A Better Understanding of Coral Reef Ecosystems

Pelagic predators such as these barracuda, Sphyraena qenie, are part of the coral reef ecosystem in the U.S. Line Islands (NOAA Photo by Kevin Lino).
A team of scientists have embarked from Hawai'i on a three-month survey of coral reef ecosystems at Johnston Atoll, the U.S. Phoenix Islands, the islands of American Samoa, and the U.S. Line Islands in the tropical Pacific Ocean. The overarching objective is to better understand the coral reef ecosystems of these areas, many of which are seldom explored. The research expedition is part of a regular monitoring program, conducted by the Coral Reef Ecosystem Division (CRED), headquartered in Honolulu, Hawai'i. The expedition is supported by NOAA's Coral Reef Conservation Program and involves extensive cooperation among NOAA scientists and research partners, including the University of Hawaii Joint Institute for Marine and Atmospheric Research (JIMAR), the U.S. Fish and Wildlife Service, San Diego State University, and the Papahānaumaokuākea Marine National Monument.

The research expedition will be carried out from February 27 to May 24, 2012 aboard the NOAA ship Hi'ialakai. Under the leadership of Chief Scientists Dr. Jill Zamzow, Dr. Bernardo Vargas-Angél, and Jamison Gove, a diverse team of researchers will be conducting multidisciplinary coral reef ecosystem surveys, assessing the status of fishes, corals, algae, marine invertebrates, and the oceanographic conditions in which these organisms exist. The scientific data collected during the three-month research expedition will enable informed and effective implementation of ecosystem-based management and conservation strategies for coral reef ecosystems, helping to ensure their protection for generations to come.

Wednesday, May 13, 2009

Coming to a close

We arrived back in Saipan on May 7, concluding a monumental expedition to Wake, Guam and the Commonwealth of the Northern Mariana Islands.  We all have mixed emotions.  On the one hand is it nice to sleep in our own beds, see our loved ones, and spend some time on dry land again.  On the other hand we all miss the water and the islands we have come to know and love so  much.

We will spend the next several weeks error checking all the data we collected and putting together our reports of all that we saw and discovered.  Our final cruise report should be ready in a month or so.  Stay tuned for a link to that and follow along both here and on our FaceBook page for continuing research and future expeditions.

Monday, May 4, 2009

Where are all the little guys?

Did you know that a coral reef ecosystem contains thousands of creatures besides fish and coral? We just can’t easily see them because many are cryptic, nocturnal, or simply too small to easily see.   And yet, these invertebrates make up most of the diversity in a coral reef system. So how do we monitor and assess all the organisms that we can’t see? Our answer is the Autonomous Reef Monitoring Structure, otherwise known as ARMS.

ARMS were developed as a long term sampling and monitoring device to detect, measure, and monitor the diversity of cryptic invertebrates in reef systems over time. They are designed to simulate a reef environment.  The layers of the ARMS have both open and closed spaces which provide both hard settlement areas and small hiding holes for various kinds of small organisms. Our ARMS are installed by two divers and remain on the sea floor for 2 years collecting organisms before we remove them an analyze their contents.

Overtime, critters will start to colonize the ARMS. Sessile invertebrates such as sponges, tunicates, and bryozoans, will recruit to and settle on them. Small motile critters such as majid crabs, squat lobsters, polychaetes, brittle stars, and nudibranchs will eventually make their way within the layers and call the ARMS their new home. It’s like a little reef apartment building.

An aspiration of the ARMS project is to create indices of biodiversity across diverse habitat gradients around the world. ARMS currently exist in Moorea, Australia, Brazil, Hawaii, American Samoa, and the U.S. Pacific Islands and will soon be deployed in Papua New Guinea, Panama, Cayman Islands, Puerto Rico, and the Seychelles. MARAMP 2009 added Wake Atoll, Guam, and Saipan, Pagan, and Maug in the Marianas to the ever growing list. This global ARMS effort is a part of the Census of Marine Life, CReefs project.

Friday, May 1, 2009

Fishy Fun at Farallon de Pajaros

The island of Farallon de Pajaros (aka Uracus), is the northernmost island in the Mariana Archipelago. It is also considered the most volcanically active. Although, the last major eruption was recorded in 1967, undersea vents and the nearby Makhahnas seamount are still reportedly active. Its steep slopes are stark, but populated by thriving seabird communities, which nest on the platforms created by past lava flows.

Underwater, the relatively young reef ecosystem is populated by scattered coral colonies. In some areas, the corals are attached to boulders surrounded by black sand, but in others they are attached directly on the dark volcanic rock substrate along steep walls. While the reef here is not as well developed as others in the chain, the fish population here was surprisingly robust and interesting. (Photo: R. Schroeder)

The Fish Team was able to document two important findings at this island: the continued presence of the endemic yellow-crowned butterflyfish, Chaetodon flavocoronatus, first noted during the 2007 MARAMP, and a species of fish previously not recorded in the Marianas, the saddleback hogfish (Bodianus bilunulatus).

Yellow-crowned butterflyfish (Chaetodon flavocoronatus) Photo: M. Nadon

Black Jack (Caranx lugubris) Photo: V. Brown

White-tip Reef Shark (Triaenodon obesus) Photo: M. Ferguson

Those were not the only interesting finds of the day, because every REA site provided close encounters with curious large predators from friendly black jacks, Caranx lugubris, to more intimidating great barracuda (Sphyraena barracuda), white-tip reef sharks (Triaenodon obesus), and gray reef sharks (Carcharhinus amblyrhynchos).

Great barracuda (Sphyraena barracuda) Photo: V. Brown

But clearly, the highlight of our day had to be the entertainment we received during our safety stop, as we were visited by a school of more than a hundred Spadefish, also known as Batfish, or Platax teira to the scientists on the Fish Team. These beautiful, somewhat goofy fish surrounded us as we floated at fifteen feet. They swam in circles around us, first one way, then another, boldly approaching close enough to stare into our eyes, almost close enough to touch. Their antics amused and delighted us, bringing a bright ray of light into an otherwise cloudy, overcast day. The evening was spent sharing pictures and stories of our encounters. It was definitely a memorable experience for both the Oceanography and REA teams who encountered these gregarious fish.

Spadefish (Platax teira) Photo: M. Ferguson

Spadefish School Photo: R. Schroeder

Thanks for Visiting! Photo: V. Brown

Sunday, April 26, 2009

Does Sand Kill Corals?

Depending on the scenario, sand can hurt corals … but corals have also developed ways to protect themselves from sand or sedimentation.  Sand can affect corals in a number of ways:
  • When there are a lot of waves, sand particles can become suspended in the water column and as the waves move the water back and forth, these particles can scour the reef (and corals) like a slow but steady sand blaster.
  • When there is a lot of sand in the water, the visibility (how far you can see) and the amount of sunlight reaching the bottom is decreased.  Since corals use sunlight for energy(by way of their symbiotic zooxanthellae) this can reduce the rate at which the corals grow and in extreme cases can cause bleaching or even kill the coral.
  • Even in calmer areas, where there are not as many waves, sand can sometimes land on corals. If too much sand lands on a coral it can be smothered and killed.  ... but many corals have a way to rid themselves of this “unwanted sand.”  They can secrete a mucous layer which acts as a protective shield.  When sand lands on the coral, it gets stuck in the mucous layer and then when water motion increases, the coral sheds the mucous layer – and all the sand that was stuck to it.

Hearing the Reef with our "EARs"

Scientists deploy an EAR on a nearby reef

Recently we have had several questions about the EARs or "Ecological Acoustic Recorders" we are deploying at various islands and reef to monitor sounds in the shallow water areas during the year or two between expeditions.

Mr. Hill's period 2 class asks: "What type of fish can you hear with the EAR or what was the most exciting thing you have heard on the EAR?"

The Ecological Acoustic Recorder can record a variety of sounds. We often listen to whales, dolphins, snapping shrimp and of course fish. Some of the most common fish sounds that we have identified are the domino damsel fish Dascyllus albisella (a purr), the soldierfish Myrispristis sp. (drum sound) and the butterfly fish Chaetodon sp.  Many of the fish sounds we listen to have not yet been linked to a particular species and we are collaborating with the University of Hawaii and Dr. Tim Tricas to identify fish and sounds they produce.

One of the most exciting findings the EARs have provided is the discovery of Humpback whales using the Northwestern Hawaiian Islands (NWHI) as a winter habitat, just as they do in the main Hawaiian Islands.  It was commonly thought that Humpbacks only transited through the NWHI.  EARs in the NWHI have recorded Humpback whale song, indicating the use of the area as a breeding site.

We have had an occasion where some unknown sounds on one of our EARs puzzled us for a couple of days.  We would only hear snippets of what sounded like human voice.  But the dates of occurrence of these sounds did not correspond with our deployment or retrieval of the device, so it could have not been from our divers, not to mention the fact that humans cannot usually make comprehensible sound underwater.  In the end, it turned out to be a filming crew who was getting underwater footage and we suppose they had underwater speakers.  The first full recording that we got of it said "ACTION, Action ... Follow the diver to the left..."

Who knows what we will hear next ...

A deployed EAR listens and waits ...

Thursday, April 23, 2009

Fish and How we Count Them

Orangepeel Angelfish (Centropyge shepardi)

Fish are some of the most conspicuous residents of the coral reef environment and, along with corals, tend to get the majority of the attention.  These communities also tend to be the ones we get the most questions about.  Recently we received some excellent questions from Mr. Hill's period 2, 5 and 6 classes.  They ask the following:
  • "Have any of the scientists on your team ever discovered a new species of fish?"
  • "Do you search for particular species of fish on your dives or do you simple count and measure all the fish that you come across."
  • "What type of sharks have you identified on your trip to date? What was the biggest fish that you have seen on your trip to date?"
Ornate Butterflyfish (Chaetodon ornatissimus)

We have three teams of scientists whose job it is to assess the overall condition of the reef fish community at each of the islands we visit.  While we haven't yet discovered any new species of fish on this expedition, one of our scientists may have discovered on on an expedition a few years ago.  The process of discovering a new species is more complicated than you might imagine.  You may find something you don't recognize, but that doesn't mean that NO ONE has ever seen it before.  If you find something you can't identify you have just started down a very long but exciting path.  First you have to do quite a lot of research to make sure you really are the first person to see and describe your particular fish.  You look through all your fish guides and all the scientific papers you can find, consult regional and local experts and taxonomist at universities and museums to see if ANYONE has ever seen the fish you found.  If you really are the first person to see it you then need to describe it and publish your findings in the scientific literature to let other scientists know of your find.  You describe in extreme detail what the fish looks like so that other scientists can compare fish they may find to your notes.  You describe what color it is, how big it is, what shape it is, how many scales it has along its lateral line, how many fin rays or spines it has in each of its fins, you may even take a sample for genetic analysis so that the DNA sequence of your fish can go into a taxonomic gene bank.  This process can take years but it is very exciting.  When all is said and done, you get to name your fish!

Saddled Butterflyfish (Chaetodon ephippium)

So ... Do we count all fish we encounter? That’s an excellent question. We do count every single fish we encounter in our survey area. Of course, we know very well that we are missing some, especially the ones that are hiding deep inside the recesses of the reef, but we do the best we can.  Often we are not as much trying to get an accurate count of the total number of fish in a particular area, but more how a given site compares to other sites we visit.  For this purpose, as long as we are making our counts in the same way at each site, we are likely missing the same things each time so our counts are comparable.  The more counts we make, the more accurate we are.  Although we pay special attention to the typical “food” fishes, we also want to understand what is happening to the entire fish community and how it is changing through time.  Are we seeing different species now compared to what we saw in the past?  Is the total number of species or species diversity changing from site to site or over time?

Pyramid Butterflyfish (Hemitaurichthys polylepis)

So how do we count all those hundreds of fish belonging to various species swirling around us?  We use a variety of different methods al of which involve SCUBA.  For many of the smaller fishes: we stay at the center of our survey area, take 5 minutes to establish a species presence list, and than proceed to enumerate and size all the fish in this list, one species at a time.  It's a little tricky, but you get the hang of it and get better the more times you do it.  There is a lot of training involved.

Divers counting small fish along transects

For some of the larger species we use what we call a towed-diver or towboard method.  These large fishes tend to exist in very low densities, that is to say, we don't find very many of them in a given area.  So, you have to cover a lot of area in order to get a good idea of how many there are at a given island.  The scientists who study these fish use dive planes which are towed behind a small boat along the coral reef for distances of up to a mile or more.

A towboarder flying over the reef

We fly these dive planes at a depth of about 50 feet and count all of the large fishes we come across during a 50 minute survey.  We don't count as many fish, but the ones we see tend to be bigger.  We see a whole variety of species including a lot of sharks.  On this expedition most of the sharks we have seen have been white-tip reef sharks (Triaenodon obesus) but we have also seen a few gray reef sharks (Carcharhinus amblyrhynchos) and tawny nurse sharks (Nebrius ferrugineus).  What is the biggest fish we have seen so far?  Definitely one of the nurse sharks which was about 6 feet long.  We have also seen some big dogtooth tuna (Gymnosarda unicolor).

Blackfin Barracuda (Sphyraena qenie)

Dogtooth tuna (Gymnosarda unicolor)

Monday, April 20, 2009

Small but Colorful

photo by Cristi Richards

A nudibranch (Chromodoris elisabethina) crawling along the reef

While many of the animals that people think of when someone mentions coral reefs are large or conspicuous like turtles, fish, and even the coral itself, other residents of the reef are small and easily missed. One such creature is the nudibranch.  Nudibranch literally means 'Naked Gills' which is appropriate because it breathes through a set of bushy external appendages on its back, sort of like wearing your lungs on your back. Nudibranchs, also sometimes called sea slugs, are a group of shell-less snails that live in all oceans of the world and at almost every depth. They are often very colorful but are easily overlooked because they are usually less than an inch long. They tend to be carnivorous, feeding on sponges, anemones, or other sea slugs and the 'horns' that you see at the front are actually sensory organs used for touch, taste and smell. They defend themselves either by blending into the algae or coral around them or by using bright colors to indicate that they are poisonous.  If you look closely, you may be lucky enough to spy one crawling along the reef.

Sunday, April 19, 2009

A little more about corals

by Jean Kenyon, photo by Cristi Richards

While on the expedition we have received some excellent questions from students following the expedition.  From time-to-time we will try our best to answer as many of your questions as we can.  For Mr. Hill's period one class, here is a brief discussion on corals by Dr. Jean Kenyon:

Corals can reproduce in two major ways. One is by "sexual reproduction" in which an egg is fertilized by a sperm, which then develops over a period of time into an adult coral. Another way used by some, but not all, types of coral is "asexual reproduction", which usually involves a piece of the adult colony breaking off, becoming re-attached to the bottom, and continuing to grow. Sexual reproduction produces a genetically distinct individual, while asexual reproduction produces offspring that are identifical genetic copies of the parent.

More than 200 species of corals are known from Guam. Wake has been less well studied, but at least 80 species have been documented.

Corals get their color from two sources. Some of the color actually comes from colored pigment in microscopic algae (zooxanthellae) that live inside their tissue. Some, but not all, corals, have additional colored pigment inside their own cells.

For more information on corals, you might want to head over to this coral biology page put together by the Bermuda Biological Station for Research.  Corals exist all around the world in warm tropical waters and while the BBSR deals mainly with Atlantic corals, the basic biology remains the same.

Saturday, April 18, 2009

Last days at Tinian

We finished surveys around Tinian a few days ago and it was one of the first really spectacular weather days we've had. We were treated to sunny skies and calm water with not a swell or white cap in site.  We were also treated to some amazing scenery ... as the last few islands we have explored (Guam, Rota, Aguijan, and Tinian) have all been composed of limestone that has dissolved through the years from the pounding of waves and rain. These combined forces have created some amazing caves and overhangs. Some of the caves are at the water's edge while others are half way up the cliff face. It has made for some dramatic transits between survey sites.

Unfortunately, one of our small boats (HI-1) wasn't having quite as good of a day as we were. It has been having intermittent transmission troubles for the last few days which clear up every time we bring the engineers out to take a look (kind of like when you take your car to the mechanic). On their last dive, while on the bottom, the REA team could hear the boat overhead and a rhythmic knocking as if there was tribal music playing.  Then everything went quiet and as they were swimming back to the boat, they noticed that the anchor line was out - not a good sign. The boat had evidently stopped working all together and a tow boat from the ship was on the way to bring them home. It was a very quiet, slow ride back with plenty of time to consider the luxury of such a large diving platform versus the inflatable Avon that they will be using until HI-1 is up and running again. So begins our adventures aboard Avons! Wish us luck ...

Sunday, April 12, 2009

Plectroglyphidodon imparipennis

What is that? It's this guy:
How do you say it? Your guess is as good as mine.

Plectroglyphidodon imparipennis is the scientific name for the bright-eyed damselfish. So why can’t we just call it that? Common names for fish vary widely. Scientific names are more specific, and are used world-wide. Here at CRED, the fish team has come up with four-letter codes to make data recording a little easier. We usually use the first two letters of the genus, and the first two letters of the species name. So Plectroglyphidodon imparipennis would simply be PLIM. This is much easier to write underwater when you see many fish at once. It’s easier for our brains to say, “hmm, that’s 4 PLIM at 5 cm, 1 EPPO at 45 cm, and 4 GNAU at 22 cm.” Instead of writing down:
4 Plectroglyphidodon imparipennis’ at 5 cm, 1 Epinephelus polyphekadion at 45 cm, and 4 Gnathodentex aureolineatus’ at 22 cm. Here’s some interesting species we’ve seen so far:

Hoplolatilus starcki, or HOST, the starks tilefish

Triaenodon obesus, or TROB, a whitetip reef shark

Exallias brevis, or EXBR, the leopard blenny

Cirrhitichthys falco, or CIFL, the dwarf hawkfish

Here's Paula Ayotte pausing to write down some species codes during a survey:
and here's what a data sheet looks like after a survey:

If you are lucky and discover a new species, you get to name it. I think the species name kaylynii sounds great. Keep that in mind, all of you aspiring fish biologists.

Thursday, April 9, 2009

Finished at Guam & moving on

We’ve spent the past 4 days (4/5-4/8) working in the waters surrounding Guam. Our scientific party conducted an impressive 204 dives in those 4 days. Twenty-five REA (Rapid Ecological Assessment) sites were surveyed for fish and benthic communities. The Fish and Benthic Tow-Board teams completed 23 towed-dives covering an astounding 46.8 km! In addition to all of those surveys, the Oceanography team successfully deployed/recovered a number of moored instruments and conducted CTD casts and water sampling. We have been busy!

Today we surveyed along the south side of the island of Rota. We have one more day here before heading to north to Aguijan and then Tinian.

Tuesday, April 7, 2009

Oceanography Update!

During our 5 days in port I had the opportunity to speak to some great people from Guam's 'Lets Do Science', about oceanography and the instruments we're putting in around Guam. We've got instruments to measure sea surface temperature, subsurface temperature and the sound of the reef.

Sea Surface Temperature Buoy
Temperature is important to know because, just like you and me, corals can only survive in the right temperatures -not too hot and not too cold.

We also put out an instrument that measures the sounds of the reef.

Acoustic Recorder
This gives us data on how noisy the reef is which gives us an idea of how healthy it is with animals, as they make noises going about their everyday business. We can also listen to how many boats there are in the area.

Today was our 3rd day at Guam and we have been roasted by the sun and thrown about by the waves, especially on the east side.
We've put in all our instruments now and seen amazing things around Guam.

Tomorrow is our last day, and we'll be doing water samples and measuring the temperature and salinity (how salty the water is) using an instrument called a CTD.

Feel free to send us any of your oceanography, cruise or any other questions and we'll do our best to answer them!


Saturday, April 4, 2009

You don't have to go far

Guam is littered with history and one needn't go very far to find it.  For the past few days we have been tied up at one of the piers at the US Navy base in Apra Harbor, Guam.  Leaving the ship one is greeted by a huge anchor, originally belonging to a Japanese ship sunk off of Saipan and recently brought to Guam.
Not too far down the road is an anti-aircraft gun emplacement still waiting for incoming planes.  While many of the artifacts have been moved from their original positions, a few can still be found where they have stood for the past 60 years.  A harsh reminder of turbulent times.
Unfortunately WWII also served to obliterate much of Guam's prior history with entire towns wiped off the map either by the occupation or by the shelling and bombing which proceeded the recapture of the island.  Near the eastern end of the naval base, a partial cemetery with broken headstones is all that remains of Sumay town.Guam was also a way station for the original trans-pacific cable line linking the US mainland to her interests in the far east.  The relay station at Sumay was a prime target during the Japanese invasion, and the ruins are still pockmarked with bullet holes and mortar damage. For many of us, our knowledge of this era is limited by the black-and-white footage and photographs of the war years and it is sobering and yet beautiful to see these monuments set against the brilliant colors of the tropical pacific.

Monday, March 30, 2009

Transit Days

This particular CRED cruise leg has the most transit days of any trip. Like good scientists, we spend most of the time working. This is a great time to write up our cruise reports and compile preliminary findings from our data. We also attempt to organize photos and plan for the next leg of our cruise.
Most of us don’t know what the date is, or what day of the week it is, but we all know when it’s 7:00 AM, 11:00 AM and 5:00 PM, because that’s when we get fed. I wouldn’t say there’s a stampede to the galley, but it’s hard to ignore the delicious smells that waft their way through the ship.

Yesterday we had a training exercise in pyrotechnics. We learned how to shoot flares and rescue lines safely, and helped the ship get rid of their expired flares. It was a welcome break from the computer screen, and everyone had all of their fingers and toes when we were done. The only thing we lost (temporarily) was a plastic rocket used for launching line, and that was recovered by conducting a man-overboard drill. With all of the drills we partake in, I believe we are the safest ship in the Pacific right now.

The small gym on the ship is usually full and rocking. We want healthy scientists, and it is a nice break from working. We have an elliptical machine, a bike, a Bowflex, and free weights. The other day we had a record of 5 people in the gym, no small feat. Another favorite past-time is ping-pong. The chart table in the dry lab is just about the same size as a ping-pong table. The only challenge is that we are on a rocking ship in the middle of the ocean. It makes for some exciting ping-pong games. The scientists have accepted the fact that they may get beamed by rogue ping-pong balls, and take it in stride. It’s a small price to pay for having happy ship-mates.

Most of us aren’t used to being dry for this long and are starting to shrivel up. At long last, Guam was spotted today, so we will be back in the water before we know it!