Researchers have provided new insights into how ancestral elephants developed their dextrous trunks.
The study, published today as an eLife Reviewed Preprint, combines multiple analyses to reconstruct feeding behaviours in the extinct longirostrine elephantiforms- elephant-like mammals characterised by elongated lower jaws and tusks. The work is described by the editors as fundamental to our understanding of how the elongated lower jaw and long trunks evolved in these animals during the Miocene epoch, around 11-20 million years ago. It provides compelling evidence for the diversity of these structures in longirostrine gomphotheres, and their likely evolutionary responses to global climatic changes.
The findings may also shed light on why modern day elephants are the only animals able to feed themselves using their trunks.
Longirostrine gomphotheres are part of the proboscidean family -- a group of mammals including elephants and known for their elongated and versatile trunks. Longirostrine gomphotheres are notable as they underwent a prolonged evolutionary phase characterised by an exceptionally elongated lower jaw, or mandible, which is not found in later proboscideans. It is thought that their elongated mandible and trunk may have co-evolved in this group, but this change among early to late proboscideans remains incompletely understood.
"During the Early to Middle Miocene, gomphotheres flourished across Northern China," says lead author Dr. Chunxiao Li, a postdoctoral researcher at the University of Chinese Academy of Sciences, Beijing, China. "Across species there was huge diversity in the structure of the long mandible. We sought to explain why proboscideans evolved the long mandible and why it subsequently regressed. We also wanted to explore the role of the trunk in these animals' feeding behaviours, and the environmental background for the co-evolution of their mandibles and trunks."
Li and colleagues used comparative functional and eco-morphological investigations, as well as a feeding preference analysis, to reconstruct the feeding behaviour of three major families of longirostrine gomphotheres: Amebelodontidae, Choerolophodontidae and Gomphotheriidae.
To construct the feeding behaviours and determine the relation between the mandible and trunk, the team examined the crania and lower jaws of the three groups, sourced from three different museums. The structure of the mandible and tusks differed across the three groups, indicating differences in feeding behaviours. The mandibles of Amebelodontidae were generally shovel-like and the tusks were flat and wide. Gomphotheriidae had clubbed lower tusks and a more narrow mandible, while Choerolophodontidae completely lacked mandibular tusks and their lower jaw was long and trough-like.
Next, the team conducted an analysis of the animals' enamel isotopes to determine the distribution and ecological niches of the three families. The results indicated that Choerolphontidae lived in a relatively closed environment, whereas Platybelodon, a member of the Amebelodontidae family, lived in a more open habitat, such as grasslands. Gomphotheriidae appeared to fill a niche somewhere in between these closed and open habitats.
A Finite Element analysis helped the team determine the advantages and disadvantages of the mandible and tusk structure between each group. Their data indicated that the Choerolophodontidae mandible was specialised for cutting horizontally or slanted-growing plants, which may explain the absence of mandibular tusks. The Gomphotheriidae mandible was found to be equally suited for cutting plants growing in all directions. Platybelodon had structures specialised for cutting vertically growing plants, such as soft-stemmed herbs, which would have been more common in open environments.
The three families also showed differences in their stages of trunk evolution, which could be inferred from the narial structure -- the region surrounding the nostrils. The narial region in Choerolophodontidae suggested that they had a relatively primitive, clumsy trunk. In Gomphotheriidae, the narial region was most similar to modern day elephants, suggesting they had a relatively flexible trunk. The trunks of Platybelodons may be the first example of a proboscidean trunk with the ability to coil and grasp. The evolutionary level of the trunk appeared to relate to the ability of the mandible to cut horizontally, strongly suggesting a co-evolution between the trunk and the mandible in longirostrine gomphotheres.
During the Mid-Miocene Climate Transition, which caused regional drying and the expansion of more open ecosystems, Choerolophodontidae experienced a sudden regional extinction and Gomphotheriidae numbers also declined in Northern China. The study suggests that the development of the coiling and grasping trunk in Platybelodon allowed this group to survive in greater numbers in their open environments. This may also explain why other animals with trunks, such as tapirs, never developed such dextrous trunks as elephants, as they never moved into open lands.
"Our cross-disciplinary team is dedicated to introducing multiple quantitative research methods to explore paleontology," says co-author Ji Zhang, associate professor of structural engineering at Huazhong University of Science and Technology, Wuhan, China. "Modern computational mechanics and statistics have injected new vitality into traditional fossil research."
The main limitation of this work is the lack of discussion comparing the team's results with the development of gigantism and long limbs in proboscideans from the same period, according to eLife's editors. The authors add that such analysis could add to our understanding of how changing feeding behaviours related to wider differences in the animals' body shapes and sizes during this time.
Read more at Science Daily
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