Scientists uncover Earth’s oldest living creature from 700 million years ago

For over a century, biologists have puzzled over the origins of animals that first emerged in ancient oceans more than 600 million years ago.

Central to this debate is the question of which group represents the first branch of the animal family tree: sponges, the simple filter-feeders, or ctenophores, also known as comb jellies, which are voracious predators propelled by rows of beating cilia.

A groundbreaking study has now provided a definitive answer, reshaping our understanding of animal evolution.

Published in Nature, the research asserts that ctenophores were the earliest animals to diverge from the shared lineage, predating sponges and all other animals. This finding not only clarifies a long-standing evolutionary puzzle but also sheds light on the origins of essential animal traits, including nervous systems and multicellularity.

Uncovering the origins of animals is challenging due to the lack of fossil records for these soft-bodied ancestors. The solution lies in examining the genetic makeup of modern organisms.

Researchers led by Daniel Rokhsar of the University of California, Berkeley, and Darrin Schultz and Oleg Simakov of the University of Vienna used comparative genomics to study the chromosomal structures of diverse animals and their unicellular relatives.

“The most recent common ancestor of all animals probably lived 600 or 700 million years ago,” Rokhsar explained. “It’s hard to know what they were like because they didn’t leave a direct fossil record. But we can use comparisons across living animals to learn about our common ancestors.”

By comparing the arrangement of genes across chromosomes, the team discovered that ctenophores share ancestral chromosomal patterns with unicellular relatives, while sponges and other animals show distinct chromosomal rearrangements. These rearrangements serve as genetic "fingerprints," revealing the evolutionary branching order.

Central to the study was the concept of synteny—the preservation of gene order along chromosomes across species. Researchers reconstructed chromosome structures from modern genomes to infer the arrangement in ancient ancestors.

Schultz, a postdoctoral researcher at the University of Vienna, highlighted the importance of this approach, stating, “The fingerprints of this ancient evolutionary event are still present in the genomes of animals hundreds of millions of years later.”

The team’s pivotal breakthrough came with the sequencing of the ctenophore Hormiphora californensis genome. This enabled comparisons between ctenophores, sponges, and other animals.

Their analysis showed that ctenophores branched off before the chromosomal rearrangements that unite sponges with bilaterians, cnidarians, and other animals. Rokhsar called this finding the “smoking gun” that solidifies ctenophores’ place as the sister group to all other animals.

This discovery challenges traditional views of animal evolution, which often placed sponges at the base of the tree due to their simplicity. Unlike sponges, ctenophores possess nerve cells, muscle-like structures, and a unique mode of locomotion driven by rows of cilia. Despite these features, their genomic evidence points to a deeper divergence.

Schultz emphasized the broader significance of these findings: “This research gives us context for understanding what makes animals animals. This work will help us understand the basic functions we all share, like how they sense their surroundings, how they eat, and how they move.”

Previous studies relying on gene sequence comparisons yielded conflicting results. Some concluded that sponges diverged first, while others supported ctenophores. Rokhsar explained the difficulty: “The results of sophisticated sequence-based studies were split. There hasn’t really been any convergence to a definitive answer.”

The use of chromosomal synteny provided clarity where earlier methods failed. The conserved gene patterns revealed by this study suggest that sponges, rather than representing a primitive stage of animal life, are more closely related to other animals like jellyfish and humans than to ctenophores.

Understanding which animals diverged first helps illuminate the evolution of traits like nervous systems, muscles, and multicellularity. Ctenophores’ unique features, including their distinct nerve and muscle systems, suggest these traits may have evolved independently in early animal lineages. This challenges assumptions about the linear progression of complexity in animal evolution.

Bilaterians, the group that includes humans and most other animals with centralized nervous systems and digestive tracts, represent a later evolutionary stage. In contrast, ctenophores and sponges lack many of these features, but they still exhibit the core characteristics of animals, such as multicellular development from a fertilized egg.

The study underscores the power of genomics to solve ancient mysteries. By analyzing the genetic signatures left behind in modern organisms, researchers have taken a profound step toward understanding the origins of animal life.

Schultz noted, “We developed a new way to take one of the deepest glimpses possible into the origins of animal life. This finding will lay the foundation for the scientific community to begin to develop a better understanding of how animals have evolved.”

While the direct ancestors of early animals remain unknown, the insights gained from this research provide a new framework for exploring evolution. As scientists continue to decipher the genetic clues preserved in living species, they inch closer to unraveling the secrets of life’s early history.

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