The Missing Biography: Where Do Baby Turtles Go During Their 'Lost Years'?

The life of a sea turtle begins as it hatches within the buried sand and instinctively sprints into the water amidst a gauntlet of predators. But many survive... then vanishes, their movements secretly held by the vast ocean.

Depending on the species, a sea turtle spends 1-15 years in the open sea, the so-called ‘lost years’ — the period that ensues after the turtles break free from their eggs to reach the open ocean until the time they come back as large juveniles to their feeding grounds near coastlines. Scientists find it critical to understand this because it serves as the foundation of sea turtle populations. Sea turtles live long lives so understanding this missing part of their ‘biography’ and the threats they may encounter is important to inform conservation efforts and guide policies.

According to Katherine Mansfield, who has studied turtles for more than 20 years, the challenge in completing the turtles’ biographies is that it’s just difficult to survey an entire ocean.

But they did it.

Figure from Mansfield et al. (2014)

She and her team of researchers from the University of Central Florida fit 17 newborn loggerheads with tiny satellite tags. It took them a long time to perfect this. What they realized is that turtle’s shells are made of keratin (as our fingernails are). So what they did is seek a collaborator’s manicurist, and, with her brilliant idea, they were able to fit the satellite tags using an acrylic base coat that seals the shell from peeling. The tags lasted for more than 7 months.

These efforts produced a map which clearly shows the movements of loggerheads for 27 to 220 days.

What Mansfield found out is that the basic overall pattern of movement of loggerheads coincides with previous knowledge, but there were significant nuances in the path each individual turtle takes. 

For instance, contrary to common knowledge that turtles go straight and fast to the North Atlantic Gyre (and they’re mostly right), it turns out they took their time running in local circles, even taking them away from the gyre to the Sargasso Sea.

Sargassum, a type of brown algae, is a favorable habitat for baby turtles since it provides shelter against predators. It's also a haven for the cold-blooded turtles because the warmer waters of the seaweed-filled surface allow them to grow faster and reach sexual maturity earlier.   

Unraveling clues where baby turtles go during their 'lost years' and have it mapped out has been a feat for Mansfield and her team. There are more questions though. So after 5 years, she and a large team of researchers  took it a notch higher.

They developed a computer model that predicts where sea turtle hatchlings go after they leave Florida's shores.

That's for our next blog.

Stay tuned.

Keen to learn more about these fascinating turtles? You can learn more HERE.

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Mansfield, K. L., Wyneken, J., Porter, W. P., & Luo, J. (2014). First satellite tracks of neonate sea turtles redefine the ‘lost years’ oceanic niche. Proceedings of the Royal Society B: Biological Sciences, 281(1781), 20133039.

Putman, N. F., Seney, E. E., Verley, P., Shaver, D. J., López‐Castro, M. C., Cook, M., ... & Peña, L. J. (2019). Predicted distributions and abundances of the sea turtle ‘lost years’ in the western North Atlantic Ocean. Ecography 42:1-12.

Science Daily (2019 Dec 23). Where do baby sea turtles go? New research technique may provide answers. Retrieved from http://bit.ly/37Mpcls

Yong, Ed. (2014 Mar 4). Where do Baby Turtles Go During Their Lost Years? Retrieved from https://on.natgeo.com/2uM5K9I 

Creature feature: Meet the dumbo octopus

Illustration by Maxeen Bayer based on the Disney character Dumbo

Deep in the ocean floor lives an octopus, its common name derived from the Disney character Dumbo who can fly with its big ears. Just as the sky is for the endearing elephant, the dumbo octopus hails from the deep, steering the waters by flapping its ear-like fins [1].

To date, there are 21 known species of dumbo octopus (Grimpoteuthis) [2]. Being bathypelagic animals, they live 13,000 feet below water (or almost 4000 m) and are rarely seen in shallow waters. They live in tropical to temperate latitudes and have been observed in New Zealand, California, Oregon, Philippines, and in other areas [3].

Dumbo octopus comes in different sizes, shapes, and colors. Its average size is 20 to 30 cm (7.9 to 12 inches) in length and its mantle, either U- or V-shaped. Like other families of octopi, their tentacles are umbrella-shaped, characterized by webbing between their tentacles, which help them navigate while swimming and crawling on the surface. Their ear-like lateral fins also help them propel around the water [4].

Grimpoteuthis has large eyes, about a third the diameter of their head, but it has limited use in the eternal darkness of the deep oceans. However, to defend itself against predators, it uses its ability to change color and camouflage against the ocean floor. When it camouflages, the ears emit a different color than the rest of its body [4].

They are carnivorous, eating isopods, amphipods, bristle worms and more. Their mouth is different from their kin, engulfing their prey rather than grinding and ripping [1].

The male octopus has a special protuberance in one of its 8 tentacles used to deliver the sperm to a female octopus, which the octopus stores until conditions are favorable for laying eggs on shells or small rocks on the seafloor. Young dumbo octopi are large when they are born and must survive on their own. They can live for 3 to 5 years [1].

Very little is known about these creatures. If you have more information on dumbo octopus, SeaLifeBase welcomes collaboration. Kindly send us a message at sealifebase(at)q-quatics(dot)org.

Written by Maxeen Danielle Bayer

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[1] Helmenstine, A.M. (2018, April 24). All about Grimpoteuthis, the dumbo octopus. ThoughtCo. Retrieved from https://bit.ly/2W3CUtP

[2] WoRMS Editorial Board (2019). World Register of Marine Species. Available from http://www.marinespecies.org at VLIZ. Accessed 2019-03-15. doi.10.14284/170

[3] Oceana. Cephalopods, crustaceans and other shellfish: dumbo octopus. Retrieved from https://bit.ly/2Jfo2qM

[4] Ocean Conservancy (2018, October 8). Everything you need to know about the dumbo octopus. Retrieved from https://bit.ly/2OAYNBg

[5] National Geographic (2018, October 29). Rare dumbo octopus shows off for deep-sea submersible. YouTube. Retrieved from https://bit.ly/2u9gcEP

Symbiosis special: What makes the Hawaiian bobtail squid glow?

Photo by Todd Bretl, Monterey Bay Aquarium

As adorable as the endemic Hawaiian bobtail squid Euprymna scolopes can be, its famed relationship with a microbe is even more special: among thousands of marine bacteria, only one microbe, Vibrio fischeri, is known to successfully colonize the squid's light organ within its mantle, turning the squid into an enchanting and 'disappearing' luminescent creature [1-4,8]. 

Few hours after the hatchlings are out from their egg case, V. fischeri from the surrounding water begin to enter the pores on either side of the light organ, settling on the epithelium-lined inner crypt spaces (tiny spaces within the organ)  [1,2,5].

Specificity is achieved early on through a mutual dialogue between the young host and the symbiont (i.e., agreement on entry and attachment of the microbe). Once the microbes have established, this transformation triggers a series of biological changes in both organisms, strengthening their relationship [7].

Now, the squid matures, and as if charging a weapon for the night, V. fishceri reaches its highest concentration in the light organ. And the squid shines its brightest [2,6].

While the squid hunts for prey, the microbes perfectly match the intensity of the moonlight welling down from above, reducing the squid's silhouette, ultimately giving it an 'invisibility cloak' (counter-illumination) against predators seeing from below [5,8]. What's more interesting is that the host is equipped not only to detect but to also control the amount of light emitted by the bacteria through its specialized light organ features [5]. 

Here's a video from Ed Yong (The Atlantic), illustrating this fascinating partnership.

As the dawn breaks, it secretes from its light organ a thick mucous containing 95% of its symbionts back into the sea, while the rest of the microbes replenish themselves to start another cycle [2,6]. Over the rest of the day, the squid becomes dormant and retreats into the sand [6].

For over 20 years, this squid-vibrio relationship has been key in studying many biological phenomena, like cephalopod development and the structure of tissue interacting with light [6]; this one-on-one connection has also been crucial in understanding host-microbe interactions in a natural microenvironment [1,2]. 

Beyond this, the squid-vibrio partnership is important, because, it turns out, the microbe 'remakes' and protects its host: reaching the adult state is only possible when the squid harbors the right microbial ally [8]. 

And, charmingly, the squid need not look further.

To know more about bobtail squids, visit SeaLifeBase.

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[1] Rader, B. A., & Nyholm, S. V. (2012). Host/microbe interactions revealed through “omics” in the symbiosis between the Hawaiian bobtail squid Euprymna scolopes and the bioluminescent bacterium Vibrio fischeri. The Biological Bulletin, 223(1), 103-111.

[2] Schleicher, T. R., & Nyholm, S. V. (2011). Characterizing the host and symbiont proteomes in the association between the Bobtail squid, Euprymna scolopes, and the bacterium, Vibrio fischeri. PLoS One, 6(10), e25649.

[3] Boettcher, K. J., & Ruby, E. G. (1990). Depressed light emission by symbiotic Vibrio fischeri of the sepiolid squid Euprymna scolopes. Journal of Bacteriology, 172(7), 3701-3706.

[4] Yazzie, N., Salazar, K. A., & Castillo, M. G. (2015). Identification, molecular characterization, and gene expression analysis of a CD109 molecule in the Hawaiian bobtail squid Euprymna scolopes. Fish & Shellfish Immunology, 44(1), 342-355.

[5] Peyer, S. M., Pankey, M. S., Oakley, T. H., & McFall-Ngai, M. J. (2014). Eye-specification genes in the bacterial light organ of the bobtail squid Euprymna scolopes, and their expression in response to symbiont cues. Mechanisms of Development, 131, 111-126.

[6] McFall-Ngai, M. (2014). Divining the essence of symbiosis: insights from the squid-vibrio model. PLoS Biology, 12(2), e1001783.

[7] Visick, K. L., & McFall-Ngai, M. J. (2000). An exclusive contract: specificity in the Vibrio fischeri-Euprymna scolopes partnership. Journal of Bacteriology, 182(7), 1779-1787.

[8] Yong, E. (26, Jan 2018). The lovely tale of an adorable squid and its glowing partner. The Atlantic. Retrieved from https://www.theatlantic.com/science/archive/2018/01/the-lovely-tale-of-an-adorable-squid-and-its-glowing-partner/551549/

Underwater's Ultimate Weapon

Listen to this audio recording below from Radiolab [1]. Start from 2:00 and end at 3:25.

What did you hear?

Rice pops? Twigs being burned? Frying bacon?

No – they are snapping shrimps, or rightfully called “pistol” shrimps which belong to the family Alpheidae. Do the sound even hint to a deadly weapon?

For starters, a snapping shrimp is a tiny creature, reaching one to two inches – just half of your finger [4]. Now it gets scarier: it has a distinctive large claw which it uses to stun a prey instantaneously! The cracking sound produced is what you hear during low tide in shallow waters. Some species live mutually with gobies in burrows: the shrimp provides a home for the goby, while the fish confers protection to shrimp against predators [2].

Why do these shrimps make an incessant sound? 

In 2000, European scientists discovered that the sound is produced from the formation of cavitation bubble released when the claw rapidly snaps shut [3]. Charged with a speed of up to 100 km an hour [1,3,4], the bubble can go for a swift kill in a matter of 300 microseconds [3]. As the pressure stabilizes, the bubble pops with a loud bang reaching about 220 decibels [1, 5]. That is equivalent to the sound of a jet engine [1], enough to break small jars [4]. And yes, it’s louder than a gun shot which is around 150 decibels [7]. It actually competes with the sperm whale as the loudest animal in the ocean [4].  

It emits not only a ‘deafening’ sound but an ultra-fast light when the bubble collapses. It is thought to exhibit sonoluminiscence - emission of short bursts of light [4] caused by a strong sound field [3]. If it were to be seen at the time of collapse, the temperature inside the bubbles must be a least 5,000 degrees Kelvin, comparable to the surface of the sun at 5,800 degrees Kelvin. The ephemeral flash of light lasts no longer than 300 picoseconds (a picosecond is one trillionth of a second) [3]. 

The violence of it all is lies on the sheer extremes of temperature and pressure before bursting – a truly impressive and deadly weapon. Now that’s intimidating.

Credit: National Geographic

Below is pistol shrimp in action, releasing its deadly, supersonic bubble [6].

Here’s another interesting feat.

Pistol shrimps helped the Americans win World War II. Yes, you read it right. Since the crackling sound they produce is intense enough to disrupt underwater communication, US Navy submarines used the shrimp beds to interfere with the sonar, therefore attacking the Japanese while hiding on their makeshift invisibility cloak [1,2]. They even installed speakers on their ships to mirror the shrimps’ sounds! [1]. 

Awesome, isn't it?

To know more about snapping shrimps or pistol shrimps, visit SeaLifeBase.

Written by:

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[1] Iono.fm. (2016, November 10).  Bigger than bacon [Audio file]. Retrieved from https://iono.fm/e/286830

[2] Riley, A. (2016, January 29). This shrimp is carrying a real-life working stun gun. BBC Earth. Retrieved from http://www.bbc.com/earth/story/20160129-the-shrimp-that-has-turned-bubbles-into-a-lethal-weapon

[3] Roach, J. (2001, October 3). Snapping shrimp stun prey with flashy bang. National Geographic. Retrieved from http://news.nationalgeographic.com/news/2001/10/1003_SnappingShrimp.html

[4] Anirudh (2013, February 13). 7 interesting facts about pistol shrimp or snapping shrimp. Retrieved from https://learnodo-newtonic.com/pistol-shrimp-facts

[5] Ocean Conservation Research (2016). Snapping shrimp. Retrieved from http://ocr.org/sounds/snapping-shrimp/

[6] Nat Geo Wild. (2013, April 11). World’s deadliest – amazing pistol shrimp stun “gun” [Video file]. Retrieved from https://www.youtube.com/watch?v=KkY_mSwboMQ

[7] Simon, M. (2014, July 11). Absurd creature of the week: the feisty shrimp that kills with bullets made of bubbles. Wired. Retrieved from http://www.wired.com/2014/07/absurd-creature-of-the-week-pistol-shrimp/

Sea otters beyond utter cuteness

On the left are sea otters from ©Finding Dory and opposite is its real-life counterpart, Enhydra lutris (photo by Michael Gore).

Sea otters or Enhydra lutris are nearshore marine mammals, strongly associated with rocky coastal areas near kelp beds where they forage. Other than for food, they also use these kelp to sometimes entangle themselves with, keeping them afloat [1]. Most of time they are seen in groups called rafts [8], lying on their backs with such a laid-back pose [2], holding on to each other to make sure no one drifts away in their sleep [9]. They currently inhabit the coasts of Japan, Russia, Canada, North America and Mexico [1], but the majority reside in Alaskan waters [4].

True to being so adorable and a favorite in Finding Dory, sea otters are rarely seen fighting or being aggressive with their kin. In fact, they are weakly territorial, where only adult males form turfs [1]. 

Beyond being fuzzballs, what sets them apart from other marine mammals is their unique capacity to use tools. Using their forearms to grab a stone and prey from the ocean floor, they resurface to set a prey, for example, a mussel or clam on its chest, pries it open or smashes it against a stone [2]. Known as voracious feeders, sea otters even have pouches of loose skin under each forearm, where they could easily stash their prey [5]. They also feast on a variety of organisms such as sea urchins, crabs, squids, bony fish [3] and octopuses [6].

Unlike other marine mammals, they don’t have a thick layer of blubber to keep them warm. To compensate for this, they don the thickest and densest of furs, where a square inch of its skin can grow a million hair! [4]. To further keep the warmth, they spend hours grooming their coats until they are covered with natural oils [5]. They also eat to their tummy’s content (approximately 25% of their body weight), and spend most of their time resting afloat [4]. 

Below is a video of an Alaskan sea otter pup floating on its own [7].

It might not be obvious with how sea otters behave and handle themselves, but they are, most importantly, keystone species. That means their existence or absence has a greater effect in the ecosystem relative to other species. That is, sea otters help keep sea urchin population in check, and in turn maintain a healthy kelp forest [4].

Sea otters have been considered endangered since 2000 [1]. Today there are only about 100,000 to 150,000 individuals [2].

To know more about Enhydra lutris and other characters from Finding Dory, visit SeaLifeBase.

Written by:

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[1] Doroff, A. & Burdin, A. 2015. Enhydra lutris. The IUCN Red List of Threatened Species 2015: e.T7750A21939518. http://dx.doi.org/10.2305/IUCN.UK.2015-2.RLTS.T7750A21939518.en. Downloaded on 26 July 2016.

[2] National Geographic (2016). Sea otter - Enhydra lutris. Retrieved from http://animals.nationalgeographic.com/animals/mammals/sea-otter/

[3] Gaichas, S. K. (2006). Development and application of ecosystem models to support fishery sustainability: A case study for the Gulf of Alaska. Retrieved from Proquest Dissertations and Theses database.

[4] Defenders of Wildlife (2016). Basic facts about sea otters. Retrieved from http://www.defenders.org/sea-otter/basic-facts

[5] Monterey Bay Aquarium (2016). Southern sea otter. Retrieved from https://www.montereybayaquarium.org/animal-guide/marine-mammals/southern-sea-otter

[6] Vincent, T. L. S., Scheel, D., & Hough, K. R. (1998). Some aspects of diet and foraging behavior of Octopus dofleini (Wülker, 1910) in its Northernmost Range. Retrieved from http://onlinelibrary.wiley.com/doi/10.1111/j.1439-0485.1998.tb00450.x/abstract

[7] BBC (2015, January 28). Sea otter pup left to float alone - Alaska: Earth's frozen kingdom: episode 1 preview - BBC two [Video file]. Retrieved from https://www.youtube.com/watch?v=sWJXG2SS6AA
[8] World Wildlife Fund (2016). Ten facts about sea otters. Retrieved from http://www.worldwildlife.org/blogs/good-nature-travel/posts/ten-facts-about-sea-otters
[9] Schweig, S. V. (2016, April 13). Sea otters hold hands while they're sleeping. The Dodo. Retrieved from https://www.thedodo.com/sea-otters-hold-hands-1727255897.html

Meet Hank, the east Pacific red octopus

Left photo is is ©Finding Dory's red octopus Hank (Source: movie.disney.co.uk)  and on the right is its real-life counterpart, Octopus rubescens (Photo by Ken Phenicie Jr.).

The octopus is considered as one of the most elusive and intelligent of sea creatures [1]. We sure were fascinated with Hank, the animated counterpart of Octopus rubescens, more commonly known as the east Pacific red octopus. This species is known to inhabit the waters of Bering Strait, Alaska down to Baja California, from low intertidal to a depth of 210 m.  It can reach a total length of 45 cm [2] and lives up to two years [9]. It has a neutral color of red or reddish brown [3]. In the movie Hank wishes to live in captivity permanently, away from all the dangers of the wild. In reality though, juveniles are found among kelps [9] while adults settle on rock and soft bottoms [2]. It is a voracious predator of crabs [4] and also feeds on bony fish [4], mollusks, and euphausiids [6]. It can even drill holes on shells of the bivalve Venerupis philippinarum [5].

What makes them so interesting is beyond what we have encountered in the movie. Sure, they can change into a kaleidoscope of colors before and after capturing a prey. Based on one study, it displayed various colors before detection of a crab, turned light orange to gray during a free-swimming attack, colorless and almost transparent on landing, spotted or mottled upon grabbing the crab, and back to various colors. This series of color change may be associated with locomotor acts and postural adjustments [7]. Below is a video of O. rubescens feeding on a crab [8].

Because of its soft flexible body and small papilla (projections on its skin), O. rubescens can morph into different shapes and textures, an ability that is very useful against predation. At the point of detection, it can rapidly change color, shape or even texture, confusing and alarming its predator altogether [9].

Much like Hank’s crafty moves in Finding Dory, O. rubescens is truly capable of escaping captivity and surviving on land. According to Monterey Bay Aquarium, a juvenile O. rubescens sneaked into an aquarium using a sponge as a cover, and was only caught red handed (after a year in an exhibit) while walking in the middle of the night. Workers also noticed that the crabs in the exhibit were decimated [10].

And yes, this species has three hearts as other octopuses do: one pumps blood through the body, specifically for the organs, while the other two exclusively pump blood through the gills [1]. No doubt Hank, in the end, had the heart (or hearts?) to return and help Dory and her friends go back to their true home, the ocean.

To know more about O. rubsecens and other characters from Finding Dory, visit SeaLifeBase.

Written by:

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[1] Nuwer, R. (2013, October 31). Ten curious facts about octopuses. Retrieved from http://www.smithsonianmag.com/science-nature/ten-curious-facts-about-octopuses-7625828/?no-ist

[2] Gotshall, D. W. (2005). Guide to marine invertebrates: Alaska to Baja California (2nd ed. revised). Sea Challengers.

[3] Biodiversity of the Central Coast (2014). Pacific red octopus – Octopus rubescens. Retrieved from http://www.centralcoastbiodiversity.org/pacific-red-octopus-bull-octopus-rubescens.html

[4] Boletzky, S. V., & Hanlon, R. T. (1983). A review of the laboratory maintenance, rearing and culture of cephalopod molluscs. Memoirs of the National Museum Victoria, 44, 147-187. Retrieved from https://www.researchgate.net/profile/Roger_Hanlon/publication/279192347_A_review_of_laboratory_maintenance_rearing_and_culture_of_cephalopod_molluscs/links/56b13e1008ae5ec4ed48808c.pdf

[5] Anderson, R. C., Sinn, D. L., & Mather, J. A. (2008). Drilling localization on bivalve prey by Octopus rubescens Bery, 1953 (Cephalopoda: Octopodidae). The Veliger, 50(4), 326-328. Retrieved from http://eprints.utas.edu.au/8464/

[6] Laidig, T. E., Adams, P. B., Baxter, C. H., & Butler, J. L. (1995).  Feeding on euphausiids by Octopus rubescens. California Fish and Game, 81, 77-79. Retrieved from https://137.110.142.7/publications/FED/00169.pdf

[7] Warren, L. R., Scheier, M. F., & Riley, D. A. (1974). Colour changes of Octopus rubescens during attacks on unconditioned and conditioned stimuli. Animal Behaviour, 22(1), 211-219. Retrieved from http://www.sciencedirect.com/science/article/pii/S0003347274800710

[8] NgomaMom (2014, May 21). East Pacific red octopus in the mood for food [Video file]. Retrieved from https://www.youtube.com/watch?v=_Wkl3exDmys

[9] Orwick, S. (2005). Crypsis, substrate preference and prey detection in the red octopus, Octopus rubescens (Berry, 1952). Retrieved from Oregon Institute of Marine Biology https://scholarsbank.uoregon.edu/xmlui/bitstream/handle/1794/8072/Orwick%2005.pdf?sequence=1&isAllowed=y

[10] Monterey Bay Aquarium (2016). Red octopus.  Retrieved from  https://www.montereybayaquarium.org/animal-guide/octopuses-and-kin/red-octopus

Secret of resilience revealed in Antarctic octopod

Photo by Thomas Lundälv.

At a constant temperature of -1.8°C to 2°C in the Antarctic, ectotherms adapt various strategies to survive near-freezing temperatures. Such a condition may increase the solubility of oxygen but increase blood viscosity, making it difficult to deliver oxygen in tissues [1,2]. But such a dire circumstance does not thwart the Antartic octopod’s survival in freezing waters.

However, this octopod does not only thrive in cold temperatures, evidence suggests that a functional change in its blue-blood pigment ‘haemocyanin' enhances oxygen supply to octopod tissues, notably at higher temperatures. This could mean increased resiliency to warmer climate as global warming advances in the Antarctic Peninsula [1,2].

How does an Antartic octopod survive temperature extremes? Researchers analyzed the haemolymph of three octopod species – the Antarctic octopod Pareledone charcoti and the two species residing in warmer climates, Octopus pallidus and Eledone moschata. They found out that P. charcoti has one of the highest concentration of haemolymph recorded for octopods, allowing sufficient oxygen supply. Also, relative to the two other species, oxygen transport via haemocyanin in P. charcoti (76.7% on average) was significantly improved at 10°C compared to 0°C. Such a remarkable feat may allow the Antarctic octopod to thrive in both warm and cold temperatures [1]. Amazing, isn’t it?

To know more about these species and octopods in general, visit SeaLifeBase.

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[1] BioMed Central. (2015, March 10). “Blue-blood on ice: How an Antarctic octopus survives the cold.” ScienceDaily. Retrieved March 16, 2015 from http://www.sciencedaily.com/releases/2015/03/150310205703.htm

[2] Oellermann, M., Lieb, B., Pörtner, H.O., Semmens, J.M., Mark, F.C. (2015). Blue blood on ice: modulated blood oxygen transport facilitates cold compensation and eurythermy in an Antarctic octopod. Frontiers in Zoology.

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Seven Sea Turtle Wonders

Artwork by Mike Yap

To develop an appreciation for something can take as little as a glimpse – an instant connection – or sometimes a profound amount of time to see the beauty within. In the life of James Spotila, a remarkable sea turtle biologist, it only took a sighting of a healthy leatherback about to lay its eggs to be held captivated by it forever. Such a moment held a big part of him, enough to commit his lifetime into studying these wonderful, often miraculous sea creatures.

Since World Sea Turtle Day, June 16, is especially dedicated to the 7 sea turtle species (Green turtle, Leatherback, Kemp’s Ridley, Olive Ridley, Hawksbill, Loggerhead and Flatback) we have today, let us take the time to see how amazing and resilient they really are.

1. Did you know that sea turtles don’t have sex chromosomes? Instead, sex is determined by temperature at which eggs incubate. In the case of green turtles, at 28^oC, hatchlings develop into males; at 31^oC the hatchlings grow into females [1]. This has great implication in conservation [2].

2. The largest recorded leatherback turtle weighs nearly a ton [1]. With jellyfish as its main food, it’s kind of hard to imagine how much it has to eat to weigh that much.

3. Sea turtles have magnetite in their brains; they use it as their internal magnetic compass [1]. They don’t have the superpowers of Magneto but they are tuned to migrate thousands of miles in the ocean and get back to the beach were they hatched.

4. Different species bury their eggs in sand at varying depths. Don't worry the eggs have porous shells so they can breathe. The shallowest depth is observed for Olive ridley and Kemp’s rildey nests at 15 inches while the deepest is for leatherback eggs buried at 25 inches. The deeper it is, the more stable the temperature [2].

5. Sea turtles have to spend at least a decade or more in the open sea before going to back to mate and reproduce in their natal beach [1]. Imagine that they are already independent from the time that they were hatchlings, racing to the open sea. It only becomes tougher (and tougher) for the succeeding years as they have to avoid being captured in destructive shrimp trawls, longlines, and gillnets. What is more worrisome is their affinity to ingest plastics which they mistake for a sumptuous jellyfish.

6. Sea turtles are excellent divers and can prolong their breathing underwater for 45 minutes. The deepest dive a leatherback has bagged is 4250 m [3], beating that of a sperm whale at 3686 m [1].

7. They have survived the mass extinction which obliterated dinosaurs and so have lived for 110 million years now [1]. And it is of course in our hands to make certain that they get to be seen and conserved by the next generations.

The list of how beautiful sea turtles are goes on. Never cease to see and celebrate what’s amazing.

We have considerable information on the seven species of sea turtles. Feel free to visit us at SeaLifeBase, or become a collaborator. Happy World Sea Turtle Day!

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[1] Spotila, J.R. (2004). Sea Turtles: A Complete Guide to their Biology, Behavior and Conservation. The Johns Hopkins University Press.

[2] Spotila, J.R. (2011). Saving Sea Turtles. The Johns Hopkins University Press.

[3] OBIS Search Interface. http://www.iobis.org/mapper/ [Accessed 6/8/2015]. 

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Ocean Giants: Giant Squid

Last week we talked about the Kraken, that it's a squid-like sea monster and that its identity can be either of the two known largest extant squids. First was the heaviest, the colossal squid Mesonychoteuthis hamiltoni (read article here). The second is the longest, the giant squid Architeuthis dux with a cosmopolitan distribution.

Photo taken by Tsunemi Kubodera from Ogasawara Islands, off Tokyo on December 4, 2006 [1].

There are many different species listed under the genus Architeuthis, 21 nominal species in total. But based on a genetic study conducted by Guerra et al (2013), all species are synonyms of A. dux; thus, there is only one giant squid. Furthermore, like the majority of deep sea species, little is known of its biology. Obviously it's a predator; it feeds on fishes and other cephalopods. It has a short life cycle; spawning occurs only once and the females die after bearing their eggs. The largest recorded species measured 12 m in length, unfortunately there was no record of its weight. Studies on its growth and mortality were very limited since getting a sample population from the ocean was tough. Thus, if you have other information on them, which you wish to include in our information system, please e-mail us at sealifebase@fin.ph or join us as a collaborator.

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[1] Accessed from http://animals.nationalgeographic.com/animals/invertebrates/giant-squid/
[2] McClain CR et al (2015) Sizing ocean giants: patterns of intraspecific size variation in marine megafauna. PeerJ 2:e715. Accessed from https://peerj.com/articles/715/
[3] Guerra A et al (2013) Architeuthis dux: única especie de calamar gigante en el mundo. MOL. Revista de la Sociedad de Ciencias de Galicia 53:46-53.
[4] Bolstad KS et al (2004) Gut contents of a giant squid Architeuthis dux (Cephalopoda: Oegopsida) from New Zealand waters. New Zealand Journal of Zoology 31(1):15-21.


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Ocean Giants: Colossal Squid

Who here have watched the movie "Clash of the Titans"? Remember the scene when Zeus shouted "Release the Kraken!" to his men? Kraken actually refers to a squid-like sea monster and among the family of squids, there are two known largest species. First is the heaviest - the colossal squid Mesonychoteuthis hamiltoni commonly found in the Antartic.

The short clip above presents the largest specimen ever caught, it weighed 495 kg and measured 4.2 m in length [1]; but the measurements stated are underrated. Experiments conducted by the Te Papa staff from the Museum of New Zealand showed that fresh specimens can shrink up to 22% when preserved and the specimen above was believed to have shrunk by 14%. Unfortunately, only 9 adult specimens have been recorded and were not enough to fully study their biology [2]. Thus, if you have other information on them, which you wish to include in our information system, please e-mail us at sealifebase@fin.ph or join us as a collaborator.

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[1] McClain CR et al (2015) Sizing ocean giants: patterns of intraspecific size variation in marine megafauna. PeerJ 2:e715. Accessed from https://peerj.com/articles/715/
[2] The Museum of New Zealand Te Papa Tongarewa. The Squid Files. Accessed from http://squid.tepapa.govt.nz/the-squid-files


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Mother knows best! Don't we all agree?

Harp seals (Pagophilus groenlandicus) are famous for being white and fluffy, which makes them adorable; but did you know that the white harp seals we see are pups? Adults on the other hand are black-faced with silver-gray body [1].

 

(Young harp seal suckling, photo by M. Watson posted www.arkive.org)

Like any other mammal, there is a special bond formed between the mother and her young. In the case of harp seals, the mother “noses” its offspring immediately after its birth not only to recognize its scent but also for her to be able to find her pup after foraging [2, 5]. Foraging takes a few hours a day and the mothers need to eat more during the nursing phase (which lasts about 12 days) to provide milk to their pups [3, 4, 5]. They also use their sense of smell to protect their young by detecting predators on ice [1], and to get back to their pups in case there is a need to relocate them due to the unstable ice floe where they gave birth on. [6]

Newborns are sedentary and weigh around 20 lbs which is almost nothing compared to a well fed adult at around 300 lbs. [2, 6] The pups can gain an average of 5.5 lbs per day, because their mother’s milk contains 25 to 40% fat in comparison to a cow’s milk that only contains 5% fat [2]. As soon as the pup fattens up and the nursing period ends, they are then ready to live on their own. The mothers swim off leaving them on the ice in search of a new mate.

Quite a short time to start becoming independent, huh?

To know more about harp seals, visit SeaLifeBase.

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[1] Lavigne, D.M. (2009) Harp seal Phoca groenlandica. In pp. 542-546, Perrin, W.F., Wursig, B., Thewissen, J.G.M. (2009) Encyclopedia of Marine Mammals, Second Edition. Academic Press: London. 1316pp.

[2]  Dougan, J.L., & Roland, K. (1982). The Ice Lover: Biology of the Harp Seal (Phoca groenlandica). Science, New Series 215(4535):928-933.

[3] Ellis, R. (2003). The Empty Ocean. Island Press, 367p.

[4] Innes, S., Lightfoot, N., & Stewart, R. E. A. (1981). Parturition in Harp Seals. Journal of Mammology 62(4):845-850.

[5] Lydersen, C. & Kovacs, K. M. (1999). Behaviour and energetics of icebreeding,

North Atlantic phocid seals during the lactation period. Marine Ecology Progress Series 187:265–281.

[6] Van Opzeeland, & I.C., Van Parijs, S.M. (2004) Individuality in harp seal, Phoca groenlandica, pup vocalizations. Animal Behaviour 68:1115-1123.

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