Going Solar

It seems like the news on energy these days is all about solar. Solar collectors, community solar programs, solar getting cheaper than fossil fuel. Solar, solar, solar. We humans may think we're hot stuff for figuring out how to harvest the energy from the sun for our own needs, but other animals have been using their own kinds of solar panels for eons.

In particular, corals and sea anemones have been acting as green power plants since the times of the earliest dinosaurs. Which is pretty clever when you consider they don't have a brain. Of all the photosynthetic cnidarians out there my favorite has got to be the Aggregating Anemone (Anthopleura elegantissima) AKA the Pink-tipped Anemone.

You can probably guess how it got those names.

Courtesy: Bureau of Land Management via Flickr

If you live on or have visited the Pacific coast of North America, you probably recognize this anemone. They're extremely common very high in the intertidal zone. Which means that if you've ever visited a rocky beach when the tide was even a little low, you've probably encountered these anemones. They're often found in large aggregations, hence the name. These mats of anemones would be astonishing just for their sheer number, but they're even more incredible when you realize each colony is a series of clones.

Have you ever had one of those days where you're so ambivalent about a decision that you wish you could just tear yourself in two and do both? Well aggregating anemones basically have that luxury. They're so good at restoring their tissues after damage that they can literally pull themselves in two different directions and split into separate anemones.

"I weigh a fraction of what I used to, thanks to the elgantissima 
weight loss program!"
Courtesy: Brocken Inaglory via Wikipedia

If the conditions on a particular rock are good enough; one anemone will make many clones, which will make many clones, and so on, and so on until entire sections of beach are covered in copies of the original. These colonies work together to make each individual anemone more successful. Some anemones will specialize in spawning and produce more eggs and sperm than the other clones. Anemones at the edge of the colony will grow more stinging cells than those toward the center, and act as warriors to defend the colony from predators and other aggregating anemones trying to horn in on their turf. If Lenin had a spirit animal, it was probably pink-tipped anemones.

Fight, fight, fight! The white bulbs are sacks of densely packed
stinging cells used to ward of predators and other anemone colonies.
Courtesy: Brocken Inaglory via Wikipedia

Okay so aggregating anemones are pretty cool on their own, but what do all these adaptations have to do with collecting solar energy? Everything. Just under the skin of aggregating anemones live colonies of dinoflagellates, single-celled algae, or both. In the southern portions of the anemone's range you only find dinoflagellates in their tissues, but further north you find a combination of algae and dinoflagellates. We believe that the dinoflagellates are better able to tolerate warm water, and that the algae may help the anemone collect more sun where the days are shorter in fall and winter.

Dinoflagellates (pronounced: dai-no-fla-jell-ates) are a confusing single-celled organism that isn't quite animal and isn't quite plant. Most are a single cell with a wavy appendage like a sperm tail called a flagella. Many can both consume food and produce it via photosynthesis. The dinoflagellates under the skin of aggregating anemones are exclusively photosynthesizers and they're only found living in the tissues of cnidarians.

These individual cells work like the individual panels on a solar array. When exposed to sunlight each cell produces carbon and oxygen, both essential ingredients for the chemistry of life in complex organisms. Aggregating anemones harvest these products from their photosynthetic roomates just like electrical engineers harvest electricity from photovoltaic panels. In turn the anemone maintains the solar power plant by producing carbon dioxide, and waste. Carbon dioxide, which the anemone breathes out, is an essential ingredient in photosynthesis, and animal waste is full of the nutrients plants crave.

The anemone's green-blue color actually comes from the algae
and dinoflagellates in the skin. This clear one probably lives in 
the shade of a large boulder and so doesn't host photosynthesizers.
Courtesy: Peter Pearsall/USFWS via Flickr

Now it's not as easy being a living solar farm as it is being a synthetic one. Human solar arrays can be made of glass and other materials that resist wear and tear, but anemones and their symbiotic solar cells are made of good old squishy, damageable protein.

In order for their symbionts to do photosynthesis, aggregating anemones have to live where there's plenty of sun, hence their high position in the intertidal. However, as any fair-skinned individual can attest, sunlight is loaded with ultraviolet radiation which wreaks havoc on organic tissues. In order survive exposure to all that radiation aggregating anemones have to possess some unique defenses. Thankfully the dinoflagellates secrete a chemical that coats the anemone's cells and acts as a sunscreen. The chemical absorbs the most dangerous parts of the UV and dissipates them as softer visible light.

Of course they say help comes to those who help themselves, and the anemone pulls its own weight in protecting its investments. Along the sides of aggregating anemones are little sticky bumps called verrucae (pronounced: ver-oo-key). The anemone uses its verrucae pick up particles of shell, sand, and other materials. These bits act like a big floppy sun hat to protect the anemone's sensitive skin.

Who Wore it Better? Sandy Beach Edition.
Couretsy: A. Strakey & Diane Main via Flickr

 Even though the anemones have solved the sun exposure problem, there's even more challenges to running a living solar facility. Photosynthesis produces oxygen, which is great if your tide pool is getting hot and losing gas to the atmosphere, but not so great if you're cells start to fall apart from oxidation. Oxygen is a really powerful molecule because it often comes in a form you might of heard of called a free radical. Free radical oxygen has characteristics that make it pull other molecules apart, which is why oxygen is toxic in high concentrations. So if the algae and dinoflagellates are phtosythesizing away, pumping free radical oxygen almost directly into their hosts cells, the anemone could die of oxygen poisoning. Thankfully the anemone's body produces high concentrations of chemicals that bind with free radical oxygen and render it harmless.

The final challenge for an organism trying to run a biological green power facility brings us back to where we started at the anemone's position along the shore. Living high up the beach means that a couple of times a day the tide is going to go out on you. If you're an animal that's normally adapted to living underwater that's a challenge. The shells and sand grains on the anemone's stalk will help block some of the desiccating effects of the dry air, but it's not always enough; so aggregating anemones hold their breath. As the tide recedes the anemones suck as much water as they can into their body cavity to keep them moist and oxygenated while the water is out. If you've ever touched an aggregating anemone and it squirted you, you know what I'm talking about. Careful though, as making them spray their water is kind of like telling your friend to hold their breath and then punching them in the gut. Sure its funny as the air or water comes rushing out, but the anemone/guy who just got punched is left very winded and uncomfortable.

"Anemone Punch" The new album from Olympia punk band: Cnidaria 
Courtesy: Ingrid Taylor via Flickr

More and more, engineers are drawing inspiration from nature for building materials that improve our daily lives. If the flippers of humpback whales can make wind turbines more efficient, maybe we can draw inspiration from nature's original solar plants to improve other areas of green infrastructure. It's a beautiful irony that the fight to save species from climate change might be resolved by looking at the very animals we're trying to protect.

References:

Furla et Al.. "The Symbiotic Anthazoan: A Physiological Chimera Between Alga and Animal", Integrative and Comparative Biology, vol. 45, issue 4, pg 594-604, 2005

Accessed via: https://academic.oup.com/icb/article/45/4/595/636401/The-Symbiotic-Anthozoan-A-Physiological-Chimera 

Lajeunesse, T.C., & Trench R.K., "Biogeography of Two Species of Symbiodinium (Freudenthal) Inhabiting the Intertidal Sea Anemone Anthopleura elegantissima (Brandt)", The Biological Bulletin, vol. 199, no. 2, October 2000

A Clam for Ken Kesey

"That's a CLAM!?" This reaction to a particular animal is almost guaranteed when people look at them for the first time. Check it out.

Oh man, who just leaves a tie-dye shirt laying around on a coral reef?
Courtesy: Nick Hobgood via Flickr

Okay first off, that looks nothing like what belongs in my chowder. Second, this animal just goes to prove that the 60's got to everyone. So where does counter-culture clam come from and why's it so psychedelic? Editor's Note: This post is greatly improved when accompanied by Strawberry Alarm Clock's: Incense and Peppermints, or your own favorite psychedelic rock song.

Well what you're looking at is a Tridacna (pronounced: Tri-dack-na) clam. They're more commonly called giant clams, but I don't really like that name because not all of them are giant. In fact one species, Tridacna maxima, has the common name "small giant clam"; that's just silly so were gonna stick with their scientific name for this post. Anyway Tridacna don't look much like their relatives, but all the pieces are still there. They have heavy rippled shells like their cousins the cockles, and the part that you see sticking out is their mantle (the body of a mollusk) and their siphons (The channels clams use to feed and breathe). These combined anatomical parts are what make up the "meat" of the clam that we eat.

Plankton filled water flows into the hole on the right, and strained 
water flows out of the tube on the left.
Courtesy edgeplot via Flickr

Tridacna clams live on coral reefs in the tropical Western Pacific. Once they settle out from the plankton they spend their entire lives in that single spot. They don't dig into the ground, but instead let it all hang out. Truly these bivalves (animals with two shells) have gotten the hippy lifestyle down pat.

In fact it turns out that Tridacna's trippy colors and patterns are essential to its survival. The reason Tridacna don't dig into the sand is that they're part of a self sustaining commune. Just like the stony corals around them; these mollusks host symbiotic algae under their skin. In order for the algae to photosynthesize they need to be exposed to the sun. The hinge of the clam's shell is heavier than the opening, so it can tilt face up and spend the daylight hours with its skin spread out in the light. The algae get protection from consumers, and the clam gets nutrients without having to feed. Having a backup way to get your food is especially helpful on coral reefs because the water around them is usually lacking in plankton. Completely clear water is great for snorklers' ability to see, but not so great for filter feeders' ability to eat.

"Come on baby light my zooxanthellae" -Jim Molluskson
Courtesy: Eric Johnson via the NOAA Photo Library

Now as anyone who's forgotten sun screen on a tropical vacation can attest, the sun at the equator is incredibly strong. Solar radiation in the middle of the day is so intense that photosynthesis can actually decrease as the clam's symbiotic algae try to protect themselves from sun burn. But this is a collective man, and the clam does its part to help the algae function efficiently.

The algal cells under the clam's skin are arranged in stacked towers, which is confusing because that means the cells on top shade out those below them. To counter this Tridacna have their own cool cells called iridiocytes (pronounced: ear-id-ee-oh-sites) which bend light in different directions. The iridiocytes reflect yellow and green light (which aren't used by the algae) away from the stacks, and reflect blue and red light (which are useful) towards them. Essentially the iridiocytes screen out the best light for the algae, soften its intensity, and evenly distribute it across the stacks of cells.

The combination of colorful algae and reflected light come together to create the mind expanding visual experience of looking at a Tridacna's skin. Cameras can't really capture how magnificently colored these animals are, so I really encourage you all to take a trip to your local aquarium and see them for yourselves. But here's another picture to tide you over 'til then.

  Couretsy: Nick Hobgood via Flickr

References:

Holt et al., "Photsymbiotic giant clams are transformers of solar flux", Journal of the Royal Society Interface, Oct. 2014, DOI 10.1098/rsif.2014.0678 Accessed via:

http://rsif.royalsocietypublishing.org/content/11/101/20140678 

Soo, Pamela & Todd, Peter A., "The behaviour of giant clams (Bivalvia: Cardiidae: Tridacninae)", Marine Biology, 2014, DOI 10.1007/s00227-014-2545-0 Accessed via:

http://link.springer.com/article/10.1007/s00227-014-2545-0/fulltext.html

Getting Ston(ey)ed with Coral

We're Back! The new Depth and Taxa headquarters (AKA my apartment) is all set up with a fancy desk and everything. Thanks everyone for your patience during my moving process. So without further ado let's get back in the swing of things.

There was some great news that came out of the US National Oceanographic and Atmospheric Administration (NOAA) last month. Twenty coral species have been listed under the Endangered Species Act. "What? That's horrible, more corals are at risk of extinction!" you might be saying, but listing as endangered actually benefits many animals that are at the brink. When organisms are imperiled by extinction listing them serves to provide legal protections for, not only them, but also their ecosystems. It's kind of like a silent alarm going off. When someone breaks in, property is at risk, but once the alarm goes off; the police can come and take steps to keep you from being burgled. It's about time we got serious about protecting coral too. Whole reefs are in danger of disappearing. One study suggests that coral cover in the region between Asia, Australia and Hawaii has decreased by 20% since just the early eighties.

So why do we care? Coral is certainly very pretty, but it's also a fascinating and essential organism.

Seen here being all three at once.

Courtesy Ian Robertson via Flickr

Coral is a massive and incredibly old group of animals. In fact just about anything you think of as ancient, corals were there for its beginning: Megalodon? Coral bemoans its short time on the planet. Dinosaurs? Yeah coral thought they were cool for a while. Coelocanths? They're just trying to steal coral's old-timey charm. What I'm getting at is that coral shows up very early in the fossil record, something like 480 million years ago!

So what's the secret to coral's success? Well diversity is a big part of it. There are something like 2,500 coral species on earth today. They can be hard, soft, individual, colonial, small, large, tropical, temperate, shallow, and deep.  The corals we're most familiar with, and all of those recently added to the endangered species list, are the shallow-living stony corals we like to brag about snorkeling among when we take a trip to the tropics.

All corals are a part of the cnidarian phylum which you may remember from the earlier post about jellyfish.You might also remember that the scyphozoa, hydrozoa, and cubozoa have two life stages: the free-living medusa and the stuck-on polyp. Corals are part of the anthozoa which are all the animals that have no medusa stage.

Perseus can get behind an animal that removes the medusa. (I will not apologize for this terrible joke)
Courtesy Wally Gobetz via Flickr

What stands stony corals out from other members of their phylum is their structure. Unlike sea anemones or jellies; stony corals actually secrete a skeleton. Coral that you might find at a jeweler's, or on the beach, is in fact the skeletal remains of a stony coral. So your beach house may have skeletons in its closet as well as on its coffee table. These skeletons, made of the same molecules as eggshells, are what allow for the gigantic reefs seen in tropical waters throughout the world. And amazingly every reef starts out as a single teeny-tiny coral polyp.

See when a coral mommy-daddy and daddy-mommy (many stony corals are hermaphroditic) love each other very much, and the season and tidal phase are right, they pour floating packets of sperm and eggs out of their bodies and into the water. It's all very romantic as thousands of other animals circle the waters around them devouring their genetic material before it even has a chance to mix. But luckily there are so many of these gamete (reproductive cells) balloons that some do make a new baby coral. At this point in their life baby corals are called a planula, they're microscopic, and they're covered in little cellular oars that allow them to move and find a place to settle. As they settle, baby coral metamorphoses into its adult form, but its still incredibly tiny and all alone. So our intrepid hero begins making itself some friends, by cloning.

"I'm pleased...we're pleased...it's nice to meet you"
Courtesy Nhobgood via Wikimedia Commons

Each of those little anemone looking things up there is a clone of a single polyp that settled on a hard surface. If the entire colony is very large, then the original polyp probably settled decades ago. Some head's of coral have been estimated to be over a thousand years old! This slow growth rate is one of the reasons many coral reefs are at risk of extinction.

 Amazingly, although the clones are separate individuals from the other polyps they all share body tissues with one another. As the polyps catch prey with their stinging tentacles and eat it; the nutrients from that food are actually spread across the shared tissue so that the whole colony benefits. These shared tissues are also what secrete the hard skeleton of stony corals. And it's inside the corals' shared tissues that we can find the reason for their stony skeleton.

Just beneath the skin of stony corals lives one of a number of different algae. These single-celled seaweeds, called zooxanthellae, (pronounced zo-zan-thell-ee) are taken in by the coral deliberately because they can benefit one another greatly. The algae is protected from the thousands of mouths out in the plankton and the corals' wastes make great fertilizer. The coral also benefits because the algae's photosynthesis provides oxygen and nutrients both of which the coral can use. So the coral creates this elaborate skeleton in part to reach for the sun. The skeleton acts like the trunk and branches of a tree pushing the coral and its algae buddies towards the light. The constant competition for sun is what has driven the evolution of so many amazing forms and shapes of different corals.

Enough sun salutes to make a yogi weep for joy
Courtesy US Fish and Wildlife via Flickr

 This mutual symbiosis has been going on for so long and is so beneficial that some coral species can't feed themselves without their zooxanthellae. When people talk about coral bleaching this is what they mean. Something has gone wrong in the ecosystem, so the algae have either gone elsewhere or died. Leaving only skeletons behind. Luckily you can easily help prevent bleaching if you visit tropical areas. Danovaro et. al discovered that synthetic sunscreens actually encourage the growth of viruses that infect and kill zooxanthellae. So when you take that snorkeling trip make sure to use non-synthetics like titanium dioxide or zinc oxide. Often times these sunscreens are labeled as "coral safe" or "sensitive skin" so they're easily found.

References:

http://www.fws.gov/endangered/laws-policies/

http://www.noaanews.noaa.gov/stories2014/20140827_corallisting.html

http://www.ucmp.berkeley.edu/cnidaria/anthozoafr.html

https://marine.rutgers.edu/pubs/private/Mass%20et%20al_Immunolocalization_PNAS2014.full.pdf

Danovaro et. al, "Sunscreens Cause Coral Bleaching by Promoting Viral Infections", Environmental Heatlth Perspectives Apr. 2008: 116(14): 441-447. Accessed via http://www.ncbi.nlm.nih.gov/pmc/articles/PMC2291018/

Hoover, John P. "Hawai'i's Sea Creatures: A Guide to Hawai'i's Marine Invertebrates", pg 46-49, Mutual Publishing, 1999