size. We observed that the Antodynerus species’ forewing shape is evolutionarily more highly constrained than the hindwing. We found that A. limbatus and A. flavescens with distinct geographical distribution share a similar evolutionary history, while A. punctatipennis evolved independently.

The evolution of head size hypoallometry: Biomechanical implications and brain investment as a possible cause

Species' mean relative head size decreases with increasing species mean body size in paper wasps, which may have important implications for biomechanics in these flying animals. Here we quantify the allometric relationship (log/log slope) of head size to body size in paper wasps. We sampled species in two genera (Agelaia and Polybia) to test whether head/body allometry was consistent among genera. Head mass/total mass relationships were significantly hypoallometric (log/log slopes ∼0.90) and statistically similar between Agelaia and Polybia. We reanalyzed previously published multi-genus data to calculate the slope of head/body allometry, and to compare two different aspects of head size: the allometry of head mass which could impact weight distribution along the longitudinal axis of the body, and the allometry of head volume which could impact fluid resistance and mobility. The multi-genus data set yielded a similar estimate for the slope of head mass allometry (∼0.90), but the slope of head volume allometry was significantly shallower (∼0.80): relative head volume increases faster than relative head mass as total size decreases. We suggest the demands of brain housing affect the greater investment in head size and head weight in smaller species. Relative brain size is greater for smaller-bodied species within clades (Haller's rule), and brain volume had a significantly lower allometric slope than both head mass and head volume. Relatively large brains may require increased relative head size in smaller-bodied species. Brain housing may represent a basic developmental constraint on head size and head weight, and brain allometry could consequently impact the relationships of body shape and body mass distribution to body size.

The genetic basis of a novel reproductive strategy in Sulawesi ricefishes: How modularity and a low number of loci shape pelvic brooding

The evolution of complex phenotypes like reproductive strategies is challenging to understand, as they often depend on multiple adaptations that only jointly result in a specific functionality. Sulawesi ricefishes (Adrianichthyidae) evolved a reproductive strategy termed as pelvic brooding. In contrast to the more common transfer brooding, female pelvic brooders carry an egg bundle connected to their body for weeks until the fry hatches. To examine the genetic architecture of pelvic brooding, we crossed the pelvic brooding Oryzias eversi and the transfer brooding Oryzias nigrimas (species divergence time: ∼3.6 my). We hypothesize, that a low number of loci and modularity have facilitated the rapid evolution of pelvic brooding. Traits associated to pelvic brooding, like rib length, pelvic fin length, and morphology of the genital papilla, were correlated in the parental species but correlations were reduced or lost in their F1 and F2 hybrids. Using the Castle-Wright estimator, we found that generally few loci underlie the studied traits. Further, both parental species showed modularity in their body plans. In conclusion, morphological traits related to pelvic brooding were based on a few loci and the mid-body region likely could evolve independently from the remaining body parts. Both factors presumably facilitated the evolution of pelvic brooding.