Exploring the Flourishing Complexity of Colonial Life During the Cambrian Explosion

Bryozoans, small colonial animals, were traditionally believed to have appeared millions of years after the Cambrian explosion. However, remarkable fossils discovered in 520 million-year-old rocks in China reveal that these fascinating creatures have been present since the dawn of time.



Reconstruction of the early Cambrian ocean floor showing Protomerision Gatehouse and Daingomellission Hexacritia flourishing in the shallow waters of Archaeossias Reef. Image credit: Zhifei Zhang.

Bryozoans are small, filter-feeding, colonial invertebrates that continue to thrive in the world’s oceans today. Yet, their origins remained a mystery for decades,” noted paleontologist Dr. Timothy Topper from Northwest University and the Swedish Museum of Natural History.

“While nearly all other major animal groups emerged during the Cambrian explosion around 530 million years ago, the fossil record for bryozoans remained conspicuously absent until the Ordovician period, roughly 50 million years later.”

In a groundbreaking study, paleontologists analyzed a stunning bryozoan fossil from the early Cambrian Sennudo Formation in China.

The samples represent two species: Protomerision Gatehouse and a newly recognized taxon, Daingomellission Hexacritia.

“For too long, bryozoans have been the missing link in Cambrian paleontology,” Dr. Topper stated.

“Except for bryozoans, all other significant animal phyla have Cambrian representations. This discovery definitively closes that gap.”



Specimen of Protomerision Gatehouse excavated from the sacrolactoid layer where a membranous sac is preserved. Image credit: Song et al., doi: 10.1038/s41586-026-10590-9.

This discovery not only fills a significant gap in the fossil record but also has profound implications for our understanding of the tree of life.

Phylogenetic analysis firmly places both Protomerision Gatehouse and Daingomellission Hexacritia within the Crown Group Stenolaemata, one of the three main classes of living bryozoans.

Since these fossils represent a more advanced branch of the Bryonidae family tree, their existence suggests that the origin of the entire group might date back to the Ediacaran period, even before the Cambrian explosion.

This study also confirms that Protomerision Gatehouse is indeed a bryozoan, despite some researchers proposing it might be a sclerotid derived from green algae or another unrelated organism.

New soft tissue data, along with detailed comparisons of colony size, shape, and internal structure, refute these alternative interpretations, clearly solidifying their association with bryozoans.



Specimen of Daingomellission Hexacritia showcasing colonies and cystids from the Xiannüdong Formation. Image credit: Song et al., doi: 10.1038/s41586-026-10590-9.

“These are not merely precursors; they are complex, modular colonies,” asserts paleontologist Baopeng Song from Northwest University.

“The combination of skeletal structure and internal anatomy provides definitive evidence that these represent true bryozoans, indicating that this phylum was already diversifying during the Cambrian radiation.”

“Together, the two Chinese taxa and previously reported Cambrian material from South Australia suggest that bryozoans were not only widespread in the early Cambrian oceans but also highly sophisticated in their development.”

“The concept of colonial body planning, where genetically identical individuals known as polypids cooperate within a communal skeleton, appears to have evolved as a core innovation of the Cambrian explosion itself rather than a late development.”

The team’s paper is published in the latest edition of Nature.

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B. Song et al. The high-fidelity modular skeleton proves the Cambrian origin of bryozoans. Nature, published online on June 3, 2026. doi: 10.1038/s41586-026-10590-9

Source: www.sci.news

Deep-Sea Submarines Uncover Flourishing Ecosystems

The inhabitants of the ocean’s depths are more extraordinary than ever.

Utilizing an advanced submarine that dives deeper than Mount Everest, researchers have unearthed a vibrant ecosystem approximately 30,000 feet beneath the Pacific Ocean’s surface.

A research team led by Chinese scientists found it racing through fields of vivid crimson tubes and interacting with a unique type of worm that resembles a flower sprouting from the Earth’s crust.

Each organism thrived in dense beds of up to nine inches in length, with snow-like microbial mats creating ethereal underwater dust that spanned tens of feet.

Dominique Papineau, a senior research scientist at the Chinese Academy of Sciences, shared insights with NBC News.

Hadal chemical synthesis-based community,
CAS’s Institute of Deep Sea Science and Engineering

Papineau, one of the study’s authors, announced the findings in a Wednesday publication in Nature. “Many Hadal organisms from these trenches exhibit remarkable shapes and colors,” he noted, explaining that they survive by hosting microorganisms that metabolize methane instead of relying on photosynthesis.

The depth of 19,000 to 30,000 feet is the deepest zone in the ocean, occurring where one tectonic plate collides with another. “Existing theories suggest that chemical bond-based communities are becoming increasingly common in the Hadal Trench, yet few have been discovered,” Papineau stated.

Karien Schnabel, a marine ecologist from New Zealand’s Earth Sciences, commented that the discovery was “truly remarkable” even though she was not part of the study.

“In these extraordinarily deep regions, there were an abundance of signs of life and wildlife,” she remarked.

A winter valley recorded by the crew’s dive fendou at 30,000 feet.
CAS’s Institute of Deep Sea Science and Engineering
Polycharts inhabit the tube dominate at the deepest 22,500 meters of the Aleutian, with spots of white microbial mats.
CAS’s Institute of Deep Sea Science and Engineering

“We don’t generally expect life to flourish in these extreme conditions due to the immense pressure,” she commented regarding the organisms.

The researchers highlighted, “The depths explored here, alongside the robust communities found, significantly broaden the known habitats, depths, and biogeographic distributions of numerous species.”

With sunlight unable to penetrate, these organisms depend on chemical synthesis for nourishment, rather than photosynthesis.

“These ecosystems are abundant in hydrogen sulfide, methane-rich fluids flowing through faults amid deep sediment layers in the trench,” the researchers explained.

They also endure crushing pressures of up to 98 megapascals (MPA), exceeding six times the force of a crocodile’s bite.

The diving for this recent study took place in July and August of the previous year, conducted by an international group of scientists from the Institute of Deep Sea Science and Engineering at the Chinese Academy of Sciences.

A small porthole of three submarines.
Karien Schnabel

They examined the trenches of Krill Kamchatka, which stretch from Hokkaido in Japan to the Kamchatka Peninsula in Russia, spanning approximately 1,300 miles and integrating with the Aleutian trench that measures around 1,800 miles from Alaska to the Kenai Peninsula.

Schnabel had previously undertaken deep-sea studies aboard the same three submarines, known as Fendouzhe, utilized in this research.

She recounted her deep-sea experiences, one of which gained notoriety when a submarine malfunctioned during a 2023 mission to the Titanic wreck.

“Naturally, there’s a bit of anxiety when hanging over a 10-kilometer chasm on Earth,” she recalled, having explored New Zealand’s northern trenches in 2022, plunging over 32,000 feet below the Pacific Ocean’s surface.

“The window is merely 12 centimeters in diameter. It’s impossible to stretch your legs while seated on a tiny bench within a compact titanium sphere measuring only 1.8 meters in width,” she detailed.

Free-Moving Polychaete navigates dense colonies of Frenor Siboglinide.
CAS’s Institute of Deep Sea Science and Engineering

She expressed her amazement at the sights encountered at the trench’s bottom, viewed through the submarine’s 4.7-inch window.

“As I began my descent and eventually came to rest on the seabed, I was astonished by the multitude of life forms I witnessed,” she reflected.

While it was expected that life could persist at these depths, the sheer abundance of ecosystems was a pleasant surprise for the researchers.

The results “challenge existing models of life in extreme conditions” and indicate that such ecosystems may be more prevalent than previously recognized.

Source: www.nbcnews.com