How Do Predators Use Fear to Benefit Oysters?

Posted on February 25, 2013 by David

Over the last few weeks, we’ve explored the concept of the ecology of fear on oyster reefs. But, as David asks in the video, “does it matter?” Exactly how much does fear affect oyster filtration, or their ability to support commercially and ecologically important species? And how does fear affect the benefits we receive from ecosystems such as salt marshes and seagrass beds? Coming up, we see how David and Randall took these big questions and broke them down into a series of experiments and investigations geared at creating a clearer picture of fear in the intertidal zone.
Dr. David Kimbro FSU Coastal & Marine Lab

IGOR chip_ predators_NCE 150A few weeks ago, we had a bayside conversation about the important link between nutrients and oysters. But there is something else that may dictate whether a reef thrives: predators.

Academically, the importance of predators dates back to the 1960s. Some smart people proposed that the world is green because we have lots of big animals, which eat all of the smaller animals that would otherwise consume all the plants…hence the green world.

busycon eating moon snail

Busycon spiratum eating an Atlantic Moon snail on Bay Mouth Bar. These seagrass beds off of Alligator Point are home to the greatest diversity of predatory snails in the world. In the late 1950s and early 1960s, Dr. Robert Paine investigated the effect of the horse conch, the most dominant predator among the snails, on the habitat. David and his crew have similarly used the dynamic invertebrate population to test their theories on the ecology of fear. (click the photo for more on Bay Mouth Bar).

Now, that’s a pretty simple yet powerful concept.  Since then, lots of studies have tested the importance of predators and how they keep our world spinning. For example, Bob Paine relentlessly braved the icy waters of the NW Pacific for a decade in order to chunk ravenous sea stars from one rocky cliff, but not the other. After several years, the cliff with sea stars still had a tremendous diversity of sea creatures (algae, anemones etc.) and the cliff without predatory sea stars did not. The absence of sea stars allowed pushy, bullying mussels to outcompete all other animals for space and this gave the rocky cliff a uniform and boring mussel complexion.

The same concept has been tested on land. Ripple and Beschetta showed us why the national parks out west no longer have the really important and woody trees (aspen, willow, and cottonwood) that they historically had. By suppressing wolves for the last 50 years, we allowed elk numbers to explode and the elk have overrun the really important woody species.

But predators don’t just eat.  Enter my vivid memory of trying out for the Nash Central 8th grade football team in rural North Carolina. Contrary to my father in-law’s belief (who is a hall of fame football coach in Georgia), I wanted to play football instead of soccer.  But when it came time for try-outs, fear prevented me from pursuing this line of work.  To practice breaking tackles, each player had to lie on the ground and the rest of the team formed a circle around this player.  Unbeknownst to the guy on the ground, the coach secretly selected three players to tackle the football player at the sound of the whistle.  For twenty minutes, I watched physically un-developed friend after late-blooming friend get crushed by other guys who were definitely not late bloomers. The sights and sounds of this drill kept me nauseous until it was my turn. When my turn came, I couldn’t deal with the fear, didn’t perform well, and consequently became a soccer player.

My point is that fear is very powerful. Of course, I knew the charging football players were not going to eat me. But if I was paralyzed with fear from football, then imagine what it’s like for something that has to worry about being eaten. Going to back “the world is green” story: what if we overlay the concept of fear on that? How does the story change?

Well, the next generation of predator studies has examined how the fear of predators can be just as important as the appetite of predators. In addition, because predators can only eat only one animal at a time but can simultaneously frighten many more, fear can create powerful “remote-control effects”. In Australia, the fear of tiger sharks causes dugongs to avoid certain depths in a bay. As a result, only a small portion of the seagrass beds get grazed down by dugongs, possibly being one of the main reasons why areas like Shark Bay still have huge and lush seagrass meadows.

Mud crabs (like the one pictured here), oyster drills, and crown conchs are the primary consumers of oysters on the reef.

For the next few weeks, we will look at some work that my friends and I have conducted for the past three years on how predators and the fear of predators influence oyster reefs and the services that they provide us throughtout the southeast. Although we have the same predators and things that like to eat oysters from North Carolina to Florida, we suspect that differences in the environment will cause the effect of predators to play out differently.

In parting, I just want to say that this predator stuff is really interesting and I think it’s very important for oyster reefs. But of course, when you are dealing with an ecosystem that may be on the verge of collapse like Apalachicola Bay, the distinction between the appetite and fear of predators may not matter that much. But, we will soon see because we are now investigating this important system too.

We'll be following the Apalach study as well. Here, Stephanie Buhler, who we had previously seen diving in Apalachicola Bay, welds a cage to house an upcoming experiment in that research. It's a variation of the tile experiments that became such a staple of the NSF oyster study. In a few days, we break down the tile experiment, and David's collaborator, Dr. Randall Hughes, talks about what the results are telling them so far.

Music in the video by Revolution Void.

In the Grass, On the Reef is funded by a grant from the National Science Foundation.

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Notes from the Field: Overwhelmed Oysters

Posted on February 19, 2013 by Meagan Murdock
Meagan Murdock is a lab technician in the Hughes and Kimbro Labs, operating out of the FSU Coastal and Marine Laboratory. The experiment she describes in the following post is a central staple in the research conducted by Dr. Randall Hughes and Dr. David Kimbro into oyster reef ecology. They seek to measure factors affecting the health of an oyster at a given location by monitoring the growth of young oysters (spat) in a controlled unit- the spat tile. We’ll be further exploring the use of spat tiles in their NSF funded oystern study in the next couple of weeks. David Kimbro is also gearing up to deploy a tile experiment in Apalachicola Bay, with the goal of measuring conditions there (see photo below).
Meagan Murdock FSU Coastal & Marine Lab

Beautiful reef backing up to red mangroves (Rhizophora mangle) in Mosquito Lagoon, FL. Notice our experiment on the reef!

Mosquito Lagoon of Canaveral National Seashore is in the northern section of possibly the most diverse estuary in North America, the Indian River Lagoon. But don’t let the name “Mosquito” Lagoon scare you off! This lagoon is an expanse of mangrove islands, oyster beds, and home to charismatic animals like manatees and dolphins (maybe a few mosquitoes, but where in Florida can you not find mosquitoes??).  Eight months ago, we set up a rendition of the “Tile Experiment” at three National Park Service units in hopes of elucidating factors contributing to oyster spat (spat=newly settled oyster) survival and growth. Last week we ventured out to Mosquito Lagoon to check on our baby oysters and this is what I found. The tiles were covered in BARNACLES!

Tile 75 pictured after being deployed for 2 months and 8 months.

I felt bad for the little oysters. Not only are these spat expected to survive through adverse environmental conditions and hope they do not become some crab or fish’s dinner, but they also are competing for space and resources with other filter feeders. Geez it must be tough being an oyster! But-yeehaw!-the oysters are persevering and I got to enjoy the nice weather of Central Florida.

Barnacles overtaking the experimental oysters.

As Meagan continues to monitor the growth of her Canaveral oysters, David is having Stephanie Buhler and Hanna Garland deploy some test tiles in the subtidal (always submerged) oyster reefs of Apalachicola Bay.  The tiles will be protected by a steel cage which will allow access to researchers while protecting the experiment from an oysterman’s tongs.  Different prototypes of tiles and cages were deployed last week with the full experiment to begin in the coming weeks:

 In the Grass, On the Reef is funded by a grant from the National Science Foundation.

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Expedition Florida 500 Paddles to Highlight History and Conservation

Posted on February 14, 2013 by Rob
Rob Diaz de Villegas WFSU-TV

This week, we take a short break from oysters and the ecology of fear for a new EcoAdventure.  We’ll be back in oysters next week, as we look at fear and coastal predators and find out about an ongoing experiment on Florida’s East Coast.  It’s an iteration of the tile experiment examined in this video (and which we will explore more fully in a couple of weeks).  This is a research method Randall, David & co. perfected during their NSF funded oyster study and which David will soon take to his Apalachicola Bay study.  Stay tuned!

In the video, Justin Riney says, “A lot of people don’t think conservation or history is that sexy.”  As a television producer who mainly works to create content on these and similar topics (namely ecology), I appreciate the creativity with which he has designed his mission.  Stand Up Paddleboarding (SUP) has become immensely popular over the last few years, and I have to admit that it made for a cool entrance as we waited for Justin to see him appear in the distance and see him paddle his way up to the beach.

A few interesting tidbits:

  • Justin’s travel plans call for him paddling a relatively short ten miles a day.  This allows him to stop in the towns he passes and get to know people along the way. The plan calls for paddling on six out of seven days a week.  The extra days come in handy when weather delays him.

  • Justin takes a picture of me taking a picture of the trash found during the Dickerson Bay Ocean Hour cleanup on February 2.

    Ocean Hour, the other main initiative of Justin’s Mother Ocean project, has active participation on four of the seven continents (anyone up for Ocean Hour Antarctica?).  Ocean Hour is from 9 to 10 AM every Saturday, anywhere that people want to go to a coast and clean up.
  • One of Expedition Florida 500′s partners is Viva Florida 500.  You can learn more about events celebrating the 500 years since Juan Ponce de León’s arrival in Florida here.
  • When Justin was going over what he packed for his yearlong trip, he mentioned books.  This intrigued me, as a year’s worth of reading seems like a lot of weight to carry on a SUP.  What he does is trade books along the way, usually reading about the places he’s visiting.  During his time in Wakulla, he read books by Gulf Specimen Marine Lab’s Jack Rudloe, at whose home he was staying.
  • The video above took place entirely on the Saint Marks National Wildlife Refuge, which has become one of my favorite places to shoot (and visit).  Dickerson Bay is part of the Panacea Unit, off of Bottoms Road.  As you drive down Bottoms, there is a nice sized salt marsh on either side of you in which there are usually plenty of birds (the Great Florida Birding and Wildlife Trail sign on Highway 98 outside of Panacea is the signal to slow down before your turn).  I first went there with Jack Rudloe, who dragged a net in the water and gave us a quick lesson in marsh ecology from the animals he caught (and quickly released).  The WHO festival took place in the St. Marks Unit, the central unit of the Refuge.  There were plenty of birds in Lighthouse Pond, as there were when we visited last year when Migratory Shorebirds were making use of the extensive wetlands on the property.

    • Music in the piece was performed by Hot Tamale (playing live at the Festival) and we featured the track Future 03 by Necronomikon Quartett.

    The kayak we used to tape the community paddle was provided by the Wilderness Way.

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    Fear and the Choices Oysters Make

    Posted on February 6, 2013 by Randall

    Last week, Dr. David Kimbro broke nutrients and oysters down for us.  But what if oysters are too scared to eat the nutrient fed plankton they need to survive?  David and Randall take us another step closer to understanding the Ecology of Fear, examining oysters’ choices and how their behavior affects the important habitat they create.  Stay tuned over the following weeks as they unravel the relationships between predators and prey on oyster reefs and their neighboring coastal ecosystems.  We’ll also continue to follow David’s crew in Apalachicola, Hanna and Stephanie, as they research the oyster fishery crisis.

    Dr. Randall Hughes FSU Coastal & Marine Lab

    IGOR chip_ predators_NCE 150I recently moved and was faced with the dilemma of finding a place to live. This can be a touch decision, especially when you’re in a new city or town. Which neighborhood has the best schools? The best coffee shop? Friendly neighbors? Low crime? My solution was to find something short-term while I scope the place out some more, and then I can decide on something more permanent. (As anyone who has me in their address book knows, “permanent” is a very relative term – I have changed residences a lot over the last 15-20 years!) But imagine you had just one shot – one, for your whole life – to decide where to settle down. Talk about a tough decision! That’s what oysters have to do, because once they settle down and glue themselves to their location of choice, they don’t have the opportunity to move around any more. So how do they decide?

    This oyster shell, harvested from an intertidal St. George Island reef, had been settled by multiple young oysters called spat. Spat grow into mature oysters with a hard shell, fused with the oyster on which they originally landed. Clumps of attached oysters form a crucial coastal habitat.

    It turns out that oyster larvae (baby oysters swimming in the water) can use a number of “cues” to help them in the house-hunting process. First of all, they can detect calcium carbonate, the material that makes up oyster shells (and other things) – if there’s lots of calcium carbonate in an area, that could be a good sign that it’s an oyster reef. (Or it could be a sign that people have put a lot of cement blocks in the water in the hopes that oysters will settle and create a reef – that’s how a lot of oyster restoration projects are started.) Some recent research even shows that oysters can detect the sounds of an oyster reef, and then swim in that direction! Maybe these guys are smarter than we think…

    Regardless of how oysters decide, there are times when we are also faced with the question of what makes good oyster habitat, or deciding which area is better than another. As scientists, we turn to experiments. One type of experiment that we have perfected over the years involves getting juvenile oysters- (either from the field, which can be pretty difficult -as you can see from the first round of our tile experiment, or from a hatchery), and gluing them to portable sections of “reef” (ceramic tiles weighed down by bricks). LOTS of ceramic tiles and bricks. We’re talking 800+ ceramic tiles and 700+ bricks last summer alone! That’s enough to make a path that is ~2 football fields long. All moved by truck, hand, boat, hand, kayak, and hand to their temporary location on a reef (and then moved back again when the experiment is done). But I digress.

    In the second incarnation of the tile experiment, oyster spat were attached to tiles with an epoxy used in the repair of boat hulls. The tiles in the first version- the ones in the video above- were assembled differently. In a video we'll premiere later this month, we'll look at the twists and turns the experiment took.

    After attaching the juvenile oysters to the tiles with a lovely substance known as z-spar, we enclose some tiles in cages to protect them from oyster predators, and we leave others with no cage so they are “open” to predators. (There’s also a 3rd group – the “cage control” – that get 1/2 a cage so we can test whether the cage has effects on the oysters other than keeping out the predators.) Then we take our oyster tiles and put them out in the field at different sites that we want to test. By observing the survival and growth of the ones in the cage (where no predators have access), we can get a general sense for whether it’s a good environment or not. Lots of large, live oysters are a sign of a good environment – plenty of food, good salinity (not too salty or too fresh), good temperature, etc. Also, by comparing the survival of the ones in a cage vs. not in a cage, we can get an idea of how many predators are around – lots of live oysters in the cage and none out of the cage is a pretty good sign that oysters are getting eaten. (If oysters in the cage are dead and oysters outside of the cage are missing, it’s a little tougher to figure out exactly what’s causing it, but it’s clearly not a good place for oysters to live!)

    Experimental spat tiles at the Guana Tolomato Matanzas National Estuarine Research Reserve- open, closed, and partially open.

    Of course, the oysters themselves don’t know whether they are nice and safe inside our cages, or easy pickings for a predator. So if there are lots of predators lurking around the reef, the oysters may try to “hide”. Obviously, hiding for an oyster does not mean packing up and moving elsewhere, but they do have a few tools at their disposal. In the short term, the oysters can choose not to open up their shells and feed (filter water) as often. This strategy has 2 benefits – 1, they are less vulnerable to predators when their shells are closed and 2, they aren’t releasing lots of invisible chemical cues in the water when they’re closed, so it’s harder for the predators to tell they are there. But as any of you who have been sticking to your New Year’s resolution to lose weight will know, there’s only so long that you can go without eating before that strategy loses its appeal! Over the longer term, the oysters can decide to devote more of the energy that they get from eating to create a thicker, stronger, rougher shell, rather than plumping up their tissues.

    So, those are the big-time decisions that an oyster faces: where to live, and when to eat. Sounds kind of familiar…

    We want to hear from you! Add your question or comment.

    In the Grass, On the Reef is funded by the National Science Foundation.

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    What’s the deal with nutrients and oysters?

    Posted on January 30, 2013 by David

    As David & co. start their new research on the Apalachicola oyster fishery crisis, He and Randall (and their colleagues in Georgia and North Carolina) are starting to wrap up the NSF funded oyster study that we have been following over the last couple of years.  Over the next few weeks, we’ll take a look back at that research through a series of videos.  We’ll cover some oyster basics (how does an animal with no brain behave?), explore David and Randall’s ideas on the role of fear on the oyster reef (what makes a mud crab too afraid to eat an oyster?), and see the day-to-day problem solving and ingenuity it takes to complete a major study.  As these videos are released, we’ll also keep tabs on the work being done in Apalachicola Bay, in which many of the same methods will be used.
    Dr. David Kimbro FSU Coastal & Marine Lab

    After all, nutrients are basically plant food and oysters are animals.  And how could too few nutrients coming down with the trickling flow of the Apalachicola River possibly explain the record low number of Apalachicola oysters?

    This is the perfect time to use the favorite idiom of my former mentor Dr. Ted, “The long and the short of it is….”

    The short of it: Plants love nutrients and sunlight as much as I like pizza and beer. But unlike my favorite foods, these plant goodies make plants grow fast and strong. This works out well for us because we all need nutrients for basic body functioning, and because we get them by eating plants and/or by the eating animals that previously consumed plants.

    For our filter-feeding bivalve brethren, they get nutrients and energy by eating plant-like cells (phytoplankton) that float in the water. So, it is possible that the trickling flow of the Apalachicola River is bringing too few nutrients to support the size of the pizza buffet to which the Apalachicola oysters are accustomed. But this idea has yet to be tested.

    Hanna Garland and Stephanie Buhler harvest oysters from sample reefs in Apalachicola Bay.

    The long of it: Long before the flow of the Apalachicola River slowed to a trickle, there weren’t a lot of nutrients. That’s why the numbers of humans used to be so low: too few nutrients meant too few plants and other animals for us to eat.

    How could this possibly be the case given that 78% of the air we breathe is made up of a very important plant nutrient, nitrogen? And there is a lot of air out there!

    Well, only a precious few plants exist that can deal with the nitrogen in our air and these are called nitrogen-fixers. Think of these as single-lane, windy, and bumpy dirt roads. In order to help create a plant buffet for all of us animals, a lot of atmospheric nitrogen (bio-unavailable) has to travel down this very slow road that the n-fixers maintain. As a result, it naturally takes a long time for the land to become fertile enough for a large buffet. And, it only takes a couple of crop plantings to wipe out this whole supply of bio-available nitrogen that took so long to accumulate.

    guano island

    Sea birds on a guano island off the coast of Peru. (zand.net)

    Turns out that the ancient Inca civilization around Peru was not only lucky, but they were also pretty darn smart. Lucky, because they lived next to coastal islands that were basically big piles of bird poop, which is very rich in bio-available nitrogen. I’m talking thousands of years of pooping on the same spot! Smart, because they somehow figured out that spreading this on their fields by-passed that slow n-fixing road and allowed them to grow lots of food. Once Columbus tied the world together, lots of bird poop was shipped back to European farms for the same reason. That’s when the European population of humans sky-rocketed.

    Turns out that humans in general are pretty smart. Through time, some chemists figured out how to create artificial bird poop, which we now cheaply dump a lot of on our farming land. So, in these modern days, we are very, very rich in bio-available nutrients.

    Where am I going with the long of it? Well, on the one hand, these nutrients wash off into rivers and then float down into estuaries. This is how the phytoplankton that oysters eat can benefit from our solution to the slow n-fixing road. In turn, oysters thrive on this big phytoplankton buffet.

    Slide by Ashley R. Smyth, Piehler Lab, UNC Chapel Hill Institute of Marine Sciences.

    But, on the other hand, too much of these nutrients flowing down into our estuaries can create big problems. Every year, tons of nutrient-rich water makes it way down the Mississippi and into the shallow Gulf of Mexico waters. There, this stuff fuels one big time buffet of phytoplankton, which goes unconsumed. Once these guys live their short lives, they sink to the bottom and are broken down by bacteria. All this bacterial activity decreases the oxygen of water and in turn gives us the infamous dead zone. Because nutrient-rich run-off continues to increase every year, so too does the dead zone.

    I’ll close with the thought that oysters themselves may help keep the phytoplankton buffet from getting out of control by acting like anti-nitrogen fixers. In other words, they may help convert an excess of useable nitrogen back into bio-unavailable nitrogen. While this might not have been a great thing to have in low nutrient situations, we currently live in a nutrient-rich era. What’s even cooler is that it all has to do with poop again! But this time, we are talking oyster poop.

    Oyster Summit 6

    Dr. Mike Piehler, presenting to his collaborators Dr. Jeb Byers (Right), Dr. Jon Grabowski (reclined on couch), Dr. Randall Hughes and Dr. David Kimbro (out of frame). These five researchers have worked on oyster reef ecology since their time at the University of North Carolina. Three years ago, the National Science Foundation funded research into their ideas about predators and fear on oyster reefs.

    So does this really happen? Yes. Check out an earlier post for the details. But we don’t fully understand it and that’s why it is a major focus of our research. Our collaborator, Dr. Michael Piehler of UNC-Chapel Hill, is leading this portion of our research project. Read more of Dr. Piehler’s work on this topic here.

    So, hopefully this post explains why the relationship between nutrients and oysters is not so simple. But it sure is interesting and a worthy thing to keep studying!

    Cheers,
    David

    In the Grass, On the Reef is funded by the National Science Foundation.

    We want to hear from you! Add your question or comment.
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    Notes From the Field: Becoming an Oyster Woman

    Posted on January 23, 2013 by Stephanie Buhler

    Stephanie Buhler is the newest addition to the Hug-Bro family (the HUGhes and KimBRO labs).  She and Hanna Garland have been alternating Scuba diving duties for David Kimbro’s new Apalachicola Bay study.  Stephanie was nice enough to let us strap a GoPro camera to her head as she dove, allowing us to capture images of the floor of the bay.  The images give an indication as to the severity of the fishery crisis. We will continue following this study. Tomorrow, we begin a series of videos looking at David and Randall Hughes’ NSF funded oyster study. Over the course of that research, they honed many of the techniques they’re using in Apalachicola Bay. The videos will take you into that study, and into the lives of oysters and the animals that make use of the reef.

    This post was written on Sunday, January 20, 2013.
    Stephanie Buhler FSU Coastal & Marine Lab

    Today marks our sixth day out in the Apalachicola Bay surveying the oyster reefs. It could not have been a more beautiful Sunday with the sun shining bright and a crisp-cool breeze as we drove to our first reef. While Hanna and I definitely have our methods down to a routine at this point, today we had the opportunity to learn a “new” technique for grabbing oysters that did not require a single regulator. This morning our boat captain, Shawn Hartsfield, brought his oyster tongs on the boat for us, and we had a blast trying to get his method down for picking up the oysters.  Comically, he did not inform us that the metal tongs alone were about 40 lbs. as he watched our attempts in bringing our bundle of oysters to the bow of the boat. Best back and arm work out I have ever had!

    Bringing the tongs onboard could not have happened on a more relaxed day.  Typically Hanna and I alternate days being the boat tender/diver, but today all of our reefs were extremely shallow and no dive equipment or assistance was needed. A fantastic hassle-free Sunday of work.

    Hanna harvests oysters in shallow water.

    The Apalachicola Bay study is funded by Florida Sea Grant.  In the Grass, On the Reef is Funded by the National Science Foundation.

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    New Study Tackles Apalachicola Oyster Fishery Crisis

    Posted on January 12, 2013 by Rob
    Rob Diaz de Villegas WFSU-TV

    IGOR chip_ predators_NCE 150Last Thursday morning, an oyster boat departed East Point and disappeared into the fog.  Despite the crisis level lack of oysters in Apalachicola Bay, you can still see several boats working for what little is left.  That’s not what this boat was doing, however.  It was carrying two divers working for David Kimbro out of the FSU Coastal and Marine Lab.  A foggy day is appropriate for the first day of a research study. All of the knowledge is out there, just like the St. George Bridge or the island beyond it are out beyond one’s field of vision.  Eventually the sun comes out and everything is revealed.

    They’ll need a little more than the sun to reveal the specifics of the oyster crisis.  It’s easy enough to say that the record low flow of the Apalachicola River combined with harvesting pressure to decimate the reefs.  But the forces at work are a little more nuanced than that.  That’s why newly hired lab technician Stephanie Buhler and graduate student Hanna Garland are plunging into the murky waters of the bay and monitoring up to 20 sites within it for a Florida Seagrant funded project.  The techniques they use will resemble those used by David and his colleague Dr. Randall Hughes in the NSF funded oyster reef study that we have been following over the last two-and-a-half years.  The reefs they’ve worked on for that project were exposed at low tide.  These are not, and so they’ll be diving.  I’m curious to see how it goes in March, when they construct experiment cages on the floor of the bay.

    From left to right- Shawn Hartsfield, their captain; Stephanie Buhler; and Alex Chequer, FSU's Dive Safety Officer. Alex went along on the first day to ensure that all of their dive equipment was operating safely.

    One thing they’ll look at with the cages is the interaction between oysters and one of their predators.  So, alongside the environmental data they’ll accumulate- salinity, availability of plankton and nutrients, oyster recruitment (new generations of oysters growing on the reef)- they will look at how the crown conch is affecting oysters in the bay.  If you think it’s as simple “they’re just eating them all,” there’s a chance you might be right.  But what David and Randall have found is that the fear of being eaten can be even more powerful than just removing an oyster.  For a creature with no brain, oysters exhibit behavior and can be influenced by fear.  In a couple of weeks, we’ll have a series of videos chronicling their pursuit of this idea over the last couple of years to see, in David’s words, “Does it matter?”  It’ll be interesting to see how those dynamics might be at play here, where the higher salinity has invited a larger number of oyster consumers.

    Another way this study is different from the NSF study is that one end result will be a recommendation as to how the resource is managed.  David’s other collaborator on this project, Dr. J. Wilson White, will develop an Integral Projection Model for the reefs.  Essentially they will take the data collected over the next few months and use it to project how the reef will do in different scenarios.  Those scenarios will depend on the amount of water that flows down the Apalachicola River, which in 2012 was at an all time low.  In these drought conditions, water is low across the entire Apalachicola/ Chattahootchee/ Flint basin.  The basin is managed by the Army Corps of Engineers, whose Master Water Control Manual gives priority to stakeholders in the rivers upstream of the Apalachicola.  That Manual is being updated, and Monday is the last day that they are taking public comment on it.  You can lend your voice to that discussion here.

    Have you submitted comments to the Army Corps? Would you mind sharing what you wrote? Add your question or comment.

    In the Grass, On the Reef is funded by the National Science Foundation.

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    The Story of 2012

    Posted on January 3, 2013 by Rob
    Rob Diaz de Villegas WFSU-TV

    I love how David’s story evolves in the segment above.  At first, he concentrates on the oysters and their point of view in the Apalachicola fishery crisis.  It’s the biological approach.  After workshopping his story with Randy Olson, his story takes on a different aspect.  It’s about why he’s getting involved.  It’s the personal approach.  The story is still about David and his colleagues studying the reefs in Apalachicola Bay to determine how best to rehabilitate them, but the hook is different.  It’s one of the stories we’ll be following in what should be another busy year on In the Grass, On the Reef.

    Before we look forward to 2013, though, I wanted to look at the stories that made 2012 our busiest year to date:

    Funded by the NSF

    It took a couple of years, but in July we received a Communicating Research to Public Audiences grant from the National Science Foundation.  The name of that grant is meaningful, and it embodies a background narrative of this project: the work it takes to make an average person care about scientific research.  Researchers know why their work is important, they just don’t always know how to present why it’s interesting.  That’s why we had Dr. Olson come in and put on a workshop for research students (and Randall and David).  So why is Randall and David’s research important?

    Ecology is Economy

    In short, biology affects people’s livelihoods.  The seafood connection is obvious: over 90% of the species that are commercially fished in the Gulf of Mexico spend some part of their life cycles in one of the three estuarine habitats that we follow: oyster reefs, salt marshes, and seagrass beds.  We saw that oysters offer more to the seafood industry than their meat.  And we’re starting to see the effects of a full-scale ecosystem failure on a community (more on that below).  The non-seafood related benefits were surprising to me.  A rugby field sized patch of salt marsh can save $8,000 in storm surge related property damage.  Seagrass beds are the most effective habitat at storing carbon from the atmosphere.  And in a state as reliant on tourism dollars as Florida, you can’t overlook the ecotourism potential of our coastlines.  Last spring, we went down to the St. Marks National Wildlife Refuge when migratory shore birds were making their way through.  The refuge’s vast salt marshes are an all-you-can-eat buffet for those birds, and you have to figure that without healthy rivers and coasts, our state’s multi-billion dollar wildlife watching revenue would be imperiled.

    Away from the coasts, I enjoyed exploring the geology of the Aucilla Sinks and the rare plants of the Saint Joseph Bay State Buffer Preserve.  The Buffer is part of the Apalachicola River basin, and those plants rely on that water just as the oysters in the bay do.  Which brings us to:

    The Apalachicola Crisis

    Apalachicola Oysters on the Half Shell

    Earlier that afternoon, oystermen were demonstrating how few oysters there were in Apalachicola Bay for the Army Corps of Engineers. At a reception later that night at the Apalachicola National Estuarine Research Reserve, they shucked oysters for community members. Despite doubling in price over the last year, there aren't enough oysters to maintain the fishery.

    At this time last year, when we were waiting to hear whether we got the NSF grant, I was looking forward to some of the things we would do.  I knew that, as we explored the economic benefits of oysters, I would end up on an oyster boat.  It would be fun to watch tongs bring up mounds of succulent Apalachicola oysters.  My first time on an oyster boat didn’t exactly go that way.  As the year wore on, I started planning for RiverTrek 2012.  That was every bit as amazing an experience as I expected it to be, but Helen Light’s presentation on the state of the basin that first night underscored everything that happened after.  Crisis drives a lot of media coverage; it attracts viewers.  I don’t think Apalachicola needs crisis to be interesting, though.  I first visited in 2002 while working on WFSU’s Our Town series.  Each Our Town episode first aired during a pledge drive, and Our Town: Apalachicola was far and away the most successful, with over 50 new members pledging their support to our station.  And it was my favorite.  A couple of months after we premiered it at the Dixie Theatre, I came back for my birthday.  My wife and I camped out on St. George Island, went across the bay to get oysters and had drinks at the Gibson Inn.  So this isn’t the story I wanted to tell.  But there is something to be learned from this about oyster reef ecology and our connection to it.

    As David and his crew gear up to investigate more closely, that story will continue here.  Also, Randall and David’s two multi-year, NSF funded studies are concluding.  They put their ideas to the test:  Does the fear of being eaten by large predators have a significant effect on coastal ecosystems and all that they give us?  And, it’s a word we hear a lot, but what role does biodiversity play in the success of a salt marsh and its services?  Stay tuned.

    We want to hear from you! Add your question or comment.

    In the Grass, On the Reef is funded by the National Science Foundation.

    Posted in In the Grass, On the Reef | Leave a comment

    Lab Creations Catalog: Some Holiday Gift Ideas

    Posted on December 17, 2012 by Tanya
    Tanya Rogers FSU Coastal & Marine Lab

    Shopping for gifts this winter? May I suggest one of these unique Kimbro Lab inventions, available for a limited time:

     

    The Aquaclaw:

    Debuted by technician Evan after conveniently breaking his hand before a long stint of marine field work, this dual glove and zip tie hybrid can protect a non-removable cast from seawater and spray, while allowing for finger mobility and dexterity. Lightweight and available in an array of fashionable colors. (Not waterproof when fully submerged.)

     

     

    Decopod Extracto-Bar

    Need to extract stone crabs from their burrows, but worried about losing a finger? Try out Evan’s latest invention for prying stubborn crustaceans from their subterranean homes. Forged of the highest quality rebar available, this tool is optimally angled for maximum crab-removal effectiveness. Highly durable, with antique rust finish and a handle for increased leverage.

     

    Z-Pendant

    These stunning olive-green pendants are artfully fashioned by Tanya from leftover quantities of our favorite marine epoxy. Monofilament chain included. Inquire about her complete line of z-spar jewelry and sculpture. Custom pieces available.

     

    Happy Holidays!

    We hope you enjoyed this last little bit of fun for the year.  When we come back in 2013, Randall Hughes and David Kimbro get serious about animal behavior.  The consequences of oyster, crab, and conch behavior could mean life or death, or life in fear.  And as research begins in the decimated oyster reefs of Apalachicola Bay, they’ll put their theories about predators to the test.

    We want to hear from you! Add your question or comment.

    In the Grass, On the Reef is funded by the National Science Foundation.

    Posted in On the Reef | Leave a comment

    Notes From the Field: Leashing Your Clams

    Posted on December 12, 2012 by Tanya
    Tanya Rogers FSU Coastal & Marine Lab

    IGOR chip_ predators_NCE 150It’s a problem commonly faced by field biologists: You want to put some particular critters out in the field in various places, but how do you keep them from getting swept away or wandering off too far, and how do you ever find them again later to see how they did? Behold the tether! So long as tethers are designed not to interfere too much with the animals’ natural behavior (walking around, burrowing, etc), leashing them to a fixed object is generally a good way to relocate them (provided you study something like crabs or snails and not lions or bald eagles). The other fun benefit of tethering marine invertebrates: you can take them for walks (albeit slow ones).

    I recently conducted an experiment in which I put tethered baby clams (sunray venus and quahog, about 12 mm long) out on Bay Mouth Bar to see how their growth, survivorship, and burial depth was affected by (1) their location on the bar (NE, SW, SE, NW) and (2) the type of habitat the clams were in (sand, shoal grass, turtle grass). I checked on the clams a month later: some were still alive and growing, others were dead with clues indicating their likely cause of demise – gaping shell with no damage (stress), cracked shell (eaten by crab), drill hole in shell (eaten by predatory snail). My preliminary analysis suggests that survivorship and causes of death varied between habitat types. Next I hope to do a similar sort of study with tethered snails on Bay Mouth Bar.

    We want to hear from you! Add your question or comment.

    In the Grass, On the Reef is funded by the National Science Foundation.

    Posted in Notes From the Field, On the Sand | Tagged , , , , | Leave a comment