Telemetered electromyography of peroneus longus in Varecia variegata and Eulemur rubriventer: implications for the functional significance of a large peroneal process

A foot specialized for grasping small branches with a divergent opposable hallux (hallucal grasping) represents a key adaptive complex characterizing almost all arboreal non-human euprimates. Evolution of such grasping extremities probably allowed members of a lineage leading to the common ancestor of modern primates to access resources available in a small-branch niche, including angiosperm products and insects. A better understanding of the mechanisms by which euprimates use their feet to grasp will help clarify the functional significance of morphological differences between the euprimate grasp complex and features representing specialized grasping in other distantly related groups (e.g., marsupials and carnivorans) and in closely related fossil taxa (e.g., plesiadapiforms). In particular, among specialized graspers euprimates are uniquely characterized by a large peroneal process on the base of the first metatarsal, but the functional significance of this trait is poorly understood. We tested the hypothesis that the large size of the peroneal process corresponds to the pull of the attaching peroneus longus muscle recruited to adduct the hallux during grasping. Using telemetered electromyography on three individuals of Varecia variegata and two of Eulemur rubriventer, we found that peroneus longus does not generally exhibit activity consistent with an important function in hallucal grasping. Instead, extrinsic digital flexor muscles and, sometimes, the intrinsic adductor hallucis are active in ways that indicate a function in grasping with the hallux. Peroneus longus helps evert the foot and resists its inversion. We conclude that the large peroneal tuberosity that characterizes the hallucal metatarsal of prosimian euprimates does not correlate to "powerful" grasping with a divergent hallux in general, and cannot specifically be strongly linked to vertical clinging and climbing on small-diameter supports. Thus, the functional significance of this hallmark, euprimate feature remains to be determined.     

Relationships between the expression of the stapedial artery and the size of the obturator foramen in euarchontans: Functional and phylogenetic implications

Cranial arterial patterns are commonly used for determining phylogenetic patterns in extant taxa and have often been used in studies investigating the relationships among fossil taxa. In primitive eutherians, the stapedial artery provided blood to the meninges, orbits, and certain regions of the face. In many modern mammals, however, blood supply to most of these areas has been taken over by branches of the external carotid, although some groups (e.g., treeshrews, some families of primates) still retain aspects of the ancestral pattern. Here, we show that the relative size of the obturator foramen of the stapes is a reliable indicator of the presence or absence of a “functional” stapedial artery in Euarchonta. We also describe newly discovered stapedes for extinct euarchontans, Ignacius graybullianus, and Plesiadapis tricuspidens, and use the approach described here to show that these taxa likely did not have a functional stapedial artery. The implications of these findings for auditory function and phylogenetic studies are discussed.