A Model Organism Advancing Research in Genomics and Behavioral Science

(This post has been updated with new research on octopus neurology.)

While diving along the California coastline, spotting a California two-spot octopus is a rare and memorable experience. Nestled in rocky crevices or hidden among kelp, these octopuses are easily identified by their distinctive blue “eye-spots,” which are not actual eyes but mimicry patterns used to confuse predators. Such encounters provide a fascinating glimpse into the behavior of this remarkable marine species.

The California two-spot octopus (Octopus bimaculoides), found from Central California to Baja, is a master of adaptation. Its chromatophores—specialized skin cells—allow it to change color and pattern with precision, enabling camouflage, communication, and courtship displays. This ability, paired with its intelligence and problem-solving skills, highlights the octopus’s unique place in the marine ecosystem and makes it a subject of keen scientific interest.

The California two-spot octopus, Octopus bimaculoides, is a marine creature that not only captivates with its intelligence but also serves as a window into the complex tapestry of cephalopod behavior and genomics.

Their behavior is an orchestra of complexity; they are solitary creatures, favoring a reclusive life, with the exception of mating. Research has shown that they have a keen ability to learn and navigate mazes, unscrew jars, and engage in play, indicating a level of intelligence that is quite remarkable for an invertebrate. 

The study of octopus intelligence, characterized by their remarkable problem-solving abilities and behavioral sophistication, has profound implications for our understanding of intelligence as a biological phenomenon. Octopuses, having diverged from the lineage that would lead to humans around 600 million years ago, share a common ancestor with us that was likely a simple, multicellular organism, a primitive flatworm. This vast evolutionary gulf highlights the fact that octopus intelligence developed along a trajectory entirely distinct from our own. Their decentralized nervous systems, capable of independently operating limbs and complex reflex actions, challenge the mammalian-centric view of brain-body coordination and cognitive processing, suggesting that intelligent behavior can arise from a variety of neural architectures.

Unlike humans and other vertebrates, where neural control is centralized in the brain, over two-thirds of this octopus’s neurons are located in its arms. This decentralized system allows each arm to function with remarkable independence, capable of exploring, tasting, and manipulating its environment without direct input from the brain. Recent studies reveal that octopus arm neurons are arranged in segmented clusters, enabling precise control of movement and the coordination of its powerful suckers. This unique adaptation not only enhances their hunting efficiency but also underscores the intricate evolutionary design of these intelligent marine creatures.

If you haven’t seen it yet, I highly recommend YouTuber Mark Rober’s recent video on octopus intelligence. His pet octopus Sashimi is a California Two Spot Octopus.

https://youtu.be/7__r4FVj-EI

The ability of octopuses to adapt their skin color and texture in real-time, for purposes ranging from camouflage to communication, is a further testament to their cognitive prowess. This capability is controlled not just by their brains, but by the network of nerve cells spread across their body discussed above, showcasing a form of distributed intelligence. It indicates that cognition can be more holistic than previously thought, involving complex interactions between an organism’s nervous system and its environment. These findings prompt a reevaluation of intelligence, proposing that it is not a single trait but rather a spectrum of abilities that can manifest in diverse forms across different species.

Recent discoveries have shown the animal’s remarkable ability to actually see with its skin. A University of California at Santa Barbara study found that the skin of the California two-spot octopus can sense light even without input from the central nervous system. The animal does so by using the same family of light-sensitive proteins called opsins found in its eyes (and ours) — a process not previously described for cephalopods. The researchers’ findings appeared in the Journal of Experimental Biology.

The independent evolutionary path of octopus intelligence highlights the remarkable plasticity and adaptability of cognitive systems. It implies that intelligence can evolve under a variety of ecological pressures and life histories. In the case of the octopus, their short lifespans and lack of social structures, which are generally seen as drivers of intelligence in vertebrates, have not prevented them from developing complex behaviors and learning capacities. This independence suggests that intelligence is not a linear or singular progression but a trait that can emerge in multiple forms across the tree of life, shaped by the specific challenges and opportunities an organism faces in its niche.

The California Two-Spot Octopus is increasingly recognized as a valuable model organism for scientific research due to its unique biology and evolutionary position. New studies, particularly in the field of genomics using the genome of the California Two Spot octopus, have unveiled the vastness of the octopus’s genetic blueprint. Its sequenced genome provides an unparalleled resource for studying cephalopod-specific innovations, including their advanced nervous systems, remarkable cognitive abilities, and capacity for complex behaviors such as camouflage and problem-solving. As a model organism, the two-spot octopus enables researchers to explore fundamental questions about neural development, learning, and adaptation in animals, offering insights that extend to broader biological and evolutionary contexts. The genome’s wealth of information, including expanded gene families linked to neural function and adaptive traits, makes this octopus an ideal subject for addressing critical questions in genomics, neurobiology, and evolutionary biology.

Their genome is large and contains a greater number of genes than that of a human, with a massive proliferation of gene families associated with neural development hinting at the biological underpinnings of their brainpower and behavior. These genetic insights could explain not only their sophisticated nervous systems but also their adaptability and the evolution of their unique traits.

For the California science enthusiast, the two-spot octopus represents not just a local marine inhabitant but also a subject of profound scientific intrigue. The more we delve into their world, the more we uncover about the possibilities of life’s evolutionary paths. Their genomic complexity challenges our understanding of intelligence and consciousness, making them not just a marvel of the deep but a mirror reflecting the enigma of life itself.