Tag: evolution

A tale of two Joshuas…

DrAliceClement

Nope, I am not about to talk about figures from the Hebrew Bible (you’re certainly in the wrong place if that is what you’re after), but instead some fantastic student-led work that was published recently by two of my students.

Joshua Batt posing with a fossil rhizodont.
Joshua Bland CT scanning some fossil lungfish.

Firstly, Joshua Bland, who was an Honours student of mine at Flinders University during 2022-23, has published a paper in the mulitidisciplinary journal iScience with the title “Comparison of diverse mandibular mechanics during biting in Devonian lungfishes“.

He worked on fossil lungfishes from the Late Devonian Gogo Formation, of northern Western Australia, which are beautifully preserved in 3D. Gogo is an interesting site for lungfishes, as this ancient tropical reef preserves the most diverse assemblage of lungfish species in any space or time from throughout their 400 million year history.

Graphical abstract from Bland et al. (2025) https://www.sciencedirect.com/science/article/pii/S2589004225012313

The lungfish at Gogo are taxonomically diverse (many species), but also morphologically disparate (anatomically different from each other). We wondered how this may impact function, did their jaws work biomechanically differently from one another?

To answer this question, Josh used a technique adapted from engineering, called Finite Element Analysis (FEA). FEA is a computer-based method used to predict how structures respond to external forces by calculating the stress and strain within small, divided elements of the object. The first use of FEA in palaeontology was by Emily Rayfield and colleagues on the skull of a large theropod dinosaur in 2001, so its use remains quite recent for the field, and our study is the most comprehensive application to fossil fishes published thus far (yay!).

Generalised methods figure from Bland et al. (2025) showing stepwise
process to solve Finite Element Models of fossil lungfish mandibles (lower jaws) during biting.

Together with our co-authors, Hugo Dutel, John A. Long, Matteo Fabbri, Joseph Bevitt, and Kate Trinajstic, and our very own FEA guru, Olga Panagiotopoulou, we found a diversity of stress and strain experienced by our lower jaw models, with some surprising results. This diversity of jaw morphology and biomechanics seen among the lungfish at Gogo may have been one of the reasons driving their great success. Different lungfish were adapted for eating very different things and so weren’t in resource competition with each other.

Our comprehensive dataset offers the most detailed quantification of biting performance in any fossil fish thus far, providing biomechanical evidence for diverse feeding adaptations and niche partitioning within Gogo lungfishes.

And then to add to the excitement, another paper was published in the same week from another Joshua! This time it was current PhD student, Joshua Batt, publishing his first peer-reviewed paper in the Journal of Vertebrate Paleontology with “New rhizodontid (Tetrapodomorpha, Sarcopterygii) material from Romer’s gap (Tournaisian) of the Ballagan Formation (Scotland, UK).”

Working together with Dr Tom Challands, from the University of Edinburgh, researchers at Flinders University have been busy preparing and describing a real beast of a fish from the Early Carboniferous of the UK. The specimen was extracted by Tom and colleagues from Burnmouth in Scotland, but 10 or so large blocks of material came to Australia in 2020 for further study. Painstaking mechanical preparation has been done by Carey Burke and revealed what is likely to be one of, if not the most, complete articulated rhizodont fish known.

John Long, Carey Burke and Josh Batt inspect a specimen of fossil rhizodont at Flinders University.

Rhizodonts were large predatory lobe-finned fishes that lived throughout the Devonian and Carboniferous periods, usually in freshwater or estuarine environments. Some are thought to have grown as big as seven meters in length and they had very big teeth. Not a fish I would like to swim with!

Josh started working on this material for his Honours project during 2024, and there still remains a lot of it to be formally described, especially post-cranial material, but this first “rapid communication” paper presents the “main skull block”. Is this thing more beauty or beast… (perhaps beauty really is in the eye of the beholder?)

Image from Batt et al. (2025) JVP showing the dorsal view of NMS G.2025.10.1.1.

Needless to say, I felt very proud seeing two of my students have their first peer-reviewed publications come out. I expect more good things to come from both of them.

Want more? You can find both of these fantastic papers via the links below:

Science, SPring-8, and Sushi!

DrAliceClement

It seems I had such a “SPring” in my step, I completely forgot to write about my trip to Japan in November last year!

Thanks to a Flinders University International Research Engagement grant, I had the means to visit SPring-8 (the world’s largest third-generation synchrotron radiation facility) to work with my collaborator A/Prof. Tatsuya Hirasawa scanning embryos of the Australian lungfish, Neoceratodus forsteri.

The Japanese synchrotron, known as SPring-8, is nestled atop a mountain in Hyōgo Prefecture in the Kansai region of Japan. The nearest major cities are Osaka and Kobe. Sika deer amble through the grounds which are frequently shrouded in fog (they inspired me to write a haiku), and somewhat unusually for synchrotron facilities, there are paths to ride bicycles inside!

The team at SPring-8, Japan, after a successful experiment.

Sika deer through fog

SPring-8 autumnal mountain

Embryos revealed.

I was there working with Tatsuya Hirasawa and his team to image an ontogenetic (referring to the development of an organism throughout its lifespan) sequence of the Australian lungfish. I’ve previously worked on this animal to describe aspects of its brain (Clement et al. 2015) and muscle (Ziermann et al. 2017) anatomy (but see also Challands et al. 2020 where we discuss brains AND muscles in the same paper!)

Even though I had worked at the ANSTO Australian Synchrotron and ESRF in Grenoble before, I had never scanned tiny embryos of animals, and so learnt a lot about the preparation and parameters best suited to this kind of material. Other researchers working with us included Hiroki Higashiyama, as well as Toru Kawanishi and Kiiri Hama, respectively scanning either chicken embryos or bichir fish fins.

Left to right: Tatsuya Hirasawa, Masato Hoshino (beamline scientis), Toru Kawanishi, Hiroki Higashiyama, Kiiri Hama, and Alice Clement, using BL20B2 beamline at SPring-8, Japan.

Following on from our successful synchrotron experiment, I spent a week in Tokyo. I was honoured to give an Evolutionary Morphology seminar at the beautiful and historic campus of the University of Tokyo (those ginkgo leaves!) and visit Tatsuya Hirasawa’s lab. Tatsuya Hirasawa and his group analyse fossil specimens using synchrotron radiation, as well as developmental genetic analyses of living animals at the gene and cellular level to investigate “Evo-Devo” of vertebrates. To his group and other guests from various institutions in Tokyo, I presented research on “Digital Palaeontology of the Early Vertebrates” to a very engaged and interesting group.

Evolutionary Morphology seminar, University of Tokyo, Japan, November 2024.
Alice and Tatsuya at the University of Tokyo.

I also took the opportunity to travel nearby Tsukuba to visit A/Prof. Daichi Suzuki (University of Tsukuba), whom I had met recently at the ISELV meeting in Quebec. He investigates the evolutionary origin of the vertebrate brain and consciousness, which is absolutely fascinating! Whilst there I got to look at some cool lamprey scans he and his students are working on, and give a palaeontology seminar. Biiiiiiiiiiiiiig thanks to the amazing Chisako Sakata for the tour of the National Museum of Nature and Science Tsukuba Research Center!

Visiting the National Museum of Nature and Science Tsukuba Research Center with my family.
Paleomorphology Seminar, University of Tsukuba.

I had such a wonderful time in Japan, AND was lucky enough to get back briefly less than two months after this visit for the 4th International Coelacanth Symposium, also held in Tokyo. Two visits in close succession was a great reason to revive my old high school Japanese… (また日本に行きたい!) That being said, I can’t wait for the next trip!!!

4th International Coelacanth Symposium

DrAliceClement

Do you know what was the greatest zoological discovery of the 20th century? Many people would probably say that it was the discovery and identification of a living coelacanth fish (Latimeria), dragged up from the oceanic depths off the coast of Southern Africa. This discovery revived a lineage of fish that had been thought extinct for 70 million years!

Alice Clement with Latimeria chalumnae, at the JLB Smith Institute of Ichthyology in Makhanda (Grahamstown, South Africa)

I’ve written about coelacanths several times before: fossil ones, living ones, and even “living fossil” ones, but this month was the first time I attended a scientific symposium dedicated wholly to this enigmatic and enduring group of fishes.

I was fortunate enough to attend the 4th International Coelacanth Symposium, held at Josai University, in Tokyo, Japan. The meeting was co-organised with Aquamarine Fukushima Marine Science Museum and attracted speakers from 7 countries (somewhat remarkably spanning all 6 continents except Antarctica).

Coelacanth scientists at the 4th ICS. Back row, L-R: Frensly D. Hukom (Indonesia), Gaël Clément (France), Yoshitaka Yabumoto (Japan), Camila Cupello (Brazil), Paulo M. Brito (Brazil), Alexis Chappuis (France), Alice Clement (Australia), Shinya Miyata (Japan), Yuji Takakuwa (Japan), Shinya Yamauchi (Japan). Front row: Masamitsu Iwata (Japan), Kerry Sink (South Africa), Tatsuya Hirasawa (Japan), Augy Syahailatua (Indonesia).

The speakers were a diverse range of scientists who covered everything from ecology and conservation of living populations, anatomy, as well as the evolution and disparity of fossil forms, and much more. I spoke about our recently described new fossil coelacanth from Australia, Ngamugawi wirngarri, and rates of evolution in the group since their appearance in the fossil record ~410 million years ago.

Many thanks to the organising committee (Masamitsu Iwata, Yoshitaka Yabumoto, Paulo M. Brito, and Shinya Miyata) for such a fabulous meeting, and I am very much looking forward to the next one (2027 in Indonesia, perhaps?). We were very well looked after in Tokyo, and it will be an honour to collaborate with this fabulous group of researchers!

ありがとうございました!!!

Hello Harajicadectes (is that you grannie?)

DrAliceClement

Meet Harajicadectes, your 380 million year old great, great, great (etc) Grannie.

This fish, which was given the full name Harajicadectes zhumini, was described by myself and other colleagues, published this week in the Journal of Vertebrate Paleontology “A new stem-tetrapod fish from the Middle–Late Devonian of central Australia“.

This is a tetrapodomorph, or tetrapod-like fish, from ancient rock deposits in central Australia. This means this fish is more closely related to tetrapods (amphibians, reptiles & mammals), than it is to a salmon, for example. It bears important features suggesting it was capable of air-breathing, among other things.

Bits and pieces of this fish have been found since the 70s by Gavin Young (ANU) and Alex Ritchie (Australian Museum), among others. However it wasn’t until a Flinders University field trip (with colleagues from ANU & MAGNT) to the area in 2016 uncovered the first complete specimen of Harajicadectes. Finally, all the little bits and pieces could confidently assigned to a single species.

Dr Brian Choo led this paper and is the artist behind the beautiful life reconstruction of this extinct predatory fish from an ancient central Australian river. No doubt there are many more treasures lying in wait to be discovered in the rocks of outback Australia!

Harajicadectes zhumini (Choo et al. 2024). Artwork by Brian Choo.

If you would like to red more about this beastie, find our article published in The Conversation, “A 380-million-year old predatory fish from Central Australia is finally named after decades of digging.”

CAVEPS 2023

DrAliceClement

What is the collective noun for palaeontologists? An assemblage? A formation? A museum? Whatever it is, there was a big one last week in Melbourne/Naarm, Australia, for the 18th Conference on Australasian Vertebrate Evolution, Palaeontology & Systematics (CAVEPS 2023).

VAMP CHAMPS:
Alice Clement, Aaron Camens, & Jacob van Zoelen

Some >180 attendees from Australia, New Zealand and beyond gathered to share their research on all aspects of the evolution and palaeontology of vertebrate animals (animals with a backbone). It was a very exciting and promising indication of the future of palaeontology in our region with more than half of all attendees being students (who often gave the best presentations).

It was a busy week for me, giving a presentation in the “Synchrotron Imaging” workshop on Monday, presenting a poster (VAMP!) and giving one of the plenary lectures (alongside Tim Flannery & Kliti Grice).

Dr Alice Clement giving a plenary presentation.

A very important and insightful component was the session about why palaeontologists need to collaborate with First Nations people, facilitated by Jillian Garvey and Steve Salisbury. I was very pleased to see the beginnings of some (hopefully) meaningful change in our discipline and look forward to seeing how our approaches evolve in the years to come.

Attendees of the 18th CAVEPS, Melbourne/Naarm, 2023 (with Siderops for scale).

A big thank you to the organisers for a wonderful meeting, and I hope everyone is looking forward to the next one, to be held in Adelaide in 2025!