Giant Pacific octopuses avoid predation by remaining in a protective den, camouflaging itself, or hiding among kelp. Although juveniles are eaten by a variety marine life, adult giant Pacific octopuses have few predators other than humans, which have hunted this species to use as food and as bait for Pacific halibut. Giant Pacific octopuses are known for their ability to release an ink cloud, although they rarely do so as a direct form of defense. Instead, they tend to fight off predators with their arms. Once released, they use their propulsion abilities to jet away. As giant Pacific octopuses escape, they then expel a cloud of ink as a screen, allowing them to seek safe refuge.
Known Predators:
Anti-predator Adaptations: cryptic
Giant Pacific octopuses are larger than any other species of octopus. Specimens have weighed as much as 272 kg and measured 9.6 m in radius. However, most reach an average weight of 60 kg with a dorsal mantle length of 50 to 60 cm. Giant Pacific octopuses are usually reddish in color but are able to change color and texture when threatened or for camouflage. The dorsal mantle is shaped like a sack and contains the brain, reproductive organs, digestive organs, and eyes. Giant Pacific octopuses have two eyes, one on each side of their head, which provide extremely acute vision. Giant Pacific octopuses also have four pairs of arms that extend from the mantle. Each pair is covered with up to 280 suckers, which contain thousands of chemical receptors.
Average mass: 60 kg.
Other Physical Features: ectothermic ; bilateral symmetry
Giant Pacific octopuses on average live 4.5 to 5 years in the wild. A similar lifespan has been observed for members this species held in public aquariums.
Average lifespan
Status: wild: 4.5 to 5 years.
Average lifespan
Status: captivity: 4.5 to 5 years.
Giant Pacific octopuses are generally found in tidal pools and up to depths of 110 m, although they can also reside in deeper waters of up to 1,500 m. They often live in dens or lairs, under boulders, and in rock crevices. Ideal habitat for this species includes a soft substrate of mud, sand or gravel that includes large boulders for creating dens. Giant Pacific octopuses are found in greater densities near dense kelp fields. Members of this species are ectothermic, and their metabolism is dependent upon water temperature. Optimal water temperatures for giant Pacific octopuses range between 7 and 9.5 degrees Celsius.
Range depth: 0 to 1500 m.
Habitat Regions: saltwater or marine
Aquatic Biomes: benthic ; coastal
Each pair of arms of giant Pacific octopuses has up to 280 suckers, which have thousands of chemical receptors. These provide an acute sense of touch and taste, which this species use to help detect prey. Typically calm animals, giant Pacific octopuses are unusually adept at navigating by using landmarks in the wild and at adapting objects as tools. They are the only invertebrate known to use their well-developed vision to learn through observation. Giant Pacific octopuses are considered extremely intelligent, partially do to their larger-than-average brain-to-body weight ratio. Individuals in captivity are known for having having unique temperaments and personalities, ranging from playful to destructive. Their high level of intelligence and desire to interact with human caretakers have earned captive members of this spices a reputation as notorious escape artists.
Perception Channels: visual ; tactile ; chemical
Giant Pacific octopuses are not considered at risk by the IUCN Red List, CITES, or the US Federal List of Endangered Species. Although this spices is commercially fished in some areas, this does not appear to be greatly affecting population sizes.
US Federal List: no special status
CITES: no special status
The lifespan of giant Pacific octopuses is characterized by a fast growth period that continues throughout its entire life of 4 to 5 years. Larvae hatch from a cluster of eggs and are on average 9.5 to 10.1 mm in length. The larvae, with limited swimming ability, move to the surface to begin a planktonic existence that lasts 1 to 3 months. At the end of the planktonic stage, juveniles descend to the benthos where they undergo rapid growth. Giant Pacific octopuses continue to grow until they reproduce. Within 3 months of breeding, males normally undergo a period of senescence and die. Symptoms of senescence in this species include reduced food intake, retraction of skin around the eyes, aimless movement (wandering) and lesions that do not heal. Females that survive brooding undergo a similar period of senescence and die within weeks of the eggs hatching.
There are no known adverse effects of giant Pacific octopuses on humans.
Giant Pacific octopuses were commonly used as bait for Pacific halibut during the late 1950s and 1960s, though this is no longer a common practice. In some ares, this species is commercially fished and is eaten in some countries in the Pacific.
Positive Impacts: food
Giant Pacific octopuses do not specialize on any one particular species of prey and are not the main source of food for any particular predator. They do, however, serve as host to some dicyemid mesozoans. Dicyemennea nouveli is a large, conical-shaped species that reaches up to 12,000 um in length. Dicyemennea nouveli inserts the pointed anterior end of its body into the folds of the renal appendages of giant Pacific octopuses. Other members of g. Dicyemennea are also found in shallow-water cephalopods.
Commensal/Parasitic Species:
Giant Pacific octopuses are considered generalist foragers. They return to their den in order to consume their prey, and they deposit the prey's remains at the entrance of their den. This collection of skeletal remains is known as a middens. Examination of middens indicates that the diet of giant Pacific octopuses is primarily composed of clams, crabs, fish, and squid. Giant Pacific octopuses are visual hunters that utilize a variety of hunting strategies including stalking, chasing, and camouflaging themselves in order to ambush prey. They possesses a well-developed sense of vision, allowing them to coordinate the use of all eight arms to attack their victim. Members of this species also use different methods to prepare meals for consumption. One method includes pulling the protective shell apart in order to reach the meat contained inside. Another method involves crushing prey with their strong beak located in the center of its appendages. The most common method of obtaining food, however, involves drilling a hole in the prey's shell, in which an octopus injects its toxic saliva.
Animal Foods: fish; mollusks; aquatic crustaceans
Primary Diet: carnivore (Molluscivore )
Giant Pacific octopuses, Enteroctopus dofleini, are found throughout the Pacific Ocean. They have been documented as far north as the Alaskan Aleutian Islands and as far south as the Baja California region of Mexico. This species ranges as far northeast as Japan.
Biogeographic Regions: pacific ocean (Native )
Male reproductive organs of great Pacific octopuses are enclosed inside the mantle cavity within a genital bag. Spermatozoa are encapsulated in a spindle-shaped spermatophoric sac. Males utilizes a hectocotylized arm, a specialized tentacle used for the transfer of sperm, to insert the two spermatophores (each 1 m in length) into an oviduct located in the mantle of the female. The balloon part of the spermatophore remains inside the oviduct while the remainder of the sac hangs from the female. Eventually, the sac bursts and releases millions of spermatozoa. The entire mating process takes 2 to 3 hours. Giant Pacific octopuses are polygynous.
Mating System: polygynous
Giant Pacific octopuses breed throughout the year, though spawning peaks in winter. Males may breed with several females, but females mate only once in their lifetime. Over several days, females lay 20,000 to 100,000 rice-shaped eggs (avg. 50,000) in grape-like clusters of 200 to 300 eggs each. These clusters are hung from the ceiling of the den. Females remain with the eggs throughout the entire brooding period, guarding them from predators and using her syphon to aerate and clean the clusters. Hatching can take anywhere from 150 days to almost 1 year depending on water temperature. Cooler temperatures delay the development of the embryo and therefore lengthen incubation time.
Breeding interval: Male giant Pacific octopuses may breed with several females once reaching maturity, but females mate only once in their lifetime.
Breeding season: Giant Pacific octopuses breed year-round.
Range number of offspring: 20,000 to 100,000.
Average number of offspring: 50,000.
Average time to independence: 0 minutes.
Range age at sexual or reproductive maturity (female): 3 to 5 years.
Range age at sexual or reproductive maturity (male): 3 to 5 years.
Key Reproductive Features: semelparous ; year-round breeding ; sexual ; fertilization (Internal ); broadcast (group) spawning; oviparous
Female giant Pacific octopuses remain with their eggs throughout the entire brooding period, guarding them from predators and using their syphon to aerate and clean the clusters. Females do not leave the den during this period, not even to eat. Females die during the brooding period or shortly thereafter, and males die within three months of breeding. Therefore, there is no post-hatching parental investment evident in giant Pacific octopuses.
Parental Investment: pre-hatching/birth (Provisioning: Female, Protecting: Female)
The giant Pacific octopus (Enteroctopus dofleini), also known as the North Pacific giant octopus, is a large marine cephalopod belonging to the genus Enteroctopus. Its spatial distribution includes the coastal North Pacific, along Mexico (Baja California), The United States (California, Oregon, Washington, and Alaska), Canada (British Columbia), Russia, Eastern China, Japan, and the Korean Peninsula.[3] It can be found from the intertidal zone down to 2,000 m (6,600 ft), and is best adapted to cold, oxygen-rich water. It is the largest octopus species, based on a scientific record of a 71-kilogram (157-pound) individual weighed live.[4]
The specific name dofleini was chosen by Gerhard Wülker in honor of German scientist Franz Theodor Doflein.[5] It was moved to genus Enteroctopus by Eric Hochberg in 1998.[6][7][8]
E. dofleini is distinguished from other species by its large size. Adults usually weigh around 15 kg (33 lb), with an arm span up to 4.3 m (14 ft).[9] The larger individuals have been measured at 50 kg (110 lb) and have a radial span of 6 m (20 ft).[3] American zoologist G. H. Parker found that the largest suckers on a giant Pacific octopus are about 6.4 cm (2.5 in) and can support 16 kg (35 lb) each.[3] The alternative contender for the largest species of octopus is the seven-arm octopus (Haliphron atlanticus) based on a 61-kilogram (134-pound) incomplete carcass estimated to have a live mass of 75 kg (165 lb).[10][11] However, a number of questionable size records would suggest E. dofleini is the largest of all octopus species by a considerable margin,[12] including a report of one up to 272 kg (600 lb) in weight with a 9-metre (30-foot) arm span.[13] Guinness World Records lists the biggest as 136 kg (300 lb) with an arm span of 9.8 m (32 ft).[3][14] A UN catalog of octopuses sizes E. dofleini at 180 kg (400 lb) with an arm length of 3 m (9.8 ft).[15]
E. dofleini preys upon shrimp, crabs, scallop, abalone, cockles, snails, clams, lobsters, fish, squid, and other octopuses.[16][17][18] Food is procured with its suckers and then bitten using its tough beak of chitin. It has also been observed to catch spiny dogfish (Squalus acanthias) up to 1.2 m (4 ft) in length while in captivity.[19] Additionally, consumed carcasses of this same shark species have been found in giant Pacific octopus middens in the wild, providing strong evidence of these octopuses preying on small sharks in their natural habitat.[20] In May 2012, amateur photographer Ginger Morneau was widely reported to have photographed a wild giant Pacific octopus attacking and drowning a seagull, demonstrating that this species is not above eating any available source of food within its size range, even birds.[21]
Scavengers and other organisms often attempt to eat octopus eggs, even when the female is present to protect them. Giant Pacific octopus paralarvae are preyed upon by many other zooplankton and filter feeders. Marine mammals, such as harbor seals, sea otters, and sperm whales depend upon the giant Pacific octopus as a source of food. Pacific sleeper sharks are also confirmed predators of this species.[22] In addition, the octopus (along with cuttlefish and squid) is a significant source of protein for human consumption. About 3.3 million tonnes (3.6 million short tons) are commercially fished, worth $6 billion annually.[3] Over thousands of years, humans have caught them using lures, spears, pot traps, nets, and bare hands.[23] The octopus is parasitized by the mesozoan Dicyemodeca anthinocephalum, which lives in its renal appendages.[24]
The giant Pacific octopus is considered to be long-lived compared to other species, with lifespans typically 3–5 years in the wild. Many other octopuses go through a complete life cycle in one year, from egg to end of life.[3] To help compensate for its relatively short lifespan, the octopus is extremely prolific. It can lay between 120,000 and 400,000 eggs which are coated in chorion, and attached to a hard surface by the female. The spawn is intensively cared for exclusively by the female, who continuously blows water over it and grooms it to remove algae and other growths. While she fulfills her duty of parental care the female stays close to her spawn, never leaving to feed, leading to her death soon after the young have hatched.[25] The female's death is the result of starvation, as she subsists on her own body fats[26] during this period of approximately 6 months.[23] Hatchlings are about the size of a grain of rice,[27] and very few survive to adulthood. Their growth rate is quite rapid: starting from 0.03 g (0.0011 oz) and growing to 20–40 kg (44–88 lb) at adulthood, which is an increase of around 0.9% per day.[3] Because they are cool-blooded, they are able to use most of their consumed energy for body mass, respiration, physical activity, and reproduction.[23] During reproduction, the male octopus deposits a spermatophore (or sperm packet) more than 1 m (3.3 ft) long using his hectocotylus (specialized arm) in the female's mantle. Large spermatophores are characteristic of octopuses in this genus.[12] The female stores the spermatophore in her spermatheca until she is ready to fertilize her eggs. One female at the Seattle Aquarium was observed to retain a spermatophore for seven months before laying fertilized eggs.[23]
Unlike males, only the female giant Pacific octopuses are semelparous, meaning they only breed a single time in their life.[26] After reproduction, they enter a stage called senescence, which involves obvious changes in behavior and appearance, including a reduced appetite, retraction of skin around the eyes giving them a more pronounced appearance, increased activity in uncoordinated patterns, and white lesions all over the body. While the duration of this stage is variable, it typically lasts about one to two months. Death is typically attributed to starvation, as the females have stopped hunting in order to protect their eggs; males often spend more time in the open, making them more likely to be preyed upon.[28]
Octopuses are ranked as the most intelligent invertebrates.[29] Giant Pacific octopuses are commonly kept on display at aquariums due to their size and interesting physiology, and have demonstrated the ability to recognize humans with whom they frequently come in contact. These responses include jetting water, changing body texture, and other behaviors that are consistently demonstrated to specific individuals.[30] They have the ability to solve simple puzzles, open childproof bottles and use tools.[23] The octopus brain has folded lobes (a distinct characteristic of complexity) and visual and tactile memory centers. They have about 300 million neurons.[23] They have been known to open tank valves, disassemble expensive equipment, and generally wreak havoc in labs and aquaria.[23] Some researchers even claim that they are capable of motor play[31] and having personalities.[32]
Giant Pacific octopuses are not currently under the protection of Convention on International Trade in Endangered Species of Wild Fauna and Flora or evaluated in the IUCN Red List.[33] The giant Pacific octopus has not been assessed by the Monterey Bay Aquarium Seafood Watch, although other octopus species are listed.[34] Combined with lack of assessment and mislabeling, tracking the species's abundance is nearly impossible. Scientists have relied on catch numbers to estimate stock abundance, but the animals are solitary and difficult to find.[23] DNA techniques have assisted in genetic and phylogenetic analysis of the species' evolutionary past. Following its DNA analysis, the giant Pacific octopus may actually prove to be three subspecies (one in Japan, another in Alaska, and a third in Puget Sound).
In Puget Sound, the Washington Fish and Wildlife Commission adopted rules for protecting the harvest of giant Pacific octopuses at seven sites, after a legal harvest caused a public outcry.[35] Populations in Puget Sound are not considered threatened.
Regardless of these data gaps in abundance estimates, future climate change scenarios may affect these organisms in different ways. Climate change is complex, with predicted biotic and abiotic changes to multiple processes including oxygen limitation, reproduction, ocean acidification, toxins, effects on other trophic levels, and RNA editing.
Octopuses have been found to migrate for a variety of reasons. Using tag and recapture methods, scientists found they move from den to den in response to decreased food availability, change in water quality, increase in predation, or increased population density (or decreased available habitat/den space)[36] Because their blue blood is copper-based (hemocyanin) and not an efficient oxygen carrier, octopuses favor and move toward cooler, oxygen-rich water. This dependency limits octopus habitat, typically to temperate waters 8–12 °C (46–54 °F).[3] If seawater temperatures continue to rise, these organisms may be forced to move to deeper, cooler water.
Each fall in Washington's Hood Canal, a habitat for many octopuses, phytoplankton and macroalgae die and create a dead zone. As these micro-organisms decompose, oxygen is used up in the process and has been measured to be as low as 2 parts per million (ppm). This is a state of hypoxia. Normal levels are measured at 7–9 ppm.[37] Fish and octopuses move from the deep towards the shallow water for more oxygen. Females do not leave, and die with their eggs at nesting sites. Warming seawater temperatures promote phytoplankton growth, and annual dead zones have been found to be increasing in size.[23] To avoid these dead zones, octopuses must move to shallower waters, which may be warmer in temperature and less oxygen-rich, trapping them between two low-oxygen zones.
Increased seawater temperatures also increase metabolic processes. The warmer the water, the faster octopus eggs develop and hatch.[3] After hatching, the paralarvae swim to the surface to join other plankton, where they are often preyed upon by birds, fish, and other plankton feeders. Quicker hatching time may also affect critical timing for food availability.[38] One study found that higher water temperatures accelerated all aspects of reproduction and even shortened lifespan by up to 20%.[39] Other studies concur that warming climate scenarios should result in higher embryo and paralarvae mortalities.[40]
The burning of fossil fuels, deforestation, industrialization, and other land-use changes cause increased carbon dioxide levels in the atmosphere. The ocean absorbs an estimated 30% of emitted anthropogenic CO2.[41] As the ocean absorbs CO2, it becomes more acidic and lowers in pH. Ocean acidification lowers available carbonate ions, which is a building block for calcium carbonate (CaCO3). Calcifying organisms use calcium carbonate to produce shells, skeletons, and tests.[42] The prey base that octopuses prefer (crab, clams, scallops, mussels, etc.) are negatively impacted by ocean acidification, and may decrease in abundance. Shifts in available prey may force a change in octopus diets to other, nonshelled organisms.
Because octopuses have hemocyanin as copper-based blood, a small change in pH can reduce oxygen-carrying capacity. A pH change from 8.0 to 7.7 or 7.5 will have life-or-death effects on cephalopods.[23]
Researchers have found high concentrations of heavy metals and PCBs in tissues and digestive glands, which may have come from these octopus' preferred prey, the red rock crab (Cancer productus).[43] These crabs bury themselves in contaminated sediments and eat prey that live nearby.[3] What effects these toxins have on octopuses are unknown, but other exposed animals have been known to show liver damage, changes in immune systems, and death.
Potential changes in octopus populations will affect upper and lower trophic levels.[38] Lower trophic levels include all prey items, and may fluctuate inversely with octopus abundance. Higher trophic levels include all predators of octopuses, and may fluctuate with octopus abundance, although many may prey upon a variety of organisms. Protection of other threatened species may affect octopus populations (the sea otter, for example), as they may rely on octopuses for food. Some research suggests that fishing other species has aided octopus populations, by taking out predators and competitors.
Some octopuses exhibit the ability to alter speeds of sodium and potassium ion movement across cell membranes, allowing them to live in very cold water. Researchers at the University of Puerto Rico's Institute of Neurobiology have found that they have altered protein synthesis, and can speed up production of potassium channels in cold water to keep up with sodium ion exchange. They are now looking into whether individuals can alter their protein synthesis in response to changing temperatures, or if this change occurs species-wide, over long-term adaptations. If changes are possible by the individual, these octopuses might be able to adapt quickly to changing climate scenarios.[23]
The giant Pacific octopus (Enteroctopus dofleini), also known as the North Pacific giant octopus, is a large marine cephalopod belonging to the genus Enteroctopus. Its spatial distribution includes the coastal North Pacific, along Mexico (Baja California), The United States (California, Oregon, Washington, and Alaska), Canada (British Columbia), Russia, Eastern China, Japan, and the Korean Peninsula. It can be found from the intertidal zone down to 2,000 m (6,600 ft), and is best adapted to cold, oxygen-rich water. It is the largest octopus species, based on a scientific record of a 71-kilogram (157-pound) individual weighed live.
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