An international team of scientists, led by Egyptian researchers, has made a groundbreaking discovery of a new species of extinct whale, Tutcetus rayanensis, that inhabited the ancient sea covering present-day Egypt around 41 million years ago. This new whale is the smallest basilosaurid whale known to date and one of the oldest records of that family from Africa. Despite its tiny size, Tutcetus has provided unprecedented insights into the life history, phylogeny, and paleobiogeography of early whales.
Basilosauridae, a group of extinct fully aquatic whales, represents a crucial stage in whale evolution, as they transitioned from land to sea. They developed fish-like characteristics, such as a streamlined body, a strong tail, flippers, and a tail fin, and had the last hind limbs visible enough to be recognized as “legs”, which were not used for walking but possibly for mating.
The newly discovered Tutcetus rayanensis was found in the middle Eocene rocks and unambiguously, it helps to illuminate the picture of early whale evolution in Africa. The new whale’s name draws inspiration from both Egyptian history and the location where the specimen was found. The genus name, Tutcetus, combines "Tut" – referring to the famous Egyptian Pharaoh Tutankhamun – and "cetus," Greek for whale, highlighting the specimen's small size and subadult status. The name also commemorates the discovery of the king's tomb a century ago and coincides with the impending opening of the Grand Egyptian Museum in Giza. The species name, rayanensis, refers to the Wadi El-Rayan Protected Area in Fayum where the holotype was found.
Hesham Sallam, a Professor of Vertebrate Paleontology at the American University in Cairo, founder of Mansoura University Vertebrate Paleontology Center, and the leader of the project, commented that "Whales’ evolution from land-dwelling animals to beautiful marine creatures embodies the marvelous adventurous journey of life." He continued, “Tutcetus is a remarkable discovery that documents one of the first phases of the transition to a fully aquatic lifestyle that took place in that journey."
The holotype specimen consists of a skull, jaws, hyoid bone, and the atlas vertebra of a small-sized subadult basilosaurid whale which is embedded in an intensively compacted limestone block. With an estimated length of 2.5 meters and a body mass of approximately 187 kilograms, Tutcetus is the smallest known basilosaurid to date.
The team's findings have been published in Communications Biology, and the lead author, Mohammed Antar, from the Mansoura University Vertebrate Paleontology Center, and the National Focal Point for Natural Heritage stated, "Tutcetus significantly broadens the size range of basilosaurid whales and reveals considerable disparity among whales during the middle Eocene period." Antar added, “The investigation of the older layers in Fayum layers may reveal the existence of an older assemblage of early whale fossils, potentially influencing our current knowledge of the emergence and dispersal of whales."
Sanaa El-Sayed, a Ph.D. student at University of Michigan, a member of the Sallam Lab, and a co-author of the study stated, “The relatively small size of Tutcetus (188 kg) is either primitive retention or could be linked to the global warming event known as the 'Late Lutetian Thermal Maximum (LLTM).' El-Sayed further commented, “This groundbreaking discovery sheds light on the early evolution of whales and their transition to aquatic life."
Through detailed analyses of Tutcetus's teeth and bones, using CT scanning, the team was able to reconstruct the growth and development pattern of this species, providing an unparalleled understanding of the life history of early whales. The rapid dental development and small size of Tutcetus suggest a precocial lifestyle with a fast pace of life history for early whales. Additionally, the discovery of Tutcetus contributes to the understanding of the basilosaurids' early success in the aquatic environment, their capacity to outcompete amphibious stem whales, and their ability to opportunistically adapt to new niches after severing their ties to the land. The team's findings suggest that this transition likely occurred in the (sub)tropics.
Abdullah Gohar, a Ph.D. student at Mansoura University, a member of Sallam Lab, and a co-author of the study stated that “Modern whales migrate to warmer, shallow waters for breeding and reproduction, mirroring the conditions found in Egypt 41 million years ago. This supports the idea that what is known as now Fayum was a crucial breeding area for ancient whales, possibly attracting them from various locations and, in turn, drawing in larger predatory whales like Basilosaurus."
The team's findings have significant paleobiogeographic implications, demonstrating that basilosaurids likely achieved a rapid spread over the Southern Hemisphere, reaching high latitudes by the middle Eocene. Erik Seiffert, Chair and Professor of Integrative Anatomical Sciences at the University of Southern California and a co-author of the study, remarked, "The Eocene fossil sites of Egypt’s Western Desert have long been the world’s most important for understanding the early evolution of whales and their transition to a fully aquatic existence." adding, “The discovery of Tutcetus demonstrates that this region still has so much more to tell us about the fascinating story of whale evolution."