Octopuses are known to be intelligent, advanced creatures, able to create their own shelter, change color in an instant and even adapt well to climate change.
In a new study, a group of 33 international scientists suggest these unique traits may have an unearthly origin. They investigated the theory that octopuses may have evolved from life forms that came to earth on ancient comets.
This isn’t a new concept. Scientists have been grappling with the origins of life on our planet for centuries. And this study adds an intriguing look into the theory of panspermia, that suggests the evolution of life on Earth has, and continues to be, influenced by the arrival of organisms from space.
The study has faced some criticism, but the scientists have also supported their claims with well-established research. Let’s take a closer look at their findings.
THE THEORY OF PANSPERMIA
In the 1980s, astronomer Fred Hoyle teamed up with astrobiologist Chandra Wickramasinghe to propose that life didn’t originate on earth. In fact, life was seeded on our planet by comets carrying space-hardy bacteria, viruses and perhaps even fertilized eggs and plant seeds. This concept is scientifically known as “panspermia”.
The earliest microbial life found on Earth was discovered in Canadian rocks and is estimated to be about 4.1-4.23 billion years old. This was during the Hadean epoch, when the earth was still forming its core and crust, as well as its atmosphere and oceans. Our planet had frequent and violent collisions with asteroids and comets during that period, and the surface was still extremely hot and unstable.
The study’s researchers propose that it was impossible for life to have formed on Earth during this time. The first microbes found in Canada were most likely delivered by comets and meteorites that impacted with our planet, and these microbes went on to become the basis of terrestrial life on Earth.
WHAT CAN ACTUALLY SURVIVE ON A COMET?
Comet-hopping life forms may sound far-fetched, but research is starting to show this may be a distinct reality. Evidence has found that comets would have contained vast amounts of water in their interiors when they were first formed billions of years ago at the dawn of our solar system. These protected, watery environments would have provided ideal conditions for early bacteria and viruses to grow and multiply.
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The discovery of a wide variety of ancient organic particles in comets also supports this theory. Organic particles are important precursors for the creation of molecules that are the foundation of life, such as sugars, amino acids and DNA bases.
Once comets had cooled down and after millions of years in space, evidence suggests the primitive bacteria and viruses living on them became embedded in rock, carbonaceous material or ice. This effectively protected them from the intense radiation and sub-zero temperatures encountered in space.
Although not proven, it is also possible that more complex life forms, such as fertilized eggs and plant seeds, could also have survived in similar conditions.
Masters of disguise – Mediterranean Octopus
WHAT OCTOPUSES CAN TELL US ABOUT EVOLUTION
Octopuses are actually related to slugs and snails. They belong to a group of mollusks known as cephalopods that developed about 500 million years ago during what’s known as the Cambrian Explosion. This was a time when life in the earth’s oceans went through a dramatic stage of diversification and evolution, and most of the ancestors of modern life were born.
The new study, titled “Cause of the Cambrian Explosion – Terrestrial or Cosmic?”, investigated panspermia and how it may relate to the Cambrian Explosion, and the rise of life forms like octopuses. They made a few important conclusions.
1. Virus-bearing comets fueled the Cambrian Explosion.
Viruses are the smallest living organism on earth, and they reproduce by attaching themselves to a host cell in another living organism and inserting their own genetic material into the cell. This changes the genetic structure of the host cells, which can cause disease in the host.
This also means that a viral infection can alter the host’s genetic code, and potentially change its course of evolution. Retroviruses are a specific type of virus that first appeared and multiplied just before the Cambrian Explosion.
And the researchers believe these retroviruses came from cometary bombardment the Earth was experiencing around the same time. As the comets broke up and left debris trails in the Earth’s atmosphere, dormant retroviruses were released and spread across our planet’s surface.
This wide-spread introduction of new genetic material in the form of viruses affected the development of life in our planet’s oceans, and potentially all land-dwelling life forms that came later.
2. Octopuses appeared too abruptly to have evolved on Earth.
The introduction of interstellar viruses may have increased the genetic diversity of life on our planet, but octopuses have some unique genetic traits that simply don’t make sense from an evolutionary stand point.
Genetically, octopuses are significantly different than most other life forms on Earth. Their large brains, sophisticated nervous systems, flexible bodies and ability to instantly switch color and shape are still very unique compared to other modern life forms.
And these striking traits appeared very suddenly on the evolutionary scene about 270 million years ago. The research group concluded that this sudden “great leap forward” would be impossible in such a short time frame.
“Thus the possibility that cryopreserved squid and/or octopus eggs, arrived in icy bolides several hundred million years ago should not be discounted,” the researchers say.
HOW DOES THIS RELATE TO LIFE ON EARTH TODAY?
We may never know whether or not octopus eggs actually arrived on Earth from outer space, but the theory of panspermia does hold the potential for a radical shift in our world view.
The research group concluded their study by discussing the need to change from our outdated view of life originating exclusively on Earth to one incorporating “cosmic biology,” which recognizes the scientific evidence that life on our planet may have been, and continues to be, influenced by organisms that arrive from outer space.
They also point out the vast number of Earth-like planets and other life-friendly planetary bodies that exist in our galaxy, and the potential for billions of exchanges of material between them through meteorites, cometary bolides and even space dust.
“One is thus forced in our view to conclude that the entire galaxy (and perhaps our local group of galaxies) constitutes a single connected biosphere,” the researchers write.
What do you think? Is Earth part of an intergalactic web of life? Or are we alone in the universe? Please share your thoughts in the comments!
In 2008 the staff at Sea Star Aquarium in Coburg, Germany, had a mystery on their hands. Two mornings in a row, they had arrived at work to find the aquarium eerily silent: the entire electrical system had shorted out. Each time they would reset the system only to find the same eerie silence greeting them the next morning. So on the third night a couple of staff members kept vigil, taking turns to sleep on the floor.
Sure enough the perpetrator was apprehended: Otto, a six-month-old octopus.
He had crawled out of his tank and, using his siphon like a fire hose, aimed it at the overhead light. Apparently it annoyed him or maybe he was just bored. As director Elfriede Kummer told The Telegraph, “Otto is constantly craving for attention and always comes up with new stunts… Once we saw him juggling hermit crabs in his tank”.
Anecdotes of the mischievous intelligence of octopuses abound. Individuals have been reported to solve mazes, screw open child-proof medicine bottles and recognise individual people. Keepers are inclined to give them names because of their personalities.
Problem solving, tool use, planning, personality: these are hallmarks of the complex, flexible intelligence that we associate with back-boned animals, mostly mammals.
But a squishy octopus?
Some researchers who study the octopus and its smart cousins, the cuttlefish and squid, talk about a ‘second genesis of intelligence’ – a truly alien one that has little in common with the mammalian design.
While the octopus has a large central brain in its head, it also has a unique network of smaller ‘brains’ within each of its arms. It’s just what these creatures need to coordinate the mind-boggling complexity of eight prehensile arms and hundreds of sensitive suckers, which provide the octopus with the equivalent of opposable thumbs (roboticists have been taking note). Not to mention their ability to camouflage instantly on any of the diverse backgrounds they encounter on coral reefs or kelp forests. Using pixelated colours, texture and arm contortions, these body artists instantly melt into the seascape, only to reappear in a dazzling display to attract a mate or threaten a rival.
STEVEN TRAINOFF PHD / GETTY IMAGES
“They do things like clever animals even though they’re closely related to oysters,” says neuroscientist Clifton Ragsdale, at the University of Chicago. “What I want to know is how large brains can be organised not following the vertebrate plan.”
So how did evolution come up with this second genesis of intelligence or what film-maker Jacques Cousteau referred to as ‘soft intelligence’ back in the 1970s?
Cousteau inspired many a researcher to try and find answers. But it has been hard to advance beyond Technicolor screenshots and jaw-dropping tales – what zoologist Michael Kuba at Okinawa Institute of Science and Technology (OIST) refers to as “YouTube science”.
For decades the number of octopus researchers could be counted on one hand. They were poorly funded, and their valiant efforts were held in check by notoriously uncooperative subjects and inadequate tools. “You really had to be a fanatic,” says Kuba.
In the last few years, with more and more researchers lured to these enigmatic creatures, the field appears to have achieved critical mass. And these newcomers are the beneficiaries of some powerful new tools. In particular, since 2015 they’ve had the animals’ DNA blueprint, the genome, to pore over. It has offered some compelling clues.
Octopus are famous escape artists.
CARLINA TETERIS / GETTY IMAGES
It turns out the octopus has a profusion of brain-forming genes previously seen only in back-boned animals. But its secret weapon may not be genes as we know them.
A complex brain needs a way to store complex information. Startlingly, the octopus may have achieved this complexity by playing fast and free with its genetic code.
To build a living organism, the decoding of the DNA blueprint normally proceeds with extreme fidelity. Indeed it’s known as ‘the central dogma’. A tiny section of the vast blueprint is copied, rather like photocopying a single page from a tome. That copy, called messenger RNA (mRNA), then instructs the production of a particular protein. The process is as precise as a three-hat chef following her prized recipe for apple pie down to the letter.
But in a spectacular example of dogma-breaking, the octopus chef takes her red pen and modifies copies of the recipe on the fly. Sometimes the result is the traditional golden crusted variety; other times it’s the deconstructed version – apple mush with crumbs on the side.
This recipe tweaking is known as ‘RNA editing’. In humans only a handful of brain protein recipes are edited. In the octopus, the majority get this treatment.
“It introduces a level of sophistication and complexity we never thought of. Perhaps it’s related to their memory,” says Eli Eisenberg, a computational biologist at the University of Tel Aviv. Though he quickly adds, “I must stress this is complete speculation”.
Jennifer Mather, who studies squid and octopus behaviour at the University of Lethbridge in Alberta, Canada, suggests it might go some way to explaining their distinct personalities.
Pigment filled sacs on octopus skin are called chromatophores.
JEAN LECOMTE / GETTY IMAGES
There’s no doubt that linking octopus intelligence to RNA editing is the realm of fringe science. The good news is it’s a testable hypothesis.
Researchers are now gearing up with state-of-the-art tools such as the gene-editing technology CRISPR, new types of brain recorders and rigorous behavioural tests to see whether RNA editing is indeed the key to octopus intelligence.
How did the octopus get so smart?
Some 400 million years ago, cephalopods – creatures named for the fact that their heads are joined to their feet – ruled the oceans. They feasted on shrimp and starfish, grew to enormous sizes like the six-metre long Nautiloid, Cameroceras, and used their spiral-shaped shells for protection and flotation.
Then the age of fishes dawned, dethroning cephalopods as the top predators. Most of the spiral-shelled species became extinct; modern nautilus was one of the few exceptions.
But one group shed or internalised their shells. Thus unencumbered, they were free to explore new ways to compete with the smarter, fleeter fish. They gave rise to the octopus, squid and cuttlefish – a group known as the coleoids.
Their innovations were dazzling. They split their molluscan foot, creating eight highly dexterous arms, each with hundreds of suckers as agile as opposable thumbs. To illustrate this dexterity, Mather relates the story of a colleague who found his octopus pulling out its stitches after surgery.
But those limber bodies were a tasty treat to fish predators, so the octopus evolved ‘thinking skin’ that could melt into the background in a fifth of a second. These quick-change artists not only use a palette of skin pigments to paint with, they also have a repertoire of smooth to spiky skin textures, as well as body and arm contortions to complete their performance – perhaps an imitation of a patch of algae, as they stealthily perambulate on two of their eight arms.
“It’s not orchestrated by simple reflexes,” says Roger Hanlon, who researches camouflage behaviour at the Marine Biological Laboratory in Woods Hole, Massachusetts. “It’s a context-specific, fast computation of decisions carried out in multiple levels of the brain.” And it depends critically on a pair of camera eyes with keen capabilities.
It takes serious computing power to control eight arms, hundreds of suckers, ‘thinking skin’ and camera eyes. Hence the oversized brain of the octopus. With its 500 million neurons, that’s two and a half times that of a rat. But their brain anatomy is very different.
A mammalian brain is a centralised processor that sends and receives signals via the spinal cord. But for the octopus, only 10% of its brain is centralised in a highly folded, 30-lobed donut-shaped structure arranged around its oesophagus (really). Two optic lobes account for another 30%, and 60% lies in the arms. “It’s a weird way to construct a complex brain,” says Hanlon. “Everything about this animal is goofy and weird.”
Take the arms: they’re considered to have their own ‘mini-brain’ not just because they are so packed with neurons but because they also have independent processing power. For instance, an octopus escaping a predator can detach an arm that will happily continue crawling around for up to 10 minutes.
Indeed, until an experiment by Kuba and colleagues in 2011, some suspected the arms’ movements were independentof their central brain. They aren’t. Rather it appears that the brain gives a high-level command that a staff of eight arms execute autonomously.
“The arm has some fascinating reflexes, but it doesn’t learn,” says Kuba, who studied these reflexes between 2009 and 2013 as part of a European Union project to design bio-inspired robots.
And then there’s their ‘thinking’ skin. Again the brain, primarily the optic lobes, controls the processing power here. The evidence comes from a 1988 study by Hanlon and John Messenger from the University of Sheffield. They showed that blinded newly hatched cuttlefish could no longer match their surroundings.
KELLY MURPHY ILLUSTRATION
They were still able to change colour and body patterns but in a seemingly random fashion. Anatomical evidence also shows that nerves in the lower brain connect directly to muscles surrounding the pigment sacs or chromatophores.
Like an artist spreading pigment on a pallet, activating the muscles pulls the sacs apart spreading the chromatophore pigments into thin discs of colour. But the octopus is not composing a picture. Hanlon’s experiments with cuttlefish show they are deploying one of three pre-existing patterns – uniform, mottled or disruptive – to achieve camouflage on diverse backgrounds.
As far as detailed brain circuitry goes, researchers have made little progress since the 1970s when legendary British neuroscientist J.Z Young worked out the gross anatomy of the distributed coleoid brain. Escaping Britain’s dismal winter for the Stazione Zoologica in balmy Naples, Young’s research was part of an American Air Force funded project to search for the theoretical memory circuit, the ‘engram’.
“They were ahead of their time,” says Hanlon, who experienced a stint with Young in Naples. Nevertheless they were limited by the paucity of brain-recording techniques that were suited to the octopus.
It’s a problem that has continued to hold back the understanding of how their brain circuits work. “Is it the same as the way mammals process information? We don’t know,” says Ragsdale.
Unwilling subjects
It’s not for want of trying, as Kuba will tell you. In the 1990s, he joined the lab of neuroscientist Binyamin Hochner at the Hebrew University of Jerusalem. Hochner was a graduate of Eric Kandel’s lab, the Nobel laureate who pioneered studies on how the sea slug Aplysia learns.
All the action takes place in the gaps between individual neurons, the ‘synapse’. The synapse may look like an empty gap under the microscope but it’s a crowded place. It’s packed with over 1,000 proteins that assemble into a pinpoint-size microprocessor. If each neuron is like a wire, it’s up to this microprocessor to decide whether the signal crosses over from one wire to the next. When the sea slug learns a lesson, for instance withdrawing its gill in response to a tail shock, that’s because new computations at the synapse rerouted the connections.
Kuba, however, found an octopus to be far less obliging than a sea slug. Whatever electrical probe he stuck into its brain was rapidly removed thanks to all those opposable thumbs. Ragsdale also had his share of frustration. “We have a technical problem with sharp electrodes. For example, if you put an electrode into the optic lobe, the neurons will fire for about 10 to 20 minutes and then become silent.”
Kuba, who is now based at the Okinawa Institute of Science and Technology, hopes that a new kind of miniature brain logger that sits on the surface of the brain, hopefully out of reach of prying suckers, will kick-start the era of octopus brain-circuit mapping.
“There’s a lot of technical challenges, but they are surmountable,” agrees Ragsdale.
The irony is that the first insights into how the vertebrate brain sends signals came from a squid. In 1934 Young identified a giant squid nerve cell that controlled the massive contractions of its mantle, the bulbous muscular sac behind the eyes that both houses the organs and squeezes water through the siphon with such great effect!
Like mammalian neurons, the most distinctive feature of the squid cell was its wire-like axon, but with a diameter of around one millimetre, it was 1,000 times fatter than those of mammals. The colossal size allowed researchers to insert a metal electrode and measure the changing electrical voltage as a nerve impulse travelled along the axon.
All this foundational knowledge shed light on vertebrate brains, but the detailed circuitry of the squid brain was largely left in the dark.
Octopus are body artists that use skin colour, texture and arm contortions for their disappearing acts.
ULLSTEIN BILD / GETTY IMAGES
Breaking the central dogma
It was another frustrated neuroscientist who opened the latest front into the understanding of soft intelligence.
In the early 1990s, Josh Rosenthal, based at William Gilly’s lab at Stanford, was making use of the time-honoured giant squid motor axon. But with a new purpose. Rather than measure its electrical properties, Rosenthal wanted to isolate one of its key components: the ‘off’ switch. It is a protein called the potassium channel.
The squid neuron made this protein according to a recipe carried by its DNA blueprint, which is cached in the cell’s nucleus. To access the recipe, the cell makes a mRNA transcript, rather like transcribing a single recipe from a recipe book. Rosenthal wanted to isolate these transcripts and read the code sequence for the protein channels.
But he had a problem. Every time he read the sequence for the potassium channel, it was slightly different. Was it just an error? If so, it was highly consistent. The changes were not random. They always occurred at one or more precise positions in the code. And, invariably, the letter A was always changed to the letter G.
For instance, imagine a recipe for apple pie was supposed to read: Place the crust around the pie. Instead it was being edited to: Place the crust ground the pie. Such a change might instruct the modern-day deconstructed apple pie rather than the traditional crusted version.
Unbeknownst to Rosenthal, Peter Seeburg at the University of Heidelberg was puzzling over a similar glitch in a recipe for a human brain protein, the glutamate receptor. When Seeburg’s paper was published in 1991, Rosenthal recalls, “everyone got excited”.
Clearly editing brain recipes was important for humans and squid. But why?
In the human (or mouse), editing the glutamate receptor changed how much calcium could flow into brain cells. In mice, failure to edit was lethal, as it allowed toxic levels of calcium to stream in. There’s also evidence that failure to edit the same receptor in humans is associated with the neurodegenerative disease Amyotrophic Lateral Sclerosis.
An enzyme called ADAR2 carried out these crucial edits to the RNA recipe. Just why evolution hasn’t gone ahead and ‘fixed’ the DNA source code of the glutamate receptor remains a mystery.
As for the squid potassium channel, Rosenthal had a hunch. After an electrical signal has passed through a neuron, it needs a ‘reset’ for the next signal. The potassium channel plays a crucial part. In cold temperatures, the reset might take longer, making the animal a bit sluggish. Could RNA editing be a way of fine tuning the system in response to temperature? Rosenthal tested his idea by spending several years collecting octopuses that live in either tropical, temperate or polar climates. It was indeed the polar octopuses that were the most avid editors of their potassium channels.
Potassium channels turned out to be just the tip of the iceberg. Rosenthal teamed up with computation geek Eli Eisenberg at Tel Aviv University to trawl through mRNA databases and find out just how much recipe tweaking was going on with squid genes. In humans, tweaking is rare – restricted to a handful of brain gene recipes. In the squid, the majority of brain recipes received this treatment. Many of them were related to proteins found at the synapses, the microprocessors for memory and learning.
Could this extemporising with brain protein recipes be important for soft intelligence? It’s a tantalising idea. “Coleoids show it. Nautilus – the stupid cousin – does not, it’s like any other mollusc,” says Eisenberg.
“Coleoids are editing the same proteins that we know are involved in learning and memory. By editing them or not, it’s not a stretch to hypothesise that they are adding flexibility and complexity to the system,” says Rosenthal.
Cuttlefish have an impressive capacity to learn. These Australian giants are learning about the birds and the bees at Whyalla, South Australia.
WILDESTANIMAL / GETTY IMAGES
Clues from the blueprint
Over in Chicago, Cliff Ragsdale, another frustrated octopus neuroscientist, was also turning his interest to octopus DNA.
In 2015, working with Daniel Rokhsar and Oleg Simakov of OIST, the Ragsdale laboratory managed to read the genome of the California two-spot octopus.
It turns out that the octopus has more genes that we do: 33,000 compared to our 21,000. But gene number per se doesn’t bear much relation to brain power: water fleas also have about 31,000. In fact most of the genes in the octopus catalogue were not all that different to those of its close relative – the limpet, a type of sea snail. But there were two gene families that stood out like a sore thumb. One was a family of genes called protocadherins. This family of ‘adhesion’ proteins are known to build brain circuits. Like labels on the tips of growing neurons, they allow the correct types of neurons to wire to each other — so neuron 370 connects up to neuron 471 at the right time and the right place. Limpets and oysters have between 17-25 types of protocadherins. Vertebrates have 70 types of protocadherins plus over 100 different types of related cadherins. These circuit builders have long been thought to be the key to vertebrate braininess.
So it was stunning to find that the octopus has a superfamily of 168 protocadherins. Ragsdale says the squid genome, also now being sequenced, shows it is similarly equipped with hundreds of circuit-building genes.
The other stand-out in the octopus genome was a family of genes called ‘zinc fingers’. They get their name because the encoded proteins have a chain structure that is cinched by zinc atoms into a series of fingers. These fingers poke into the coils of DNA to regulate the transcription of genes.
Limpets have about 413 of these zinc fingers. Humans have 764. Octopuses have 1,790! Perhaps this profusion of octopus zinc fingers is involved in regulating the network of brain genes?
COSMOS MAGAZINE
So far, the octopus has revealed three big clues as to how it generates brain complexity: it has multiplied its set of circuit-building protocadherin genes and its network-regulating zinc fingers. It has also unleashed RNA editing to generate more complexity on the fly.There may also be a fourth mechanism at work.
Genes are supposed to stay put. But ‘jumping genes’, which are closely related to viruses, have a tendency to up anchor and insert themselves into different sections of the DNA code. That can scramble or otherwise change its meaning. Imagine if the words ‘jumping gene’ just started appearing randomly in this text. Fred Gage’s group at the Salk Institute in San Diego has found that during the development of the nervous system in mice and humans, jumping genes start jumping.
What this means is that each individual brain cell ends up with slightly different versions of its DNA code. Gage speculates that this may be a way to generate diversity in the way neurons wire up. Perhaps it goes some way to explaining why twins, born with the same DNA, nevertheless end up with different behaviours.
“If you believe that theory,” says Ragsdale, “you’ll be struck by the fact that we also found a high number of jumping genes active in the brain tissues of the octopus.” Testing the theory
Unravelling the details of how octopus and squid are using and abusing the genetic code is generating iconoclastic hypotheses about how they generate their complex brain circuitry.
And researchers are not blind to the problems of dogma-breaking. For one thing, playing fast and free with the genetic code creates an astronomical number of possible proteins, most of which would be toxic to the animal, says Eisenberg. “It’s very troubling; one hypothesis is that this may explain their short lifespan of one to three years.”
Troubling or not, Rosenthal and colleagues at Woods Hole are moving full speed ahead to test the role of RNA editing in the coleoids by bringing together researchers with different expertise. “There’s a lot of moving pieces,” says Rosenthal.
For starters, their Woods Hole team is cultivating four species of small squid and cuttlefish that reach sexual maturity in two to three months. The goal is to manipulate the squid’s genes using the genetic engineering tool, CRISPR. To see if they can get CRISPR working, they will try to ‘knock-out’ the pigment genes. If they’re successful they should see the result on the squid bodies. “It’s a beautiful in-built test,” says Rosenthal.
If that works, they will try the big experiment. Does impairing the ability to edit proteins at the synapse (by knocking out the ADAR2 gene responsible for RNA editing) tamper with learning and memory?
Meanwhile, collaborator Alex Schnell, a behavioural biologist based at the University of Cambridge in the UK, is developing rigorous tests for complex learning and memory in cuttlefish. In particular, she is testing their capacity for “episodic memory”, a detailed weaving together of memories once thought to be a strictly human attribute.
For instance, it’s thanks to your episodic memory that you recall exactly where you were and what you were doing on 11 September 2001. Since the late 1990s, we know that animals like great apes, crows and jays also have that capacity. Maybe cuttlefish do too. Schnell’s initial results show that cuttlefish can learn and memorise complex information about their favourite food, such as when and where it is likely to be found.
With other teams around the world pursuing similar strategies, it seems likely that after decades of awe and wonder, the mystery of soft intelligence may soon yield to hard science.
[Back on October 4th I posted about the New rule banning octopus hunting in Seattle because of the public outcry when a diver killed a 6 foot “specimen” and left it clearly displayed in the back of his truck (like a wolf in Jackson Hole). Then on October 14th, the New York Times ran an absurdly-titled article praising the killer, while disparaging the people who called for an end to octopus hunting in Puget Sound (who were ultimately successful).
I’m not going to include the entire article (hell, I’m not even going to read it all), since it goes on for 4 or 5 pages, but here’s the first page so you can see how feebly the media sucks up to animal killers these days]:
In the months leading up to the hunt, Dylan Mayer trained twice a week in his parents’ swimming pool, asking friends to attack him, splay their arms and grab him, drag him to the surface and shove him below it, pull off his mask, snatch his regulator, time his recovery. By last Halloween, he was ready, and as the light began to fade that afternoon, the broad-shouldered 19-year-old jumped into a red Ford pickup truck with his buddy and drove some 40 minutes from Maple Valley, Wash., to West Seattle. They arrived at Alki Beach around 4 p.m., put on their wet suits and ambled into Cove 2. Then they slipped into Elliott Bay, the Space Needle punctuating the city line in the distance like an inverted exclamation point.
Dylan Mayer holding the giant Pacific octopus that he caught in Puget Sound.
Under the dark water, the teenagers looked around with the help of a diving light. At 45 feet, they passed a sunken ship, the Honey Bear, and at 85 feet, beneath the buoy line, they saw further evidence of the former marina — steel beams, pilings and sunken watercraft. Marine life thrived in this haven of junk, and for this reason, Cove 2 was a popular dive site. According to the permit he had just purchased at Walmart, Mayer was allowed to catch this sea life and cook it, which is exactly what he set out to do. He wasn’t much of a chef, but he had experience foraging for his dinner. Mayer had attended a high school known for its Future Farmers of America program; he also knew how to slaughter cows and castrate bulls. Now he was going to community college, where he was asked to draw something from nature. He figured that he might as well eat it too. And as he scanned the bay, he could already imagine searing the marine morsels on high heat and popping them, rare and unctuous, into his mouth. He soon spotted his prey. “That’s a big [expletive] octopus,” he scribbled on his underwater slate.
The giant Pacific octopus was curled inside a rock piling, both its color and texture altered by camouflage. Mayer judged it to be his size, about six feet, and wondered if he could take it on alone. He lunged at the octopus, grabbing one of its eight arms. It slipped slimily between his fingers, its suckers feeling and tasting his hand. He reached for it again, and again it retreated. Able to squeeze its body through a space as small as a lemon, the octopus was unlikely to succumb to his grip. He poked it with his finger and watched it turn brighter shades of red, until finally, it sprang forward and revealed itself to be a nine-foot wheel charging through the water.
The octopus grabbed Mayer where it could, encircling his thigh, spiraling his torso, its some 1,600 suckers — varying in size from a peppercorn to a pepper mill — latching onto his wet suit and face. It pulled Mayer’s regulator out of his mouth. His adrenaline rising, he punched the creature, and began a wrestling match that would last 25 minutes.
Eventually, he managed to pull the animal to the surface, where a number of divers couldn’t help noticing a teenager punching an 80-pound octopus. As they approached, Mayer freaked out. “Let’s get out of here,” he said, sucker marks ringing his face. “Maybe we shouldn’t have done this.” But it was too late. He dragged his kill ashore, where a few bystanders, in disbelief, took his picture and threatened to report him. Lugging the octopus to the red truck, Mayer cited his permit. But the divers kept taking pictures. That night, as Mayer butchered the octopus for dinner, they posted the photos online.
In a city finely attuned to both the ethics of food sourcing and poster-worthy animal causes (the spotted owl, the killer whale and marbled murrelet among them), Mayer’s exploits became an instant cause célèbre. On Nov. 1 and 2, Seattle’s competing news stations reported the octopus hunt. The next day, The Seattle Times ran the story on the front page. On Web forums, Seattleites tracked down the teenager’s name and address through the clues in the photos: the truck’s license plate, the high school named on Mayer’s sweatshirt and the inspection sticker affixed to his tank. “I hope this sick [expletive] gets tangled in a gill net next time he dives and thus removes a potential budding sociopath before it graduates from invertebrates to mammals,” read one typical comment, which received 52 “thumbs-ups.” Around the same time, Scott Lundy, one of the men who had confronted Mayer in Cove 2, issued a “Save the G.P.O.” petition to ban octopus harvesting from the beach and examine the practice statewide. By the next day, he had collected 1,105 signatures.
SEATTLE – A new rule making it illegal to hunt and kill giant Pacific octopuses at more than a dozen Puget Sound dive sites takes effect this weekend.
The Washington Department of Fish and Wildlife (WDFW) says the new rule provides more protection for the species and comes nearly a year after a scuba diver legally captured and killed one off Alki Point in West Seattle. That incident sparked a huge public outcry – prompting the WDFW to consider new harvesting regulations.
This past summer, the Washington Fish and Wildlife Commission voted to ban all recreational harvesting of giant Pacific octopuses at the following seven sites:
Deception Pass north of Oak Harbor
Seacrest Park Coves 1, 2 and 3 near Alki Point in West Seattle
Alki Beach Junk Yard in West Seattle
Three Tree Point in Burien
Redondo Beach in Des Moines
Les Davis Marine Park adjacent to the Les Davis Fishing Pier in Tacoma
Exposing the Big Game 
