Published Apr 23 2021

Like a jackal in wolf’s clothing: The Tasmanian tiger was no wolfish predator

The thylacine (Thylacinus cynocephalus), commonly known as the Tasmanian tiger, is an Aussie icon. It was the largest historical marsupial predator, and a powerful example of human-caused extinction. And despite being extinct since 1936, it still gets featured in popular media.

But much is still unknown about the thylacine, as its extinction left us with almost no direct observational data. We do know it was a member of the canid family that includes dogs, wolves and foxes. But several mysteries remained regarding its specific ecology, including the question of whether it was more wolf-life or dog-like.

In a new study published in BMC Ecology and Evolution, my colleagues and I tackle this question. We show the thylacine was actually most similar to canids, which evolved to hunt small animals — not to the wolf (Canis lupus) or wild dog/dingo (Canis lupus dingo), which are large-prey specialists.


Read more: The Tasmanian tiger was hunted to extinction as a 'large predator' – but it was only half as heavy as we thought


Moulded by our environments

When European colonisers first saw the thylacine, they noted its wolf-like appearance and judged it based on that assumption – like the wolf, it would pose a threat to their livestock.

The thylacine and its canid comparatives: Thylacine photo by E.J.K. Baker and colourised by D.S. Rovinsky; wolf photo by Neil Herbert; dingo photo by Jarrod Amoore, Image: Author-provided

This superficially wolf-like appearance has been taken to mean the thylacine is a textbook example of convergent evolution – where two unrelated animals evolve similar traits in response to similar pressures. The similarities are so striking, it’s even sometimes called the “marsupial wolf”.

Although Eurhinosaurus (bottom) is a reptile and Eurhinodelphis (middle) is a mammal, both are strikingly convergent with the modern swordfish. Thus, we can infer a great deal about their ecology. Image: D.S. Rovinsky

Studying convergent evolution is a promising way for scientists to infer the behaviour and ecology of extinct animals that can’t be directly observed. Ecology is the study of how species interact with their physical surroundings. So, if an extinct animal shares a similar shape with one living today, we can assume they probably filled a similar ecological niche.

Since the thylacine’s ecology is uncertain, comparisons with comparable species are one of the only ways to understand it. And it’s wolf-like appearance at face value has led to the thylacine and its ecology being assumed similar to that of the grey wolf and its closest relatives, such as the dingo.

But what if that was wrong?

Getting into the right headspace

We decided to put this assumption of ecological similarity to the test. To do so we needed a wide range of ecologically meaningful animals to compare with the thylacine. After all, even though the thylacine was a marsupial (like a koala), it’s fair to say it wasn’t hanging out in trees munching on eucalyptus!

Using hand-held 3D scanners, we scanned hundreds of skulls from 56 different species of carnivorous mammals, with specimens obtained from more than a dozen museums around the world. This enabled us to build a skull “shapespace” to then see where the thylacine would fit among the others.

A broad selection of ecologically-meaningful species, shown on this wheel-shaped evolutionary tree, were selected to compare to the thylacine. Image: D.S. Rovinsky

We looked for evidence of convergent evolution by observing which of the other carnivorous mammals’ skulls were shaped most like the thylacine’s.

A case of mistaken identity

It turns out the skull shape of the thylacine is significantly convergent with that of some canids, but not with the usual suspects. We found no meaningful level of convergence with either the grey wolf or the dingo, and only a small degree with the red fox.

What we did find, however, was strong support for convergent evolution between the skulls of the thylacine and another rag-tag group of canids – African jackals and South American “foxes” (which aren’t actually foxes). Ecologically, these canids are vastly different from the wolf and dingo. Also, unlike the wolf, they specialise in hunting small prey.

The wolf skull on the left is more different (shown by colour) to the thylacine skull than the skull in the middle, which is the average skull shape of the significantly convergent canids. White areas are more similar to the thylacine skull, while blue and red respectively show constriction or expansion. The difference is especially strong in the facial area, where the biting happens! Image: D.S. Rovinsky

This brings us back to one of the more powerful uses of studying convergent evolution – the ability to infer the ecology of an extinct animal. Since the thylacine’s skull shape was more similar to that of the African jackals and South American “foxes” than the wolf, it likely shared a similar ecological niche with the former.

The canids most like the thylacine are all small-prey hunters with relatively delicate faces – not robust big-biters like the wolf or dingo. Image: D.S. Rovinsky

Therefore, the thylacine probably also preferred hunting relatively small prey such as pademelons, bettongs, bandicoots and young wallabies.

Interestingly, however, one of the most striking findings was that the thylacine did not actually overlap with any of the other predators, canid or otherwise. While it was similar to some canids, it wasn’t identical. This highlights that even our more precise analysis may paint the thylacine with too broad a brush.

Judged by appearance

The thylacine was hunted to extinction for its wolf-like appearance. This reaction, like most based on first glance, was devastatingly wrong. Although the thylacine turns out to not be very wolf-like, it’s still a wonderful example of convergent evolution.


Read more: Why did the Tasmanian tiger go extinct?


Then again, it truly was different enough from other carnivorous mammals that we still can’t say we precisely understand its ecological niche. When we lost the thylacine, we lost something truly unique for its time.

Our understanding of the thylacine is, even now, that of a faded and blurry snapshot. Perhaps, with more research in the coming years, we can make it a little more clear.

This article originally appeared on The Conversation.

About the Authors

  • Douglass rovinsky

    PhD Candidate, Monash University

    Douglass’ PhD, the evolutionary context and functional ecology of the thylacine, brings together his interests in living and extinct animals. He received a BSc in Biology at Grand Valley State University, MI, USA and does research as a palaeontologist in ancient cave sites in South Africa, including the famous Drimolen site in the UNESCO Cradle of Humankind, South Africa - a site recovering an amazing assortment of extinct and living animals (including three species of human ancestor).

  • Alistair evans

    Associate Professor (Research), School of Biological Sciences

    Alistair is a Senior Research Fellow and ARC Future Fellow. His research areas of interest include functional morphology, particularly of mammalian teeth, 3D imaging and analysis, morphological evolution, evolution and development (evo-devo), body mass evolution and evolutionary rates.

  • Justin adams

    Senior Lecturer, Anatomy and Developmental Biology, BDI

    Justin has led fieldwork and faunal analysis at sites in and around the Cradle of Humankind UNESCO World Heritage Site. His ongoing research projects and collaborations address outstanding questions on the palaeobiology of Pliocene and early Pleistocene South African mammalian faunas and the taphonomy and palaeoecology of palaeocave sites. His Integrated Morphology and Palaeontology lab brings together comparative methods and advanced 3D imaging resources to the study of living and fossil mammal anatomy.

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