- Newly discovered fossils push back the origin of humans’ earliest invertebrate ancestors much further in time than scientists previously thought.
- The fossils reveal key features linking modern animals – including humans – to simple, worm-like organisms.
- The find reshapes our understanding of early animal evolution and the timeline of life on Earth.
By Luke Parry, University of Oxford; Frankie Dunn, University of Oxford, and Gaorong Li, University of Oxford
Fossils show humans’ invertebrate ancestors are much older
Animal life is extraordinarily diverse and complex, having colonized almost all environments on Earth, from hostile hydrothermal vents in the deep sea to the skies across our continents.
But the planet was not always teeming with complex animal life. For the first 3.7 billion years after it originated, life was small, simple and largely confined to the oceans. This microbe-dominated world was a tumultuous place, with several major swings in its climate.
But all this appears to have changed about 538 million years ago during the Cambrian period. This critical juncture in the history of life saw animals bursting on to the scene in an event known as the Cambrian explosion.
The appearance of animals
All sorts of animals easily recognizable as groups alive today appeared in the fossil record, from echinoderms (starfish, sea cucumbers, urchins) and arthropods (spiders, crustaceans, insects) to various types of worm. This seemingly abrupt appearance of animals in a geological blink of an eye has puzzled scientists from Charles Darwin onwards.
Many of these new lifeforms belonged to a group of animals called Bilateria, so-named for their symmetrical left and right sides. This group now contains all animals with brains and complex musculature.
However, a longstanding question for paleontologists has been whether this astonishing diversification event happened all at once during the Cambrian explosion … or if ancestors of Cambrian and modern animal groups can be traced further back in time. Our new study, published in the journal Science, could help to resolve this question.
Strange bodies
The preceding Ediacaran period (635-538 million years ago) was much more enigmatic than the Cambrian. Many organisms from that period have defied efforts to classify them. Their strange bodies – often resembling shapeless sacs or thin, quilted pillows – have no obvious counterparts among living species, let alone modern animals.
As a result, interpretations of Ediacaran creatures have encompassed almost all multicellular forms of life, from fungi and lichens to an extinct kingdom unrelated to anything multicellular alive today. These Ediacaran organisms lived in close association with mats of microbes that smothered the seafloor. They were a type of ecosystem that did not survive the advent of grazing bilaterians.
More recent evidence relating to their reproductive strategy and how they grew and developed has suggested they were, in fact, animals. Albeit they were very simple ones without any direct, living descendants.
Transitioning to complex animals
It isn’t until the very end of the Ediacaran period that the fossil record gives hints that more complex – and recognizable – animals were around. And most of the evidence for these bilaterian animals has come from fossilized burrows and trails. These are suggestive of complex animal life, but tell us little about the animals that made them.
This has led to much debate about the nature of the transition from the Ediacaran to the Cambrian period – the start of which geologists have defined by the action of complex animals churning up ocean sediment for the first time.
A discovery to fill the fuzzy gap
In spring 2023, one of us, Gaorong Li – then a PhD student at Yunnan Key Laboratory for Palaeobiology (YKLP) – made a discovery that helps to clarify this fuzzy gap between the weird Ediacaran world and the recognizable, complex animal-dominated Cambrian period.
Along with my PhD supervisors Wei Fan and Peiyun Cong, we explored Ediacaran rocks in the Chinese region of Eastern Yunnan. We were principally looking for fossil algae (seaweeds), the focus of my PhD thesis, in rocks known for well-preserved fossils called the Jiangchuan biota.
What we found in addition was a bizarre worm that lived tethered to the seafloor by an anchoring disc, and which could turn its strange proboscis inside out to collect food. These specimens were clearly complex animals, but not as they are known today.
We nicknamed it the bugle worm. And our team is still figuring out exactly where this strange beast fits into the classification of animals. Previously, it had been described based only on the disc anchoring it to the seafloor and named Cycliomedusa. But we found the whole organism, revealing it as something unexpected and strange.
Animals hiding in the rocks
As we continued splitting more and more rocks, it became clear there were more animals hiding in the Jiangchuan biota. In 2024 – now joined by a team from the University of Oxford including the co-authors of this article, Luke and Frankie – we went back into the field and pieced together this new fossil community.
We found some fossilized organisms characteristic of both the Ediacaran and Cambrian periods. But surprisingly, we also found some that had previously only been known from the time of the Cambrian explosion. These included a primitive animal similar to the Cambrian organism Mackenzia, as well as various worms and swimming predators called ctenophores.
Most striking of all, we found the oldest evidence for the group to which we humans belong: the deuterostomes.
More than just the Cambrian explosion
Several of these specimens have a stalk and tentacles. They closely resemble a group of Cambrian fossils called cambroernids. These now-extinct animals are related to living starfish and acorn worms, the closest invertebrate relatives to humans. This shows our own evolutionary story has its roots in the Ediacaran period.
The discovery of diverse, complex animals in the Jingchuan biota suggests several animal groups shared the world with the weird and wonderful Ediacarans for millions of years. Diverse complex animal life has a more ancient heritage than the Cambrian explosion.
Luke Parry, Associate Professor of Palaeobiology, Department of Earth Sciences, University of Oxford; Frankie Dunn, Senior Researcher of Natural History, Museum of Natural History, University of Oxford, and Gaorong Li, China Scholarship Council Post-Doctoral Research Fellow, Museum of Natural History, University of Oxford
This article is republished from The Conversation under a Creative Commons license. Read the original article.
Bottom line: New fossils show humans’ invertebrate ancestors arose far earlier than thought, reshaping the timeline of early animal evolution.
Read more: Rare fossils of mass extinction survivors found in China
The post Fossils show humans’ invertebrate ancestors are older than we thought first appeared on EarthSky.
from EarthSky https://ift.tt/mUnIr8B
- Newly discovered fossils push back the origin of humans’ earliest invertebrate ancestors much further in time than scientists previously thought.
- The fossils reveal key features linking modern animals – including humans – to simple, worm-like organisms.
- The find reshapes our understanding of early animal evolution and the timeline of life on Earth.
By Luke Parry, University of Oxford; Frankie Dunn, University of Oxford, and Gaorong Li, University of Oxford
Fossils show humans’ invertebrate ancestors are much older
Animal life is extraordinarily diverse and complex, having colonized almost all environments on Earth, from hostile hydrothermal vents in the deep sea to the skies across our continents.
But the planet was not always teeming with complex animal life. For the first 3.7 billion years after it originated, life was small, simple and largely confined to the oceans. This microbe-dominated world was a tumultuous place, with several major swings in its climate.
But all this appears to have changed about 538 million years ago during the Cambrian period. This critical juncture in the history of life saw animals bursting on to the scene in an event known as the Cambrian explosion.
The appearance of animals
All sorts of animals easily recognizable as groups alive today appeared in the fossil record, from echinoderms (starfish, sea cucumbers, urchins) and arthropods (spiders, crustaceans, insects) to various types of worm. This seemingly abrupt appearance of animals in a geological blink of an eye has puzzled scientists from Charles Darwin onwards.
Many of these new lifeforms belonged to a group of animals called Bilateria, so-named for their symmetrical left and right sides. This group now contains all animals with brains and complex musculature.
However, a longstanding question for paleontologists has been whether this astonishing diversification event happened all at once during the Cambrian explosion … or if ancestors of Cambrian and modern animal groups can be traced further back in time. Our new study, published in the journal Science, could help to resolve this question.
Strange bodies
The preceding Ediacaran period (635-538 million years ago) was much more enigmatic than the Cambrian. Many organisms from that period have defied efforts to classify them. Their strange bodies – often resembling shapeless sacs or thin, quilted pillows – have no obvious counterparts among living species, let alone modern animals.
As a result, interpretations of Ediacaran creatures have encompassed almost all multicellular forms of life, from fungi and lichens to an extinct kingdom unrelated to anything multicellular alive today. These Ediacaran organisms lived in close association with mats of microbes that smothered the seafloor. They were a type of ecosystem that did not survive the advent of grazing bilaterians.
More recent evidence relating to their reproductive strategy and how they grew and developed has suggested they were, in fact, animals. Albeit they were very simple ones without any direct, living descendants.
Transitioning to complex animals
It isn’t until the very end of the Ediacaran period that the fossil record gives hints that more complex – and recognizable – animals were around. And most of the evidence for these bilaterian animals has come from fossilized burrows and trails. These are suggestive of complex animal life, but tell us little about the animals that made them.
This has led to much debate about the nature of the transition from the Ediacaran to the Cambrian period – the start of which geologists have defined by the action of complex animals churning up ocean sediment for the first time.
A discovery to fill the fuzzy gap
In spring 2023, one of us, Gaorong Li – then a PhD student at Yunnan Key Laboratory for Palaeobiology (YKLP) – made a discovery that helps to clarify this fuzzy gap between the weird Ediacaran world and the recognizable, complex animal-dominated Cambrian period.
Along with my PhD supervisors Wei Fan and Peiyun Cong, we explored Ediacaran rocks in the Chinese region of Eastern Yunnan. We were principally looking for fossil algae (seaweeds), the focus of my PhD thesis, in rocks known for well-preserved fossils called the Jiangchuan biota.
What we found in addition was a bizarre worm that lived tethered to the seafloor by an anchoring disc, and which could turn its strange proboscis inside out to collect food. These specimens were clearly complex animals, but not as they are known today.
We nicknamed it the bugle worm. And our team is still figuring out exactly where this strange beast fits into the classification of animals. Previously, it had been described based only on the disc anchoring it to the seafloor and named Cycliomedusa. But we found the whole organism, revealing it as something unexpected and strange.
Animals hiding in the rocks
As we continued splitting more and more rocks, it became clear there were more animals hiding in the Jiangchuan biota. In 2024 – now joined by a team from the University of Oxford including the co-authors of this article, Luke and Frankie – we went back into the field and pieced together this new fossil community.
We found some fossilized organisms characteristic of both the Ediacaran and Cambrian periods. But surprisingly, we also found some that had previously only been known from the time of the Cambrian explosion. These included a primitive animal similar to the Cambrian organism Mackenzia, as well as various worms and swimming predators called ctenophores.
Most striking of all, we found the oldest evidence for the group to which we humans belong: the deuterostomes.
More than just the Cambrian explosion
Several of these specimens have a stalk and tentacles. They closely resemble a group of Cambrian fossils called cambroernids. These now-extinct animals are related to living starfish and acorn worms, the closest invertebrate relatives to humans. This shows our own evolutionary story has its roots in the Ediacaran period.
The discovery of diverse, complex animals in the Jingchuan biota suggests several animal groups shared the world with the weird and wonderful Ediacarans for millions of years. Diverse complex animal life has a more ancient heritage than the Cambrian explosion.
Luke Parry, Associate Professor of Palaeobiology, Department of Earth Sciences, University of Oxford; Frankie Dunn, Senior Researcher of Natural History, Museum of Natural History, University of Oxford, and Gaorong Li, China Scholarship Council Post-Doctoral Research Fellow, Museum of Natural History, University of Oxford
This article is republished from The Conversation under a Creative Commons license. Read the original article.
Bottom line: New fossils show humans’ invertebrate ancestors arose far earlier than thought, reshaping the timeline of early animal evolution.
Read more: Rare fossils of mass extinction survivors found in China
The post Fossils show humans’ invertebrate ancestors are older than we thought first appeared on EarthSky.
from EarthSky https://ift.tt/mUnIr8B
