Bryozoans from the Early Cambrian Cambrian Xiannüdong Formation of Shaanxi Province, China.

Molecular clock studies have suggested that the Phylum Bryozoa, or Moss Animals, first appeared in the Early Cambrian, which is consistent with the appearance of nearly all other Animal phyla at this time. However, for a long time the earliest known fossil Bryozoans came from the Early Ordovician, at which point six of the eight known orders of Bryozoans appear abruptly. Several putative Cambrian Bryozoan fossils, such as Pywackia, Archaeotrypa, and Marcusodictyon, were described, but none of these was universally accepted as a Bryozoan. In 2021 a more plausible Brozoan, Protomelission gatehousei, was described from the Early Cambrian of Australia and South China. In this it was possible to identify several Brozoan traits, including monomorphic zooid capsules, modular construction, organic composition, and a simple linear budding growth geometry, leading to the conclusion that this was probably a stem-group Bryozoan.

Protomelission gatehousei from the Cambrian Wirrealpa Limestone, South Australia. (a)–(g) Holotype, SADME 10470. (a) Front side of the colony showing the seven series of zooids. Top box corners indicate the area shown in (f); bottom box corners show the broken-off part in (c). (b) The top broken part of (a). (c) The lower broken part of (a). (d) Oblique lateral view of the bilaminate colony. (e) Enlarged view of (d) showing the staggered budding pattern and the curved basal walls of the two back-to-back layers (arrows and tailed arrows) in the bifoliate colony. (f) Quincuncial arrangement of sub-hexagonal zooids with broken frontal walls. (g) Lateral view of uncovered zooids; note the minute spoon-shaped structure (arrow) at the proximal end of basal wall extending backwards underneath the distal part of the parent zooid. (h), (i) SADME 10470-2. (h) Lateral view of a broken colony, showing the largely broken frontal walls (tailed arrows) and basal walls of opposite layer (arrows). (i) Enlarged view of three adjacent zooids. Note the dome shape of the distal part of frontal wall (tailed arrows), and almost circular orifice of zooid. Abbreviations: B, basal wall; F, frontal wall. Zhang et al. (2021).

However, while Protomelission gatehousei shows enough Bryozoan-like features that most palaeontologists have accepted it to be at least a stem group Bryozoan, the specimens used to describe the species lacked the definitive Bryozoan soft-tissue anatomy and diagnostic skeletal microstructure which would be necessary for complete conformation, leaving the identity of these fossils open to challenge.

In a paper published in the journal Nature on 3 June 2026, Baopeng Song (宋宝鹏) and Zhifei Zhang (张志飞) of the Department of Geology at Northwest University, Luke Strotz, also of the Department of Geology at Northwest University and also of the Department of Earth Sciences at Utrecht University, Timothy Topper, again of the Department of Geology at Northwest University, and of the Department of Palaeobiology at the Swedish Museum of Natural History, Andrej Ernst of the Institut für Geologie at Universität Hamburg, Zhiliang Zhang of the Department of Geology at Northwest University, and the Institut für Geologie at Universität Hamburg, Mei Luo (罗梅), again of the Department of Geology at Northwest University, Lars Holmer, again of the Department of Geology at Northwest University, and of the Department of Earth Sciences at Uppsala University, Yue Liang (梁悦), Yazhou Hu (胡亚洲), Caibin Zhang (张彩彬), and Yanlong Chen (陈延龙), all of the Department of Geology at Northwest University, and Glenn Brock, once again of the Department of Geology at Northwest University, and of the School of Natural Sciences at Macquarie University, describe new specimens of Protomelission gatehousei from the Early Cambrian Xiannüdong Formation of southern Shaanxi Province, China, as well as a second new species of Bryozoan from the same formation.

Notably, these fossils preserve soft-tissue features in exceptional fidelity, including internal moulds of membranous sacs in the zooid chambers, which allow the unequivocal placement of these taxa within the Phylum Bryozoa. The presence of two separate Bryozoan taxa within these Early Cambrian deposits pushes the origin of the group still earlier, confirming that this group appeared during the Cambrian explosion.

Specimen of Protomelission gatehousei from the Xiannüdong Formation in which the membranous sacs are preserved (ELI DYCX 8-001). (a) Front side of the colony. The outlined area is magnified in (h). (b) Back side of the colony. The outlined area is magnified in (j). (c) Lateral view of the bifoliate colony. (d) Oblique lateral view of the bifoliate colony showing the hollow arched mesotheca (arrow). (e) Partial enlargement of (c) showing the staggered budding pattern. (f), (g) X-ray tomographic microscopy images showing the longitudinal section of the colony and the orifice of autozooids (arrowheads) (f, oblique lateral view; (g) lateral view). (h) Quincuncial arrangement of sub-hexagonal membranous sacs with elliptical orifice. Note the 10-μm gap present between adjacent membranous sacs, indicating the loss of skeletal walls during the taphonomic processes. The outlined area is the membranous sac magnified in (i). (i) Enlarged view of a membranous sac showing the orifice (asterisk), circular fibres (arrow) and longitudinal fibres (arrowhead). These features suggest muscle preservation in the membranous sac. (j) Enlarged view of a zooid. Note that the aperture is coated with secondary phosphate. (k) Enlarged view of a zooid. Note that the secondary phosphate coating of the aperture is partially stripped away. (l), (m) Enlarged view of the membranous sac showing the longitudinal fibres in (l) arrowhead, and circular fibres in (m), arrow. These features suggest muscle preservation in the membranous sac. Scale bars, 500 μm (a)–(d), 50 μm (e), (i)–(k), 200 μm (f), 150 μm (g), 100 μm (h) and 30 μm (l), (m). Song et al. (2026).

These new specimens show Protomelission gatehousei as forming upright colonies with two curved lamellar sheets of zooids back-to-back, with the largest colonies being 1-2 mm in width and about 3 mm high, tapering towards their tip. Each of these lamellae has six-to-eight rows of zooids, with budding originating from a planar mesotheca.

Soft-tissue preservation of Protomelission gatehousei. (a)–(e) ELI DYCX 8-005. (a) Front side of the colony, box corners indicate the area shown in (d). (b) The back side of the colony. (c) Lateral view of the bifoliate colony. (d), (e) Enlarged view of elongated hexagonal zooids. Note the longitudinally neatly arranged cylindrical structures on the both sides of the ridge-like orifice, which are possible secondary coatings of protective shields. (f) Protective shields developed in an extant Cheilostome Bryozoan, Valdemunitella sp. photographed by Dennis Gordon (Wellington). Song et al. (2026).

The new species described is named Dayingomelission hexaclitia, where 'Dayingomelission' means 'honeycomb from Daying' and 'hexaclitia' means 'six slopes' in reference to the sloped, hexagonal apertures of its autozooids. Colonies of Dayingomelission hexaclitia form a sheet-like grown covering the substrate. This sheet is interpreted as having spread by linear branching, with a single row of zooids diverging to form two new rows. Each autozooid is hexagonal and box-like, between 200 µm to 400 µm in diameter, and separated from its neighbours by a double-walled structure. All vertical walls show this double-walled structure, while the basal wall is planar, sometimes showing a slight curvature. 

Specimens of Dayingomelission hexaclitia from the Xiannüdong Formation showing the colony and cystids. (a), (b) ELI ZJBX 10-001 (holotype). (a) Oblique view of the front side of a unilaminate colony form clearly showing the regular hexagonal, compactly arranged, honeycomb-shaped cystids. The outlined area is shown in (b). (b) Hexagonal cystid with vertical wall and ring septa clearly evident (arrow). (c)–(e) ELI ZJBX 10-002. (c) Front side of a unilaminate colony form. The bottom outlined area shows the cystids magnified in (d); whereas the top outline shows the cystids magnified in (e). (d) Enlarged view of adjacent cystids. Note the hexagonal vertical wall (arrow) and the basal exterior wall of cystids (arrowheads). (e) Row bifurcation showing change in zooid width along rows. (f)–(i) ELI ZJBX 3-001. (f) Front side of a unilaminate colony form with styles indenting the zooidal chambers. (g) Oblique view showing hexagonal cystids with styles. (h) Oblique view of colony surface. Note that the styles arise in the endozone and extend through most of exozone. (i) Enlarged view of the vertical wall with planar spherulitic fabric. Scale bars, 500 μm (a), (c), 80 μm (b), 100 μm (d), 200 μm (e), 300 μm (f), (g), 100 μm (h) and 25 μm (i). Song et al. (2026).

Both species have hexagonal zooids with a box-shaped profile and a non-porous phosphatized or silicified skeleton. These are more-or-less uniform in size, and angled at 30-75° to the median lamina or basal exterior wall. They have preserved phosphatized internal structures interpreted as membranous sacks, the outer end of which comprises an elliptical orifice surrounded by an undulating fold. These are made up of densely packed circular and longitudinal fibres interpreted as annular and longitudinal muscles. Longitudinally aligned cylindrical structures, possibly representing protective shields or a broad operculum are present in some specimens. In others sac is attached to the cystid wall in the inner part of the zooid cell.

Membranous sacs preserved in situ in the autozooid cystids of Protomelission gatehousei and Dayingomelission hexaclitia and colonial growth reconstruction of Protomelission gatehousei . (a), (b) Protomelission gatehousei  ELI DYCX 8-016. (a) Front side of a bifoliate colony showing the eight series of zooids. The outlined area is magnified in (b). (b) Enlarged view of a zooid. Note that the membranous sac (arrow) is preserved in the cystid (arrowhead). (c)–(g) Dayingomelission hexaclitia ELI DYCX 8-004. (c) Front side of a unilaminate colony, with ten series of zooids, all with membranous sacs and cystids. The outlined area is magnified in (g). (d) Back side of the colony showing the membranous sacs of the zooids and the gap between the sacs. The outlined area is magnified in (e). (e) Enlarged view showing capsule￾like membranes and gaps. (f) X-ray tomographic microscopy image showing the longitudinal section of zooids with membranous sacs and cystids. (g) Enlarged view highlighting that the membranous sacs (arrow) are captured in the cystids (arrowhead), and the membranous sacs are in contact with the cystids 20 μm from the apertures (ligamentous attachment, asterisks). (h) Three-dimensional reconstruction of a Bryozoan zooid with protruding lophophore. (i) Longitudinal section of reconstructed Bryozoan zooid. Greyish white, cystid; translucent white, membranous sac and tentacles; pink, polypide excluding tentacles. (j) Reconstruction of Protomelission gatehousei , front surface view. Scale bars, 500 μm (a), (c), (d), 40 μm (b), 200 μm (e), (f) and 100 μm (g). Song et al. (2026).

Both Protomelission gatehousei and Dayingomelission hexaclitia show most of the key features associated with Palaeozoic Bryozoans, including  aspects of their colony morphology, their skeletal architecture,  the presence of soft-tissue structures such as membranous sacs, as well as annular and longitudinal musculature. Notably they contain a number of features associated with the Class Stenolaemata, including styles and  a free-walled colony organisation, which would make both species crown-group Brozoans. This makes it more likely that they were biomineralized in life, although it is impossible to determine the initial composition of their skeletons. Brozoans are known to have undergone a number of independent biomineralization events, with a molecular clock analysis indicating that the first of these was likely to have happened in the Early Cambrian. These results also imply that the common ancestor of the organic￾walled Gymnolaemata and the mineralized Stenolaemata probably originated in the early Cambrian (Terreneuvian) or even perhaps in the Ediacaran Period.

Phylogenetic relationships of Bryozoans. A 50% majority-rule consensus phylogenetic tree inferred using morphological characters and Bayesian analysis based on a matrix of 22 taxa and 50 characters. Node values are Bayesian posterior probability support values. Coloured areas indicate the three taxonomic classes that comprise the Bryozoa along with outgroups, with Protomelission and Dayingomelission belonging to Stenolaemata. Song et al. (2026).

The presence of two species of Bryozoan in the Early Cambrian Xiannüdong Formation of Shaanxi Province, as well as one of these species being present in the lower Wirrealpa Limestone of South Australia makes it likely that Bryazoans had already diversified and become widespread in the Early Cambrian. This lends support to the idea that the tentative mineralised Bryomorphs from the Lower Cambrian of Nevada recently described by Pruss et al. (2022) are also Bryozoans, and that Moss Animals were therefore widespread in shallow Cambrian seas, particularly Archaeocyath reef-associated carbonate platform settings. 

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Observing Animal and Human interactions around a Marburg Virus-infected Bat colony.

Zoonotic infections, diseases which spread from an Animal host into a Human population, are a serious threat to public health, in some cases being the source of pandemics which kill millions of people around the globe, such as the Influenza and Covid Viruses and the medieval Plague outbreaks. Filoviruses, such as the Bundibugyo, Ebola, Marburg, and Sudan Viruses, can cause outbreaks of hemorrhagic fever which kill hundreds or even thousands of people in tropical Africa, after jumping from a natural host, usually a Fruit Bat. The Bats themselves seem to suffer little harm from infection with these Viruses, but Humans and other Animals often succumb very rapidly. 

Since the nature of the wild host of these Viruses became apparent, public health campaigns in many countries have tried to minimise the extent to which people interact with Fruit Bats, but the often remote nature of the communities most at risk, combined with the ability of the Virus to jump from Bats into a variety of other hosts before infecting Humans, has limited the effectiveness of these, underlining the need to better understand the nature of interactions between Fruit Bats, Humans, and other Animals.

In a letter published in the journal Current Biology on 20 April 2026, Bosco Atukwatse, Orin Cornille, Johnson Muhereza, Winfred Nsabimana, and Yahaya Ssemakula of the Kyambura Lion Project of the Volcanoes Safaris Partnership Trust, Eric Enyel of the Uganda Wildlife Authority, Charlie Gould of the School of Biological Science at the University of Edinburgh, Arjun Gopalaswamy of Carnassials Global, and Alexander Braczkowski, also of the Kyambura Lion Project of the Volcanoes Safaris Partnership Trust, present the results of an study in which camera traps were deployed at Python Cave in the Queen Elizabeth National Park, the dwelling place of a colony of  Egyptian Rousette Bats, Rousettus aegyptiacus, known to act as a reserve for Marburg Virus.

The camera traps were deployed as part of a carnivore-monitoring program in Queen Elizabeth National Park between 16 February and 23 June 2025, with a total of 8832 hours of filming producing evidence of at least 14 species of Animal visiting the size, including Carnivores, Primates, Raptors, and Reptiles. The most common visitors to the cave were Nile monitors, Varanus niloticus, (72 visits), Large Spotted Genets, Genetta tigrina, (69 visits), and Palm-nut Vultures, Gypohierax angolensis, (35 visits). The cave was visited twice by Olive Baboons, Papio anubis, and ten times by Blue Monkeys, Cercopithecus mitis, which were seen actively preying on Bats. African Fish Eagles, Icthyophaga vocifer, made 33 visits to the cave, Black Sparrowhawks, Astur melanoleucus, made 19 visits, Crowned Eagles, Stephanoaetus coronatus, made 17 visits, and Verreaux’s Eagle-owls, Bubo lacteus, made six visits. Seventeen Leopard visits were directly recorded, but parts of a cycle in which the same Leopard repeatedly entered the cave, captured Bats, and exited with them were recorded, leading the team to conclude at least 43 such hunts took place during the study time. A total of 63 incidents of hunting or scavenging Bats by different species were recorded, with a further 258 incidents of Animals entering the caves for less clear reasons.

 Multi-species predation and scavenging at a Marburg Virus Bat reservoir. The distribution of detections per species across 368 trap nights at Python Cave recorded using  6 remote, solar-powered camera traps. Blue indicates predation and scavenging events, whereas  orange represents detections where cave exploration, entry, exit, or resting was observed. Atukwatse et al. (2026).

More alarmingly, over the course of the study Atukwatse et al. also observed 214 individual Humans approaching the cave. These came in 22 different groups, including school groups, researchers, and tourists, many of whom came within meters of the cave entrance (a direct contradiction of park regulations), bypassing a designated observation platform 30 m from the entrance. Only one person, a tourist, was observed to wear a mask when approaching the cave.

Atukwatse et al. do not suggest that these observations represent evidence of Virus transmission, but rather a direct record of ecological interactions at a potential spillover site. This included direct predation of potentially-infected Bats during repeated visits to the cave, and provide direct evidence of the predator-guild targeting Bats in this setting. 

A collage of hunting and foraging by a variety of species. Insets show confirmed prey contact and feeding events. (i) An African Leopard, Panthera pardus, with its Bat prey emerging from the cave interior. (ii) A Crowned Eagle, Stephanoaetus coronatus, with its Bat prey. (iii) A Blue Monkey, Cercopithecus mitis, holding a Bat in its left hand. (iv) A Melanistic Genet, Genetta victoriae, with Bat prey. (v) A Nile Monitor, Varanus niloticus, approaching and then consuming a fallen Bat. (vi) An interspecific interaction (likely a fight) between a Crowned Eagle and a Nile Monitor over two Bats captured by the Eagle. (vii) An African Civet, Civettictis civetta, scavenging on Bat remains. (viii) A Palm-nut Vulture, Gypohierax angolensis, scavenging a Bat carcass. (ix) A group of Olive Baboons, Papio anubis, at the cave mouth, possibly foraging on Bat guano. Atukwatse et al. (2026).

Unlike other famous tropical Bat roosts within caves, such as Kitaka Mine in Uganda, Kitum Cave in Kenya, Goroumbwa Mine in Democratic Republic of Congo, or Macaregua Cave in Colombia, Python Cave lacks a vertical space separating the Bats from ground-based predators. Parts of the cave roof have collapsed, and the cave is partly filled with large volumes of guano, providing predators a way of directly reaching the Bats where they roost. This it turn provides an easy opportunity for any Virus present in the Bat community to spread to other wildlife within the cave. Atukwatse et al. observed instances of bats falling from the overcrowded roof of the cave, then having to crawl over the floor, presenting another tempting target for both terrestrial and airborne predators.

First ever large scale predation by at least 14 species on Egyptian Fruit Bats (a known Marburg Filovirus reservoir) in Python Cave Uganda. The trail cameras were placed at the cave as part of the Volcanoes Safaris Partnership Trust Kyambura Lion Project's long term Leopard and Hyena monitoring work in Queen Elizabeth National Park. Alex Braczkowski/YouTube.

The presence of piles of Bat bones and frequent and repeated visits to the caves by a variety of predators indicates that the site has become a prime feeding site for both predators and scavenges, and that to some extent the richness of the resource has led to a relaxation of normal inter-species hostilities, with, for example, Fish Eagles feeding alongside Vultures, Nile Monitors feeding alongside Pythons, and even a Genet and Python seen together. This implies a loss of territoriality and aggression only seen at the most abundant food sites, although on one occasion  Atukwatse et al. did observe a Crowned Eagle and a Nile Monitor squabbling over a Bat.

These interactions are all the more remarkable in that they are occurring at a site with a frequent Human presence, something which many Animals avoid where possible. The Uganda Wildlife Authority has placed an observation platform about 30 m from the entrance to Python Cave, with the specific intention of limiting Human exposure to Marburg Virus-infected Bats, but despite this Atukwatse et al.'s camera traps recorded Tourists, students from a nearby wildlife training institute, and even school trips approaching the cave mouth without any form of protection. It is particularly concerning that this was happening during the Bat's birthing season, when they are known to shed the Virus at a higher rate. Atukwatse et al. recognise that Bat-viewing is a valuable contribution to the nation's ecotourism income, but nevertheless recommend that the Uganda Wildlife Authority imposes stricter regulation on the site, with mandates for protective gear, enforced distancing, and locally trained guides to serve as sentinels for biosurveillance and education.

It has generally been assumed that the spillover events which lead to outbreaks of Marburg Virus Disease, and other zoonotic infections, occur in locations effectively beyond the observation of science. Atukwatse et al.'s results refute this, providing an example of a site where Marburg-infected Bats are interacting with a variety of other Animals, which is also integrated into the local tourist industry. Some of the species observed, such as Blue Monkeys, have previously been associated with Marburg Virus, and are commonly hunted and consumed by Humans as bushmeat. The consumption of Bats by these Monkeys presents a new route by which Marburg Virus could make its way from the wild Bat reserve into Human populations. Atukwatse et al. recommend that serological surveys are carried out of both the predators seen frequenting Python Cave, and of park rangers who regularly enter the site, in order to assess potential exposure to Marburg or other Filoviruses. This, combined with enhanced surveillance of Python Cave and other similar sites, could enable the development of a new dataset to complement the genomic tools already being developed.

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Seven Asiatic Lion cubs die in suspected disease outbreak.

Seven Asiatic Lion cubs have died in the Gir Forest National Park in the last week of May 2026, with a number of extra deaths thought to have occurred in areas of the forest outside the park. Seventeen adult Lions from the same population have been taken into quarantine by park officials.

A female Asiatic Lion with a cub in the Gir Forest National Park. Priyank Dhami/Wikimedia Commons.

The initial cause of the deaths was thought likely to be Canine Distemper Virus, a single-stranded RNA Virus of the Family Paramyxoviridae (the family of Viruses that includes the agents which cause Measles and Mumps in Humans), which can spread from domestic Dogs to wild Mammals, with Big Cats being particularly vulnerable. An outbreak of Canine Distemper in the Gir Forest killed 11 Lions in less than a month in 2018, and an outbreak in the Kanha National Park in Madhya Pradesh has killed four Tigers in April and May 2026.

However, it is now thought more likely that the Lions have been infected with Babesiosis, which is caused by Babesia spp., a type of Apicomplexan (single-celled parasitic Eukaryote) related to the Malaria parasite, Plasmodium. The Babesia is common in Deer, which make up a significant part of the diet of Asiatic Lions, although it can be spread to other species via biting Ticks. Like the Plasmodium parasite which causes Malaria, Babesia attacks the red blood cells, causing a similar illness to Malaria, with symptoms including anaemia and failure of the liver and kidneys. This can occasionally infect Humans, but is more commonly a problem for Cattle who can become infected if grazing in areas where Deer graze. In Lions, Babesiosis is particularly dangerous to cubs, with healthy adults usually able to shake off the infection.

Asiatic Lions are a sub-population of the Northern Lion, Panthera leo leo, which was once found across West, Central, and North Africa, southern Europe, the Middle East, and the North Indian Plain. The Lions of Southern and East Africa are a separate subspecies, Panthera leo melanochaita. All surviving Asiatic Lions are found within a single population, the Gir Forest of southern Gujarat State, India. This population has been growing in recent years, with 350 Lions recorded in 2008 and 891 in 2025. However, like all Lions, Asiatic Lions are territorial, and with each pride needing a fairly large home range. Thus the recovery of the species means that they have spread beyond the Gir Forest National Park into the neighbouring Amreli and Bhavnagar districts, areas where they come into conflict with Human herders and farmers, presenting additional challenges for their conservation. Asiatic Lions are considered to be Endangered under the terms of the International Union for the Conservation of Nature's Red List of Threatened Species.

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Were Octopuses the largest predators in the Cretaceous seas?

Vertebrates became the top predators in almost all marine ecosystems shortly after the evolution of jaws, about 370 million years ago. This has allowed them to shape the structure of these ecosystems, as they have repeatedly evolved large body sizes, combined with increased strength, mobility, and cognitive abilities. In the Mesozoic Era marine predators such as Fish and Sharks were joined by Marine Reptiles such as Ichthyosaurs, Plesiosaurs, Mosasaurs, and Turtles, which secondarily returned to the seas from the land. In the Tertiary Mammalian predators such as Whales and Seals also followed this route. The evolution of the ability to crush shells and other hard parts (durophagy) among various Vertebrate groups caused a major reshaping of marine ecosystems during the Mesozoic (sometimes known as the 'Mesozoic Marine Revolution') in which many marine Invertebrates became smaller, more heavily shelled, and more cryptic in their habits, in response to this increased predation.

The only Invertebrate group which has apparently been occasionally able to challenge the vertebrates for this top-predator status are the Cephalopods (Octopuses, Cuttlefish, Squid, Nautiluses, and the extinct Ammonoids), free-swimming Molluscs which independently evolved jaws at about the same time as Vertebrates. Modern Octopuses are highly intelligent mid-level predators which have either lost their shells or retain them only as vestigial structures. This loss of a mineralised shell has enabled the Octopuses to become more mobile, develop better eyesight, and much greater intelligence.

The Mesozoic fossil record has produced a number of large Cephalopod jaws which have been interpreted as those of Octobranchians (Octopuses or Vampire Squid) likely to have exceeded 2 m in total length. The owners of these jaws have been assumed to have been 'high-level' predators, but little has actually been determined about them, as there are no cases of soft tissue preservation nor stomach contents from which this could be determined. Furthermore, it is very hard to determine the diet of a Cephalopod from its jaw structure, as, while there is considerable variation in such structure across the group, it does not appear to be related to diet.

In a paper published in the journal Science on 23 April 2026, Shin Ikegami of the Department of Earth and Planetary Sciences at Hokkaido University, Jörg Mutterlose of the Department of Geosciences at Ruhr University Bochum, Kanta Sugiura, also of the Department of Earth and Planetary Sciences at Hokkaido University, Yusuke Takeda of the Spectroscopy and Imaging Division at the Japan Synchrotron Radiation Research Institute, Mehmet Oguz Derin of Morgenrot Inc., Aya Kubota of the Department of Geosciences at Osaka Metropolitan University, Kazuki Tainaka of the Brain Research Institute at Niigata University, Takahiro Harada, also of Morgenrot Inc., Harufumi Nishida of the Department of Biological Sciences at Chuo University, and Yasuhiro Iba, once again of the Department of Earth and Planetary Sciences at Hokkaido University, re-examine the status of large Cephalopod jaws from the Mesozoic.

Ikegami et al. examined wear on the jaws of fossil Cephalopods. All such jaws are made from stiffened chitin in life, and therefore are more prone to cracking and wear in more durophagous species, i.e. those which are using their beaks to crack the skeletons of their prey.

Octopus jaws. (A) The entire body of a finned octopus and the position of their upper and lower jaw. (B) Anatomy of feeding organs. (C) The upper jaw. (D) The lower jaw. Ikegami et al. (2026).

Ikegami et al. examined 15 sets of large Octobranchian jaws which had previously been described from Japan and Vancouver Island. They also discovered a series of 12 further such jaws by using a method which they describe as 'digital fossil mining', in which high resolution tomography combined with an artificial intelligence system was used to search for specimens within Cretaceous rocks from Japan. All 27 specimens came from outer-shelf environments lacking wave or current influence, so that transportation-related abrasion to the jaws is unlikely. 

Precise, automatic segmentation of an Octopus jaw fossil and its fine structures using zero-shot learning AI. Ikegami et al. (2026).

All of the preserved specimens are interpreted as having come from members of the Order Cirrata (Finned Octopuses). The excellent preservation of the specimens and the lack of any potential to have been caused during preparation in specimens which had not been freed from the matrix allowed identification of wear patterns caused by the feeding habits of the living Octopuses with some confidence. Pigmentation patterns within the jaws enabled the reconstruction of growth patterns, and the large dataset being used enabled a reassessment of the taxonomy of Cretaceous Cirratans.

Descriptive terms of the Coleoid lower jaw. (A) Inner and outer lamellae. (B) Terms for the individual parts of the lower jaw. (C) Terms for the specific morphological characteristics of the lower jaw. (D) Morphological terms for the area near the jaw edges. (E) Measurements of lengths. Ikegami et al. (2026).

Previous studies have led to the description of five species of Octobranchians from the Cretaceous, all on the basis of fossil jaws. Upon re-examination of this material, Ikegami et al. conclude that only two of these species are valid, Nanaimoteuthis jeletzkyi and Nanaimoteuthis haggarti. Both are assigned to the genus Nanaimoteuthis, which was formerly thought to be a Vampire Squid, i.e. a member of the Order Vampyromorpha, but which Ikegami et al. reassign to the Winged Octopuses, Suborder Cirrata. Modern Winged Octopuses come in two forms, long-bodied forms, which have broad jaw wings, and short-bodied forms, which have narrow wings on their jaws. Because both species of Nanaimoteuthis have broad wings on their jaws, they are interpreted as long-bodied Winged Octopuses. Taking all the specimens, including the newly discovered ones, into account, Nanaimoteuthis jeletzkyi first appeared in the earliest Cenomanian (about 100 million years ago) and disappeared in the late Campanian (about 72 million years ago), while Nanaimoteuthis haggarti first appeared during the Santonian (about 86 million years ago, and also disappeared in the late Campanian (about 72 million years ago).

Huge lower jaws of fossil Octopuses and of an extant Giant Squid. (A) and (B) The largest lower jaws of the Late Cretaceous Finned Octopus species Nanaimoteuthis jeletzkyi, (A) NMNS DS00042 3LmvTpM, and Nanaimoteuthis haggarti, (B) KMNH IvP 902001. Both specimens show extensive loss of jaw material caused by wear. (C) A lower jaw of the extant Giant Squid Architeuthis dux (NSMT-Mo 85956), a species having the largest jaw among modern Cephalopods. (A) is a digital fossil jaw visualized as a 3D model; (B) is an exceptionally well-preserved non-digital fossil jaw; and (C) is a modern jaw dissected from a carcass of about 10 m total body length. Solid lines indicate the extension of striation on the outer surface of the hood and broken lines show the estimated outline of the rostrum without wear. The hood and lateral walls lost by weathering, shown as shadowed areas, are reconstructed based on the holotype and specimen NMNS DS00182 Ru8pBBo. (A) and (C) are exhibited in a mirrored position. Scale bar is 20 mm. Ikegami et al. (2026).

In Cephalopods, there is a direct relationship between the growth of the jaws and that of the soft body, allowing reliable body-size calculations to be made from the jaws alone. Based upon this, the largest specimens of Nanaimoteuthis jeletzkyi are estimated to have had a mantle length of between 67 cm and 184 cm, with a total body-length (including tentacles) of 2.8-7.7 m, while the largest specimens of Nanaimoteuthis haggarti are estimated to have had a mantle length of between 158 cm and 443 cm, with a total body length of 6.6-18.6 m, making it potentially one of the largest predators in the seas of the Late Cretaceous.

Body size estimation of Late Cretaceous Octopuses. The graph shows an allometric relationship between the length of the jaw and mantle in long-bodied species of extant Finned Octopus. The name of the corresponding species is shown along each growth curve. The sizes of Nanaimoteuthis jeletzkyi and Nanaimoteuthis haggarti are based on their largest specimens and are indicated by black vertical lines. Reconstruction of these two species, the extant Giant Squid, and gigantic Vertebrate predators in the Late Cretaceous are shown with their maximum total length. Ikegami et al. (2026).

The largest specimens of both species have beaks blunted and worn by continuous wear, while in juveniles the beaks tend to be sharp. However, it was possible to reconstruct the unworn beak length from the striations and ornamentation of the jaw surface. Thus the largest specimen of Nanaimoteuthis jeletzkyi has lost about 5.7 mm from the tip of its rostrum, while the largest specimen of Nanaimoteuthis haggarti has lost about 10.6 mm. In both cases this represents about 10% of the total jaw length. In both species the right edge of the jaw is more worn than the left edge. Wear takes the form of chips, scratches, and polishing, with the largest chips exceeding 1 mm in both species. The outer surface of the rostrum is polished, removing the original striations, but show numerous scratches, with these reaching up to 5 mm in length, extending vertically or obliquely from the jaw edge. In Nanaimoteuthis jeletzkyi the inner surface of the oral cavity is more heavily worn than the outer surface, which is indicative of the chewing of food. In Nanaimoteuthis haggarti there are many transverse cracks on the rostrum, these again reaching up to 5 mm in length.

Wear on the lower jaw of a modern Giant Pacific Octopus, Enteroctopus dofleini, (NSMT-Mo 85957). (A) Dorsal view of the entire mouth. (B) to (D) Close-ups of the wear, the positions of which are indicated by boxes in (A). (B) Lateral view of the right jaw edge. (C) Anterior view around the rostrum. (D) Dorsal view of the rostrum. Enteroctopus dofleini is the largest modern octopus species. Scale bars are 10 mm for (A) and 1 mm for (B) to (D). Ikegami et al. (2026).

There are two living suborders of Octopuses, the Finned Octopuses, or Cirrata, which are generally found in deep ocean environments, and the Finless Octopuses, of Incirrata, which are found in coastal environments. The discovery of specimens of the Finned Octopus Nanaimoteuthis jeletzkyi in deposits from the earliest Cenomanian (about 100 million years ago) pushes back the fossil record of the Ciratta by about 15 million years, and of crown-group Octopuses by about 5 million years. The presence of these fossils in Japan and on Vancouver Island indicates that large Finned Octopuses were found in outer shelf environments on either side of the Pacific during the Late Cretaceous (at which time the Pacific was already the world's largest ocean).

Wear on the largest lower jaw of Nanaimoteuthis jeletzkyi. (A) and (B) The entire specimen in (A) dorsal view and (B) anterior view. The broken line in (A) shows the boundary where striations become lost. (C) to (H) Close-ups of wear, of which the positions are indicated by boxes in (A) and (B). (C) Lateral view of the right jaw edge with chips (arrows). (D) Dorsal view of the rounded rostral part with scratches (arrows). (E) Oblique view of the rostral part with chips (arrows). (F) Area showing striations, which extends vertically in this figure (arrows). (G) Polished area where striation is lost, with scratches (arrows). (H) Asymmetric loss of the jaw edges (arrows), indicated by a mirrored image in 50% transparency overlaid beneath the original image. All panels show the specimen NMNS DS00042 3LmvTpM. Scale bars are 10 mm for (A), (B), and (H), and 1 mm for (C) to (G). Ikegami et al. (2026).

The living Cirrata can be split into two morphological groups, long-bodied forms (families Cirroctopodidae, Cirroteuthidae, Grimpoteuthidae, and Stauroteuthidae), and short-bodied forms (Family Opisthoteuthidae). Ikegami et al.'s analysis strongly suggests that both species of Nanaimoteuthis are long-bodied forms, something which is in line with both evidence from previously reported fossils, with more than 50 genera of Mesozoic Octobranchians discovered, all of which are long-bodied forms, and molecular phylogenies, which suggest that the Incerrata arose from within the Cerrata, implying that long-bodied forms arose first and that short-bodied forms evolved from these.

Wear on the largest lower jaw of Nanaimoteuthis haggarti. (A) and (B) The entire specimen in (A) dorsal view and (B) anterior view. (C) to (K) Close-ups of the wear, of which the accurate positions are indicated by boxes in (A), (B), and (G). (C) and (G) Lateral view of the right jaw edge with chips, scratches, and cracks. (E) Dorsal view of the rounded rostral part with scratches and cracks. Schematic drawings of (C), (E), and (G) are shown in (D), (F), and (H), respectively. (I) Area showing striation, which extends vertically in this figure. (J) Polished area where striation is lost. (K) Asymmetric loss of the jaw edges (arrows), indicated by a mirrored image in 50% transparency overlaid beneath the original image. All panels show the specimen KMNH IvP 902001. The broken line in (A), (G), and (H) shows the boundary where striation becomes lost. Scale bars are 10 mm for (A), (B), (E) to (H), and (K), and 1 mm for (C), (D), (I), and (J). Ikegami et al. (2026).

Nanaimoteuthis haggarti is significantly larger than Nanaimoteuthis jeletzkyi and examination of pigment patterns in the jaws of specimens of both species suggests that it grew significantly faster. Since the first known fossils of Nanaimoteuthis haggarti appeared about 86 million years ago, while the first specimens of Nanaimoteuthis jeletzkyi appeared about 100 million years ago, this suggests that these ancient Cirratans went through an evolutionary change enabling the emergence of gigantic forms about 10 million years after they first appeared.

The growth rate of Nanaimoteuthis haggarti and Nanaimoteuthis jeletzkyi based on pigmentation patterns. (A) Schematic drawings for the ontogenetic changes from juvenile to adult jaws, based on modern Octopuses. Unpigmented regions decrease with growth. (B) Nanaimoteuthis haggarti  (NMNS_DS00182_Ru8pBBo.stl), corresponding to the left stage of (A). (C) Nanaimoteuthis jeletzkyi (NMNS_DS00173_P74Doy1.stl), corresponding to the middle stage of (A). The broken lines in (B) and (C) indicate the original outline including unpigmented parts, reconstructed based on the adults of the same species. The posterior and ventral margins of (B) and (C) taper without fractures, indicating that they retain the original pigmentation patterns. The specimen of Nanaimoteuthis haggarti has a weakly pigmented inner lamella compared to that of Nanaimoteuthis jeletzkyi  with a smaller size. This pattern indicates that Nanaimoteuthis haggarti is in an earlier growth stage compared to Nanaimoteuthis jeletzkyi. Therefore, Nanaimoteuthis haggarti grew faster than Nanaimoteuthis jeletzkyi. Scale bars are 1 mm. Ikegami et al. (2026).

The extremely large size of Nanaimoteuthis haggarti makes it larger than the Giant Squid, Architeuthis dux, which has a maximum jaw length of about 80 mm, by about 50%. The Giant Squid can have a mantle length of about 2.5 m and a total length of about 12 m, something which has made it the largest known living or fossil invertebrate until now. It also rivals or exceeds the dimensions of the largest Vertebrates in the Cretaceous Seas, including the Ray-finned Fish, Xiphactinus audax, which reached about 5 m in length, the Lamniform Shark, Ptychodus mortoni, which reached about 10 m, Plesiosaurs of the genus Styxosaurus, which reached about 12 m, and the giant Mosasaur, Mosasaurus hoffmannii, the longest specimens of which may have reached about 17 m. Thus Nanaimoteuthis haggarti appears to have been one of the largest organisms in the Cretaceous oceans.

Most living Cephalopods are generalist carnivores, preying on Crustaceans, shelled Molluscs, other Cephalopods, and Bony Fish. Wear to the tip and edges of the beak is typically present in durophagous forms such as Octopuses and Cuttlefish, but absent in non-durophagous forms such as Squid. Thus the presence of such wear can be used to make judgements about the diet of fossil Cephalopods, such as Nanaimoteuthis jeletzkyi and Nanaimoteuthis haggarti. In these Cretaceous Cirratans it is estimated that about 10% of the jaws of large adult specimens had been worn away, but such wear is absent in juvenile specimens, as it is in contemporaneous Squid. The extent of wear seen is greater than is found in any living Cephalopod, suggesting that these were active carnivores, frequently using their beaks to crush hard shells and bone. The distribution of the wear on the jaws is asymmetric, which suggests lateralized behaviour (i.e. these Octopuses had a preferred side when manipulating prey, similar to handedness in Humans), something which is associated with cognative ability in Cepahlopods, suggesting that these Cretaceous Octopuses were already highly intelligent. 

The jaws of Nanaimoteuthis jeletzkyi and Nanaimoteuthis haggarti are much shorter than the jaws of most Late Cretaceous predatory marine Vertebrates. However, the long lateral walls of these jaws suggest they had powerful jaw muscles, and the cracks and chips on the beaks suggests that they were exerting forces which exceeded the resistance of the strongest parts of the jaw. In the larger Nanaimoteuthis haggarti transverse cracking is also present, probably representing larger shear failures caused by greater forces being applied. Thus these jaws appear to have been used to break up food items of considerable size and resilience. The difference in overall size is likely to have derived from the way in which Octopuses hunt, using their elongated arms to capture and overwhelm prey, rather than their jaws as in most marine Vertebrates.

Vertebrates have been the top predators in the oceans for most of the past 370 million years. The appearance of durophagous predation in a variety of lineages in the Mesozoic enabled a greater diversity of such predators, and drove marine ecosystems towards the structure we have today. Mesozoic Invertebrates have chiefly been viewed as prey during this process, adapting to increased predation pressures by becoming smaller, more heavily armoured, and more cryptic in their habits (better at hiding). Ikegami et al.'s study suggests that some Octopuses did not follow this path, instead becoming giant predators which rose to the top of the food web.

Convergent evolution among marine top predators in the Palaeozoic–Mesozoic. This model shows the acquisition of jaws and the reduction of superficial skeletons in the evolutionary history of marine Vertebrates (top) and Cephalopods (bottom) to become top predators. The grey horizontal bars show the chronological range of some selected groups of Vertebrates and Cephalopods. For Cephalopods, stepwise reductions of skeletons are indicated by the blue background. Ikegami et al. (2026).

Both Vertebrates and Cephalopods first evolved jaws in the Late Silurian or Early Devonian, between 423 and 407 million years ago, something which greatly improved their hunting efficiency. Vertebrates subsequently lost their external bony plates, and in larger species greatly reduced their scaly coverings to achieve smooth skin, while at the same time Cephalopods first internalised and then gradually lost their shells. In both cases, this was associated with increased swimming speeds, size, and intelligence. Vertebrates became top predators in the oceans long before Cephalopods completed this process, but during the Cretaceous some Octopuses were able to evolve a bodyplan which enabled them to compete with the very largest Vertebrates.

See also...